Woodward LS-51 Series Technical Manual
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Woodward LS-51 Series Technical Manual

Woodