Page 1 Grid Solutions Motor Protection System Instruction Manual Product version: 7.6x GE publication code: 1601-0108-AF1 (GEK-131005) E83849 LISTED IND.CONT. EQ. 52TL 1601-0108-AF1...
Page 2 The contents of this manual are the property of GE Multilin Inc. This documentation is furnished on license and may not be reproduced in whole or in part without the permission of GE Multilin. The content of this manual is for informational use only and is subject to change without notice.
Page 3: Table Of Contents
Type tests ..........................2-37 2.5.14 Production tests ........................2-37 2.5.15 Approvals ..........................2-38 2.5.16 Maintenance.........................2-38 3 INSTALLATION Unpack and inspect ....................3-1 Panel cutouts ......................3-2 3.2.1 Horizontal units ........................3-2 3.2.2 Vertical units ........................... 3-5 M60 MOTOR PROTECTION SYSTEM – INSTRUCTION MANUAL...
Page 4 3.7.5 Automatic discovery of UR devices................3-62 Connect to the M60 ....................3-63 3.8.1 Connect to the M60 in EnerVista ................3-63 3.8.2 Use Quick Connect via the front panel RS232 port..........3-64 3.8.3 Use Quick Connect via a rear Ethernet port............3-65 Set up CyberSentry and change default password........3-66...
Page 5 Teleprotection ........................5-138 5.3.19 Installation ..........................5-139 Remote resources ....................5-139 5.4.1 Remote resources configuration ................5-139 System setup.......................5-141 5.5.1 AC inputs ..........................5-141 5.5.2 Power system........................5-142 5.5.3 Signal sources........................5-143 5.5.4 Motor.............................5-146 5.5.5 Breakers..........................5-148 5.5.6 Disconnect switch control...................5-153 M60 MOTOR PROTECTION SYSTEM – INSTRUCTION MANUAL...
Page 6 5.11.1 Test mode function ......................5-341 5.11.2 Test mode forcing......................5-342 5.11.3 Force contact inputs ..................... 5-342 5.11.4 Force contact outputs ....................5-343 6 ACTUAL VALUES Actual Values menu ....................6-1 Front panel.......................6-3 Status........................6-4 M60 MOTOR PROTECTION SYSTEM – INSTRUCTION MANUAL...
Page 7 Virtual inputs........................... 7-2 7.1.2 Clear records .......................... 7-2 7.1.3 Set date and time......................... 7-3 7.1.4 Relay maintenance......................7-3 7.1.5 Security ............................. 7-4 Targets menu......................7-5 7.2.1 Target messages ........................7-5 7.2.2 Relay self-tests ........................7-6 M60 MOTOR PROTECTION SYSTEM – INSTRUCTION MANUAL...
Page 8 FlexAnalog items ....................A-1 OPERANDS B RADIUS SERVER RADIUS server configuration ................B-1 CONFIGURATION C COMMAND LINE Command line interface ..................C-1 INTERFACE D MISCELLANEOUS Warranty ......................... D-1 Revision history ..................... D-1 ABBREVIATIONS viii M60 MOTOR PROTECTION SYSTEM – INSTRUCTION MANUAL...
Page 9 TABLE OF CONTENTS INDEX M60 MOTOR PROTECTION SYSTEM – INSTRUCTION MANUAL...
Page 10 TABLE OF CONTENTS M60 MOTOR PROTECTION SYSTEM – INSTRUCTION MANUAL...
Page 11: Introduction
Ensure that the control power applied to the device, the alternating current (AC), and voltage input match the ratings specified on the relay nameplate. Do not apply current or voltage in excess of the specified limits. M60 MOTOR PROTECTION SYSTEM – INSTRUCTION MANUAL...
Page 12: For Further Assistance
Website: http://www.gegridsolutions.com/multilin When contacting GE by e-mail, optionally include a device information file, which is generated in the EnerVista software by clicking the Service Report button. When using the optional graphical front panel, the report instead can be generated by connecting a USB drive to the front panel.
Page 13 CHAPTER 1: INTRODUCTION FOR FURTHER ASSISTANCE Figure 1-1: Generate service report in EnerVista software M60 MOTOR PROTECTION SYSTEM – INSTRUCTION MANUAL...
Page 14 FOR FURTHER ASSISTANCE CHAPTER 1: INTRODUCTION M60 MOTOR PROTECTION SYSTEM – INSTRUCTION MANUAL...
Page 15: Product Description
This chapter outlines the product, order codes, and specifications. 2.1 Product description The M60 Motor Protection System is part of the Universal Relay (UR) series of products. It is a microprocessor-based relay for the protection and management of medium and large motors.
Page 16: Description
IEC 61850, Modbus/TCP, TFTP, and PTP (according to IEEE Std. 1588-2008 or IEC 61588), and it allows access to the relay via any standard web browser (M60 web pages). The IEC 60870-5-104 protocol is supported on the Ethernet port.
Page 17: Security
• Password security — Basic security present by default • EnerVista security — Role-based access to various EnerVista software screens and configuration elements. The feature is present by default in the EnerVista software. M60 MOTOR PROTECTION SYSTEM – INSTRUCTION MANUAL...
Page 18 The M60 supports password entry from a local or remote connection. Local access is defined as any access to settings or commands via the front panel interface. This includes both keypad entry and the through the front panel RS232 port.
Page 19 |--------------- Demand |--------------- User-Programmable LEDs |--------------- User-Programmable Self Tests |--------------- Control Pushbuttons RW |--------------- User-Programmable Pushbuttons |--------------- Flex state Parameters |--------------- User-Definable Displays |--------------- Direct I/O |--------------- Teleprotection |--------------- Installation |---------- System Setup M60 MOTOR PROTECTION SYSTEM – INSTRUCTION MANUAL...
Page 20 Supervisor = RW (default), Administrator = R (default), Administrator = RW (only if Supervisor role is disabled) NA = the permission is not enforced by CyberSentry security CyberSentry user authentication The following types of authentication are supported by CyberSentry to access the UR device: M60 MOTOR PROTECTION SYSTEM – INSTRUCTION MANUAL...
Page 21: Order Codes
The order code is on the product label and indicates the product options applicable. The M60 is available as a 19-inch rack horizontal mount or reduced-size (¾) vertical unit. It consists of the following modules: power supply, CPU, CT/VT, contact input and output, transducer input and output, and inter-relay communications.
Page 22 French display with 4 small and 12 large programmable pushbuttons Russian display with 4 small and 12 large programmable pushbuttons Chinese display with 4 small and 12 large programmable pushbuttons Enhanced front panel with English display Enhanced front panel with French display M60 MOTOR PROTECTION SYSTEM – INSTRUCTION MANUAL...
Page 23 Channel 1 - RS422; Channel 2 - 1300 nm, single-mode, Laser Channel 1 - G.703; Channel 2 - 1300 nm, single-mode Laser G.703, 1 Channel G.703, 2 Channels RS422, 1 Channel 7W RS422, 2 Channels M60 MOTOR PROTECTION SYSTEM – INSTRUCTION MANUAL...
Page 24 ORDER CODES CHAPTER 2: PRODUCT DESCRIPTION Table 2-5: M60 order codes for reduced-size vertical units - * ** - * * * - F ** - H ** - M ** - P/R ** Reduced Size Vertical Mount (see note regarding P/R slot below)
Page 25 Channel 1 - RS422; Channel 2 - 1300 nm, single-mode, Laser 7Q Channel 1 - G.703; Channel 2 - 1300 nm, single-mode Laser G.703, 1 Channel G.703, 2 Channels RS422, 1 Channel 7W RS422, 2 Channels M60 MOTOR PROTECTION SYSTEM – INSTRUCTION MANUAL 2-11...
Page 26: Order Codes With Process Bus Modules
ORDER CODES CHAPTER 2: PRODUCT DESCRIPTION 2.3.2 Order codes with process bus modules Table 2-6: M60 order codes for horizontal units with process bus - * ** - * * * - F ** - H ** - M **...
Page 27 Channel 1 - RS422; Channel 2 - 1300 nm, single-mode, Laser Channel 1 - G.703; Channel 2 - 1300 nm, single-mode Laser G.703, 1 Channel G.703, 2 Channels RS422, 1 Channel 7W RS422, 2 Channels M60 MOTOR PROTECTION SYSTEM – INSTRUCTION MANUAL 2-13...
Page 28 ORDER CODES CHAPTER 2: PRODUCT DESCRIPTION Table 2-7: M60 order codes for reduced-size vertical units with process bus - * ** - * * * - F ** - H ** - M ** - P/R ** Reduced Size Vertical Mount (see note regarding P/R slot below)
Page 29: Replacement Modules
Replacement modules can be ordered separately. When ordering a replacement CPU module or front panel, provide the serial number of your existing unit. Not all replacement modules apply to the M60 relay. The modules specified in the order codes for the M60 are available as replacement modules for the M60.
Page 30 4 DCmA inputs, 4 DCmA outputs (only one 5A module is allowed) 8 RTD inputs 4 RTD inputs, 4 DCmA outputs (only one 5D module is allowed) 4 DCmA inputs, 4 RTD inputs 8 DCmA inputs 2-16 M60 MOTOR PROTECTION SYSTEM – INSTRUCTION MANUAL...
Page 31 4 DCmA inputs, 4 DCmA outputs (only one 5A module is allowed) 8 RTD inputs 4 RTD inputs, 4 DCmA outputs (only one 5D module is allowed) 4 DCmA inputs, 4 RTD inputs 8 DCmA inputs M60 MOTOR PROTECTION SYSTEM – INSTRUCTION MANUAL 2-17...
Page 32: Signal Processing
The UR samples its AC signals at 64 samples per cycle, that is, at 3840 Hz in 60 Hz systems, and 3200 Hz in 50 Hz systems. The sampling rate is dynamically adjusted to the actual system frequency by an accurate and fast frequency tracking system. The A/D converter has the following ranges of AC signals: 2-18 M60 MOTOR PROTECTION SYSTEM – INSTRUCTION MANUAL...
Page 33 Measured analog values and binary signals can be captured in COMTRADE format with sampling rates from 8 to 64 samples per power cycle. Analog values can be captured with Data Logger, allowing much slower rates extended over long period of time. M60 MOTOR PROTECTION SYSTEM – INSTRUCTION MANUAL 2-19...
Page 34: Specifications
STATOR DIFFERENTIAL Pickup: 0.050 to 1.00 pu in steps of 0.01 Slope 1 and 2: 1 to 100% in steps of 1 Break 1: 1.00 to 1.50 pu in steps of 0.01 2-20 M60 MOTOR PROTECTION SYSTEM – INSTRUCTION MANUAL...
Page 35 > 2.0 × CT: ±1.5% of reading > 2.0 × CT rating Curve shapes: IEEE Moderately/Very/Extremely Inverse; IEC (and BS) A/B/C and Short Inverse; GE IAC Inverse, Short/Very/ Extremely Inverse; I t; FlexCurves™ (programmable); Definite Time (0.01 s base curve) Curve multiplier: Time Dial = 0.00 to 600.00 in steps of 0.01...
Page 36 0 to 600.00 s in steps of 0.01 Timer accuracy: ±3% of operate time or ±10 ms, whichever is greater Pickup time: <55 ms at 60 Hz SENSITIVE DIRECTIONAL POWER Measured power: 3-phase, true RMS 2-22 M60 MOTOR PROTECTION SYSTEM – INSTRUCTION MANUAL...
Page 37 Reset delay: 0 to 600.00 s in steps of 0.01 Timer accuracy: ±3% of operate time or ±1/4 cycle (whichever is greater) <30 ms at 1.10 × pickup at 60 Hz Operate time: M60 MOTOR PROTECTION SYSTEM – INSTRUCTION MANUAL 2-23...
Page 38 FlexLogic operand Compensation for auxiliary relays: 0 to 65.535 s in steps of 0.001 Alarm threshold: 0 to 50000 kA -cycle in steps of 1 Fault duration accuracy: 0.25 of a power cycle 2-24 M60 MOTOR PROTECTION SYSTEM – INSTRUCTION MANUAL...
Page 39: User-Programmable Elements
NOT, XOR, OR (2 to 16 inputs), AND (2 to 16 inputs), NOR (2 to 16 inputs), NAND (2 to 16 inputs), latch (reset-dominant), edge detectors, timers Inputs: any logical variable, contact, or virtual input Number of timers: M60 MOTOR PROTECTION SYSTEM – INSTRUCTION MANUAL 2-25...
Page 40 12 on standard front panel 16 on enhanced horizontal front panel 6 on enhanced vertical front panel 16 on graphical front panel (8 physical pushbuttons, 8 graphical interface pushbuttons) Mode: self-reset, latched 2-26 M60 MOTOR PROTECTION SYSTEM – INSTRUCTION MANUAL...
Page 41: Monitoring
Storage capacity: (NN is dependent on memory) 1-second rate: 01 channel for NN days 16 channels for NN days ↓ 60-minute rate: 01 channel for NN days 16 channels for NN days M60 MOTOR PROTECTION SYSTEM – INSTRUCTION MANUAL 2-27...
Page 42: Metering
Relay burden: < 0.2 VA at rated secondary Conversion range: Standard CT: 0.02 to 46 × CT rating RMS symmetrical Sensitive Ground CT module: 0.002 to 4.6 × CT rating RMS symmetrical 2-28 M60 MOTOR PROTECTION SYSTEM – INSTRUCTION MANUAL...
Page 43 ±2°C Isolation: 36 V pk-pk REMOTE RTD INPUTS Wire type: three-wire Sensor type: 100 Ω platinum (DIN 43760), 100 Ω nickel, 120 Ω nickel, 10 Ω copper RTD sensing current: 3 mA M60 MOTOR PROTECTION SYSTEM – INSTRUCTION MANUAL 2-29...
Page 44: Power Supply
88 V at 25 to 100 Hz Maximum AC voltage: 265 V at 25 to 100 Hz Voltage loss hold-up: 200 ms duration at maximum load ALL RANGES Volt withstand: 2 × Highest Nominal Voltage for 10 ms 2-30 M60 MOTOR PROTECTION SYSTEM – INSTRUCTION MANUAL...
Page 45: Outputs
1 to 2.5 mA FORM-A CURRENT MONITOR Threshold current: approx. 80 to 100 mA FORM-C AND CRITICAL FAILURE RELAY Make and carry for 0.2 s: 30 A as per ANSI C37.90 Carry continuous: M60 MOTOR PROTECTION SYSTEM – INSTRUCTION MANUAL 2-31...
Page 46 1.6 A at L/R = 20 ms 0.8 A L/R = 40 ms CONTROL POWER EXTERNAL OUTPUT (For dry contact input) Capacity: 100 mA DC at 48 V DC Isolation: ±300 Vpk DIRECT OUTPUTS Output points: 2-32 M60 MOTOR PROTECTION SYSTEM – INSTRUCTION MANUAL...
Page 47: Communication Protocols
SIMPLE NETWORK TIME PROTOCOL (SNTP) Clock synchronization error: <10 ms (typical) PRECISION TIME PROTOCOL (PTP) PTP IEEE Std 1588 2008 (version 2) Power Profile (PP) per IEEE Standard PC37.238TM2011 Slave-only ordinary clock Peer delay measurement mechanism M60 MOTOR PROTECTION SYSTEM – INSTRUCTION MANUAL 2-33...
Page 48: Inter-Relay Communications
At extreme temperatures these values deviate based on component tolerance. On average, the output power decreases as the temperature is increased by a factor of 1 dB / 5 °C. 2-34 M60 MOTOR PROTECTION SYSTEM – INSTRUCTION MANUAL...
Page 49: Cybersentry Security
1 phasor metering page for each AC Source 5 tabular metering pages with dynamic metering and status event records page with dynamic update product information page settings, actual values, error messages (targets) M60 MOTOR PROTECTION SYSTEM – INSTRUCTION MANUAL 2-35...
Page 50: Environmental
95% (non-condensing) at 55°C (as per IEC60068-2-30 variant 1, 6 days) OTHER Altitude: 2000 m (maximum) Pollution degree: Overvoltage category: Ingress protection: IP20 front, IP10 back Noise: 0 dB 2-36 M60 MOTOR PROTECTION SYSTEM – INSTRUCTION MANUAL...
Page 51: Type Tests
Insulation: class 1, Pollution degree: 2, Over voltage cat II 1 Not tested by third party. 2.5.14 Production tests THERMAL Products go through an environmental test based upon an Accepted Quality Level (AQL) sampling process. M60 MOTOR PROTECTION SYSTEM – INSTRUCTION MANUAL 2-37...
Page 52: Approvals
Normally, cleaning is not required. When dust has accumulated on the front panel display, wipe with a dry cloth. To avoid deterioration of electrolytic capacitors, power up units that are stored in a de-energized state once per year, for one hour continuously. 2-38 M60 MOTOR PROTECTION SYSTEM – INSTRUCTION MANUAL...
Page 53: Installation
For any issues, contact GE as outlined in the For Further Assistance section in chapter 1. Check that you have the latest copy of the M60 Instruction Manual and the UR Family Communications Guide, for the applicable firmware version, at http://www.gegridsolutions.com/multilin/manuals/index.htm...
Page 54: Panel Cutouts
3.2.1 Horizontal units The M60 is available as a 19-inch rack horizontal mount unit with a removable front panel. The front panel can be specified as either standard or enhanced at the time of ordering. The enhanced front panel contains additional user-programmable pushbuttons and LED indicators.
Page 55 CHAPTER 3: INSTALLATION PANEL CUTOUTS Figure 3-1: Horizontal dimensions (enhanced front panel) Figure 3-2: Horizontal mounting (enhanced and graphical front panel) M60 MOTOR PROTECTION SYSTEM – INSTRUCTION MANUAL...
Page 56 PANEL CUTOUTS CHAPTER 3: INSTALLATION Figure 3-3: Horizontal mounting and dimensions (standard front panel) Figure 3-4: Horizontal dimension (graphical front panel) M60 MOTOR PROTECTION SYSTEM – INSTRUCTION MANUAL...
Page 57: Vertical Units
3.2.2 Vertical units The M60 is available as a reduced size (¾) vertical mount unit, with a removable front panel. The front panel can be specified as either standard or enhanced at the time of ordering. The enhanced front panel contains additional user- programmable pushbuttons and LED indicators.
Page 58 PANEL CUTOUTS CHAPTER 3: INSTALLATION Figure 3-5: Vertical dimensions (enhanced front panel) M60 MOTOR PROTECTION SYSTEM – INSTRUCTION MANUAL...
Page 59 CHAPTER 3: INSTALLATION PANEL CUTOUTS Figure 3-6: Vertical and mounting dimensions (standard front panel) For side-mounting M60 devices with the enhanced front panel, see the following documents available on the UR DVD and the GE Grid Solutions website: • GEK-113180 —...
Page 60 PANEL CUTOUTS CHAPTER 3: INSTALLATION For side-mounting M60 devices with the standard front panel, use the following figures. Figure 3-7: Vertical side-mounting installation (standard front panel) M60 MOTOR PROTECTION SYSTEM – INSTRUCTION MANUAL...
Page 61 CHAPTER 3: INSTALLATION PANEL CUTOUTS Figure 3-8: Vertical side-mounting rear dimensions (standard front panel) M60 MOTOR PROTECTION SYSTEM – INSTRUCTION MANUAL...
Page 62: Rear Terminal Layout
Two-slot wide modules take their slot designation from the first slot position (nearest to CPU module), indicated by an arrow marker on the terminal block. The figure shows an example of rear terminal assignments. 3-10 M60 MOTOR PROTECTION SYSTEM – INSTRUCTION MANUAL...
Page 63 Wire connections to these two modules at 13 inch-pounds. Figure 3-10: CPU modules and power supply The following figure shows the optical connectors for CPU modules. Figure 3-11: LC fiber connector (left) and ST fiber connector (right) M60 MOTOR PROTECTION SYSTEM – INSTRUCTION MANUAL 3-11...
Page 64: Wiring
WIRING CHAPTER 3: INSTALLATION 3.3 Wiring 3.3.1 Typical wiring Figure 3-12: Typical wiring diagram (T module shown for CPU) 3-12 M60 MOTOR PROTECTION SYSTEM – INSTRUCTION MANUAL...
Page 65: Dielectric Strength
The power supply module can be ordered for two possible voltage ranges, and the M60 can be ordered with or without a redundant power supply module option. Each range has a dedicated input connection for proper operation. The ranges are as follows (see the Specifications section of chapter 2 for details): •...
Page 66: Ct/Vt Modules
CT input of standard CT/VT modules. However, the phase CT inputs and phase VT inputs are the same as those of regular CT/VT modules. These modules have enhanced diagnostics that can automatically detect CT/VT hardware failure and take the relay out of service. 3-14 M60 MOTOR PROTECTION SYSTEM – INSTRUCTION MANUAL...
Page 67 UR models. Substitute the tilde “~” symbol with the slot position of the module in the following figure. Figure 3-15: CT/VT module wiring M60 MOTOR PROTECTION SYSTEM – INSTRUCTION MANUAL 3-15...
Page 68: Process Bus Modules
3.3.5 Process bus modules The M60 can be ordered with a process bus interface module. The module interfaces with the HardFiber Process Bus System, or HardFiber Brick, allowing bidirectional IEC 61850 fiber optic communications with up to eight HardFiber Bricks.
Page 69 Where a tilde “~” symbol appears, substitute the slot position of the module. Where a number sign “#” appears, substitute the contact number. M60 MOTOR PROTECTION SYSTEM – INSTRUCTION MANUAL 3-17...
Page 70 ~6a, ~6c 2 Inputs Fast Form-C ~7a, ~7c 2 Inputs ~7a, ~7c 2 Inputs ~7a, ~7c 2 Inputs Fast Form-C ~8a, ~8c 2 Inputs ~8a, ~8c 2 Inputs ~8a, ~8c 2 Inputs 3-18 M60 MOTOR PROTECTION SYSTEM – INSTRUCTION MANUAL...
Page 71 ~5a, ~5c 2 Inputs 2 Outputs Solid-State Solid-State ~6a, ~6c 2 Inputs 2 Outputs Not Used Not Used ~7a, ~7c 2 Inputs 2 Outputs Solid-State Solid-State ~8a, ~8c 2 Inputs Not Used M60 MOTOR PROTECTION SYSTEM – INSTRUCTION MANUAL 3-19...
Page 72 WIRING CHAPTER 3: INSTALLATION Figure 3-17: Contact input and output module wiring (Sheet 1 of 2) 3-20 M60 MOTOR PROTECTION SYSTEM – INSTRUCTION MANUAL...
Page 73 CHAPTER 3: INSTALLATION WIRING Figure 3-18: Contact input and output module wiring (Sheet 2 of 2) For proper functionality, observe the polarity shown in the figures for all contact input and output connections. M60 MOTOR PROTECTION SYSTEM – INSTRUCTION MANUAL 3-21...
Page 74 M60 input even when the output is open, if there is a substantial distributed capacitance (represented by C1) present in the wiring between the output and the M60 input and the debounce time setting in the M60 relay is low enough.
Page 75 This operation of contact inputs also can be prevented by using the Auto-Burnish contact inputs or contact inputs with active impedance. Figure 3-21: Contact input connected to a contact output with resistor (R2) across the input M60 MOTOR PROTECTION SYSTEM – INSTRUCTION MANUAL 3-23...
Page 76 Eq. 3-2 The 2 mA current is used in case the contact input is connected across the GE Form A contact output with voltage monitoring. Otherwise use the amperage of the active circuit connected to the contact input when its contact output is open and the voltage across the contact input is third trigger threshold to calculate the resistor value.
Page 77 Consequently, the threshold voltage setting is also defined per group of two contact inputs. The auto-burnish feature can be disabled or enabled using the DIP switches found on each daughter card. There is a DIP switch for each contact, for a total of 16 inputs. M60 MOTOR PROTECTION SYSTEM – INSTRUCTION MANUAL 3-25...
Page 78 Contact inputs susceptible to parasitic capacitance caused by long cable runs affected by switching surges from external circuits can result in inadvertent activation of contact inputs with the external contact open. In this case, GE recommends using the contact I/O module with active impedance circuit.
Page 79: Transducer Inputs And Outputs
The following figure illustrates the transducer module types (5A, 5C, 5D, 5E, and 5F) and channel arrangements that can be ordered for the relay. M60 MOTOR PROTECTION SYSTEM – INSTRUCTION MANUAL 3-27...
Page 80 WIRING CHAPTER 3: INSTALLATION Where a tilde “~” symbol appears, substitute the slot position of the module. Figure 3-25: Transducer input/output module wiring The following figure show how to connect RTDs. 3-28 M60 MOTOR PROTECTION SYSTEM – INSTRUCTION MANUAL...
Page 81: Rs232 Port
EnerVista UR Setup software provided with the relay. Cabling for the RS232 port is shown in the following figure for both 9-pin and 25-pin connectors. The baud rate for this port can be set, with a default of 115200 bps. M60 MOTOR PROTECTION SYSTEM – INSTRUCTION MANUAL 3-29...
Page 82: Cpu Communication Ports
Figure 3-27: RS232 front panel port connection 3.3.9 CPU communication ports 3.3.9.1 Overview In addition to the front panel RS232 port, there is a rear RS485 communication port. The CPU modules do not require a surge ground connection. 3-30 M60 MOTOR PROTECTION SYSTEM – INSTRUCTION MANUAL...
Page 83 This common voltage is implied to be a power supply common. Some systems allow the shield (drain wire) to be used as common wire and to connect directly to the M60 COM terminal (#3); others function correctly only if the common wire is connected to the M60 COM terminal, but insulated from the shield.
Page 84: Irig-B
IRIG-B is a standard time code format that allows stamping of events to be synchronized among connected devices. The IRIG-B code allows time accuracies of up to 100 ns. Using the IRIG-B input, the M60 operates an internal oscillator with 1 µs resolution and accuracy.
Page 85: Direct Input And Output Communications
UR-series relays with the following connections: UR1-Tx to UR2-Rx, UR2-Tx to UR3-Rx, UR3-Tx to UR4-Rx, and UR4-Tx to UR1-Rx. A maximum of 16 URs can be connected in a single ring. M60 MOTOR PROTECTION SYSTEM – INSTRUCTION MANUAL 3-33...
Page 86 UR1-Tx1 to UR2-Rx1, UR2-Tx1 to UR3-Rx1, UR3-Tx1 to UR4-Rx1, and UR4-Tx1 to UR1-Rx1 for the first ring; and UR1-Tx2 to UR4-Rx2, UR4-Tx2 to UR3-Rx2, UR3-Tx2 to UR2-Rx2, and UR2-Tx2 to UR1-Rx2 for the second ring. 3-34 M60 MOTOR PROTECTION SYSTEM – INSTRUCTION MANUAL...
Page 87 Those that apply depend on options purchased. The options are outlined in the Inter-Relay Communications section of the Order Code tables in Chapter 2. All of the fiber modules use ST type connectors. M60 MOTOR PROTECTION SYSTEM – INSTRUCTION MANUAL 3-35...
Page 88: Fiber: Led And Eled Transmitters
The following figure shows the configuration for the 72, 73, 7D, and 7K fiber-laser modules. Figure 3-36: 7x Laser fiber modules The following figure shows configuration for the 2I and 2J fiber-laser modules. 3-36 M60 MOTOR PROTECTION SYSTEM – INSTRUCTION MANUAL...
Page 89: Interface
The following figure shows the typical pin interconnection between two G.703 interfaces. For the actual physical arrangement of these pins, see the Rear Terminal Layout section earlier in this chapter. All pin interconnections are to be maintained for a connection to a multiplexer. M60 MOTOR PROTECTION SYSTEM – INSTRUCTION MANUAL 3-37...
Page 90 Once the clips have cleared the raised edge of the chassis, engage the clips simultaneously. When the clips have locked into position, the module is inserted fully. 3-38 M60 MOTOR PROTECTION SYSTEM – INSTRUCTION MANUAL...
Page 91 (S1 = ON) and set timing mode to loop timing (S5 = OFF and S6 = OFF). The switch settings for the internal and loop timing modes are shown. M60 MOTOR PROTECTION SYSTEM – INSTRUCTION MANUAL 3-39...
Page 92 One source lies on the G.703 line side of the interface while the other lies on the differential Manchester side of the interface. Figure 3-43: G.703 dual loopback mode 3-40 M60 MOTOR PROTECTION SYSTEM – INSTRUCTION MANUAL...
Page 93: Rs422 Interface
(data module 1) connects to the clock inputs of the UR RS422 interface in the usual way. In M60 MOTOR PROTECTION SYSTEM – INSTRUCTION MANUAL 3-41...
Page 94 Figure 3-46: Timing configuration for RS422 two-channel, three-terminal application Data module 1 provides timing to the M60 RS422 interface via the ST(A) and ST(B) outputs. Data module 1 also provides timing to data module 2 TT(A) and TT(B) inputs via the ST(A) and AT(B) outputs. The data module pin numbers have been omitted in the figure because they vary by manufacturer.
Page 95: Rs422 And Fiber Interface
For the direct fiber channel, address power budget issues properly. When using a laser interface, attenuators can be necessary to ensure that you do not exceed maximum optical input power to the receiver. Figure 3-48: RS422 and fiber interface connection M60 MOTOR PROTECTION SYSTEM – INSTRUCTION MANUAL 3-43...
Page 96: And Fiber Interface
Connection — as per all fiber optic connections, a Tx to Rx connection is required The UR-series C37.94 communication module can be connected directly to any compliant digital multiplexer that supports the IEEE C37.94 standard. The figure shows the concept. 3-44 M60 MOTOR PROTECTION SYSTEM – INSTRUCTION MANUAL...
Page 97 5.60. For customers using firmware release 5.60 and higher, the module can be identified with "Rev D" printed on the module and is to be used on all ends of M60 communication for two and three terminal applications.
Page 98 When the clips have locked into position, the module is inserted fully. Figure 3-53: IEEE C37.94 timing selection switch setting Modules shipped since January 2012 have status LEDs that indicate the status of the DIP switches, as shown in the following figure. 3-46 M60 MOTOR PROTECTION SYSTEM – INSTRUCTION MANUAL...
Page 99: C37.94Sm Interface
Fiber optic cable length — Up to 11.4 km • Fiber optic connector — Type ST • Wavelength — 1300 ±40 nm • Connection — As per all fiber optic connections, a Tx to Rx connection is required M60 MOTOR PROTECTION SYSTEM – INSTRUCTION MANUAL 3-47...
Page 100 5.60. For customers using firmware release 5.60 and higher, the module can be identified with "Rev D" printed on the module and is to be used on all ends of M60 communication for two and three terminal applications.
Page 101 When the clips have locked into position, the module is inserted fully. Figure 3-56: C37.94SM timing selection switch setting Modules shipped since January 2012 have status LEDs that indicate the status of the DIP switches, as shown in the following figure. M60 MOTOR PROTECTION SYSTEM – INSTRUCTION MANUAL 3-49...
Page 102: Activate Relay
Press the right arrow until the message displays. MESSAGE SECURITY Press the down arrow until the message displays. MESSAGE INSTALLATION Press the right arrow until the Not Programmed message displays. MESSAGE RELAY SETTINGS: 3-50 M60 MOTOR PROTECTION SYSTEM – INSTRUCTION MANUAL...
Page 103: Install Software
To communicate via the RS232 port, use a standard straight-through serial cable. Connect the DB-9 male end to the relay and the DB-9 or DB-25 female end to the computer COM2 port as described in the CPU Communication Ports section earlier in this chapter. M60 MOTOR PROTECTION SYSTEM – INSTRUCTION MANUAL 3-51...
Page 104: System Requirements
This device (catalog number F485) connects to the computer using a straight-through serial cable. A shielded twisted-pair (20, 22, or 24 AWG) connects the F485 converter to the M60 rear communications port. The converter terminals (+, –, GND) are connected to the M60 communication module (+, –, COM) terminals. See the CPU Communication Ports section in chapter 3 for details.
Page 105: Install Software
Click the Next button to begin the installation. The files are installed in the directory indicated, and the installation program automatically creates icons and adds an entry to the Windows start menu. M60 MOTOR PROTECTION SYSTEM – INSTRUCTION MANUAL 3-53...
Page 106: Add Device To Software
3.7 Add device to software You connect remotely to the M60 through the rear RS485 or Ethernet port with a computer running the EnerVista UR Setup software. The M60 also can be accessed locally with a computer through the front panel RS232 port or the rear Ethernet port using the Quick Connect feature.
Page 107 From the Windows desktop, right-click the My Network Places icon and select Properties to open the network connections window. Or in Windows 7, access the Network and Sharing Center in the Control Panel. Right-click the Local Area Connection icon and select Properties. M60 MOTOR PROTECTION SYSTEM – INSTRUCTION MANUAL 3-55...
Page 108 Select the Internet Protocol (TCP/IP) item from the list, and click the Properties button. Click the “Use the following IP address” box. Enter an IP address with the first three numbers the same as the IP address of the M60 relay and the last number different (in this example, 1.1.1.2).
Page 109 Minimum = 0ms, Maximum = 0ms, Average = 0 ms Pinging 1.1.1.1 with 32 bytes of data: verify the physical connection between the M60 and the computer, and double-check the programmed IP address in setting, then repeat step 2. Product Setup  Communications  Network  IP Address...
Page 110 Click the Quick Connect button to open the window. Select the Ethernet interface and enter the IP address assigned to the M60, then click the Connect button. The EnerVista UR Setup software creates a site named “Quick Connect” with a corresponding device also named “Quick Connect”...
Page 111: Configure Serial Connection
For the RS232 connection, a computer with an RS232 port and a serial cable are required. To use the RS485 port at the back of the relay, a GE Grid Solutions F485 converter (or compatible RS232-to-RS485 converter) is required. See the F485 instruction manual for details.
Page 112: Configure Ethernet Connection
SEL-2032. This option enables display of a terminal window to allow interaction with the other device. 11. Click the Read Order Code button to connect to the M60 and upload the order code to the software. If a communications error occurs, ensure that the EnerVista software serial communications values entered in the previous step correspond to the relay setting values, and also ensure that the same IP address is not assigned to multiple M60 ports.
Page 113 12. If using a gateway to connect to the device, select Yes from the drop-down list. 13. Click the Read Order Code button to connect to the M60 device and upload the order code. If the device was entered already, a message displays "Device ’x’ is also using IP address.." If a communications error occurs, ensure that the values entered in the previous steps correspond to the relay setting values, and also ensure that the same IP address is not assigned to multiple M60 ports.
Page 114: Configure Modem Connection
ADD DEVICE TO SOFTWARE CHAPTER 3: INSTALLATION The device has been configured for Ethernet communications. Proceed to the Connect to the M60 section to begin communications. 3.7.4 Configure modem connection A modem connection allows a computer to communicate with a UR device over phone lines.
Page 115: Connect To The M60
When unable to connect because of an "ACCESS VIOLATION," access Device Setup and refresh the order code for the device. When unable to connect, ensure that the same IP address is not assigned to multiple M60 ports, for example under Settings > Product Setup > Communications > Network.
Page 116: Use Quick Connect Via The Front Panel Rs232 Port
Connect a nine-pin to nine-pin RS232 serial cable to the computer and the front panel RS232 port. Verify that the latest version of the EnerVista UR Setup software is installed (available from the GE EnerVista DVD or online from http://www.gegridsolutions.com/multilin). See the software installation section if not already installed.
Page 117: Use Quick Connect Via A Rear Ethernet Port
Connect" and displays them in the Online Window. Expand the sections to view data directly from the M60 device. Use the Device Setup button to change the site name. Each time that the EnerVista software is initialized, click the Quick Connect button to establish direct communications to the M60.
Page 118: Set Up Cybersentry And Change Default Password
IID — Instantiated IED capability description file — Actual settings on UR • CID — Configured IED description file — Settings sent to the UR (may or may not be actual settings) The import is done in the Offline Window area. 3-66 M60 MOTOR PROTECTION SYSTEM – INSTRUCTION MANUAL...
Page 119: Connect To D400 Gateway
3.11 Connect to D400 gateway A GE Multilin D400 Substation Gateway can be used to collect data from UR devices in a local area network (LAN). It collects metering, status, event, and fault report data from serial or LAN-based intelligent substation devices, and it pre-processes the data.
Page 120: Setting Files
These are the configuration/settings files in the IEC 61850 SCL/IID format. The ur.iid file is saved with a "_YYMMDDhhmmss" retrieval time stamp, for example ur_170525183124.iid. It is stored in the D400 folder system using the UR site and device name. 3-68 M60 MOTOR PROTECTION SYSTEM – INSTRUCTION MANUAL...
Page 121: Interfaces
The EnerVista UR Setup software is provided with every M60. This chapter outlines the EnerVista software interface features. The EnerVista UR Setup Help File also provides details for getting started and using the software interface.
Page 122: Event Viewing
IP Address IP Subnet Mask IP Routing When a settings file is loaded to a M60 that is in-service, the following sequence occurs: The M60 takes itself out of service. The M60 issues a UNIT NOT PROGRAMMED major self-test error.
Page 123: File Support
Site list / online window area Settings list / offline window area Software windows, with common toolbar Settings file data view windows, with common toolbar Workspace area with data view tabs Status bar 10. Quick action hot links M60 MOTOR PROTECTION SYSTEM – INSTRUCTION MANUAL...
Page 124: Protection Summary Window
4.1.6 Protection summary window The Protection Summary is a graphical user interface to manage elements, such as enabling and disabling them. Access it under Settings > Protection Summary. See the Settings chapter for information on use. M60 MOTOR PROTECTION SYSTEM – INSTRUCTION MANUAL...
Page 125: Settings Templates
Right-click the selected device or settings file and select the Template Mode > Create Template option. The settings file template is now enabled and the file menus displayed in light blue. A message displays. The settings file is now in template editing mode. M60 MOTOR PROTECTION SYSTEM – INSTRUCTION MANUAL...
Page 126 Figure 4-4: Settings template with all settings specified as locked Specify the settings to make viewable by clicking them. A setting available to view is displayed against a yellow background. M60 MOTOR PROTECTION SYSTEM – INSTRUCTION MANUAL...
Page 127 To display only the settings available for editing: Select an installed device or a settings file from the left menu of the EnerVista UR Setup window. Apply the template by selecting the Template Mode > View In Template Mode option. M60 MOTOR PROTECTION SYSTEM – INSTRUCTION MANUAL...
Page 128 Once the template has been applied, users are limited to edit the settings specified by the template, but all settings are shown. The effect of applying the template to the phase time overcurrent settings is shown as follows. M60 MOTOR PROTECTION SYSTEM – INSTRUCTION MANUAL...
Page 129: Secure And Lock Flexlogic Equations
4.1.8.1 Lock FlexLogic equations To lock individual entries of a FlexLogic equation: Right-click the settings file or online device and select the Template Mode > Create Template item to enable the settings template feature. M60 MOTOR PROTECTION SYSTEM – INSTRUCTION MANUAL...
Page 130 The effect of applying the template to the FlexLogic entries is shown here. Figure 4-10: Locking FlexLogic entries through settings templates The FlexLogic entries are also shown as locked in the graphical view and on the front panel display. 4-10 M60 MOTOR PROTECTION SYSTEM – INSTRUCTION MANUAL...
Page 131 Right-click the setting file in the offline window area and select the Edit Device Properties item. The window opens. Figure 4-12: Settings file properties window M60 MOTOR PROTECTION SYSTEM – INSTRUCTION MANUAL 4-11...
Page 132: Settings File Traceability
With respect to the figure, the traceability feature is used as follows. The transfer date of a settings file written to a M60 is logged in the relay and can be viewed in the EnerVista software or the front panel display. Likewise, the transfer date of a settings file saved to a local computer is logged in the EnerVista software.
Page 133 4.1.9.2 Online device traceability information The M60 serial number and file transfer date are available for an online device through the actual values. Select the Actual Values > Product Info > Model Information menu item within the EnerVista online window as shown in the example.
Page 134: Front Panel Interface
The enhanced front panel consists of LED panels, an RS232 port, keypad, LCD display, control pushbuttons, and optional user-programmable pushbuttons. The front panel is hinged to allow access to removable modules inside the chassis. 4-14 M60 MOTOR PROTECTION SYSTEM – INSTRUCTION MANUAL...
Page 135 The standard front panel can be horizontal or vertical. The following figure shows the horizontal front panel. Figure 4-18: Standard horizontal front panel The following figure shows the vertical front panel for relays ordered with the vertical option. M60 MOTOR PROTECTION SYSTEM – INSTRUCTION MANUAL 4-15...
Page 136 The USB port is the square type B. User-programmable pushbuttons 9 to 16 can be programmed among the 10 pushbuttons on the left and right sides of the display. 4-16 M60 MOTOR PROTECTION SYSTEM – INSTRUCTION MANUAL...
Page 137: Front Panel Display
The front panel can be viewed and used in the EnerVista software, for example to view an error message displayed on the front panel or the LEDs. To view the front panel in EnerVista software: Click Actual Values > Front Panel, then any option. M60 MOTOR PROTECTION SYSTEM – INSTRUCTION MANUAL 4-17...
Page 138 The footer dynamically labels the Tab, or control, pushbuttons immediately below. Page content displays between the header and footer. The pages are arranged for navigation in a hierarchical structure similar to that used for the enhanced and standard front panels. 4-18 M60 MOTOR PROTECTION SYSTEM – INSTRUCTION MANUAL...
Page 139 Active targets symbol. View error messages by pressing the Menu Tab pushbutton, then accessing the TARGETS menu. M60 MOTOR PROTECTION SYSTEM – INSTRUCTION MANUAL 4-19...
Page 140 Factory default names are SLD 1, SLD 2, and so on. Pages that have no configured content have a blank Tab pushbutton label, and the Tab pushbutton does nothing. The label for the current page has a blue background. 4-20 M60 MOTOR PROTECTION SYSTEM – INSTRUCTION MANUAL...
Page 141 Single-line diagram example The following example outlines how to create a circuit breaker diagram, then how to close the second circuit breaker. The figure shows six switches, two breakers, feeder, and ground. M60 MOTOR PROTECTION SYSTEM – INSTRUCTION MANUAL 4-21...
Page 142 Line Diagram Editor. Add the four switches for the top line by clicking the GE switch symbol in the toolbar, then clicking in the window. If the UR device is not online, the software attempts to connect. Double-click to edit properties. Rotate switches SW569 and SW5682 to 270 degrees.
Page 143 Add the two lower switches. Leave rotation at 0 degrees. Add the breakers by clicking the GE breaker symbol in the toolbar, then clicking in the window. Double-click to edit properties, rotating 90 degrees and setting the color to red (open).
Page 144 Load — Opens single-line diagram files, which replaces all five windows with that in the file To save drawings as a separate file, click File > Save As. The file is saved in the .mif format. 4-24 M60 MOTOR PROTECTION SYSTEM – INSTRUCTION MANUAL...
Page 145 Up to 32 static symbols can be used per single-line diagram. To add a symbol, click it in the toolbox, then click in the window. Double-click the symbol to open its properties window to set orientation. M60 MOTOR PROTECTION SYSTEM – INSTRUCTION MANUAL 4-25...
Page 146 Each breaker and each disconnect can be configured to use the UR-style symbols, IEC symbols, or simple square/slash symbols as shown in the following figure. The symbols assume horizontal symbol orientation, red - closed color, and green - open scheme. With vertical orientation, they are rotated 90 degrees. 4-26 M60 MOTOR PROTECTION SYSTEM – INSTRUCTION MANUAL...
Page 147 (horizontal or vertical), color scheme (red - closed, or red - open), and assigned side button (if any). If the selected breaker or disconnect element M60 MOTOR PROTECTION SYSTEM – INSTRUCTION MANUAL 4-27...
Page 148 A question mark displays in a symbol on the graphical front panel when status is bad. The question mark does not rotate with orientation. Figure 4-34: Symbols when status is bad The following figures show the orientation available for the static components. The default position is 0 degrees. 4-28 M60 MOTOR PROTECTION SYSTEM – INSTRUCTION MANUAL...
Page 149 CHAPTER 4: INTERFACES FRONT PANEL INTERFACE Figure 4-35: Single-line diagram static symbol orientation (sheet 1 of 2) M60 MOTOR PROTECTION SYSTEM – INSTRUCTION MANUAL 4-29...
Page 150 User-programmable pushbuttons 9 to 16 can be programmed among the 10 pushbuttons on the left and right sides of the screen display. They show dynamically and provide a means to perform the same control as a hardware user- programmable pushbutton. 4-30 M60 MOTOR PROTECTION SYSTEM – INSTRUCTION MANUAL...
Page 151 To add a metering component, click the M symbol in the toolbox, then click in the window. Drag it to its final location. Double-click it to open the properties window. The figure shows the properties that can be edited. M60 MOTOR PROTECTION SYSTEM – INSTRUCTION MANUAL 4-31...
Page 152 Self Reset, so the alarm displays in a solid color. The blue alarm type is Acknowledgeable, so the alarm flashes until it is acknowledged, for example by navigating with the arrow keys and pressing the ENTER button. The alarm then remains blue until the trigger condition is eliminated. 4-32 M60 MOTOR PROTECTION SYSTEM – INSTRUCTION MANUAL...
Page 153 Alarm types of each window can be configured as Self Reset, Latched, or Acknowledgeable. In Self Reset mode, the window lighting follows the state of the configured FlexLogic operand. The self-reset mode alarm sequence conforms to ISA-18.1-1979 (R2004) standard type A 4 5 6. M60 MOTOR PROTECTION SYSTEM – INSTRUCTION MANUAL 4-33...
Page 154 In Acknowledgeable mode, both Off to On and On to Off state changes in the configured operand cause the background to flash; the window must be acknowledged/reset to cancel flashing. This mode conforms to ISA-18.1-1979 (R2004) standard type R-6. 4-34 M60 MOTOR PROTECTION SYSTEM – INSTRUCTION MANUAL...
Page 155 The last window is not configured and displays blank/grey. In order for the Ethernet and battery alarms to work, the corresponding self-test alarms have been enabled under Settings > Product Setup > User-Programmable Self Tests (not shown). M60 MOTOR PROTECTION SYSTEM – INSTRUCTION MANUAL 4-35...
Page 156 Five tabular metering pages can be configured, while there can be a phasor page for each configured AC source. They display on the graphical front panel using the Metering Tab pushbutton. The path to the editor is Settings > Product Setup > Graphical Panel > Metering Editor. 4-36 M60 MOTOR PROTECTION SYSTEM – INSTRUCTION MANUAL...
Page 157 Content to display is configured with the cell lines. The content can be actual values, a status indicator, or text. • Actual value — Select from the FlexAnalogs applicable to the M60, where a FlexAnalog is an analog parameter •...
Page 158: Front Panel Navigation Keys
The decimal key initiates and advances to the next character in text edit mode or enters a decimal point. key can be pressed at any time for context-sensitive help messages. HELP 4-38 M60 MOTOR PROTECTION SYSTEM – INSTRUCTION MANUAL...
Page 159 Tab pushbutton — Five pushbuttons under the display. They navigate through the page hierarchy, and on some pages activate other actions. The display footer dynamically labels the page or action that is activated by the tab pushbutton. M60 MOTOR PROTECTION SYSTEM – INSTRUCTION MANUAL 4-39...
Page 160: Led Indicators
“Enabled” or “Latched.” If a protection element target setting is “Enabled,” then the corresponding event-cause LEDs remain on as long as the operand associated with the element remains asserted. If a 4-40 M60 MOTOR PROTECTION SYSTEM – INSTRUCTION MANUAL...
Page 161 Support for applying a customized label beside every LED is provided. Default labels are shipped in the label package of every M60, together with custom templates. The default labels can be replaced by user-printed labels. User customization of LED operation is of maximum benefit in installations where languages other than English are used to communicate with operators.
Page 162 Figure 4-49: LED panels 2 and 3 (index template) Default labels for LED panel 2 The default labels are intended to represent the following: • GROUP 1...6 — The illuminated GROUP is the active settings group 4-42 M60 MOTOR PROTECTION SYSTEM – INSTRUCTION MANUAL...
Page 163 TRIP — Indicates that the selected FlexLogic operand serving as a trip output has operated. This indicator latches; initiate the reset command to reset the latch. • ALARM — Indicates that the selected FlexLogic operand serving as an alarm output has operated M60 MOTOR PROTECTION SYSTEM – INSTRUCTION MANUAL 4-43...
Page 164: Front Panel Labelling
NEUTRAL/GROUND — LED 14 — Indicates that neutral or ground was involved 4.2.5 Front panel labelling 4.2.5.1 Enhanced front panel The following procedure requires these pre-requisites: • The UR front panel label cutout sheet (GE part number 1006-0047) has been downloaded from http://www.gegridsolutions.com/products/support/ur/URLEDenhanced.doc and printed • Small-bladed knife To create custom LED and pushbuttons labels for the enhanced front panel: Start the EnerVista UR Setup software.
Page 165 LED labels. Use the tool with the printed side containing the GE part number facing the user. The label package shipped with every M60 contains the three default labels, the custom label template sheet, and the label removal tool.
Page 166 Bend the tab at the center of the tool tail as shown. To remove the LED labels from the M60 front panel and insert the custom labels: Use the knife to lift the LED label and slide the label tool underneath. Ensure that the bent tabs are pointing away from the relay.
Page 167 Slide the new LED label inside the pocket until the text is properly aligned with the LEDs, as shown. To remove the user-programmable pushbutton labels from the M60 front panel and insert the custom labels: Use the knife to lift the pushbutton label and slide the tail of the label tool underneath, as shown. Ensure that the bent M60 MOTOR PROTECTION SYSTEM –...
Page 168 Remove the tool and attached user-programmable pushbutton label. Slide the new user-programmable pushbutton label inside the pocket until the text is properly aligned with the 4-48 M60 MOTOR PROTECTION SYSTEM – INSTRUCTION MANUAL...
Page 169 To create LED and pushbutton labels for a standard front panel: In the EnerVista software, if the M60 is not already listed in the Offline Window area, add it by right-clicking it and selecting the Add Device to Offline Window option.
Page 170 4.2.5.3 Graphical front panel The M60 includes software for labelling the LEDs and pushbuttons on the graphical front panel and a sticker sheet with pre-printed and blank labels. The pre-printed labels are on the top-left of the template sheet, and the blank labels are on the bottom-right.
Page 171: Menu Navigation
Use the down, right, left, and up arrows to navigate the menu. The up and down arrow keys move within a group of headers, sub-headers, setting values, or actual MESSAGE M60 MOTOR PROTECTION SYSTEM – INSTRUCTION MANUAL 4-51...
Page 172 The Page Up and Page Down Tab pushbuttons also navigate through the list. When there is only a single page of options, they jump to the first and last entries. The options displayed depend on order code. 4-52 M60 MOTOR PROTECTION SYSTEM – INSTRUCTION MANUAL...
Page 173: Change Settings
This flash message momentarily appears as confirmation of the storing process. Numerical values that contain decimal places are rounded-off if more decimal place digits are entered than specified by the step value. M60 MOTOR PROTECTION SYSTEM – INSTRUCTION MANUAL 4-53...
Page 174 An example is a confirmation message upon saving settings. This setting specifies how long to display the message. Press the Menu pushbutton to display the main menu. 4-54 M60 MOTOR PROTECTION SYSTEM – INSTRUCTION MANUAL...
Page 175 Figure 4-56: Main menu Use the Up or Down pushbutton to select SETTINGS, then press the Right or ENTER pushbutton. Figure 4-57: Settings menu With PRODUCT SETUP selected, press the Right or ENTER pushbutton. M60 MOTOR PROTECTION SYSTEM – INSTRUCTION MANUAL 4-55...
Page 176 As the FLASH MESSAGE TIME setting accepts a numerical value, a keypad displays. The time is to be changed to 4.0 seconds. 4-56 M60 MOTOR PROTECTION SYSTEM – INSTRUCTION MANUAL...
Page 177 The shift key (up arrow on keyboard) is green upon activation, while the keyboard letters switch to upper case. The globe key (shown greyed-out) toggles the keyboard language between English and another display language selected, for example between English and French. M60 MOTOR PROTECTION SYSTEM – INSTRUCTION MANUAL 4-57...
Page 178: View Actual Values
Each phasor page has a name, which consists of the value of the SOURCE # NAME setting appended with " Phasors." Phasor pages that have no configured CTs or VTs do not have a Tab pushbutton, and phasor pages that have no configured cells cannot be displayed. 4-58 M60 MOTOR PROTECTION SYSTEM – INSTRUCTION MANUAL...
Page 179: Breaker Control
4.2.9 Breaker control The M60 can interface with associated circuit breakers. In many cases the application monitors the state of the breaker, that can be presented on front panel LEDs, along with a breaker trouble indication. Breaker operations can be manually initiated from the front panel keypad or automatically initiated from a FlexLogic operand.
Page 180: Change Passwords
The information in this section refers to password security. For information on how to set the password for the first time or change CyberSentry passwords, see the previous chapter or the Settings > Product Setup > Security > CyberSentry section in the next chapter. 4-60 M60 MOTOR PROTECTION SYSTEM – INSTRUCTION MANUAL...
Page 181 When entering a settings or command password via EnerVista or any serial interface, the user must enter the corresponding connection password. If the connection is to the back of the M60, the remote password must be used. If the connection is to the RS232 port of the front panel, the local password must be used.
Page 182: Logic Diagrams
By default, when an incorrect Command or Setting password has been entered via the front panel three times within five minutes, the FlexLogic operand is set to “On” and the M60 does not allow settings or command level LOCAL ACCESS DENIED access via the front panel for five minutes.
Page 183: Flexlogic Design Using Engineer
Works with all UR firmware versions The figure shows an example where several inputs are used to trigger an output. With the OR function, any one of the inputs can trigger the output. M60 MOTOR PROTECTION SYSTEM – INSTRUCTION MANUAL 4-63...
Page 184 This section explains how to use Engineer. It outlines the following topics: • Design logic • Send file to and from device • Monitor logic • View front panel • Generate connectivity report • Preferences 4-64 M60 MOTOR PROTECTION SYSTEM – INSTRUCTION MANUAL...
Page 185: Design Logic
Preparation — Under Settings > Inputs/Outputs > Virtual Outputs, virtual outputs 3 and 4 are named DLTrigger Top logic — Seven-minute timer trigger Bottom logic — Turn on LED 9 for 10 seconds when the trigger starts M60 MOTOR PROTECTION SYSTEM – INSTRUCTION MANUAL 4-65...
Page 186 This procedure uses input / output logic as an example. To create a logic diagram: In the Offline Window area, access Engineer for the device, then Logic Designer. If the device is not listed, right-click 4-66 M60 MOTOR PROTECTION SYSTEM – INSTRUCTION MANUAL...
Page 187 Add the input blocks to the logic diagram. For example, click the I/O Tokens tab on the right, click the Input element, then click in the logic sheet to add it. Or drag-and-drop it. M60 MOTOR PROTECTION SYSTEM – INSTRUCTION MANUAL 4-67...
Page 188 Line option. The cursor needs to be at the connection point to end the line, not elsewhere on the block. Note that the outline color is no longer red on the blocks. 4-68 M60 MOTOR PROTECTION SYSTEM – INSTRUCTION MANUAL...
Page 189 The warning "input using disabled feature" means that input needs to be enabled. Double-click the block, click the View Associated Screen button, enable the setting, save, and recompile. The output and messages are explained in the next section. M60 MOTOR PROTECTION SYSTEM – INSTRUCTION MANUAL 4-69...
Page 190 IEC 61850 panel and thereby become synchronized. The CID file and the IID file (depending on the preference 'Do not update IID file when updating SCL files') are updated. If the CID file is not already there, it is generated. 4-70 M60 MOTOR PROTECTION SYSTEM – INSTRUCTION MANUAL...
Page 191 FLEXLOGIC DESIGN USING ENGINEER The location of these files is C:\ProgramData\GE Power Management\urpc, for example, in the Offline and Online folders. Any FlexLogic equations entered in the Offline Window area are erased. The logic drawn in the Logic Designer window in Engineer in the Offline Window area remain.
Page 192 Click the Ok button to save and exit from the window. In the logic diagram, select an element, then click in the drawing area to add it, click again to add a second box, and so on. 4-72 M60 MOTOR PROTECTION SYSTEM – INSTRUCTION MANUAL...
Page 193 Optimization Summary. Changes also display when the FlexLogic Equation Editor is accessed. The logic diagram does not change. In the example shown, no lines were saved to free up space. Figure 4-81: Code optimization results M60 MOTOR PROTECTION SYSTEM – INSTRUCTION MANUAL 4-73...
Page 194 Type in the second text string box, or select any of the 32 previous searches from the drop-down list. Click the Search button. Any results display. The search applies to all tabs, not just the active tab. Double-click a search result to view the item. 4-74 M60 MOTOR PROTECTION SYSTEM – INSTRUCTION MANUAL...
Page 195: Send File To And From Device
When a window opens, select the device to which you want to send the file, then click the Send button and confirm. The order codes must match. The file is sent to the live device. Any errors can be viewed in the log file at the prompt. M60 MOTOR PROTECTION SYSTEM – INSTRUCTION MANUAL 4-75...
Page 196: Monitor Logic
(green box outline). In this case, the battery is weak and needs to be replaced. This can be viewed as the Replace Battery message on the front panel of the device and in the EnerVista software under Actual Values > Front Panel > Front Panel or Display/Keypad. 4-76 M60 MOTOR PROTECTION SYSTEM – INSTRUCTION MANUAL...
Page 197: View Front Panel And Print Labels
To save the report and labels, click File > Save As, enter a file name, and select the FPR, JPG, or PDF format. Use the instructions in the second tab of the window to add the labels to the physical device. M60 MOTOR PROTECTION SYSTEM – INSTRUCTION MANUAL 4-77...
Page 198: Generate Connectivity Report
View > Toolbar > Advanced Actions — Active when in Logic Designer. Toggles a toolbar to nudge, rotate, flip, or change the order of an element. View > Show Unused Pins — Enable to display unconnected pins. Disable to eliminate unconnected pins from the view, for example when printing. 4-78 M60 MOTOR PROTECTION SYSTEM – INSTRUCTION MANUAL...
Page 199 File Information The text entered here displays at the bottom right of a diagram when printing, provided that the Show Title Block option is enabled. Note the option to change the logo from the GE logo to your company logo. Display The panel sets how the element boxes display.
Page 200 The software displays the color specified when an element is on. There is no color when the element is off. The software displays another color when the status cannot be determined and is unknown. 4-80 M60 MOTOR PROTECTION SYSTEM – INSTRUCTION MANUAL...
Page 201 Options display for filtering, such as recording timing for Virtual Inputs and Outputs, but not Communications Status. 4.4.6.4 COMTRADE waveforms Waveform files are viewable in the EnerVista software. The preferences are unrelated to Engineer and are outlined in the UR Family Communications Guide. M60 MOTOR PROTECTION SYSTEM – INSTRUCTION MANUAL 4-81...
Page 202: Toolbars
When you re-launch the EnerVista software, communication is on by default. 4.4.7.2 Token Toolbox Drawing Tools Draw a line. Click and drag to draw. Draw multiple joined lines. Click and drag for each line. Double-click to finish. 4-82 M60 MOTOR PROTECTION SYSTEM – INSTRUCTION MANUAL...
Page 203 Remote inputs from other devices Input from another UR device. Teleprotection inputs/outputs and direct inputs/outputs are mutually exclusive and cannot be used simultaneously. Teleprotection inputs/outputs and direct inputs/outputs are mutually exclusive and cannot be used simultaneously. M60 MOTOR PROTECTION SYSTEM – INSTRUCTION MANUAL 4-83...
Page 204 Tag-In can is used to reference an existing Tag-Out. It joins another diagram to a previous diagram. Boolean Tokens These symbols are used to create FlexLogic Equations. Use them as intermediate logic for the Virtual Output equations. The display can vary from that shown here. 4-84 M60 MOTOR PROTECTION SYSTEM – INSTRUCTION MANUAL...
Page 205 Place a positive one shot and a negative one shot symbol in the Logic Designer diagram Place a timer in the Logic Designer diagram Elements These blocks configure properties of the element or use element operands as input to FlexLogic equations. M60 MOTOR PROTECTION SYSTEM – INSTRUCTION MANUAL 4-85...
Page 206 Set the width of the selected components to the same width as the reference component Same Height Set the height of the selected components to the same height as the reference component 4-86 M60 MOTOR PROTECTION SYSTEM – INSTRUCTION MANUAL...
Page 207 Front, Back Moves current components to the absolute front or back of all viewable layers Forward, Backward Moves current components on layer higher or lower than its original layer hierarchy M60 MOTOR PROTECTION SYSTEM – INSTRUCTION MANUAL 4-87...
Page 208 FLEXLOGIC DESIGN USING ENGINEER CHAPTER 4: INTERFACES 4-88 M60 MOTOR PROTECTION SYSTEM – INSTRUCTION MANUAL...
Page 209: Settings
 REAL TIME See page 5-109   CLOCK  USER-PROGRAMMABLE See page 5-113   FAULT REPORT  OSCILLOGRAPHY See page 5-114    DATA LOGGER See page 5-116   M60 MOTOR PROTECTION SYSTEM – INSTRUCTION MANUAL...
Page 210 See page 5-189    LATCHES  SETTINGS  SETTING GROUP 1 See page 5-191   GROUPED ELEMENTS   SETTING GROUP 2     SETTING GROUP 3   M60 MOTOR PROTECTION SYSTEM – INSTRUCTION MANUAL...
Page 211     SETTINGS  DCMA INPUTS See page 5-331   TRANSDUCER I/O   RTD INPUTS See page 5-332     RRTD INPUTS See page 5-334   M60 MOTOR PROTECTION SYSTEM – INSTRUCTION MANUAL...
Page 212: Overview
For example, on a system with a 13.8 kV nominal primary voltage, the base quantity is 13800 V. With 14400:120 V delta- connected VTs, the secondary base quantity and secondary voltage setting is: Eq. 5-1 M60 MOTOR PROTECTION SYSTEM – INSTRUCTION MANUAL...
Page 213: Introduction To Ac Sources
A given source can contain all or some of the following signals: three-phase currents, single-phase ground current, three-phase voltages, and an auxiliary voltage from a single VT for checking for synchronism. M60 MOTOR PROTECTION SYSTEM – INSTRUCTION MANUAL...
Page 214 RMS levels, fundamental frequency phasors, symmetrical components, and harmonics for voltage or current, as allowed by the hardware in each channel. These modules can calculate other parameters as directed by the CPU module. M60 MOTOR PROTECTION SYSTEM – INSTRUCTION MANUAL...
Page 215: Product Setup
Password security and EnerVista security are disabled. Lost password If all passwords are lost, recovery is possible by resetting the unit to default values. Note that the relay is reset to default values, not just the passwords. M60 MOTOR PROTECTION SYSTEM – INSTRUCTION MANUAL...
Page 216 CHAPTER 5: SETTINGS To reset the unit after a lost password: Email GE customer service at multilin.tech@ge.com with the serial number and using a recognizable corporate email account. Customer service provides a code to reset the relay to the factory defaults.
Page 217 When entering a settings or command password via EnerVista or any serial interface, the user must enter the corresponding connection password. If the connection is to the back of the M60, the remote password must be used. If the connection is to the RS232 port of the front panel, the local password must be used.
Page 218 Re-enter the password in the Confirm Password field. Click the OK button. The password is checked to ensure that it meets requirements. If you establish a local (serial) connection to the relay, you cannot view remote passcodes. 5-10 M60 MOTOR PROTECTION SYSTEM – INSTRUCTION MANUAL...
Page 219 INVALID ATTEMPTS BEFORE LOCKOUT The M60 provides a means to raise an alarm upon failed password entry. If password verification fails while accessing a password-protected level of the relay (either settings or commands), the FlexLogic operand is UNAUTHORIZED ACCESS asserted.
Page 220 Access Authorized Timeout setting value is started. When this timer expires, remote setting access is denied immediately. If access is permitted and an off-to-on transition of the FlexLogic operand is detected, the timeout is restarted. The status of this timer updates every five seconds. 5-12 M60 MOTOR PROTECTION SYSTEM – INSTRUCTION MANUAL...
Page 221 If you force password entry by using this feature, ensure that you know the Administrator password. If you do not know the password and are locked out of the software, contact GE Grid Solutions for the default password of a UR device.
Page 222 The EnerVista security management system must be enabled (the Enable Security check box enabled) To modify user privileges: Select the Security > User Management item from the top menu to open the user management window. Locate the username in the User field. 5-14 M60 MOTOR PROTECTION SYSTEM – INSTRUCTION MANUAL...
Page 223 This feature requires a CyberSentry software option. See the Order Codes section in chapter 2 for details. The EnerVista software provides the means to configure and authenticate the M60 access using either a server or the device. Access to functions depends on user role.
Page 224 When the "Device" button is selected, the M60 uses its local authentication database and not the RADIUS server to authenticate the user. In this case, it uses built-in roles (Administrator, Engineer, Supervisor, Operator, Observer, or Administrator and Supervisor when Device Authentication is disabled), as login accounts and the associated passwords are stored on the M60 device.
Page 225 Figure 5-3: Security panel when CyberSentry installed For the Device > Settings > Product Setup > Supervisory option, the panel looks like the following. Figure 5-4: Supervisory panel For the Security panel, the following settings are available. M60 MOTOR PROTECTION SYSTEM – INSTRUCTION MANUAL 5-17...
Page 226 Administrator is to re-enable Device authentication when Device authentication is disabled. To re-enable Device authentication, the Supervisor unlocks the device for setting changes, and then the Administrator can re- enable Device authentication. 5-18 M60 MOTOR PROTECTION SYSTEM – INSTRUCTION MANUAL...
Page 227 LOGIN: Range: Administrator, Engineer, Supervisor,   None Operator, Factory (for factory use only), None  CHANGE LOCAL See page 5-20   PASSWORDS  SESSION See page 5-21   SETTINGS M60 MOTOR PROTECTION SYSTEM – INSTRUCTION MANUAL 5-19...
Page 228 • Observer — This role has read-only access to all M60 settings. This role allows unlimited concurrent access but it has no download access to any files on the device. Observer is the default role if no authentication has been done to the device.
Page 229 In Device authentication mode, the Observer role does not have a password associated with it. In Server authentication mode the Observer role requires a password. If you are locked out of the software, contact GE Grid Solutions for the default password. When using CyberSentry, the default password is "ChangeMe1#".
Page 230 SETTINGS  PRODUCT SETUP  SECURITY  SUPERVISORY  SELF TESTS  SELF TESTS  FAILED See below   AUTHENTICATE  FIRMWARE LOCK: Range: Enabled, Disabled  Enabled SETTINGS LOCK: Range: Enabled, Disabled  Enabled 5-22 M60 MOTOR PROTECTION SYSTEM – INSTRUCTION MANUAL...
Page 231 After making any required changes, log out. When changing settings offline, ensure that only settings permitted by the role that performs the settings download are changed because only those changes are applied. M60 MOTOR PROTECTION SYSTEM – INSTRUCTION MANUAL 5-23...
Page 232 Clear Energy command (not applicable to all UR products) Clear Unauthorized Access command Clear Teleprotection Counters command (not applicable to all UR products) Clear All Relay Records command Role Log in Role Log off 5-24 M60 MOTOR PROTECTION SYSTEM – INSTRUCTION MANUAL...
Page 233: Display Properties
CHAPTER 5: SETTINGS PRODUCT SETUP In addition to supporting syslog, a M60 with CyberSentry also saves the security events in two local security files, these being SECURITY_EVENTS.CSV and SETTING_CHANGES.LOG. Details on these files and how to retrieve them are available in the EnerVista software under Maintenance >...
Page 234 Some customers prefer very low currents to display as zero, while others prefer the current to display even when the value reflects noise rather than the actual signal. The M60 applies a cut-off value to the magnitudes and angles of the measured currents.
Page 235: Graphical Front Panel
The path is Settings > Product Setup > Graphical Panel > Home Page. The menu does not display when there is no graphical front panel. M60 MOTOR PROTECTION SYSTEM – INSTRUCTION MANUAL 5-27...
Page 236 Whenever an annunciator window changes state this list is re-evaluated, which can result in the home page displaying a different annunciator page. The Tabular option displays a configured actual values/metering page. The Targets option displays error messages. 5-28 M60 MOTOR PROTECTION SYSTEM – INSTRUCTION MANUAL...
Page 237 If the display rolls, the rolling mode pages remain displaying regardless of the home page or rolling mode delay specified. Each page displays for a few seconds; duration cannot be set. The path is Settings > Product Setup > Graphical Panel > Rolling Mode. M60 MOTOR PROTECTION SYSTEM – INSTRUCTION MANUAL 5-29...
Page 238 Range: 1 to 10 in steps of 1 Default: 1 This setting specifies the number of rolling pages. During rolling mode, the graphical front panel displays pages from 1 to the selected number. 5-30 M60 MOTOR PROTECTION SYSTEM – INSTRUCTION MANUAL...
Page 239 Metering Tab pushbutton on the graphical front panel. The Metering Editor is not used. The figures show setup and preview for monitoring actual values in a table on the graphical front panel. M60 MOTOR PROTECTION SYSTEM – INSTRUCTION MANUAL 5-31...
Page 240 A maximum of eight Status Inputs can be used per metering page, and 16 in all metering pages. Select the metering input from the drop-down list. The options reflect the FlexLogic operands applicable to the M60. They are inputs for all five metering pages, not just the current page.
Page 241 Range: 24-bit color selector Default: Black Set the text color to display in the specified cell. BACK COLOR Range: 24-bit color selector Default: Grey Set the background color to display for the specified cell. M60 MOTOR PROTECTION SYSTEM – INSTRUCTION MANUAL 5-33...
Page 242 Range: 1 to 12 in steps of 1 Default: 1 This setting specifies the number of integers in the displayed metered value. It can be used to provide for leading character spacing of the display value. 5-34 M60 MOTOR PROTECTION SYSTEM – INSTRUCTION MANUAL...
Page 243 User-Programmable Self Tests (not shown). When the alarms are triggered, they display with a red background. An alarm is acknowledged by using the arrow keys on the graphical front panel then pressing the Enter button. M60 MOTOR PROTECTION SYSTEM – INSTRUCTION MANUAL 5-35...
Page 244 Range: up to 20 alphanumeric characters Default: Page 1...Page 8 Up to 20 characters can be input as the name of each annunciator page. The number of pages depends on the Layout. 5-36 M60 MOTOR PROTECTION SYSTEM – INSTRUCTION MANUAL...
Page 245 The background color to display for any triggered cell, for example when alarm is triggered. Configure Range: Configure Default: Configure The Configure button becomes active when the CONTENT field is set to "Actual" or "Mixed." The window configures metered values. M60 MOTOR PROTECTION SYSTEM – INSTRUCTION MANUAL 5-37...
Page 246 (such as wrong password), IRIG-B clock failure, or breaker trouble, the Event Records display. When a breaker opens, a single-line diagram displays. For the Ethernet and IRIG-B failure operation to work, these functions also have been enabled under Settings > Product Setup > User-Programmable Self Tests. 5-38 M60 MOTOR PROTECTION SYSTEM – INSTRUCTION MANUAL...
Page 247: Clear Relay Records
SETTINGS  PRODUCT SETUP  CLEAR RELAY RECORDS  CLEAR RELAY CLEAR USER REPORTS: Range: FlexLogic operand   RECORDS CLEAR MOTOR DATA: Range: FlexLogic operand  CLEAR EVENT RECORDS: Range: FlexLogic operand  M60 MOTOR PROTECTION SYSTEM – INSTRUCTION MANUAL 5-39...
Page 248: Communications
Selected records can be cleared from user-programmable conditions with FlexLogic operands. Assigning user- programmable pushbuttons to clear specific records is a typical application for these commands. Since the M60 responds to rising edges of the configured FlexLogic operands, they must be asserted for at least 50 ms to take effect.
Page 249 5.3.5.2 Serial ports The M60 is equipped with up to two independent serial communication ports. The faceplate RS232 port is for local use and is fixed at 19200 baud and no parity. The rear COM2 port is used for either RS485 or RRTD communications.
Page 250 5.3.5.3 Ethernet network topology The M60 has three Ethernet ports. Each Ethernet port must belong to a different network or subnetwork. Configure the IP address and subnet to ensure that each port meets this requirement. Two subnets are different when the bitwise AND operation performed between their respective IP address and mask produces a different result.
Page 251 LAN2, to which port 2 (P2) is connected, and communications with SCADA on LAN3, to which port 3 (P3) is connected. There is no redundancy. M60 MOTOR PROTECTION SYSTEM – INSTRUCTION MANUAL 5-43...
Page 252 IP addresses and mask. Configure the network IP and subnet settings before configuring the routing settings. To obtain a list of all port numbers used, for example for audit purposes, contact GE technical support with substantiating information, such as the serial number and order code of your device.
Page 253 2 is performed. The delay in switching back ensures that rebooted switching devices connected to the M60, which signal their ports as active prior to being completely functional, have time to completely initialize themselves and become active. Once port 2 is active again, port 3 returns to standby mode.
Page 254 UR 7 redundancy Failover is selected for redundancy. 5.3.5.6 Parallel Redundancy Protocol (PRP) The M60 is provided with optional PRP capability. This feature is specified as a software option at the time of ordering. See the Order Codes section in chapter 2 for details.
Page 255 Host routes are not supported at present. The routing table configuration is available on the serial port and front panel. This is a deliberate decision, to avoid loss of connectivity when remotely configuring the M60. M60 MOTOR PROTECTION SYSTEM – INSTRUCTION MANUAL 5-47...
Page 256 Starting with UR 7.10, up to six static network routes can be configured in addition to a default route. The default route configuration was also moved from the network settings into the routing section. The figure shows an example of topology that benefits from the addition of static routes. 5-48 M60 MOTOR PROTECTION SYSTEM – INSTRUCTION MANUAL...
Page 257 EnerVista. Show routes and ARP tables This feature is available on the Web interface, where the main menu contains an additional Communications menu and two submenus: • Routing Table • ARP Table M60 MOTOR PROTECTION SYSTEM – INSTRUCTION MANUAL 5-49...
Page 258 0 disables Modbus over TCP/IP, meaning closes the Modbus TCP port. When the port number is changed to 0, the change takes effect when the M60 is restarted. When it is set to 0, use the front panel or serial port to communicate with the relay.
Page 259 SETTINGS  PRODUCT SETUP  COMMUNICATIONS  DNP PROTOCOL  DNP PROTOCOL  DNP CHANNELS See below    DNP ADDRESS: Range: 0 to 65535 in steps of 1   DNP NETWORK See below   CLIENT ADDRESSES M60 MOTOR PROTECTION SYSTEM – INSTRUCTION MANUAL 5-51...
Page 260 Range: 1, 2, 5, 6  DEFAULT VARIATION: 1 DNP OBJECT 21 Range: 1, 2, 9, 10  DEFAULT VARIATION: 1 DNP OBJECT 22 Range: 1, 2, 5, 6  DEFAULT VARIATION: 1 5-52 M60 MOTOR PROTECTION SYSTEM – INSTRUCTION MANUAL...
Page 261 DNP ADDRESS unique address to each DNP slave. The M60 can specify a maximum of five clients for its DNP connections. These are IP addresses for the controllers to which the M60 can connect. The settings follow. M60 MOTOR PROTECTION SYSTEM – INSTRUCTION MANUAL...
Page 262 DNP TCP connection for greater than the time specified by this setting, the connection is aborted by the M60. This frees up the connection to be re-used by a client. For any change to take effect, restart the relay.
Page 263 60870-5-104 point lists must be in one continuous block, any points assigned after the first “Off” point are ignored. 5.3.5.12 IEC 61850 protocol The M60 is provided with optional IEC 61850 communications. This feature is specified as a software option at the time of ordering. See the Order Codes section in chapter 2 for details.
Page 264 The maximum number of simultaneous clients supported by the UR family is five. EnerVista setup for IEC 61850 The EnerVista UR Setup software provides the interface to configure M60 settings for the IEC 61850 protocol. This section describes this interface. The software also supports import/export and merging of IEC 61850 Substation Configuration Language (SCL) files as documented in the UR Family Communications Guide.
Page 265 Figure 5-19: IEC 61850 panel Opening the IEC 61850 window while online causes the UR Setup software to retrieve and import an SCL file from the M60. This System Configuration Description (SCD) file contains all the settings in the UR at the time of the file request, both those that are mapped into the IEC 61850 information model (that is, the "public"...
Page 266 When the Save button is clicked in the online IEC 61850 window, UR Setup software prepares a configured IED description (CID) file containing all the settings of the UR and sends the CID file to the M60. Upon receipt, the M60 checks the CID file for correctness, going out of service, then back into service when the CID file is accepted.
Page 267 Default: TEMPLATE The value entered sets the IED name used by IEC 61850 for the M60. An IED name unique within the network must be entered for proper operation. Valid characters are upper and lowercase letters, digits, and the underscore (_) character.
Page 268 Range: status-only, direct-with-normal-security, sbo-with-normal-security Default: sbo-with-normal-security This setting specifies the control service that clients must use to control the TEST MODE FUNCTION of the M60. An "on" control to <LDName>/LLN0.Mod changes TEST MODE FUNCTION to Disabled, an "on-blocked" control changes it to Forcible, and a "test/blocked"...
Page 269 Protection logical device has been set to instance name "Prot", the function-related name "Feeder1Prot" and the configuration revision "2016-03-07 08:46." The text is clipped on the right if the line is longer than the available width. The next paragraphs explain how to do this setup. M60 MOTOR PROTECTION SYSTEM – INSTRUCTION MANUAL 5-61...
Page 270 Figure 5-23: Menu for logical node If the insert option is selected, or the edit option is selected for other than the Master logical device, a logical device parameters edit dialog opens. 5-62 M60 MOTOR PROTECTION SYSTEM – INSTRUCTION MANUAL...
Page 271 Each logical device inst name is required to be unique within the device, and it cannot be blank. Also, if the corresponding functional ldName setting is blank, the concatenation of the IED name and the logical device M60 MOTOR PROTECTION SYSTEM – INSTRUCTION MANUAL 5-63...
Page 272 The UR increments the value of paramRev by one whenever one or multiple setting changes occurs in one Modbus write request by any means (front panel, Modbus, or MMS) other than by SCL file 5-64 M60 MOTOR PROTECTION SYSTEM – INSTRUCTION MANUAL...
Page 273 A v7.4 device can send an R-GOOSE message to another v7.4 device when both have R-GOOSE active as the protocol • A v7.4 device can send a GOOSE message to another v7.4 device when both have GOOSE active as the protocol M60 MOTOR PROTECTION SYSTEM – INSTRUCTION MANUAL 5-65...
Page 274 Navigate to Settings > Product Setup > Communications > IEC 61850 > GOOSE > TxGOOSE > TxGOOSE1 to access the settings for the first TxGOOSE. The settings and functionality for the others are similar. 5-66 M60 MOTOR PROTECTION SYSTEM – INSTRUCTION MANUAL...
Page 275 Range: 0 to 129 VisibleString characters Default: TxGOOSE1 The entered value sets the goID value published in TxGOOSE1 messages, and can be used by subscribers to discriminate the TxGOOSE1 messages from other GOOSE messages. M60 MOTOR PROTECTION SYSTEM – INSTRUCTION MANUAL 5-67...
Page 276 VID values of 0 and 1 are assigned by IEEE 802.1Q to other functions and are not to be used for GOOSE. 5-68 M60 MOTOR PROTECTION SYSTEM – INSTRUCTION MANUAL...
Page 277 Also, Port 3 configuration in the CID file is ignored. The Port 3 ConnectedAP elements has no meaning, as ports 2 and 3 use the port 2 MAC address, IP address, and mask. M60 MOTOR PROTECTION SYSTEM – INSTRUCTION MANUAL 5-69...
Page 278 (test field in edition 1.0 messages) are accepted only when the UR Test Mode Function setting is set to Forcible or Isolated. RxGOOSE messages can be received through any UR Ethernet port. 5-70 M60 MOTOR PROTECTION SYSTEM – INSTRUCTION MANUAL...
Page 279 RxGOOSE1 messages. An entered address of zero disables RxGOOSE1. If the publisher is a UR series 7.3x device, the setting needs to match the value of the publisher’s TxGOOSE DST MAC setting. M60 MOTOR PROTECTION SYSTEM – INSTRUCTION MANUAL 5-71...
Page 280 <GoCBName> is the name of the publishing control block. The M60 translates the ACSI format required for this setting to the MMS format used in GOOSE messages: <LDName>/LLN0$GO$<GoCBName> If the publisher is a UR 7.3x or 7.40 series device, <LDName> is the value of the publisher's Master functional ldName setting if that setting is not empty, otherwise it is the value of the publisher's IED NAME suffixed with "Master".
Page 281 7.40 UR Setup RxGOOSE Inputs pages. In this case the Member setting displays as the product-related name used by the publishing IED of the data object or data attribute, in standard SCSM format (e.g. Publisher1LD1/LLN0$ST$Off$stVal). M60 MOTOR PROTECTION SYSTEM – INSTRUCTION MANUAL 5-73...
Page 282 (supported in version 7.40 and later). When the file format is SCD, the system lists all IEDs inside the SCD file and lets the user select the ones to add. The figure shows a selection being made by importing a CID file using the Add IED function. 5-74 M60 MOTOR PROTECTION SYSTEM – INSTRUCTION MANUAL...
Page 283 This setting selects the logic state for the RxGOOSE Boolean1 FlexLogic operand if the UR has just completed startup and the selected RxGOOSE has not yet received a message, or the selected RxGOOSE has lost its connectivity with the publisher. The following choices are available: M60 MOTOR PROTECTION SYSTEM – INSTRUCTION MANUAL 5-75...
Page 284 Range: None, RxGOOSE1, RxGOOSE2, and so on Default: None This setting selects the GOOSE message containing the value that drives the RxGOOSE DPS1 FlexLogic operand. If set to None, the RxGOOSE DPS1 FlexLogic operand assumes its default state. 5-76 M60 MOTOR PROTECTION SYSTEM – INSTRUCTION MANUAL...
Page 285 (supported in version 7.40 and later). When the file format is SCD, the system lists all IEDs inside the SCD file and lets the user select the ones to add. Figure 5-31: RxGOOSE Analog Inputs panel There are 32 RxGOOSE analog inputs. M60 MOTOR PROTECTION SYSTEM – INSTRUCTION MANUAL 5-77...
Page 286 Range: 0.000 to 1000000000.000 in steps of 0.001 Default: 1.000 This setting specifies the per-unit base value for other M60 features to use with the RxGOOSE Analog1 operand. A FlexElement for instance subtracts two quantities after converting their values to integers rescaled to a common base, the common base being the largest of the base values of the two quantities.
Page 287 RptEna attribute is false. Buffered and unbuffered reports Navigate to Settings > Product Setup > Communications > IEC 61850 > Reports > Buffered Reports or Unbuffered Reports. M60 MOTOR PROTECTION SYSTEM – INSTRUCTION MANUAL 5-79...
Page 288 Also, the control block can be configured to send integrity reports containing the present value of all members either on demand from the client or periodically. A TCP handshaking mechanism causes messages that are not read and acknowledged by the client to be retransmitted. 5-80 M60 MOTOR PROTECTION SYSTEM – INSTRUCTION MANUAL...
Page 289 Control blocks and data sets can be pre-configured by sending the M60 a CID file. See the UR Family Communications Guide for details. EnerVista UR Setup also can be used to select the data set members and to pre-configure the control blocks.
Page 290 This setting selects the data set whose members' status is reported in Unbuffered Report1 messages using the UR Setup software designator for the data set. The IEC 61850 name of the data sets are configured in the Datasets panel, as described later. 5-82 M60 MOTOR PROTECTION SYSTEM – INSTRUCTION MANUAL...
Page 291 DataSets Navigate to Settings > Product Setup > Communications > IEC 61850 > DataSets. M60 MOTOR PROTECTION SYSTEM – INSTRUCTION MANUAL 5-83...
Page 292 The DataSet name is not copied or pasted. In short, use this feature to copy a DataSet Member setting and paste it into another Member setting, a text file, or Word, as examples. 5-84 M60 MOTOR PROTECTION SYSTEM – INSTRUCTION MANUAL...
Page 293 Select the member from the drop-down list. Or right-click an entry to copy, paste, delete, or insert. Product setup Navigate to Settings > Product Setup > Communications > IEC 61850 > Product Setup. M60 MOTOR PROTECTION SYSTEM – INSTRUCTION MANUAL 5-85...
Page 294 Deadband parameters of measured values related to the Energy metering are configured here. Real Time Clock Navigate to Settings > Product Setup > Communications > IEC 61850 > Product Setup > Real Time Clock. 5-86 M60 MOTOR PROTECTION SYSTEM – INSTRUCTION MANUAL...
Page 295 The analog value that each deadband setting applies is usually obvious from the name of the setting. However, a tabulation of the analog values and their associated deadband setting can be found in the UR Family Communications Guide. M60 MOTOR PROTECTION SYSTEM – INSTRUCTION MANUAL 5-87...
Page 296 Auxiliary voltage — 275 x auxiliary VT ration setting • Power (real, reactive, apparent, 3-phase, and 1-phase) — 4 × phase CT primary setting × 1.5 × VT Secondary setting × VT ratio setting 5-88 M60 MOTOR PROTECTION SYSTEM – INSTRUCTION MANUAL...
Page 297 While the selected operand is asserted, Bkr0XCBR1.Loc.stVal is true and IEC 61850 commands to BkrCSWI1.Pos and Bkr0XCBR1.Pos are not accepted, and a Negative Response (-Rsp) is issued with the REASON CODE of Blocked-by- switching-hierarchy. M60 MOTOR PROTECTION SYSTEM – INSTRUCTION MANUAL 5-89...
Page 298 Bkr0XCBR1.BlkOpn.ctlVal signal on the Breaker Control Logic (Sheet 1 of 2) diagram in the Settings > System Setup section later. This signal when true blocks breaker 1 trip control while the operand selected by setting XCBR1 ST.LOC OPERAND is not active. 5-90 M60 MOTOR PROTECTION SYSTEM – INSTRUCTION MANUAL...
Page 299 Navigate to Settings > Product Setup > Communications > IEC 61850 > System Setup > Switches > Switch 1 to access the settings that configure the IEC 61850 protocol interface with the first disconnect switch control and status monitoring element. The settings and functionality for the others are similar. M60 MOTOR PROTECTION SYSTEM – INSTRUCTION MANUAL 5-91...
Page 300 > System Setup section later. These signals force a disconnect switch trip or close control while the operand selected by setting XSWI1 ST.LOC OPERAND is not active. "sbo" here is select-before-operate. Enhanced security means that the M60 reports to the client the disconnect switch 1 position the end of the command sequence.
Page 301 SelectEditSG. The setting related to these IEC 61850 commands are described here. Navigate to Settings > Product Setup > Communications > IEC 61850 > Control Elements > Setting Groups to access the setting that configures the IEC 61850 setting group commands. M60 MOTOR PROTECTION SYSTEM – INSTRUCTION MANUAL 5-93...
Page 302 Navigate to Settings > Product Setup > Communications > IEC 61850 > Settings for Commands to access the settings that configure the IEC 61850 protocol interface for record clear commands. Figure 5-43: Commands panel 5-94 M60 MOTOR PROTECTION SYSTEM – INSTRUCTION MANUAL...
Page 303 This setting selects the control model clients must use to successfully control the command CLEAR FAULT REPORTS. "sbo" here is select-before-operate. Enhanced security means that the M60 reports to the client the breaker 1 position at the end of the command sequence.
Page 304 Navigate to Settings > Product Setup > Communications > IEC 61850 > GGIO > GGIO2 to access the settings that configure the IEC 61850 protocol interface for Virtual Input commands. Figure 5-45: GGIO2 panel 5-96 M60 MOTOR PROTECTION SYSTEM – INSTRUCTION MANUAL...
Page 305 <LDName>/GGIO4.AnIn01.instMag.f. The value of the FlexAnalog operand is converted automatically to the format and scaling required by the standard, that is to say primary amperes, primary volts, and so on. See Appendix A for a list of FlexAnalog operands. M60 MOTOR PROTECTION SYSTEM – INSTRUCTION MANUAL 5-97...
Page 306 File transfer by IEC 61850 The M60 supports file transfer by IEC 61850. The approach is as follows, using the SISCO AX-S4 61850 client software as an example. In the AX-S4 61850 Explorer window, click the Tools menu and access the SISCO File Transfer Utility.
Page 307 NUMBER(80): 80 The M60 contains an embedded web server and can display pages in a web browser. The web pages are organized as a series of menus that can be accessed starting at the M60 “Main Menu.” Web pages are read-only and are available showing DNP and IEC 60870-5-104 points lists, Modbus registers, event records, fault reports, and so on.
Page 308 NUMBER: 0 The Trivial File Transfer Protocol (TFTP) can be used to transfer files from the M60 over a network. The M60 operates as a TFTP server. TFTP client software is available from various sources, including Microsoft Windows NT. The dir.txt file obtained from the M60 contains a list and description of all available files, for example event records and oscillography.
Page 309 COMMUNICATIONS  PROTOCOL connected to a maximum of two masters (usually either an RTU or a SCADA master station). Since the M60 maintains two sets of IEC 60870-5-104 data change buffers, ideally no more than two masters actively communicate with the M60 at one time.
Page 310 CHAPTER 5: SETTINGS The M60 can specify a maximum of five clients for its IEC 104 connections. These are IP addresses for the controllers to which the M60 can connect. A maximum of two simultaneous connections are supported at any given time.
Page 311 EXCH 1 DATA ITEM 1 to 20/50 from the M60 memory map can be configured to be included in an EGD exchange. The settings are the starting Modbus register address for the data item in decimal format. See the Modbus memory map in the UR Series Communications Guide for details.
Page 312 PTP, or SNTP, its time is overwritten by these three sources, if any of them is active. If the synchronization timeout occurs and none of IRIG-B, PTP, or SNTP is active, the M60 sets the invalid bit in the time stamp of a time-tagged message.
Page 313 Spontaneous transmission occurs as a response to cyclic Class 2 requests. If the M60 wants to transmit Class 1 data at that time, it demands access for Class 1 data transmission (ACD=1 in the control field of the response).
Page 314 FlexAnalog operands. The measurands sent are voltage, current, power, power factor, and frequency. If any other FlexAnalog is chosen, the M60 sends 0 instead of its value. Note that the power is transmitted in KW, not W. Measurands are transmitted as ASDU 3 or ASDU 9 (type identification value set to measurands I, respectively measurands II).
Page 315 Range: Virtual input  COMMAND 31 OFF: Range: Virtual input  Commands are received as General Command (Type Identification 20). The user can configure the action to perform when an ASDU command comes. M60 MOTOR PROTECTION SYSTEM – INSTRUCTION MANUAL 5-107...
Page 316: Modbus User Map
PRODUCT SETUP CHAPTER 5: SETTINGS A list of available mappings is provided on the M60. This includes 64 virtual inputs (see the following table). The ON and OFF for the same ASDU command can be mapped to different virtual inputs.
Page 317: Real-Time Clock
For the Other protocols, whenever a time synchronization message is received through any of the active protocols, the M60 clock updates. However, given that IEC 60870-5-103, IEC 60870-5-104, Modbus, and DNP are low-accuracy time synchronization methods, avoid their use for synchronization when better accuracy time protocols, such as IRIG-B and PTP, are active in the system.
Page 318 See the Order Codes section in chapter 2 for details. The M60 supports the Precision Time Protocol (PTP) specified in IEEE Std 1588 2008 using the Power Profile (PP) specified in IEEE Std C37.238 2011. This enables the relay to synchronize to the international time standard over an Ethernet network that implements PP.
Page 319 When a clock on start-up discovers that it is “better” than the present grandmaster, it assumes the grandmaster role and the previous grandmaster reverts to slave. The M60 qualification mechanism accepts a potential master clock as a new grandmaster, when in a four-second interval it has received three announce messages from it, all better than the present grandmaster clock and better than any other announce in this interval.
Page 320 M60 clock is closely synchronized with the SNTP/ NTP server. It takes up to two minutes for the M60 to signal an SNTP self-test error if the server is offline.
Page 321: User-Programmable Fault Report
 2:00 The M60 maintains two times: local time and Universal Coordinated Time (UTC). Local time can be provided by IRIG-B signals. UTC time is provided by SNTP servers. The real-time clock (RTC) and time stamps reported in historical records and communication protocols can be incorrect if the Local Time settings are not configured properly.
Page 322: Oscillography
The user programmable record contains the following information: the user-programmed relay name, detailed firmware revision (x.xx, for example) and relay model (M60), the date and time of trigger, the name of pre-fault trigger (a specific FlexLogic operand), the name of fault trigger (a specific FlexLogic operand), the active setting group at pre-fault trigger, the active setting group at fault trigger, pre-fault values of all programmed analog channels (one cycle before pre-fault trigger), and fault values of all programmed analog channels (at the fault trigger).
Page 323 Parameters set to “Off” are ignored. To populate quickly the rows in the Offline Window, use Ctrl C/V to copy/paste, or click then double-click a row to display a quick selection window. M60 MOTOR PROTECTION SYSTEM – INSTRUCTION MANUAL 5-115...
Page 324: Data Logger
DATA LOGGER CHNL 1: Range: Off, any FlexAnalog/actual value parameter  See Appendix A for list  DATA LOGGER CHNL 16: Range: Off, any FlexAnalog/actual value parameter  See Appendix A for list 5-116 M60 MOTOR PROTECTION SYSTEM – INSTRUCTION MANUAL...
Page 325 — This display presents the total amount of time that the Data Logger can record the channels not DATA LOGGER CONFIG selected to “Off” without overwriting old data. M60 MOTOR PROTECTION SYSTEM – INSTRUCTION MANUAL 5-117...
Page 326: User-Programmable Leds
LEDs. This test checks for hardware failures that lead to more than one LED being turned off from a single logic point. This stage can be interrupted at any time. 5-118 M60 MOTOR PROTECTION SYSTEM – INSTRUCTION MANUAL...
Page 327 The test responds to the position and rising edges of the control input defined by the LED TEST CONTROL setting. The control pulses must last at least 250 ms to take effect. The following diagram explains how the test is executed. Figure 5-50: LED test sequence M60 MOTOR PROTECTION SYSTEM – INSTRUCTION MANUAL 5-119...
Page 328 LED column 2 — User-programmable LEDs 1 through 12 • LED column 3 — User-programmable LEDs 13 through 24 • LED column 4 — User-programmable LEDs 25 through 36 • LED column 5 — User-programmable LEDs 37 through 48 5-120 M60 MOTOR PROTECTION SYSTEM – INSTRUCTION MANUAL...
Page 329 Event Cause LED 7 LED PHASE B EVENT CAUSE LED 7 Orange Event Cause LED 8 LED PHASE C EVENT CAUSE LED 8 Orange Event Cause LED 9 LED NEUTRAL/GROUND EVENT CAUSE LED 9 Orange M60 MOTOR PROTECTION SYSTEM – INSTRUCTION MANUAL 5-121...
Page 330: User-Programmable Self-Tests
These are user-programmable and can be used for various applications such as performing an LED test, switching setting groups, and invoking and scrolling though user-programmable displays. The location of the control pushbuttons are shown in the following figures. 5-122 M60 MOTOR PROTECTION SYSTEM – INSTRUCTION MANUAL...
Page 331 PRODUCT SETUP Figure 5-51: Control pushbuttons (enhanced front panel) An additional four control pushbuttons are included on the standard front panel when the M60 is ordered with the 12 user- programmable pushbutton option. Figure 5-52: Control pushbuttons (standard front panel) Control pushbuttons are not typically used for critical operations and are not protected by the control password.
Page 332: User-Programmable Pushbuttons
 EVENTS: Disabled The M60 is provided with this optional feature, specified as an option at the time of ordering. Using the order code for your device, see the order codes in chapter 2 for details. User-programmable pushbuttons provide an easy and error-free method of entering digital state (on, off) information. The number depends on the front panel ordered.
Page 333 Figure 5-55: User-programmable pushbuttons (standard front panel) Figure 5-56: User-programmable pushbuttons (graphical front panel) Front panel pushbuttons and LEDs can be custom labelled as outlined in the Front Panel Labelling section in the previous chapter. M60 MOTOR PROTECTION SYSTEM – INSTRUCTION MANUAL 5-125...
Page 334 — This setting selects the mode of the pushbutton (Self-Reset, Latched, Disabled). If set to PUSHBUTTON 1 FUNCTION “Disabled,” the pushbutton is not active and the corresponding FlexLogic operands (both “On” and “Off”) are de-asserted. If set to "Latched," the pushbutton remains on until reset. 5-126 M60 MOTOR PROTECTION SYSTEM – INSTRUCTION MANUAL...
Page 335 "Latched" mode the off message displays when the user-programmable pushbutton becomes deactivated. When set to "Normal", the duration the message displays is as specified by the setting. FLASH MESSAGE TIME M60 MOTOR PROTECTION SYSTEM – INSTRUCTION MANUAL 5-127...
Page 336 — If this setting is enabled, each user-programmable pushbutton state change is logged as an PUSHBUTTON 1 EVENTS event into the event recorder. The figures show the user-programmable pushbutton logic. Figure 5-57: User-programmable pushbutton logic (Sheet 1 of 2) 5-128 M60 MOTOR PROTECTION SYSTEM – INSTRUCTION MANUAL...
Page 337: Flexstate Parameters
The state bits can be read out in the “Flex States” register array beginning at Modbus address 0900h. Sixteen states are packed into each register, with the lowest-numbered state in the lowest-order bit. Sixteen registers accommodate the 256 state bits. M60 MOTOR PROTECTION SYSTEM – INSTRUCTION MANUAL 5-129...
Page 338: User-Definable Displays
When this type of entry occurs, the sub-menus are automatically configured with the proper content—this content can be edited subsequently. 5-130 M60 MOTOR PROTECTION SYSTEM – INSTRUCTION MANUAL...
Page 339 If the parameters for the top line and the bottom line items have the same units, then the unit is displayed on the bottom line only. The units are only displayed on both lines if the units specified both the top and bottom line items are different. M60 MOTOR PROTECTION SYSTEM – INSTRUCTION MANUAL 5-131...
Page 340: Direct Inputs And Outputs
DIRECT OUTPUT DEVICE ID messages. All UR-series IEDs in a ring need to have unique numbers assigned. The IED ID is used to identify the sender of the direct input and output message. 5-132 M60 MOTOR PROTECTION SYSTEM – INSTRUCTION MANUAL...
Page 341 DIRECT I/O DATA RATE setting applies to a M60 with dual-channel communication cards and allows crossing DIRECT I/O CHANNEL CROSSOVER over messages from channel 1 to channel 2. This places all UR-series IEDs into one direct input and output network regardless of the physical media of the two communication channels.
Page 342 DIRECT I/O CH1 RING CONFIGURATION: “Yes” DIRECT I/O CH2 RING CONFIGURATION: “Yes” For UR-series IED 2: DIRECT OUTPUT DEVICE ID: “2” DIRECT I/O CH1 RING CONFIGURATION: “Yes” DIRECT I/O CH2 RING CONFIGURATION: “Yes” For UR-series IED 3: 5-134 M60 MOTOR PROTECTION SYSTEM – INSTRUCTION MANUAL...
Page 343 Figure 5-62: Three-terminal line application A permissive pilot-aided scheme can be implemented in a two-ring configuration, shown as follows (IEDs 1 and 2 constitute a first ring, while IEDs 2 and 3 constitute a second ring). M60 MOTOR PROTECTION SYSTEM – INSTRUCTION MANUAL 5-135...
Page 344 In this application, apply the following settings. For UR-series IED 1: DIRECT OUTPUT DEVICE ID: “1” DIRECT I/O CH1 RING CONFIGURATION: “Yes” DIRECT I/O CH2 RING CONFIGURATION: “Yes” For UR-series IED 2: 5-136 M60 MOTOR PROTECTION SYSTEM – INSTRUCTION MANUAL...
Page 345 EVENTS: Disabled The M60 checks integrity of the incoming direct input and output messages using a 32-bit CRC. The CRC alarm function is available for monitoring the communication medium noise by tracking the rate of messages failing the CRC check. The monitoring function counts all incoming messages, including messages that failed the CRC check.
Page 346: Teleprotection
 EVENTS: Disabled The M60 checks integrity of the direct input and output communication ring by counting unreturned messages. In the ring configuration, all messages originating at a given device should return within a pre-defined period of time. The unreturned messages alarm function is available for monitoring the integrity of the communication ring by tracking the rate of unreturned messages.
Page 347: Remote Resources
5.4 Remote resources 5.4.1 Remote resources configuration When the M60 is ordered with a process card module as a part of HardFiber system, an additional Remote Resources menu tree is available in the EnerVista software to allow configuration of the HardFiber system.
Page 348 Bricks. Remote resources settings configure the point-to-point connection between specific fiber optic ports on the M60 process card and specific Brick. The relay is then configured to measure specific currents, voltages and contact inputs from those Bricks, and to control specific outputs.
Page 349: Ac Inputs
The same rule applies for current sums from CTs with different secondary taps (5 A and 1 A). 5.5.1.2 Voltage banks SETTINGS  SYSTEM SETUP  AC INPUTS  VOLTAGE BANK F5(M5)  VOLTAGE BANK F5 PHASE VT F5 Range: Wye, Delta   CONNECTION: Wye M60 MOTOR PROTECTION SYSTEM – INSTRUCTION MANUAL 5-141...
Page 350: Power System
PHASE ROTATION sequence, either ABC or ACB. CT and VT inputs on the relay, labelled as A, B, and C, must be connected to system phases A, B, and C for correct operation. 5-142 M60 MOTOR PROTECTION SYSTEM – INSTRUCTION MANUAL...
Page 351: Signal Sources
“Disabled” only in unusual circumstances; consult GE Grid Solutions for special variable- FREQUENCY TRACKING frequency applications. The frequency tracking feature functions only when the M60 is in the “Programmed” mode. If the M60 is “Not Programmed,” then metering values are available but can exhibit significant errors. 5.5.3 Signal sources SETTINGS ...
Page 352 0.02 pu; thus by default the disturbance detector responds to a change of 0.04 pu. The metering sensitivity setting ) controls the sensitivity of the disturbance detector PRODUCT SETUP  DISPLAY PROPERTIES  CURRENT CUT-OFF LEVEL accordingly. 5-144 M60 MOTOR PROTECTION SYSTEM – INSTRUCTION MANUAL...
Page 353 8 CTs 4 CTs, 4 VTs 4 CTs, 4 VTs C60, D60, G30, G60, L30, L90, M60, T60 not applicable This configuration can be used on a two-winding transformer, with one winding connected into a breaker-and-a-half system. The following figure shows the arrangement of sources used to provide the functions required in this application, and the CT/VT inputs that are used to provide the data.
Page 354: Motor
— This setting defines the current level at which the motor is considered to be overloaded. If the MOTOR OVERLOAD FACTOR motor current exceeds the threshold, the M60 thermal model reacts by accumulating thermal MOTOR OVERLOAD FACTOR capacity. Normally, this factor is set slightly above the motor service factor to account for inherent load measuring errors (CTs and limited relay accuracy).
Page 355 FlexLogic operand is de-asserted, the algorithm switches to speed 1 (low speed). This allows the M60 to determine which settings are to be active at any given time. To maintain correct motor status indication, the M60 expects a transition from speed 1 to speed 2 within two seconds;...
Page 356: Breakers
Range: FlexLogic operand  BREAKER 1 CLOSE: Range: FlexLogic operand  BREAKER 1 BLK CLOSE: Range: FlexLogic operand  BREAKER1 ΦA/3P CLSD: Range: FlexLogic operand  BREAKER1 ΦA/3P OPND: Range: FlexLogic operand  5-148 M60 MOTOR PROTECTION SYSTEM – INSTRUCTION MANUAL...
Page 357 BREAKER 1 NAME related to breaker 1. — Selects “3-Pole” mode, where all breaker poles are operated simultaneously, or “1-Pole” mode where all BREAKER 1 MODE breaker poles are operated either independently or simultaneously. M60 MOTOR PROTECTION SYSTEM – INSTRUCTION MANUAL 5-149...
Page 358 If this setting is set to Off, the racked status is not considered. 5-150 M60 MOTOR PROTECTION SYSTEM – INSTRUCTION MANUAL...
Page 359 CHAPTER 5: SETTINGS SYSTEM SETUP Figure 5-69: Dual breaker control logic (Sheet 1 of 3) M60 MOTOR PROTECTION SYSTEM – INSTRUCTION MANUAL 5-151...
Page 360 SYSTEM SETUP CHAPTER 5: SETTINGS Figure 5-70: Dual breaker control logic (Sheet 2 of 3) 5-152 M60 MOTOR PROTECTION SYSTEM – INSTRUCTION MANUAL...
Page 361: Disconnect Switch Control
Range: Disabled, Enabled   FUNCTION: Disabled SWITCH 1 NAME: Range: up to six alphanumeric characters  SW 1 SWITCH 1 MODE: Range: 3-Pole, 1-Pole  3-Pole SWITCH 1 OPEN: Range: FlexLogic operand  M60 MOTOR PROTECTION SYSTEM – INSTRUCTION MANUAL 5-153...
Page 362 — This setting selects “3-Pole” mode, where disconnect switch poles have a single common auxiliary SWITCH 1 MODE switch, or “1-Pole” mode where each disconnect switch pole has its own auxiliary switch. 5-154 M60 MOTOR PROTECTION SYSTEM – INSTRUCTION MANUAL...
Page 363 — This setting specifies the delay interval during which a disagreement of status among the pole SWITCH 1 ALARM DELAY position tracking operands do not declare a pole disagreement. This allows for non-simultaneous operation of the poles. M60 MOTOR PROTECTION SYSTEM – INSTRUCTION MANUAL 5-155...
Page 364 CHAPTER 5: SETTINGS IEC 61850 functionality is permitted when the M60 is in “Programmed” mode and not in local control mode. The switch element has direct hard-coded connections to the IEC 61850 model as shown in the logic diagrams. This allows remote open/close operation of each switch, using either CSWI or XSWI IEC 61850 logical nodes.
Page 365 CHAPTER 5: SETTINGS SYSTEM SETUP Figure 5-73: Disconnect switch control status logic (sheet 2 of 3) M60 MOTOR PROTECTION SYSTEM – INSTRUCTION MANUAL 5-157...
Page 366: Flexcurves
FlexCurve, enter the reset and operate times (using the keys) for each selected pickup point (using the VALUE up/down keys) for the required protection curve (A, B, C, or D). MESSAGE 5-158 M60 MOTOR PROTECTION SYSTEM – INSTRUCTION MANUAL...
Page 367 The recloser curve configuration window shown here appears when the Initialize From setting in the EnerVista software is set to “Recloser Curve” and the Initialize FlexCurve button is clicked. M60 MOTOR PROTECTION SYSTEM – INSTRUCTION MANUAL 5-159...
Page 368 MRT and from then onwards the operating time remains at 200 ms. Figure 5-76: Composite recloser curve with HCT disabled With the HCT feature enabled, the operating time reduces to 30 ms for pickup multiples exceeding eight times pickup. 5-160 M60 MOTOR PROTECTION SYSTEM – INSTRUCTION MANUAL...
Page 369 EnerVista software generates an error message and discards the proposed changes. 5.5.7.5 Standard recloser curves The following graphs display standard recloser curves available for the M60. Figure 5-78: Recloser curves GE101 to GE106 M60 MOTOR PROTECTION SYSTEM – INSTRUCTION MANUAL...
Page 370 SYSTEM SETUP CHAPTER 5: SETTINGS Figure 5-79: Recloser curves GE113, GE120, GE138, and GE142 Figure 5-80: Recloser curves GE134, GE137, GE140, GE151, and GE201 5-162 M60 MOTOR PROTECTION SYSTEM – INSTRUCTION MANUAL...
Page 371 CHAPTER 5: SETTINGS SYSTEM SETUP Figure 5-81: Recloser curves GE131, GE141, GE152, and GE200 Figure 5-82: Recloser curves GE133, GE161, GE162, GE163, GE164, and GE165 M60 MOTOR PROTECTION SYSTEM – INSTRUCTION MANUAL 5-163...
Page 372 SYSTEM SETUP CHAPTER 5: SETTINGS Figure 5-83: Recloser curves GE116, GE117, GE118, GE132, GE136, and GE139 Figure 5-84: Recloser curves GE107, GE111, GE112, GE114, GE115, GE121, and GE122 5-164 M60 MOTOR PROTECTION SYSTEM – INSTRUCTION MANUAL...
Page 373: Flexlogic
FlexLogic. In general, the system receives analog and digital inputs that it uses to produce analog and digital outputs. The figure shows major subsystems of a generic UR-series relay involved in this process. M60 MOTOR PROTECTION SYSTEM – INSTRUCTION MANUAL 5-165...
Page 374 Figure 5-86: UR architecture overview The states of all digital signals used in the M60 are represented by flags (or FlexLogic operands, which are described later in this section). A digital “1” is represented by a set flag. Any external contact change-of-state can be used to block an element from operating, as an input to a control feature in a FlexLogic equation, or to operate a contact output.
Page 375 The following table lists the operands available for the relay. The operands can be viewed online by entering the IP address of the relay in a web browser and accessing the Device Information Menu. M60 MOTOR PROTECTION SYSTEM – INSTRUCTION MANUAL 5-167...
Page 376 Breaker 1 flashover element phase C has dropped out BKR 1 FLSHOVR DPO Breaker 1 flashover element has dropped out BKR 2 FLSHOVR Same set of operands as shown for BKR 1 FLSHOVR 5-168 M60 MOTOR PROTECTION SYSTEM – INSTRUCTION MANUAL...
Page 377 BREAKER 2 Same set of operands as shown for BREAKER 1 ELEMENT: CT FAIL 1 PKP CT fail has picked up CT fail CT FAIL 1 OP CT fail has dropped out M60 MOTOR PROTECTION SYSTEM – INSTRUCTION MANUAL 5-169...
Page 378 NEG SEQ OV1 DPO Negative-sequence overvoltage element has dropped out overvoltage NEG SEQ OV1 OP Negative-sequence overvoltage element has operated NEG SEQ OV2 to 3 Same set of operands as shown for NEG SEQ OV1 5-170 M60 MOTOR PROTECTION SYSTEM – INSTRUCTION MANUAL...
Page 379 Phase B of overvoltage 1 has dropped out PHASE OV1 DPO C Phase C of overvoltage 1 has dropped out PHASE OV2 to 3 Same set of operands as shown for PHASE OV1 M60 MOTOR PROTECTION SYSTEM – INSTRUCTION MANUAL 5-171...
Page 380 Asserted when the trip stage of RTD input 1 protection drops out RTD Ip 2 to 48 The set of operands shown are available for the RTD Ip 2 and higher elements 5-172 M60 MOTOR PROTECTION SYSTEM – INSTRUCTION MANUAL...
Page 381 Phase A of stator differential phase comparison has been satisfied STATOR DIFF DIR B Phase B of stator differential phase comparison has been satisfied STATOR DIFF DIR C Phase C of stator differential phase comparison has been satisfied M60 MOTOR PROTECTION SYSTEM – INSTRUCTION MANUAL 5-173...
Page 382 Asserted when the speed 2 undercurrent alarm operates speed 2 U/CURR SP2 TRIP PKP Asserted when the speed 2 undercurrent trip picks up U/CURR SP2 TRIP OP Asserted when the speed 2 undercurrent trip operates 5-174 M60 MOTOR PROTECTION SYSTEM – INSTRUCTION MANUAL...
Page 383 Virt Op 1 Flag is set, logic=1 Virtual outputs Virt Op 2 Flag is set, logic=1 Virt Op 3 Flag is set, logic=1 ↓ ↓ Virt Op 96 Flag is set, logic=1 M60 MOTOR PROTECTION SYSTEM – INSTRUCTION MANUAL 5-175...
Page 384 RxGOOSE 1 On Flag is set, logic=1 ↓ ↓ RxGOOSE 64 On Flag is set, logic=1 RxGOOSE 1 Off Flag is set, logic=1 ↓ ↓ RxGOOSE 64 Off Flag is set, logic=1 5-176 M60 MOTOR PROTECTION SYSTEM – INSTRUCTION MANUAL...
Page 385 ID of any of these operands, the assigned name appears in the relay list of operands. The default names are shown in the FlexLogic operands table. The characteristics of the logic gates are tabulated in the following table, and the operators available in FlexLogic are listed in the FlexLogic operators table. M60 MOTOR PROTECTION SYSTEM – INSTRUCTION MANUAL 5-177...
Page 386: Flexlogic Rules
Assigning the output of an operator to a virtual output terminates the equation. A timer operator (for example, "TIMER 1") or virtual output assignment (for example, " = Virt Op 1") can be used once 5-178 M60 MOTOR PROTECTION SYSTEM – INSTRUCTION MANUAL...
Page 387: Flexlogic Evaluation
Inspect each operator between the initial operands and final virtual outputs to determine if the output from the operator is used as an input to more than one following operator. If so, the operator output must be assigned as a virtual output. M60 MOTOR PROTECTION SYSTEM – INSTRUCTION MANUAL 5-179...
Page 388 Figure 5-89: Logic for virtual output 3 Prepare a logic diagram for virtual output 4, replacing the logic ahead of virtual output 3 with a symbol identified as virtual output 3, shown as follows. 5-180 M60 MOTOR PROTECTION SYSTEM – INSTRUCTION MANUAL...
Page 389 Assume for this example that the state is to be ON for a closed contact. The operand is therefore “Cont Ip H1c On”. M60 MOTOR PROTECTION SYSTEM – INSTRUCTION MANUAL 5-181...
Page 390 [88] Virt Ip 1 On [89] DIG ELEM 1 PKP [90] XOR(2) [91] Virt Op 3 On [92] OR(4) [93] LATCH (S,R) [94] Virt Op 3 On [95] TIMER 1 [96] Cont Ip H1c On 5-182 M60 MOTOR PROTECTION SYSTEM – INSTRUCTION MANUAL...
Page 391 Virt Op 1 On Virt Op 2 On Virt Ip 1 On DIG ELEM 1 PKP XOR(2) Virt Op 3 On OR(4) LATCH (S,R) Virt Op 3 On TIMER 1 Cont Ip H1c On OR(3) M60 MOTOR PROTECTION SYSTEM – INSTRUCTION MANUAL 5-183...
Page 392: Flexlogic Equation Editor
FLEXELEMENT 1 NAME: Range: up to six alphanumeric characters  FxE 1 FLEXELEMENT 1 +IN: Range: Off, any analog actual value parameter  FLEXELEMENT 1 -IN: Range: Off, any analog actual value parameter  5-184 M60 MOTOR PROTECTION SYSTEM – INSTRUCTION MANUAL...
Page 393 The element can be programmed to respond either to a signal level or to a rate-of-change (delta) over a pre-defined period of time. The output operand is asserted when the operating signal is higher than a threshold or lower than a threshold, as per your choice. M60 MOTOR PROTECTION SYSTEM – INSTRUCTION MANUAL 5-185...
Page 394 — Enables the relay to respond to either high or low values of the operating signal. The following FLEXELEMENT 1 DIRECTION figure explains the application of the , and FLEXELEMENT 1 DIRECTION FLEXELEMENT 1 PICKUP FLEXELEMENT 1 HYSTERESIS settings. 5-186 M60 MOTOR PROTECTION SYSTEM – INSTRUCTION MANUAL...
Page 395 Figure 5-95: FlexElement direction, pickup, and hysteresis In conjunction with the setting, the element can be programmed to provide two extra FLEXELEMENT 1 INPUT MODE characteristics, as shown in the following figure. M60 MOTOR PROTECTION SYSTEM – INSTRUCTION MANUAL 5-187...
Page 396 (Brk X Arc Amp A, B, and C) CURRENT UNBALANCE BASE = 100% (Amp Unbalance) DCmA BASE = maximum value of the DCMA INPUT MAX setting for the two transducers configured under the +IN and –IN inputs 5-188 M60 MOTOR PROTECTION SYSTEM – INSTRUCTION MANUAL...
Page 397: Non-Volatile Latches
Range: up to 20 alphanumeric characters  NV Latch 1 LATCH 1 TYPE: Range: Reset Dominant, Set Dominant  Reset Dominant LATCH 1 SET: Range: FlexLogic operand  LATCH 1 RESET: Range: FlexLogic operand  M60 MOTOR PROTECTION SYSTEM – INSTRUCTION MANUAL 5-189...
Page 398: Grouped Elements
The active setting group can be preset or selected in the menu (see the Control Elements section SETTING GROUPS later in this chapter). See also the Introduction to Elements section at the beginning of this chapter. 5-190 M60 MOTOR PROTECTION SYSTEM – INSTRUCTION MANUAL...
Page 399: Setting Group 1
See page 5-221   5.7.3.2 Acceleration time SETTINGS  GROUPED ELEMENTS  SETTING GROUP 1(6)  MOTOR  ACCELERATION TIME  ACCELERATION TIME ACCELERATION Range: Disabled, Enabled   FUNCTION: Disabled M60 MOTOR PROTECTION SYSTEM – INSTRUCTION MANUAL 5-191...
Page 400 This setting can be estimated experimentally by starting a given motor several times under various load and electrical conditions and measuring the starting time. Also apply a security margin. 5-192 M60 MOTOR PROTECTION SYSTEM – INSTRUCTION MANUAL...
Page 401 COOL TIME CONSTANT Range: 1 to 65000 min. in steps of 1  RUNNING: 15 min. COOL TIME CONSTANT Range: 1 to 65000 min. in steps of 1  STOPPED: 30 min. M60 MOTOR PROTECTION SYSTEM – INSTRUCTION MANUAL 5-193...
Page 402 When the motor has been stopped for a long time, it is at ambient temperature and thermal capacity used is zero. When the motor is in overload, the output operand is set once the thermal capacity used reaches 100%. 5-194 M60 MOTOR PROTECTION SYSTEM – INSTRUCTION MANUAL...
Page 403 Once the motor load current exceeds the overload level (FLA x overload factor), it enters an overload phase; that is, the heat accumulation becomes greater than the heat dissipation. The M60 thermal model reacts by incrementing the thermal capacity used (TCU) at a rate dependent on the selected thermal curve and overload level. When the thermal capacity reaches 100%, the operand (typically configured to trip the motor) is set.
Page 404 20.82 If “IEC” is selected as the thermal model curve, the M60 can apply the IEC 255-8 hot and cold curve characteristics to the thermal model. The M60 evaluates the thermal capacity at motor start and chooses the appropriate curve. The hot curve characteristic is applied when the thermal capacity is greater than or equal to 5% (that is, a point above where the motor is not at complete rest, or cold).
Page 405 In case of uncertainty, use the more conservative “Cutoff” value. The following figure illustrates the impact of this setting on the time to trip thermal curves. Figure 5-100: Impact of the thermal model curve effect setting M60 MOTOR PROTECTION SYSTEM – INSTRUCTION MANUAL 5-197...
Page 406 IEC CURVE TIME CONSTANT per the IEC 255-8 standard. When the IEC motor curves are selected, the M60 calculates the time to trip using the IEC255- 8 cold curve and IEC255-8 hot curve equations and increases thermal capacity used as defined by the thermal capacity used equation earlier.
Page 407 In these cases, it can be necessary to use a custom curve so the motor can be started successfully and used to its full potential without compromising protection. For these conditions, it is recommended that M60 MOTOR PROTECTION SYSTEM – INSTRUCTION MANUAL 5-199...
Page 408 This function is explained later in this section. Figure 5-102: FlexCurve example The FlexCurve programming is based on per-unit current values. The equivalent primary amperes and multiplier of full load current are also indicated above. 5-200 M60 MOTOR PROTECTION SYSTEM – INSTRUCTION MANUAL...
Page 409 Enter the motor cooling time constants for both the stopped and running cases. A stopped motor normally cools significantly slower than a running motor. M60 MOTOR PROTECTION SYSTEM – INSTRUCTION MANUAL 5-201...
Page 410 = cool time constant (running or stopped per current motor status and corresponding COOL TIME CONSTANT RUNNING settings) COOL TIME CONSTANT STOPPED = equivalent motor heating current overload_pickup = overload pickup setpoint as a multiple of FLA hot / cold = hot/cold curve ratio 5-202 M60 MOTOR PROTECTION SYSTEM – INSTRUCTION MANUAL...
Page 411 HOT/COLD SAFE STALL RATIO The M60 algorithm uses this data if this setting is programmed. The value entered for this setting dictates the level at which thermal capacity used settles for current that is below the motor service factor times FLA. When the motor is running at a...
Page 412 100%, the load current must be above the overload pickup setting to set the output. Do not program setpoint greater than 200°C if using a remote RTD unit, since the RRTD only measures RTD BIAS MAXIMUM temperatures up to 200°C. 5-204 M60 MOTOR PROTECTION SYSTEM – INSTRUCTION MANUAL...
Page 413 The relay monitors motor starting and captures the TCU for each successful start. The largest value from the last five starts is used in the start inhibit calculation. M60 MOTOR PROTECTION SYSTEM – INSTRUCTION MANUAL 5-205...
Page 414 The following figure presents the typical thermal limit curve for high inertia application. 5-206 M60 MOTOR PROTECTION SYSTEM – INSTRUCTION MANUAL...
Page 415 Figure 5-106: Thermal limit curve for high inertia TVoltage dependent overload functionality is operational only if the selected in the MOTOR LINE SOURCE SYSTEM  menu is assigned to a valid three-phase VT. MOTOR SETUP M60 MOTOR PROTECTION SYSTEM – INSTRUCTION MANUAL 5-207...
Page 416 (I ). This value can be typically determined from motor acceleration curves. The value at the breakdown torque for the minimum voltage start is recommended for this setting. 5-208 M60 MOTOR PROTECTION SYSTEM – INSTRUCTION MANUAL...
Page 417 The current value at the breakdown torque for the 100% voltage start is recommended for this setting. The figure shows the voltage dependent overload curves. M60 MOTOR PROTECTION SYSTEM – INSTRUCTION MANUAL 5-209...
Page 418 The line connecting points 1 and 2 constructs the acceleration curve for the system voltage level defined by the setting. The acceleration time-current curve for the minimum voltage starting VOLTAGE DEPENDENT MIN MOTOR VOLTS 5-210 M60 MOTOR PROTECTION SYSTEM – INSTRUCTION MANUAL...
Page 419 The following three figures illustrate the resultant overload protection curve for minimum, 100%, and maximum line voltages. For voltages between these limits, the M60 shifts the acceleration curve linearly and constantly, based on the measured line voltage during a motor start.
Page 420 GROUPED ELEMENTS CHAPTER 5: SETTINGS Figure 5-109: Voltage dependent overload curve protection at minimum voltage Figure 5-110: Voltage dependent overload curve protection at 100% voltage 5-212 M60 MOTOR PROTECTION SYSTEM – INSTRUCTION MANUAL...
Page 421 Figure 5-111: Voltage dependent overload curve protection at 110% voltage The following three figures illustrate the motor starting curves for the following abnormal conditions: line voltages below the minimum, above 110%, and the situation for voltage loss. M60 MOTOR PROTECTION SYSTEM – INSTRUCTION MANUAL 5-213...
Page 422 GROUPED ELEMENTS CHAPTER 5: SETTINGS Figure 5-112: Voltage dependent overload curve protection at less than minimum voltage Figure 5-113: Voltage dependent overload curve protection at voltage loss condition 5-214 M60 MOTOR PROTECTION SYSTEM – INSTRUCTION MANUAL...
Page 423 CHAPTER 5: SETTINGS GROUPED ELEMENTS Figure 5-114: Voltage dependent overload curve protection at more than 110% voltage For the three abnormal voltage situations, the M60 makes a transition from the acceleration curve to Motor or FlexCurve when the operands are asserted.
Page 424 If the motor status is offline when control power is lost, the thermal capacity decays for the duration of the loss of control power based on the stopped motor cooling rate. 5-216 M60 MOTOR PROTECTION SYSTEM – INSTRUCTION MANUAL...
Page 425 AMP UNBAL 1 RESET Range: 0.00 to 600.00 s in steps of 0.01  DELAY: 0.00 s AMP UNBAL 1 BLOCK: Range: FlexLogic operand  AMP UNBAL 1 TARGET: Range: Self-reset, Latched, Disabled  Self-reset M60 MOTOR PROTECTION SYSTEM – INSTRUCTION MANUAL 5-217...
Page 426 SETTINGS  GROUPED ELEMENTS  SETTING GROUP 1(6)  MOTOR  MECHANICAL JAM  MECHANICAL JAM MECHANICAL JAM Range: Disabled, Enabled   FUNCTION: Disabled MECH JAM OVERCURRENT Range: 1.00 to 10.00 x FLA in steps of 0.01  PICKUP: 2.00 x FLA 5-218 M60 MOTOR PROTECTION SYSTEM – INSTRUCTION MANUAL...
Page 427 — This setting defines the reset delay of the element. Typical application includes time seal-in of the MECH JAM RESET DELAY tripping command. Figure 5-118: Mechanical jam logic M60 MOTOR PROTECTION SYSTEM – INSTRUCTION MANUAL 5-219...
Page 428 — This setting specifies a time delay for the trip stage. Set the time delay long enough to UNDERCURRENT TRIP PICKUP DLY overcome any short lowering of the current (for example, during system faults). 5-220 M60 MOTOR PROTECTION SYSTEM – INSTRUCTION MANUAL...
Page 429 Motor, otherwise 0.00 to 600.00 in steps of 0.01 SPEED2 VOLT DEPEND Range: Disabled, Enabled  FUNCTION: Disabled SPEED2 VOLT DEPEND Range: 60 to 99% in steps of 1  MIN MOTOR VOLTS: 80% M60 MOTOR PROTECTION SYSTEM – INSTRUCTION MANUAL 5-221...
Page 430 When two-speed motor functionality is used, these settings allow the selection of proper parameters for the thermal model when the motor is switched to the second speed. There is one thermal model in the M60, and it has inputs for overload conditions from calculations at both speeds.
Page 431 Range: 0.10 to 0.95 × FLA in steps of 0.01  PICKUP: 0.70 x FLA SPEED2 U/CURR ALARM Range: 0.00 to 600.00 s in steps of 0.01  PICKUP DLY: 2.00 s M60 MOTOR PROTECTION SYSTEM – INSTRUCTION MANUAL 5-223...
Page 432 — This setting specifies an operand used to block the speed 2 undercurrent function. A panel cutoff SPEED2 U/CURR BLOCK switch or other user specified condition typically is used to block the function. 5-224 M60 MOTOR PROTECTION SYSTEM – INSTRUCTION MANUAL...
Page 433: Stator Differential (Ansi 87S)
STATOR DIFF Range: Self-reset, Latched, Disabled  TARGET: Self-reset STATOR DIFF Range: Disabled, Enabled  EVENTS: Disabled The stator differential protection element is intended for use on the stator windings of rotating machinery. M60 MOTOR PROTECTION SYSTEM – INSTRUCTION MANUAL 5-225...
Page 434 — This setting defines the end of the transition region and the start of the Slope 2 region. Set it to the STATOR DIFF BREAK 2 level at which any of the protection CTs are expected to begin to saturate. 5-226 M60 MOTOR PROTECTION SYSTEM – INSTRUCTION MANUAL...
Page 435 In order to provide additional security against maloperations during these events, the M60 incorporates saturation detection logic. When saturation is detected, the element makes an additional check on the angle between the neutral and output current. If this angle indicates an internal fault, then tripping is permitted.
Page 436 DIR = flag indicating that the phase comparison principle is satisfied = breakpoint 1 setting = current at the terminal and neutral sources, respectively K = factory constant of 0.25 Figure 5-126: Stator differential final output logic 5-228 M60 MOTOR PROTECTION SYSTEM – INSTRUCTION MANUAL...
Page 437: Power
The operating quantity is displayed in the actual value. ACTUAL VALUES  METERING  SENSITIVE DIRECTIONAL POWER 1(2) The element has two independent (as to the pickup and delay settings) stages for alarm and trip, respectively. M60 MOTOR PROTECTION SYSTEM – INSTRUCTION MANUAL 5-229...
Page 438 For example, section (a) in the figure shows settings for reverse power, while section (b) shows settings for low forward power applications. 5-230 M60 MOTOR PROTECTION SYSTEM – INSTRUCTION MANUAL...
Page 439 DIR POWER 1 RCA setting to “90°,” active underpower by setting to “180°,” and reactive underpower by DIR POWER 1 RCA DIR POWER 1 RCA setting to “270°.” DIR POWER 1 RCA M60 MOTOR PROTECTION SYSTEM – INSTRUCTION MANUAL 5-231...
Page 440 UNDERPOWER 1 ALARM Range: 0.00 to 600.00 s in steps of 0.01  PICKUP DLY: 2.00 s UNDERPOWER 1 TRIP Range: 0.05 to 2.00 pu in steps of 0.01  PWR PICKUP: 0.50 pu 5-232 M60 MOTOR PROTECTION SYSTEM – INSTRUCTION MANUAL...
Page 441 — This setting specifies an operand used to block the underpower function. A panel cutoff switch or UNDERPOWER 1 BLOCK other user specified condition typically is used to block the function. M60 MOTOR PROTECTION SYSTEM – INSTRUCTION MANUAL 5-233...
Page 442: Phase Current
 DIRECTIONAL 2 5.7.6.2 Inverse TOC curve characteristics The inverse time overcurrent curves used by the time overcurrent elements are the IEEE, IEC, GE Type IAC, and I t standard curve shapes. This allows for simplified coordination with downstream devices.
Page 443 1.626 136.090 57.130 21.880 12.010 7.780 5.564 4.255 3.416 2.845 2.439 181.454 76.174 29.174 16.014 10.374 7.419 5.674 4.555 3.794 3.252 10.0 226.817 95.217 36.467 20.017 12.967 9.274 7.092 5.693 4.742 4.065 M60 MOTOR PROTECTION SYSTEM – INSTRUCTION MANUAL 5-235...
Page 444 Current ( I / I pickup (TDM) 10.0 IEC Curve A 0.05 0.860 0.501 0.315 0.249 0.214 0.192 0.176 0.165 0.156 0.149 0.10 1.719 1.003 0.630 0.498 0.428 0.384 0.353 0.330 0.312 0.297 5-236 M60 MOTOR PROTECTION SYSTEM – INSTRUCTION MANUAL...
Page 445 = Pickup Current setting A to E = constants defined in the table = characteristic constant defined in the table = reset time in seconds (assuming energy capacity is 100% and RESET is “Timed”) RESET M60 MOTOR PROTECTION SYSTEM – INSTRUCTION MANUAL 5-237...
Page 446 GROUPED ELEMENTS CHAPTER 5: SETTINGS Table 5-30: GE type IAC inverse time curve constants IAC curve shape IAC Extreme Inverse 0.0040 0.6379 0.6200 1.7872 0.2461 6.008 IAC Very Inverse 0.0900 0.7955 0.1000 –1.2885 7.9586 4.678 IAC Inverse 0.2078 0.8630 0.8000 –0.4180...
Page 447 The curve multiplier of 0.00 to 600.00 makes this delay adjustable from instantaneous to 600.00 seconds in steps of 10 ms. The definite time curve shapes are defined as follows: Eq. 5-35 Eq. 5-36 M60 MOTOR PROTECTION SYSTEM – INSTRUCTION MANUAL 5-239...
Page 448 = Reset Time in seconds (assuming energy capacity is 100% and RESET: Timed) RESET Recloser curves The M60 uses the FlexCurve feature to facilitate programming of 41 recloser curves. See the FlexCurves settings section earlier in this chapter for details. 5.7.6.3 Phase time overcurrent (ANSI 51P, IEC PTOC) SETTINGS ...
Page 449 — Selects the signal source for the phase time overcurrent protection element. SIGNAL SOURCE — Selects how phase current input quantities are interpreted by the M60. Inputs can be selected as fundamental INPUT phasor magnitudes or total waveform RMS magnitudes as required by the application.
Page 450 PHASE IOC1 BLOCK A: Range: FlexLogic operand   PHASE IOC1 BLOCK C: Range: FlexLogic operand  PHASE IOC1 Range: Self-reset, Latched, Disabled  TARGET: Self-reset PHASE IOC1 Range: Disabled, Enabled  EVENTS: Disabled 5-242 M60 MOTOR PROTECTION SYSTEM – INSTRUCTION MANUAL...
Page 451 Range: 0.004 to 3.000 pu in steps of 0.001  THRESHOLD: 0.700 pu PHASE DIR 1 BLOCK Range: No, Yes  WHEN V MEM EXP: No PHASE DIR 1 Range: Self-reset, Latched, Disabled  TARGET: Self-reset M60 MOTOR PROTECTION SYSTEM – INSTRUCTION MANUAL 5-243...
Page 452 (phase current) and the polarizing signal (the line voltage, shifted in the leading direction by the characteristic angle, ECA). The table shows the operating and polarizing signals used for phase directional control. 5-244 M60 MOTOR PROTECTION SYSTEM – INSTRUCTION MANUAL...
Page 453 When set to "No," the directional element allows tripping of phase overcurrent elements under directional control. — This setting enables and disables the logging of phase directional overcurrent events in the PHASE DIR 1 EVENTS sequence of events recorder. M60 MOTOR PROTECTION SYSTEM – INSTRUCTION MANUAL 5-245...
Page 454: Neutral Current
 NEUTRAL TOC 1 See below      NEUTRAL TOC 6    NEUTRAL IOC 1 See page 5-248     NEUTRAL IOC 12   5-246 M60 MOTOR PROTECTION SYSTEM – INSTRUCTION MANUAL...
Page 455 — This setting selects the signal source for the neutral time overcurrent protection element. NEUTRAL TOC1 SIGNAL SOURCE — This setting selects how neutral current input quantities are interpreted by the M60. Inputs can be NEUTRAL TOC1 INPUT selected as fundamental phasor magnitudes or total waveform RMS magnitudes as required by the application.
Page 456 The positive-sequence restraint allows for more sensitive settings by counterbalancing spurious zero-sequence currents resulting from: • System unbalances under heavy load conditions • Transformation errors of current transformers (CTs) during double-line and three-phase faults • Switch-off transients during double-line and three-phase faults 5-248 M60 MOTOR PROTECTION SYSTEM – INSTRUCTION MANUAL...
Page 457 VOLT: Calculated V0 NEUTRAL DIR OC1 OP Range: Calculated 3I0, Measured IG  CURR: Calculated 3I0 NEUTRAL DIR OC1 POS- Range: 0.000 to 0.500 in steps of 0.001  SEQ RESTRAINT: 0.063 M60 MOTOR PROTECTION SYSTEM – INSTRUCTION MANUAL 5-249...
Page 458 The following tables define the neutral directional overcurrent element. V_0 is the zero-sequence voltage, I_0 is the zero-sequence current, ECA is the element characteristic angle, and IG is the ground current. 5-250 M60 MOTOR PROTECTION SYSTEM – INSTRUCTION MANUAL...
Page 459 REV LA = 80° (reverse limit angle = the ± angular limit with the ECA for operation) Take the bias into account when using the neutral directional overcurrent element to directionalize other protection elements. M60 MOTOR PROTECTION SYSTEM – INSTRUCTION MANUAL 5-251...
Page 460 For example, if using an autotransformer neutral current as a polarizing source, ensure that a reversal of the ground current does not occur for a high-side fault. Assume that the 5-252 M60 MOTOR PROTECTION SYSTEM – INSTRUCTION MANUAL...
Page 461 — This setting defines the pickup level for the overcurrent unit of the element in the reverse NEUTRAL DIR OC1 REV PICKUP direction. When selecting this setting, keep in mind that the design uses a positive-sequence restraint technique for the “Calculated 3I0” mode of operation. M60 MOTOR PROTECTION SYSTEM – INSTRUCTION MANUAL 5-253...
Page 462: Ground Current
 GROUND CURRENT  GROUND TOC1 See page 5-260      GROUND TOC6    GROUND IOC1 See page 5-261     GROUND IOC12   5-254 M60 MOTOR PROTECTION SYSTEM – INSTRUCTION MANUAL...
Page 463 CHAPTER 5: SETTINGS GROUPED ELEMENTS 5.7.8.2 Inverse TOC curve characteristics The inverse time overcurrent curves used by the time overcurrent elements are the IEEE, IEC, GE Type IAC, and I t standard curve shapes. This allows for simplified coordination with downstream devices.
Page 464 = reset time in seconds (assuming energy capacity is 100% and is “Timed”) RESET RESET Table 5-39: IEC (BS) inverse time curve constants IEC (BS) curve shape IEC Curve A (BS142) 0.140 0.020 IEC Curve B (BS142) 13.500 1.000 43.2 5-256 M60 MOTOR PROTECTION SYSTEM – INSTRUCTION MANUAL...
Page 465 0.415 1.00 3.058 1.778 1.113 0.877 0.752 0.673 0.618 0.576 0.544 0.518 IAC curves The curves for the General Electric type IAC relay family are derived from the formulae: Eq. 5-42 where M60 MOTOR PROTECTION SYSTEM – INSTRUCTION MANUAL 5-257...
Page 466 A to E = constants defined in the table = characteristic constant defined in the table = reset time in seconds (assuming energy capacity is 100% and RESET is “Timed”) RESET Table 5-41: GE type IAC inverse time curve constants IAC curve shape IAC Extreme Inverse 0.0040 0.6379...
Page 467 T = operate time (in seconds) TDM = Multiplier setting I = Input Current = Pickup Current setting pickup = Reset Time in seconds (assuming energy capacity is 100% and : Timed) RESET RESET M60 MOTOR PROTECTION SYSTEM – INSTRUCTION MANUAL 5-259...
Page 468 = Reset Time in seconds (assuming energy capacity is 100% and RESET: Timed) RESET Recloser curves The M60 uses the FlexCurve feature to facilitate programming of 41 recloser curves. See the FlexCurves settings section earlier in this chapter for details. 5.7.8.3 Ground time overcurrent (ANSI 51G, IEC PTOC) SETTINGS ...
Page 469 — This setting selects the signal source for the ground time overcurrent protection element. GROUND TOC1 SIGNAL SOURCE — This setting selects how ground current input quantities are interpreted by the M60. Inputs can be GROUND TOC1 INPUT selected as fundamental phasor magnitudes or total waveform RMS magnitudes as required by the application.
Page 470: Breaker Failure (Ansi 50Bf)
Range: SRC 1, SRC 2, SRC 3, SRC 4  SRC 1 BF1 USE AMP SUPV: Range: Yes, No  BF1 USE SEAL-IN: Range: Yes, No  BF1 3-POLE INITIATE: Range: FlexLogic operand  BF1 BLOCK: Range: FlexLogic operand  5-262 M60 MOTOR PROTECTION SYSTEM – INSTRUCTION MANUAL...
Page 471 Valid only for 1-Pole breaker failure schemes BF1 PH C INITIATE: Range: FlexLogic operand  Valid only for 1-Pole breaker failure schemes φ BF1 BKR POS1 Range: FlexLogic operand  Valid only for 1-Pole breaker failure schemes M60 MOTOR PROTECTION SYSTEM – INSTRUCTION MANUAL 5-263...
Page 472 The high-set detector is enabled after timeout of timer 1 or 2, along with a timer that enables the low-set detector after its delay interval. The delay interval between high-set and low-set is the expected breaker opening time. 5-264 M60 MOTOR PROTECTION SYSTEM – INSTRUCTION MANUAL...
Page 473 The current supervision elements reset in less than 0.7 of a power cycle for any multiple of pickup current as shown in the following figure. Figure 5-143: Breaker failure overcurrent supervision reset time M60 MOTOR PROTECTION SYSTEM – INSTRUCTION MANUAL 5-265...
Page 474 In microprocessor relays this time is not significant. In M60 relays, which use a Fourier transform, the calculated current magnitude ramps-down to zero one power frequency cycle after the current is interrupted, and this lag needs to be included in the overall margin duration, as it occurs after current interruption.
Page 475 Upon operation of the breaker failure element for a single pole trip command, a three-pole trip command needs to be given via output operand BKR FAIL 1 TRIP M60 MOTOR PROTECTION SYSTEM – INSTRUCTION MANUAL 5-267...
Page 476 GROUPED ELEMENTS CHAPTER 5: SETTINGS Figure 5-144: Single-pole breaker failure initiate logic 5-268 M60 MOTOR PROTECTION SYSTEM – INSTRUCTION MANUAL...
Page 477 CHAPTER 5: SETTINGS GROUPED ELEMENTS Figure 5-145: Single-pole breaker failure, timers logic M60 MOTOR PROTECTION SYSTEM – INSTRUCTION MANUAL 5-269...
Page 478 GROUPED ELEMENTS CHAPTER 5: SETTINGS Figure 5-146: Three-pole breaker failure, initiate logic 5-270 M60 MOTOR PROTECTION SYSTEM – INSTRUCTION MANUAL...
Page 479 CHAPTER 5: SETTINGS GROUPED ELEMENTS Figure 5-147: Three-pole breaker failure, timers logic M60 MOTOR PROTECTION SYSTEM – INSTRUCTION MANUAL 5-271...
Page 480: Voltage Elements
The time delay is adjustable from 0 to 600.00 seconds in steps of 0.01. The undervoltage elements can also be programmed to have an inverse time delay characteristic. 5-272 M60 MOTOR PROTECTION SYSTEM – INSTRUCTION MANUAL...
Page 481 Range: 0.00 to 600.00 s in steps of 0.01  DELAY: 1.00 s PHASE UV1 MINIMUM Range: 0.000 to 3.000 pu in steps of 0.001  VOLTAGE: 0.100 pu PHASE UV1 BLOCK: Range: FlexLogic operand  M60 MOTOR PROTECTION SYSTEM – INSTRUCTION MANUAL 5-273...
Page 482 Range: 0.00 to 600.00 s in steps of 0.01  DELAY: 1.00 s PHASE OV1 BLOCK: Range: FlexLogic Operand  PHASE OV1 Range: Self-reset, Latched, Disabled  TARGET: Self-reset PHASE OV1 Range: Disabled, Enabled  EVENTS: Disabled 5-274 M60 MOTOR PROTECTION SYSTEM – INSTRUCTION MANUAL...
Page 483 Range: 0.00 to 600.00 s in steps of 0.01  DELAY: 1.00 s NEUTRAL OV1 BLOCK: Range: FlexLogic operand  NEUTRAL OV1 TARGET: Range: Self-reset, Latched, Disabled  Self-reset NEUTRAL OV1 EVENTS: Range: Disabled, Enabled  Disabled M60 MOTOR PROTECTION SYSTEM – INSTRUCTION MANUAL 5-275...
Page 484 There are three negative-sequence overvoltage elements available. Use the negative-sequence overvoltage element to detect loss of one or two phases of the source, a reversed phase sequence of voltage, or a non-symmetrical system voltage condition. 5-276 M60 MOTOR PROTECTION SYSTEM – INSTRUCTION MANUAL...
Page 485 Range: Disabled, Enabled  Disabled The M60 contains one auxiliary undervoltage element for each VT bank. This element monitors undervoltage conditions of the auxiliary voltage. selects the voltage level at which the time undervoltage element starts timing. The nominal secondary...
Page 486 Range: Disabled, Enabled  Disabled The M60 contains one auxiliary overvoltage element for each VT bank. This element is intended for monitoring overvoltage conditions of the auxiliary voltage. The nominal secondary voltage of the auxiliary voltage channel entered under SYSTEM is the per-unit (pu) base used when setting the SETUP ...
Page 487: Control Elements
The trip bus element allows aggregating outputs of protection and control elements without using FlexLogic and assigning them a simple and effective manner. Each trip bus can be assigned for either trip or alarm actions. Simple trip conditioning such as latch, delay, and seal-in delay are available. M60 MOTOR PROTECTION SYSTEM – INSTRUCTION MANUAL 5-279...
Page 488 TRIP BUS 1 RESET RESET OP operand is pre-wired to the reset gate of the latch, As such, a reset command from the front panel interface or via communications resets the trip bus output. 5-280 M60 MOTOR PROTECTION SYSTEM – INSTRUCTION MANUAL...
Page 489: Setting Groups
Prevents the active setting group from changing when the selected FlexLogic operand is "On." This SETTING GROUPS BLK — can be useful in applications where it is undesirable to change the settings under certain conditions, such as during a control sequence. M60 MOTOR PROTECTION SYSTEM – INSTRUCTION MANUAL 5-281...
Page 490: Selector Switch
RANGE: 7 SELECTOR 1 TIME-OUT: Range: 3.0 to 60.0 s in steps of 0.1  5.0 s SELECTOR 1 STEP-UP: Range: FlexLogic operand  SELECTOR 1 STEP-UP Range: Time-out, Acknowledge  MODE: Time-out 5-282 M60 MOTOR PROTECTION SYSTEM – INSTRUCTION MANUAL...
Page 491 (“Acknowledge” mode). When the new position is applied, the relay displays the SELECTOR SWITCH 1: POSITION Z IN USE message. Typically, a user-programmable pushbutton is configured as the stepping up control input. M60 MOTOR PROTECTION SYSTEM – INSTRUCTION MANUAL 5-283...
Page 492 (that is, the three-bit input is not available (0,0,0) or out of range), then the selector switch output is set to position 0 (no output operand selected) and an alarm is established ( SELECTOR 1 PWR ALARM 5-284 M60 MOTOR PROTECTION SYSTEM – INSTRUCTION MANUAL...
Page 493 The selector position pre-selected via the three-bit control input has not been confirmed before the time The following figures illustrate the operation of the selector switch. In these diagrams, “T” represents a time-out setting. M60 MOTOR PROTECTION SYSTEM – INSTRUCTION MANUAL 5-285...
Page 494 CONTROL ELEMENTS CHAPTER 5: SETTINGS Figure 5-158: Time-out mode 5-286 M60 MOTOR PROTECTION SYSTEM – INSTRUCTION MANUAL...
Page 495 1 through 3. The pre-selected setting group is to be applied automatically after five seconds of inactivity of the control inputs. When the relay powers up, it is to synchronize the setting group to the three-bit control input. M60 MOTOR PROTECTION SYSTEM – INSTRUCTION MANUAL 5-287...
Page 496 SETTINGS  PRODUCT menu: SETUP  USER-PROGRAMMABLE PUSHBUTTONS  USER PUSHBUTTON 1 : “Self-reset” PUSHBUTTON 1 FUNCTION : “0.10 s” PUSHBUTTON 1 DROP-OUT TIME The figure shows the logic for the selector switch. 5-288 M60 MOTOR PROTECTION SYSTEM – INSTRUCTION MANUAL...
Page 497: Underfrequency (Ansi 81U)
 DELAY : 2.000 s UNDERFREQ 1 TARGET: Range: Self-reset, Latched, Disabled  Self-reset UNDERFREQ 1 EVENTS: Range: Disabled, Enabled  Disabled There are six identical underfrequency elements, numbered 1 through 6. M60 MOTOR PROTECTION SYSTEM – INSTRUCTION MANUAL 5-289...
Page 498: Overfrequency (Ansi 81O)
The channels are searched for the signal input in the following order: voltage channel A, auxiliary voltage channel, current channel A, and ground current channel. The first available signal is used for frequency calculation. 5-290 M60 MOTOR PROTECTION SYSTEM – INSTRUCTION MANUAL...
Page 499: Motor Start Supervision
A method to prevent starting is by wiring an M60 output contact actuated by motor start supervision elements in the motor energizing control circuit. The output contact changes state only when the motor is stopped to accommodate control circuits that must be continuously energized, such as a contactor.
Page 500 The element uses motor status asserted by the Thermal Model element. The thermal protection must be configured properly in order for this function to operate. Figure 5-163: Maximum starting rate logic 5-292 M60 MOTOR PROTECTION SYSTEM – INSTRUCTION MANUAL...
Page 501 RESTART DELAY Range: Disabled, Enabled   FUNCTION: Disabled RESTART DELAY Range: 0 to 50000 s in steps of 1  MIN TIME: 0 s RESTART DELAY BLOCK: Range: FlexLogic operand  M60 MOTOR PROTECTION SYSTEM – INSTRUCTION MANUAL 5-293...
Page 502: Reduced Voltage Starting
 Disabled The M60 can control the transition of a motor start from reduced to full voltage. This feature uses motor load and a supervisory timer to initiate a one second control signal (the operand) that can be used to switch to full REDUCED VOLT CTRL voltage.
Page 503 Set it greater than the product of the setting and the MOTOR FULL LOAD AMPS MOTOR OVERLOAD REDUCED VOLT CTRL setting. See the Motor section under the menu for details. FACTOR SETTINGS  SYSTEM SETUP  MOTOR M60 MOTOR PROTECTION SYSTEM – INSTRUCTION MANUAL 5-295...
Page 504: Digital Elements
Do not use digital elements with transient signals, such as communications commands. Do not use digital elements where random delays of up to one cycle cannot be tolerated, such as in high speed protection. 5-296 M60 MOTOR PROTECTION SYSTEM – INSTRUCTION MANUAL...
Page 505 In most breaker control circuits, the trip coil is connected in series with a breaker auxiliary contact that is open when the breaker is open (see figure). To prevent unwanted alarms in this situation, the trip circuit monitoring logic must include the breaker position. M60 MOTOR PROTECTION SYSTEM – INSTRUCTION MANUAL 5-297...
Page 506 Using the contact input settings, this input is given an ID name, for example, “Cont Ip 1," and is set “On” when the breaker is closed. The settings to use digital element 1 to monitor the breaker trip circuit are indicated (EnerVista example shown). 5-298 M60 MOTOR PROTECTION SYSTEM – INSTRUCTION MANUAL...
Page 507: Digital Counters
 COUNTER 1 COUNTER 1 Range: Disabled, Enabled  FUNCTION: Disabled  COUNTER 1 NAME: Range: up to 12 alphanumeric characters  Counter 1 COUNTER 1 UNITS: Range: up to six alphanumeric characters  M60 MOTOR PROTECTION SYSTEM – INSTRUCTION MANUAL 5-299...
Page 508 If control power is interrupted, the accumulated and frozen values are saved into non-volatile memory during the power-down operation. 5-300 M60 MOTOR PROTECTION SYSTEM – INSTRUCTION MANUAL...
Page 509: Monitoring Elements
 BREAKER RESTRIKE 1 See page 5-310    BREAKER RESTRIKE 2    CT FAILURE See page 5-312   DETECTOR 1   CT FAILURE   DETECTOR 4 M60 MOTOR PROTECTION SYSTEM – INSTRUCTION MANUAL 5-301...
Page 510 The feature is programmed to perform fault duration calculations. Fault duration is defined as a time between operation of the disturbance detector occurring before initiation of this feature, and reset of an internal low-set overcurrent function. Correction is implemented to account for a non-zero reset time of the overcurrent function. 5-302 M60 MOTOR PROTECTION SYSTEM – INSTRUCTION MANUAL...
Page 511 -cycle) and AMP MAX (kA) values of the last event. — This setting specifies the maximum symmetrical interruption rating of the circuit breaker. BKR 1 INTERUPTION RATING Figure 5-172: Arcing current measurement M60 MOTOR PROTECTION SYSTEM – INSTRUCTION MANUAL 5-303...
Page 512 CONTROL ELEMENTS CHAPTER 5: SETTINGS Figure 5-173: Breaker arcing current logic 5-304 M60 MOTOR PROTECTION SYSTEM – INSTRUCTION MANUAL...
Page 513 (contact input indicating the breaker status is off), and no flashover current is flowing. A contact showing the breaker status must be provided to the relay. The voltage difference is not considered as a condition for open breaker in this part of the logic. M60 MOTOR PROTECTION SYSTEM – INSTRUCTION MANUAL 5-305...
Page 514 This application does not require detection of breaker status via a 52a contact, as it uses a voltage difference larger than setting. However, monitoring the breaker contact ensures scheme stability. BRK 1 FLSHOVR DIFF V PKP 5-306 M60 MOTOR PROTECTION SYSTEM – INSTRUCTION MANUAL...
Page 515 (all line breakers open), to well above the maximum line (feeder) load (line/feeder connected to load). M60 MOTOR PROTECTION SYSTEM – INSTRUCTION MANUAL 5-307...
Page 516 A six-cycle time delay applies after the selected FlexLogic operand resets. — This setting specifies the time delay to operate after a pickup condition is detected. BRK FLSHOVR PKP DELAY 5-308 M60 MOTOR PROTECTION SYSTEM – INSTRUCTION MANUAL...
Page 517 CHAPTER 5: SETTINGS CONTROL ELEMENTS Figure 5-174: Breaker flashover logic M60 MOTOR PROTECTION SYSTEM – INSTRUCTION MANUAL 5-309...
Page 518  EVENTS: Disabled One breaker restrike element is provided for each DSP in the M60. According to IEEE standard C37.100 entitled IEEE Standard Definitions for Power Switchgear, restrike is defined as “a resumption of current between the contacts of a switching device during an opening operation after an interval of zero current of ¼...
Page 519 — Specifies the reset delay for this element. When set to “0 ms,” then FlexLogic operand is BREAKER RESTRIKE 1 RESET DELAY picked up for only 1/8th of the power cycle. M60 MOTOR PROTECTION SYSTEM – INSTRUCTION MANUAL 5-311...
Page 520 CT FAIL 1 3V0 INPUT Range: 0.04 to 2.00 pu in steps of 0.01  PKP: 0.20 pu CT FAIL 1 PICKUP Range: 0.000 to 65.535 s in steps of 0.001  DELAY: 1.000 s 5-312 M60 MOTOR PROTECTION SYSTEM – INSTRUCTION MANUAL...
Page 521 CT FAIL 1 3V0 INPUT — Specifies the pickup value for the 3V_0 source. CT FAIL 1 3V0 INPUT PICKUP — Specifies the pickup delay of the CT failure element. CT FAIL 1 PICKUP DELAY M60 MOTOR PROTECTION SYSTEM – INSTRUCTION MANUAL 5-313...
Page 522 Once the fuse failure condition is declared, it is sealed-in until the cause that generated it disappears. 5-314 M60 MOTOR PROTECTION SYSTEM – INSTRUCTION MANUAL...
Page 523 START OF BRB Range: –12.00 to 11.99 Hz in steps of 0.01  OFFSET: 0.40 Hz END OF BRB Range: –11.99 to 12.00 Hz in steps of 0.01  OFFSET: 2.00 Hz M60 MOTOR PROTECTION SYSTEM – INSTRUCTION MANUAL 5-315...
Page 524  EVENTS: Disabled The M60 is provided with optional broken rotor bar detection. This feature is specified as an option at the time of ordering. See the Order Codes section in chapter 2 for details. The broken rotor bar detection function uses the same source as other motor protection functions. This source is defined by the setting.
Page 525 — This setting specifies the pickup threshold for the broken rotor bar detection feature. The BROKEN ROTOR BAR PICKUP pickup threshold normally is set to a level between –54 dB (very likely, a cracked rotor bar) and –50 dB (probably a broken rotor bar). M60 MOTOR PROTECTION SYSTEM – INSTRUCTION MANUAL 5-317...
Page 526: Inputs/Outputs
The DC input voltage is compared to a user-settable threshold. A new contact input state must be maintained for a user-settable debounce time in order for the M60 to validate the new contact state. In the following figure, the debounce time is set at 2.5 ms;...
Page 527 CONTACT INPUT THRESHOLDS value is selected according to the following criteria: 17 for 24 V sources, 33 for 48 V sources, 84 for 110 to 125 V sources and 166 for 250 V sources. M60 MOTOR PROTECTION SYSTEM – INSTRUCTION MANUAL 5-319...
Page 528: Virtual Inputs
FlexLogic equation, it likely needs to be lengthened in time. A FlexLogic timer with a delayed reset can perform this function. Figure 5-181: Virtual inputs logic 5-320 M60 MOTOR PROTECTION SYSTEM – INSTRUCTION MANUAL...
Page 529: Contact Outputs
1" : any suitable FlexLogic operand OUTPUT H1 OPERATE “Cont Op 1 OUTPUT H1 SEAL-IN IOn” : “Enabled” CONTACT OUTPUT H1 EVENTS Figure 5-182: Contact input/output module type 6A contact 1 logic M60 MOTOR PROTECTION SYSTEM – INSTRUCTION MANUAL 5-321...
Page 530 Figure 5-183: Contact input/output module type 4L contact 1 logic Application example 1 A latching output contact H1a is to be controlled from two user-programmable pushbuttons (buttons number 1 and 2). The following settings are applied. 5-322 M60 MOTOR PROTECTION SYSTEM – INSTRUCTION MANUAL...
Page 531 (assuming an H4L module): OUTPUTS  CONTACT OUTPUT H1a CONTACT OUTPUT H1c : “VO1” OUTPUT H1a OPERATE : “VO4” OUTPUT H1a RESET : “VO2” OUTPUT H1c OPERATE : “VO3” OUTPUT H1c RESET M60 MOTOR PROTECTION SYSTEM – INSTRUCTION MANUAL 5-323...
Page 532: Virtual Outputs
VIRTUAL OUTPUT 1 ID : "Disabled" VIRTUAL OUTPUT 1 EVENTS 5.9.5 Resetting 5.9.5.1 Enhanced and standard front panels SETTINGS  INPUTS/OUTPUTS  RESETTING  RESETTING RESET OPERAND: Range: FlexLogic operand   5-324 M60 MOTOR PROTECTION SYSTEM – INSTRUCTION MANUAL...
Page 533: Direct Inputs And Outputs
 EVENTS: Disabled These settings specify how the direct input information is processed. — This setting allows the user to assign a descriptive name to the direct input. DIRECT INPUT 1 NAME M60 MOTOR PROTECTION SYSTEM – INSTRUCTION MANUAL 5-325...
Page 534 Assume that contact input 1 from UR IED 2 is to be used by UR IED 1. The following settings are applied (Direct Input 5 and bit number 12 are used, as an example). UR IED 1: 5-326 M60 MOTOR PROTECTION SYSTEM – INSTRUCTION MANUAL...
Page 535 (if any default state is set to “On”), or to trip the bus on any overcurrent condition (all default states set to “Off”). Example 3: Pilot-aided schemes Consider a three-terminal line protection application shown in the following figure. M60 MOTOR PROTECTION SYSTEM – INSTRUCTION MANUAL 5-327...
Page 536 5" (forward a message from 1 to 3) DIRECT OUT 3 OPERAND "DIRECT INPUT 6" (forward a message from 3 to 1) DIRECT OUT 4 OPERAND The figure shows the signal flow among the three IEDs. 5-328 M60 MOTOR PROTECTION SYSTEM – INSTRUCTION MANUAL...
Page 537: Teleprotection
The “Latest/On” and “Latest/Off” values freeze the input in case of lost communications. If the latest state is not known, such as after relay power-up but before the first communication exchange, then the input defaults to logic 1 for “Latest/ On” and logic 0 for “Latest/Off.” M60 MOTOR PROTECTION SYSTEM – INSTRUCTION MANUAL 5-329...
Page 538 (teleprotection outputs at the sending end or corresponding teleprotection inputs at the receiving end). On three-terminal two-channel systems, redundancy is achieved by programming signal re-transmittal in the case of channel failure between any pair of relays. Figure 5-189: Teleprotection input/output processing 5-330 M60 MOTOR PROTECTION SYSTEM – INSTRUCTION MANUAL...
Page 539: Transducer Inputs/Outputs
VALUE: 0.000 The M60 is provided with optional DCmA capability. This feature is specified as an option at the time of ordering. See the Order Codes section in chapter 2 for details. Hardware and software are provided to receive signals from external transducers and to convert these signals into a digital format for use as required.
Page 540: Rtd Inputs
— Specifies the RTD type. Four different RTD types are available: 100 Ω Nickel, 10 Ω Copper, 100 Ω RTD INPUT H1 TYPE Platinum, and 120 Ω Nickel. The following table outlines reference temperature values for each type. 5-332 M60 MOTOR PROTECTION SYSTEM – INSTRUCTION MANUAL...
Page 541 A value of “None” specifies that the RTD operates individually and not part of any RTD group. All RTDs programmed to “Stator” are used for RTD biasing of the M60 thermal model. Common groups are provided for rotating machines applications such as ambient, bearing, group 1, or group 2.
Page 542: Rrtd Inputs
Menus are available to configure each of the remote RTDs. It is recommended to use the M60 to configure the RRTD parameters. If the RRTDPC software is used to change the RRTD settings directly (the application and type settings), then one of the following two operations is required for changes to be reflected in the M60: •...
Page 543 RTD types in common use. Hardware details are contained in chapter 3. On power up, the M60 reads and saves all application and type settings from the RRTD. This synchronizes the RRTD and M60.
Page 544 A value of “None” specifies that the remote RTD operates individually and not part of any RTD group. All remote RTDs programmed to “Stator” are used for RTD biasing of the M60 thermal model. Common groups are provided for rotating machines applications, such as ambient, bearing, group 1, or group 2.
Page 545: Dcma Outputs
Range: Off, any analog actual value parameter   SOURCE: Off DCMA OUTPUT H1 Range: –1 to 1 mA, 0 to 1 mA, 4 to 20 mA  RANGE: –1 to 1 mA M60 MOTOR PROTECTION SYSTEM – INSTRUCTION MANUAL 5-337...
Page 546 MAX VAL MIN VAL MAX VAL – < 0.1 pu. The resulting characteristic is illustrated in the following figure. MIN VAL Figure 5-192: DCmA output characteristic Settings 5-338 M60 MOTOR PROTECTION SYSTEM – INSTRUCTION MANUAL...
Page 547 ±1% of reading error for the active power at power factor of 0.9 For example at the reading of 20 MW, the worst-case error is 0.01 × 20 MW + 0.207 MW = 0.407 MW. M60 MOTOR PROTECTION SYSTEM – INSTRUCTION MANUAL 5-339...
Page 548 6), while at the same time the VT nominal voltage is 1 pu for the settings. Consequently the settings required in this example differ from naturally expected by the factor of The worst-case error for this application could be calculated by superimposing the following two sources of error: 5-340 M60 MOTOR PROTECTION SYSTEM – INSTRUCTION MANUAL...
Page 549: Testing
 FUNCTION: Disabled The M60 provides a test facility to verify the functionality of contact inputs and outputs, some communication functions and the phasor measurement unit (where applicable), using simulated conditions. The test mode can be in any of three states: Disabled, Isolated, or Forcible.
Page 550: Test Mode Forcing
  When in Forcible mode, the operand selected by the setting dictates further response of the M60 to TEST MODE FORCING testing conditions, as described in the following two sections. The test mode state is indicated on the relay front panel by a combination of the Test Mode LED indicator, the In-Service LED indicator, and by the critical fail relay, as shown in the following table.
Page 551: Force Contact Outputs
While the selected operand is Off, the output behaves as it does when in service. On restart, the setting and the force contact input and force contact output settings revert to TEST MODE FORCING their default states. M60 MOTOR PROTECTION SYSTEM – INSTRUCTION MANUAL 5-343...
Page 552 TESTING CHAPTER 5: SETTINGS 5-344 M60 MOTOR PROTECTION SYSTEM – INSTRUCTION MANUAL...
Page 553: Actual Values
  VIRTUAL OUTPUTS See page 6-6    RxGOOSE STATUS See page 6-6    RxGOOSE See page 6-7   STATISTICS  DIGITAL COUNTERS See page 6-7   M60 MOTOR PROTECTION SYSTEM – INSTRUCTION MANUAL...
Page 554 See page 6-21    RxGOOSE Analogs See page 6-22    TRANSDUCER I/O See page 6-23   DCMA INPUTS  TRANSDUCER I/O See page 6-23    RTD INPUTS M60 MOTOR PROTECTION SYSTEM – INSTRUCTION MANUAL...
Page 555: Front Panel
The feature applies to the enhanced and standard front panels. To view the front panel in EnerVista software: Click Actual Values > Front Panel. Figure 6-1: Front panel use in the software (C60 shown) M60 MOTOR PROTECTION SYSTEM – INSTRUCTION MANUAL...
Page 556: Status
The present status of the contact inputs is shown here. The first line of a message display indicates the ID of the contact input. For example, ‘Cont Ip 1’ refers to the contact input in terms of the default name-array index. The second line of the display indicates the logic state of the contact input. M60 MOTOR PROTECTION SYSTEM – INSTRUCTION MANUAL...
Page 557: Virtual Inputs
Range: On, Off  STATUS: Off The M60 is provided with optional IEC 61850 capability. This feature is specified as a software option at the time of ordering. See the Order Codes section of chapter 2 for details. 6.3.5 RxGOOSE DPS inputs ACTUAL VALUES ...
Page 558: Contact Outputs
 Offline The M60 is provided with optional IEC 61850 capability. This feature is specified as a software option at the time of ordering. See the Order Codes section of chapter 2 for details. M60 MOTOR PROTECTION SYSTEM – INSTRUCTION MANUAL...
Page 559: Rxgoose Statistics
 IGMP: The M60 is provided with optional IEC 61850 capability. This feature is specified as a software option at the time of ordering. See the Order Codes section of chapter 2 for details. — State number. The most recently received value in GOOSE message field stNum. The publisher increments stNum stNum each time that the state of one or more of the GOOSE message members is sent with a revised value.
Page 560: Flexstates
PTP Clock, Port 2 PTP Clock, Port 3 PTP Clock, IRIG-B, Other, and None, where "Other" means any less precise source (SNTP, IEC 103, IEC 104, or DNP). An actual value displays when the relay includes the IEEE 1588 software option. M60 MOTOR PROTECTION SYSTEM – INSTRUCTION MANUAL...
Page 561: Direct Inputs
The UNRETURNED MSG COUNT CRC FAIL values can be cleared using the command. COUNT CLEAR DIRECT I/O COUNTERS values represent the state of each direct input. DIRECT INPUT 1 DIRECT INPUT (32) M60 MOTOR PROTECTION SYSTEM – INSTRUCTION MANUAL...
Page 562: Direct Devices Status
CHANNEL 2 LOST Range: 1 to 65535 in steps of 1  PACKETS: VALIDITY OF CHANNEL Range: n/a, FAIL, OK  CONFIGURATION: FAIL The status information for two channels is shown here. 6-10 M60 MOTOR PROTECTION SYSTEM – INSTRUCTION MANUAL...
Page 563: Remaining Connection Status
Range: 0 to 4G, blank if PRP disabled  Mismatches Port B: Range: 0 to 4G, blank if PRP disabled  Total Errors: Range: 0 to 4G, blank if PRP disabled  M60 MOTOR PROTECTION SYSTEM – INSTRUCTION MANUAL 6-11...
Page 564: Txgoose Status
METERING CHAPTER 6: ACTUAL VALUES The M60 is provided with optional PRP capability. This feature is specified as a software option at the time of ordering. See the Order Codes section in chapter 2 for details. is a counter for total messages received (either from DANPs or from SANs) on Port A.
Page 565 6.4.1.2 UR convention for measuring phase angles All phasors calculated by URs and used for protection, control and metering functions are rotating phasors that maintain the correct phase angle relationships with each other at all times. M60 MOTOR PROTECTION SYSTEM – INSTRUCTION MANUAL 6-13...
Page 566 For display and oscillography purposes the phase angles of symmetrical components are referenced to a common reference as described in the previous sub-section. WYE-connected instrument transformers • ABC phase rotation: • ACB phase rotation: The above equations apply to currents as well. 6-14 M60 MOTOR PROTECTION SYSTEM – INSTRUCTION MANUAL...
Page 567 * The power system voltages are phase-referenced – for simplicity – to V and V , respectively. This, however, is a relative matter. It is important to remember that the M60 displays are always referenced as specified under SETTINGS  SYSTEM SETUP  POWER SYSTEM  FREQUENCY AND PHASE REFERENCE The example above is illustrated in the following figure.
Page 568: Stator Differential
 SRC 1  GROUND CURRENT See page 6-17   SRC 1  PHASE VOLTAGE See page 6-18   SRC 1  AUXILIARY VOLTAGE See page 6-18   SRC 1 6-16 M60 MOTOR PROTECTION SYSTEM – INSTRUCTION MANUAL...
Page 569 ACTUAL VALUES  METERING  SOURCE SRC 1  GROUND CURRENT  GROUND CURRENT SRC 1 RMS Ig:   SRC 1 0.000 A SRC 1 PHASOR Ig:  0.000 A 0.0° M60 MOTOR PROTECTION SYSTEM – INSTRUCTION MANUAL 6-17...
Page 570 ACTUAL VALUES  METERING  SOURCE SRC 1  AUXILIARY VOLTAGE  AUXILIARY VOLTAGE SRC 1 RMS Vx:   SRC 1 0.00 V SRC 1 PHASOR Vx:  0.000 V 0.0° 6-18 M60 MOTOR PROTECTION SYSTEM – INSTRUCTION MANUAL...
Page 571 S = V x Î x Î x Î Eq. 6-1 When VTs are configured in delta, the M60 does not calculate power in each phase and three-phase power is measured as S = V x Î x Î Eq. 6-2...
Page 572: Sensitive Directional Power
ACTUAL VALUES  METERING  BROKEN ROTOR BAR  BROKEN ROTOR BAR COMPONENT LEVEL:   -60.0 dB COMPONENT FREQ.:  61.85 Hz MOTOR LOAD AT BRB  CALC.: 0.81 x FLA 6-20 M60 MOTOR PROTECTION SYSTEM – INSTRUCTION MANUAL...
Page 573: Tracking Frequency
ACTUAL VALUES  METERING  FLEXELEMENTS  FLEXELEMENT 1(16)  FLEXELEMENT 1 FLEXELEMENT 1   OpSig: 0.000 The operating signals for the FlexElements are displayed in pu values using the following definitions of the base units. M60 MOTOR PROTECTION SYSTEM – INSTRUCTION MANUAL 6-21...
Page 574: Rxgoose Analogs
 0.000 The M60 is provided with optional GOOSE communications capability. This feature is specified as a software option at the time of ordering. See the Order Codes section of chapter 2 for details. The RxGOOSE Analog values display in this menu. The RxGOOSE Analog values are received via IEC 61850 GOOSE messages sent from other devices.
Page 575: Transducer Inputs And Outputs
ACTUAL VALUES  RECORDS  STARTING RECORDS  MOTOR START 1(5) NO STARTING RECORDS TO REPORT  MOTOR START 1 START 1 DATE: Range: Date in format YYYY/MM/DD  2002/08/11  START 1 TIME: Range: Time in format HH:MM:SS.ssssss  00:00:00.000000 M60 MOTOR PROTECTION SYSTEM – INSTRUCTION MANUAL 6-23...
Page 576: Motor Learned Data
The learned values for acceleration time and effective starting current are the maximum of the individual values acquired for the last N successful starts, where N is defined by the setting. NUMBER OF STARTS TO LEARN 6-24 M60 MOTOR PROTECTION SYSTEM – INSTRUCTION MANUAL...
Page 577 The starting capacity, starting current, and acceleration time values for the last start are displayed in the ACTUAL VALUES  menu. Clearing the motor data (see the Clear Records section in chapter 7) resets these values to their STATUS  MOTOR default. Figure 6-5: Motor learned data functionality M60 MOTOR PROTECTION SYSTEM – INSTRUCTION MANUAL 6-25...
Page 578: Event Records
Figure 6-6: Event records viewed in EnerVista software 6.5.4.2 Graphical front panel To display the event records page, press the Home pushbutton then the Event Record Tab pushbutton. The newest event is always at the top. 6-26 M60 MOTOR PROTECTION SYSTEM – INSTRUCTION MANUAL...
Page 579: Oscillography
COMMANDS  CLEAR menu for information on clearing the oscillography records. RECORDS 6.5.6 Data logger ACTUAL VALUES  RECORDS  DATA LOGGER  DATA LOGGER OLDEST SAMPLE TIME:  2000/01/14 13:45:51  M60 MOTOR PROTECTION SYSTEM – INSTRUCTION MANUAL 6-27...
Page 580: Breaker Maintenance
BREAKER OPERATING TIME All of the values are stored in non-volatile memory and retained with power cycling. 6-28 M60 MOTOR PROTECTION SYSTEM – INSTRUCTION MANUAL...
Page 581: Product Information
FRONT PANEL PROGRAM Range: 0.00 to 655.35  REVISION: 2.01 Revision number of front panel program firmware. COMPILE DATE: Range: YYYY/MM/DD HH:MM:SS  2016/09/15 04:55:16 Date and time when product firmware was built. M60 MOTOR PROTECTION SYSTEM – INSTRUCTION MANUAL 6-29...
Page 582 The shown data is illustrative only. A modification file number of 0 indicates that, currently, no modifications have been installed. The date format reflects the format specified for the clock and can vary from that shown here. 6-30 M60 MOTOR PROTECTION SYSTEM – INSTRUCTION MANUAL...
Page 583: Commands And Targets
The commands menu contains relay directives intended for operations personnel. All commands can be protected from unauthorized access via the command password; see the Security section of chapter 5 for details. The following flash message appears after successfully command entry. COMMAND EXECUTED M60 MOTOR PROTECTION SYSTEM – INSTRUCTION MANUAL...
Page 584: Virtual Inputs
This menu contains commands for clearing historical data such as the event records. Data is cleared by changing a command setting to “Yes” and pressing the key. After clearing data, the command setting automatically reverts to ENTER “No.” M60 MOTOR PROTECTION SYSTEM – INSTRUCTION MANUAL...
Page 585: Set Date And Time
PERFORM PUSHBUTTON Range: No, Yes  TEST? No UPDATE ORDER CODE? Range: No, Yes  REBOOT RELAY? Range: No, Yes  SERVICE COMMAND Range: 0, 101  SAVE VOLATILE DATA? Range: No, Yes  M60 MOTOR PROTECTION SYSTEM – INSTRUCTION MANUAL...
Page 586: Security
Although the diagnostic information is cleared before the M60 is shipped from the factory, the user can want to clear the diagnostic information for themselves under certain circumstances. For example, you clear diagnostic information after replacement of hardware.
Page 587: Targets Menu
A target enables the EnerVista UR Setup software to monitor automatically and display the status of any active target messages of all the devices inserted into that site. Each M60 element with a TARGET setting has a target message that when activated by its element is displayed in sequence with any other currently active target messages in the menu.
Page 588: Relay Self-Tests
Contact Factory (xxx) • Latched target message: Yes. • Description of problem: One or more installed hardware modules is not compatible with the M60 order code. • How often the test is performed: Module dependent. • What to do: Contact the factory and supply the failure code noted in the display. The “xxx” text identifies the failed module (for example, F8L).
Page 589 MAINTENANCE ALERT: Direct I/O Ring Break • Latched target message: No. • Description of problem: Direct input and output settings are configured for a ring, but the connection is not in a ring. M60 MOTOR PROTECTION SYSTEM – INSTRUCTION MANUAL...
Page 590 Latched target message: No. • Description of problem: A data item in a configurable GOOSE data set is oscillating. • How often the test is performed: Upon scanning of each configurable GOOSE data set. M60 MOTOR PROTECTION SYSTEM – INSTRUCTION MANUAL...
Page 591 This time can be from milliseconds to minutes. • What to do: Check GOOSE setup. TEMP MONITOR: OVER TEMPERATURE • Latched target message: Yes. M60 MOTOR PROTECTION SYSTEM – INSTRUCTION MANUAL...
Page 592 V-type CPU = All ports support RJ45 SFPs only The consequence of an incorrect SFP can range from damage to the M60 to no power information for the M60 on its web page (enter IP address in a web browser, then click the SFP Transceiver Information. Only the type of SFP displays and not power data).
Page 593 Any abnormal diagnostic condition indicated by the LEDs or the critical failure relay also results in a self-test Plus message, so troubleshooting is described here. For other relays, such at the B95 , see that product’s instruction manual. M60 MOTOR PROTECTION SYSTEM – INSTRUCTION MANUAL 7-11...
Page 594 Brick, but there is a discrepancy between the settings and the actual Brick serial number, order code, and/or core number. Check that the correct core on the correct Brick is patched through to the correct Process Card 7-12 M60 MOTOR PROTECTION SYSTEM – INSTRUCTION MANUAL...
Page 595 Brick output failing to respond to an output command can only be detected while the command is active, and so in this case the target is latched. A latched target can be unlatched by pressing the front panel reset key if the command has ended, however the output can still be non-functional. M60 MOTOR PROTECTION SYSTEM – INSTRUCTION MANUAL 7-13...
Page 596 TARGETS MENU CHAPTER 7: COMMANDS AND TARGETS 7-14 M60 MOTOR PROTECTION SYSTEM – INSTRUCTION MANUAL...
Page 597: Commissioning
Injection to a particular M60 frequency element must be to its configured source and to the channels that the source uses for frequency measurement. For frequency measurement, a source uses the first quantity configured in the following...
Page 598 Do not use the tracking frequency in timing measurements, as its algorithm involves phase locking, which purposely sets its frequency high or low to allow the M60 sample clock to catch-up or wait as necessary to reach synchronism with the power system.
Page 599: Theory Of Operation
9.1.1 CT saturation detection The saturation detector of the M60 takes advantage of the fact that any CT operates correctly for a short period of time, even under very large primary currents that would subsequently cause a very deep saturation. As a result, in the case of an external fault, the differential current stays very low during the initial period of linear operation of the CTs while the restraining signal develops rapidly.
Page 600 This must be kept in mind when setting the characteristic as its parameters must retain their original meaning. The operation of the saturation detector is available as the FlexLogic operand STATOR DIFF SAT A/B/C. M60 MOTOR PROTECTION SYSTEM – INSTRUCTION MANUAL...
Page 601 CHAPTER 9: THEORY OF OPERATION SATURATION DETECTOR Figure 9-2: Saturation detector state machine M60 MOTOR PROTECTION SYSTEM – INSTRUCTION MANUAL...
Page 602 SATURATION DETECTOR CHAPTER 9: THEORY OF OPERATION M60 MOTOR PROTECTION SYSTEM – INSTRUCTION MANUAL...
Page 603: Maintenance
UR Family Communications Guide for the entries. The upper part of the window displays values. The lower part of the window is for factory service use. M60 MOTOR PROTECTION SYSTEM – INSTRUCTION MANUAL 10-1...
Page 604 Float — A numbering system with no fixed number of digits before or after the decimal point. An example is 0.000000. Binary — A numbering system using 0 and 1. An example is 0000-0000-0000-0000. Entries are not saved when closing the window. 10-2 M60 MOTOR PROTECTION SYSTEM – INSTRUCTION MANUAL...
Page 605: General Maintenance
GENERAL MAINTENANCE 10.2 General maintenance The M60 requires minimal maintenance. As a microprocessor-based relay, its characteristics do not change over time. Expected service life is 20 years for UR devices manufactured June 2014 or later when applied in a controlled indoor environment and electrical conditions within specification.
Page 606 Using the Up or Down pushbuttons on the front panel, select the file. Press the COPY pushbutton. The files are copied from the M60 to the USB drive. Do not unplug the USB drive while copying is in progress, else the USB drive can be compromised.
Page 607: Convert Device Settings
Convert the settings by right-clicking one of the files in the Offline Window and selecting the Convert Device Settings option. GE recommends converting settings in firmware steps, for example when converting from 6.0 to 7.4x, convert first to 7.0 then 7.4 in order to follow embedded conversion rules and keep settings.
Page 608 Change settings in the new file, for example by looking at the original file. Write the converted file to the device, for example by dragging and dropping from the Offline Window to the Online Window. Check settings and operation. 10-6 M60 MOTOR PROTECTION SYSTEM – INSTRUCTION MANUAL...
Page 609: Copy Settings To Other Device
10.5 Copy settings to other device Settings from one M60 device can be copied to another M60 device for rapid deployment. The order codes must match. See the Settings File section at the beginning of the Interfaces chapter for a list of settings not deployed, such as IP address.
Page 610: Back Up And Restore Settings
UR device settings can be saved in a backup URS file using the EnerVista UR Setup software. The URS file is the standard UR settings file. For an introduction to settings files in the URS format, see the beginning of the Interfaces chapter. 10-8 M60 MOTOR PROTECTION SYSTEM – INSTRUCTION MANUAL...
Page 611 Have this option enabled when you want to keep the IID file from the UR device instead of from another tool. The location of the file is C:\ProgramData\GE Power Management\urpc\Offline, for example.
Page 612 The file is copied from the computer to the location specified. To save list of sites and devices with an Environment backup: In EnerVista, click File > Environment > Backup. A window opens. Name and save the .ENV file. 10-10 M60 MOTOR PROTECTION SYSTEM – INSTRUCTION MANUAL...
Page 613: Restore Settings
These messages display because the roles of the protection engineer and network engineer can be separate. The former can require a URS file, while the latter can require stored Modbus settings and protection schemes. M60 MOTOR PROTECTION SYSTEM – INSTRUCTION MANUAL 10-11...
Page 614 EnerVista UR Setup software. To restore the list of sites and devices from an Environment backup: In EnerVista, click File > Environment > Restore. A window opens. Select the .ENV file to restore. 10-12 M60 MOTOR PROTECTION SYSTEM – INSTRUCTION MANUAL...
Page 615: Upgrade Software
Click the OK button to save the change. 10.9 Upgrade firmware If upgrading both EnerVista software and M60 firmware, upgrade the software first. The firmware of the M60 device can be upgraded, locally or remotely, using the EnerVista software. M60 MOTOR PROTECTION SYSTEM – INSTRUCTION MANUAL 10-13...
Page 616 You access the Convert Device Settings option by right-clicking the file in the Offline Window area at the lower left. GE recommends converting settings in firmware steps, for example when converting from 6.0 to 7.4x, convert first to 7.0 then 7.4 in order to follow embedded conversion rules and keep settings. Note that the values of all settings that have been defaulted during conversion are not listed in the conversion report;...
Page 617: Replace Front Panel
For an enhanced front panel, loosen the thumb screw and open slightly the front panel. For a standard front panel, lift up the black plastic latch on the right side of the front panel and open slightly the front panel. M60 MOTOR PROTECTION SYSTEM – INSTRUCTION MANUAL 10-15...
Page 618 With a Phillips screwdriver, unscrew and remove the mounting bracket on the right side of the unit. The bracket for the enhanced front panel looks similar to that for the graphical front panel, but they are not the same. 10-16 M60 MOTOR PROTECTION SYSTEM – INSTRUCTION MANUAL...
Page 619 Figure 10-15: Remove standard front panel mounting bracket on right side Open the front panel. Unplug or unscrew the grey ground cable from the front panel. Unplug the RJ45 connector from the CPU module in the second slot on the left. M60 MOTOR PROTECTION SYSTEM – INSTRUCTION MANUAL 10-17...
Page 620 Unscrew and remove the mounting bracket with the front panel from the left side. Figure 10-17: Unscrew enhanced front panel mounting bracket on left side Figure 10-18: Unscrew standard front panel mounting bracket on left side 10-18 M60 MOTOR PROTECTION SYSTEM – INSTRUCTION MANUAL...
Page 621 Figure 10-19: Attach mounting bracket to relay on left side (no power supply module in first slot) Screw the right mounting bracket to the right side of the relay. M60 MOTOR PROTECTION SYSTEM – INSTRUCTION MANUAL 10-19...
Page 622 Close the front panel without tightening the screw to the mounting bracket. Optionally remove the protective plastic film on the graphical front panel. It is normally peeled off, but also can be left The graphical front panel has been installed but not connected. 10-20 M60 MOTOR PROTECTION SYSTEM – INSTRUCTION MANUAL...
Page 623 Ensure that the RS485 connector and the black cover plate are not on the back of the CPU module before sliding the module into the front of the relay. Figure 10-23: Rear of a CPU module before insertion without RS485 connector or cover plate M60 MOTOR PROTECTION SYSTEM – INSTRUCTION MANUAL 10-21...
Page 624 Insert the silver SFP connector(s) at the back of the CPU module, then connect any Ethernet connection(s). Power up the relay. If the graphical front panel does not power up immediately, disconnect power, open the front 10-22 M60 MOTOR PROTECTION SYSTEM – INSTRUCTION MANUAL...
Page 625: Replace Module
Open the enhanced front panel to the left once the thumb screw has been removed. This allows for easy access of the modules for withdrawal. The new wide-angle hinge assembly in the enhanced front panel opens completely and allows easy access to all modules in the M60. Figure 10-26: Modules inside relay with front cover open (enhanced front panel) M60 MOTOR PROTECTION SYSTEM –...
Page 626: Battery
When required, the battery can be replaced. The power supply module contains the battery. The battery type is 3 V cylindrical. 10.12.1 Replace battery for SH/SL power supply When required, the battery can be replaced. The power supply module contains the battery. 10-24 M60 MOTOR PROTECTION SYSTEM – INSTRUCTION MANUAL...
Page 627 10. Reinstall the battery holder and the metal cover, and reinsert the power supply module into the unit. 11. Power on the unit. 12. Dispose of the old battery as outlined in the next section. M60 MOTOR PROTECTION SYSTEM – INSTRUCTION MANUAL 10-25...
Page 628: Dispose Of Battery
(Cd), el plomo (Pb), o el mercurio (Hg ). Para el reciclaje apropiado, devuelva este producto a su distribuidor ó deshágase de él en los puntos de reciclaje designados. Para mas información : wwwrecyclethis.info. 10-26 M60 MOTOR PROTECTION SYSTEM – INSTRUCTION MANUAL...
Page 629 (Cd), lood (Pb) of kwik (Hg). Voor correcte vorm van kringloop, geef je de producten terug aan jou locale leverancier of geef het af aan een gespecialiseerde verzamelpunt. Meer informatie vindt u op de volgende website: www.recyclethis.info. M60 MOTOR PROTECTION SYSTEM – INSTRUCTION MANUAL 10-27...
Page 630 Bu sembolle işaretlenmiş piller Kadmiyum(Cd), Kurşun(Pb) ya da Civa(Hg) içerebilir. Doğru geri dönüşüm için ürünü yerel tedarikçinize geri veriniz ya da özel işaretlenmiş toplama noktlarına atınız. Daha fazla bilgi için: www.recyclethis.info. 10-28 M60 MOTOR PROTECTION SYSTEM – INSTRUCTION MANUAL...
Page 631: Clear Files And Data After Uninstall
For issues not solved by troubleshooting, the process to return the device to the factory for repair is as follows: • Contact a GE Grid Solutions Technical Support Center. Contact information is found in the first chapter. • Obtain a Return Materials Authorization (RMA) number from the Technical Support Center.
Page 632: Storage
Customers are responsible for shipping costs to the factory, regardless of whether the unit is under warranty. • Fax a copy of the shipping information to the GE Grid Solutions service department in Canada at +1 905 927 5098. Use the detailed return procedure outlined at https://www.gegridsolutions.com/multilin/support/ret_proc.htm...
Page 633: Flexanalog Items
Field TDR 1 Value Field TDR 1 value 5834 Field TDR 2 Value Field TDR 2 value 5836 Field TDR 3 Value Field TDR 3 value 5838 Field TDR 4 Value Field TDR 4 value M60 MOTOR PROTECTION SYSTEM – INSTRUCTION MANUAL...
Page 634 6236 SRC 2 I_1 Mag Amps Source 2 positive-sequence current magnitude 6238 SRC 2 I_1 Angle Degrees Source 2 positive-sequence current angle 6239 SRC 2 I_2 Mag Amps Source 2 negative-sequence current magnitude M60 MOTOR PROTECTION SYSTEM – INSTRUCTION MANUAL...
Page 635 6366 SRC 4 I_1 Angle Degrees Source 4 positive-sequence current angle 6367 SRC 4 I_2 Mag Amps Source 4 negative-sequence current magnitude 6369 SRC 4 I_2 Angle Degrees Source 4 negative-sequence current angle M60 MOTOR PROTECTION SYSTEM – INSTRUCTION MANUAL...
Page 636 SRC 2 Vbc Angle Degrees Source 2 phase BC voltage angle 6747 SRC 2 Vca Mag Volts Source 2 phase CA voltage magnitude 6749 SRC 2 Vca Angle Degrees Source 2 phase CA voltage angle M60 MOTOR PROTECTION SYSTEM – INSTRUCTION MANUAL...
Page 637 SRC 4 Vcg Angle Degrees Source 4 phase CG voltage angle 6863 SRC 4 Vab RMS Volts Source 4 phase AB voltage RMS 6865 SRC 4 Vbc RMS Volts Source 4 phase BC voltage RMS M60 MOTOR PROTECTION SYSTEM – INSTRUCTION MANUAL...
Page 638 7224 SRC 2 PF Source 2 three-phase power factor 7225 SRC 2 Phase A PF Source 2 phase A power factor 7226 SRC 2 Phase B PF Source 2 phase B power factor M60 MOTOR PROTECTION SYSTEM – INSTRUCTION MANUAL...
Page 639 Source 3 positive varhour 7462 SRC 3 Neg varh varh Source 3 negative varhour 7472 SRC 4 Pos Watthour Source 4 positive Watthour 7474 SRC 4 Neg Watthour Source 4 negative Watthour M60 MOTOR PROTECTION SYSTEM – INSTRUCTION MANUAL...
Page 640 DCmA Ip 11 DCmA input 11 actual value 13526 DCmA Ip 12 DCmA input 12 actual value 13528 DCmA Ip 13 DCmA input 13 actual value 13530 DCmA Ip 14 DCmA input 14 actual value M60 MOTOR PROTECTION SYSTEM – INSTRUCTION MANUAL...
Page 641 RTD Ip 34 RTD input 34 actual value 13586 RTD Ip 35 RTD input 35 actual value 13587 RTD Ip 36 RTD input 36 actual value 13588 RTD Ip 37 RTD input 37 actual value M60 MOTOR PROTECTION SYSTEM – INSTRUCTION MANUAL...
Page 642 RRTD 3 Value °C Remote RTD input 3 actual value 34755 RRTD 4 Value °C Remote RTD input 4 actual value 34756 RRTD 5 Value °C Remote RTD input 5 actual value A-10 M60 MOTOR PROTECTION SYSTEM – INSTRUCTION MANUAL...
Page 643 45596 RxGOOSE Analog 7 RxGOOSE analog input 7 45598 RxGOOSE Analog 8 RxGOOSE analog input 8 45600 RxGOOSE Analog 9 RxGOOSE analog input 9 45602 RxGOOSE Analog 10 RxGOOSE analog input 10 M60 MOTOR PROTECTION SYSTEM – INSTRUCTION MANUAL A-11...
Page 644 45640 RxGOOSE Analog 29 RxGOOSE analog input 29 45642 RxGOOSE Analog 30 RxGOOSE analog input 30 45644 RxGOOSE Analog 31 RxGOOSE analog input 31 45646 RxGOOSE Analog 32 RxGOOSE analog input 32 A-12 M60 MOTOR PROTECTION SYSTEM – INSTRUCTION MANUAL...
Page 645: B Radius Server
UR device for successful authentication, and the shortname is a short, optional alias that can be used in place of the IP address. client 10.0.0.2/24 { secret = testing123 shortname = private-network-1 In the <Path_to_Radius>\etc\raddb folder, create a file called dictionary.ge and add the following content. # ########################################################## GE VSAs ############################################################ VENDOR...
Page 646 Access Settings > Product Setup > Security. Configure the IP address and ports for the RADIUS server. Leave the GE vendor ID field at the default of 2910. Update the RADIUS shared secret as specified in the clients.conf file. Restart the relay for the IP address and port changes to take effect.
Page 647: C Command Line
When the Supervisor account is enabled, the 'Lock Relay' setting must first be changed to No before the putsettings, inservice, or reboot command can be used. This setting cannot be changed using the command line interface. • Use quotes ("") to enclose any parameter containing a space M60 MOTOR PROTECTION SYSTEM – INSTRUCTION MANUAL...
Page 648 For non-CyberSentry devices — Set <authentication type> to "traditional". Note that <authentication type> defaults to "traditional" if not specified. Set <account> to "COMMANDS" or "SETTINGS". If not specified, the SETTINGS account is used. Example: SetupCLI URPC login -d "C30 Melbourne" -A traditional -a SETTINGS -w 1password1 M60 MOTOR PROTECTION SYSTEM – INSTRUCTION MANUAL...
Page 649 Read settings from device <device> and save them to the .urs file <File>. The <File> must not already exist. The default path to the output file is C:\Users\Public\Public Documents\GE Power Management\URPC\Data Example: SetupCLI URPC getsettings -d C30 -f "C30 Markham.urs"...
Page 650 SetupCLI URPC getsettings -d demoDevice -f devicefile.urs SetupCLI URPC compare -f existingfile.urs -r devicefile.urs -o output.txt The output is similar to the following: Comparing settings file aaa.urs : C:\Users\Public\Public Documents\GE Power Management\URPC\Data\ with bbb.urs : C:\Users\Public\Public Documents\GE Power Management\URPC\Data\ Setting Name...
Page 651 SetupCLI URPC getsettings -d DEV@SETUP_CLI -f "example file.urs" SetupCLI URPC logout -d DEV@SETUP_CLI SetupCLI URPC exit DEV@SETUP_CLI has to be used as the device name in the commands followed by the 'adddevice' command. M60 MOTOR PROTECTION SYSTEM – INSTRUCTION MANUAL...
Page 652 COMMAND LINE INTERFACE APPENDIX C: COMMAND LINE INTERFACE M60 MOTOR PROTECTION SYSTEM – INSTRUCTION MANUAL...
Page 653: Warranty
This chapter provides the warranty and revision history. D.1 Warranty For products shipped as of 1 October 2013, GE Grid Solutions warrants most of its GE manufactured products for 10 years. For warranty details including any limitations and disclaimers, see the Terms and Conditions at http://www.gegridsolutions.com/multilin/warranty.htm...
Page 654 17-3561 1601-0108-AF1 7.6x 30 June 2017 17-3779 Table D-2: Major changes for M60 manual version AF1 (English) Page Description General revision Updated "faceplate" to "front panel" for consistency and to reflect web site Added graphical front panel option to order codes and specifications in chapter 2, Interfaces chapter 4, Settings chapter 5, Actual Values chapter 6 M60 MOTOR PROTECTION SYSTEM –...
Page 655 Added Convert Device Settings section 10-7 Added Copy Settings to Other Device section 10-15 Added Replace Front Panel section for retrofit with the new graphical front panel Table D-3: Major changes for M60 manual version AE3 (English) Page Description General revision Updated order codes...
Page 656 REVISION HISTORY APPENDIX D: MISCELLANEOUS Table D-5: Major changes for M60 manual version AC1 (English) Page Description General revision. Added online help and update generic online help. Deleted EAC logo from title page and deleted EAC certification from Approvals specifications because document not...
Page 657 Full Load Current Contact Output Fiber Optic Communication FPGA Field-programmable Gate Array COMM Communications FREQ Frequency COMP Compensated, Comparison Frequency-Shift Keying CONN Connection File Transfer Protocol CONT Continuous, Contact FlexElement™ CO-ORD Coordination Forward M60 MOTOR PROTECTION SYSTEM – INSTRUCTION MANUAL...
Page 658 Protection Low Voltage Parallel Redundancy Protocol PSEL Presentation Selector Machine Precision Time Protocol Machine to Machine Per Unit MilliAmpere PUIB Pickup Current Block Magnitude PUIT Pickup Current Trip Manual / Manually PUSHBTN Pushbutton M60 MOTOR PROTECTION SYSTEM – INSTRUCTION MANUAL...
Page 659 Time Dial Multiplier TEMP Temperature TFTP Trivial File Transfer Protocol Total Harmonic Distortion Timer Time Overcurrent Time Overvoltage TRANS Transient TRANSF Transfer TSEL Transport Selector Time Undercurrent Time Undervoltage TX (Tx) Transmit, Transmitter M60 MOTOR PROTECTION SYSTEM – INSTRUCTION MANUAL...
Page 660 ABBREVIATIONS M60 MOTOR PROTECTION SYSTEM – INSTRUCTION MANUAL...
Page 661 ....................4-35, 5-35 settings ....................5-277 messages ....................7-6 specifications ..................2-23 overview ....................4-32 Auxiliary voltage channel ............... 3-15 reset ......................4-35 Auxiliary voltage metering ............. 6-18 AWG wire size ........3-14, 3-37, 3-41, 3-43, 3-44 M60 MOTOR PROTECTION SYSTEM – INSTRUCTION MANUAL...
Page 662 Cannot log in .................... 2-4 settings ..................5-44, 5-51 Caution symbol in Offline Window ........... 4-70 specifications ................. 2-33, 2-34 CE certification ..................2-38 timeout ....................5-51 Certification .................... 2-38 web server ................... 5-99 M60 MOTOR PROTECTION SYSTEM – INSTRUCTION MANUAL...
Page 663 Device setup ..................3-62 actual values ..................6-16 Diagnostic alarm error ................7-7 FlexAnalogs ..................A-11 Diagnostic failure error ...............7-7 logic diagram ...................5-218 Dielectric strength ................3-13 settings ....................5-217 Differential stator ..............2-20, 5-225, 6-16, A-1 M60 MOTOR PROTECTION SYSTEM – INSTRUCTION MANUAL...
Page 664 ..............7-6 select protocol ................... 5-50 Error messages ..................7-6 settings ....................5-51 device not recognized ..............10-13 DOS partition alarm error message ......... 7-11 in Engineer ................... 4-71 Downgrade firmware ..............10-13 Downgrade software ..............10-13 M60 MOTOR PROTECTION SYSTEM – INSTRUCTION MANUAL...
Page 665 Flex State parameters Frequency tracking ................6-21 actual values ..................6-8 Frequency, nominal .................5-142 settings ....................5-129 specifications ..................2-26 FlexAnalog parameters ..............A-1 FlexCurves equation ................5-239, 5-259 settings ....................5-158 specifications ..................2-26 table .....................5-158 M60 MOTOR PROTECTION SYSTEM – INSTRUCTION MANUAL...
Page 666 URs ..........2-7 self-test errors ................... 7-11 Heartbeat messages ............. 5-66, 5-69 Help, getting ....................1-2 Home page configuration .............. 5-27 Hot/cold safe stall ratio ..............5-194 HTTP ......................5-99 port, close .................... 5-99 M60 MOTOR PROTECTION SYSTEM – INSTRUCTION MANUAL...
Page 667 IRIG-B ......................3-32 application examples ..............5-322 IRIG-B specifications ...............2-30 error messages ..................7-8 RTD input specifications ..............2-29 settings ....................5-322 RTD inputs ....................3-27 specifications ..................2-31 virtual ....................5-320 LC fiber .....................2-7, 3-11 LC fiber connector ................3-11 M60 MOTOR PROTECTION SYSTEM – INSTRUCTION MANUAL...
Page 668 ....................5-218 actual values ..................6-23 Memory requirements ..............3-52 specifications ..................2-24 Menu navigation ................. 4-51 Motor thermal model Message about upgrade over Internet ........10-14 see Thermal model Mounting ................... 3-2, 3-5 viii M60 MOTOR PROTECTION SYSTEM – INSTRUCTION MANUAL...
Page 669 Part numbering ..................2-7 Operating times ..................2-20 Operator command to force logoff ..........7-4 OR gate explained ................4-84 Order codes ....................2-7 actual values ..................6-29 update ..................3-61, 7-3 Oscillatory transient testing specifications ......2-37 M60 MOTOR PROTECTION SYSTEM – INSTRUCTION MANUAL...
Page 670 Device Connectivity Report in Engineer ........ 4-78 firmware revision ................6-29 Programmed mode ................3-50 Protection elements ................5-4 Protection Summary interface ......3-64, 4-4, 5-280 Protocol selection ................5-50 Prototype firmware error message .......... 7-11 M60 MOTOR PROTECTION SYSTEM – INSTRUCTION MANUAL...
Page 671 ................3-11 PRP actual values ................6-11 specifications ..................2-33 PRP explained ..................5-46 RTD bias ....................5-194 settings ....................5-44 RTD FlexAnalogs ..................A-9 specifications ..................2-34 Relay architecture ................5-165 Relay maintenance ................7-3 Relay name ..................5-139 M60 MOTOR PROTECTION SYSTEM – INSTRUCTION MANUAL...
Page 672 ................. 7-10 Self-tests explained ....................3-10 description ..................... 7-6 module fail message ..............7-10 error messages ..................7-6 photo ....................10-21 FlexLogic operands ...............5-177 Signal loss detection for fiber ............5-46 user-programmable ..............5-122 M60 MOTOR PROTECTION SYSTEM – INSTRUCTION MANUAL...
Page 673 .................5-225 over/underfrequency ................8-1 FlexAnalogs ................... A-1 pushbuttons ..................7-3 FlexLogic operands ...............5-173 self-test error messages ..............7-6 logic diagram ..............5-227, 5-228 settings ................5-341, 5-342 settings ....................5-225 specifications ..................2-20 Status LEDs .................4-41, 4-43 M60 MOTOR PROTECTION SYSTEM – INSTRUCTION MANUAL xiii...
Page 674 ....................5-279 settings ....................5-273 Trip LEDs ....................5-120 Unexpected restart error ..............7-10 Trouble indicator ..................7-6 Uninstall ....................10-29 Trouble LED .................... 3-50 Unit not programmed ..............5-139 Unit not programmed message ............7-6 M60 MOTOR PROTECTION SYSTEM – INSTRUCTION MANUAL...
Page 675 User-programmable self-test settings .........5-122 Wiring diagram ..................3-12 Withdrawal from operation ............10-29 Wrong transceiver message ............7-10 VAR hour actual values ..................6-20 specifications ..................2-28 XOR gate explained ................4-84 Vibration testing specifications ...........2-37 M60 MOTOR PROTECTION SYSTEM – INSTRUCTION MANUAL...
Page 676 INDEX Yellow caution icon in Offline Window ........4-70 Zero-sequence core balance ............3-15 M60 MOTOR PROTECTION SYSTEM – INSTRUCTION MANUAL...

GE M60 Instruction Manual

1 Introduction

Safety Symbols and Definitions

2 Product Description

Description

Security

3 Installation

Unpack and Inspect

4 Interfaces

Enervista Software Interface

5 Settings

Settings Menu

6 Actual Values

Actual Values Menu

7 Commands and Targets

8 Commissioning

Testing

9 Theory of Operation

10 Maintenance

Convert Device Settings

Back up and Restore Settings

Upgrade Software

Flexanalog Items

B Radius Server

RADIUS Server Configuration

C Command Line

Command Line Interface

Warranty

Revision History

Quick Links

Related Manuals for GE M60

Summary of Contents for GE M60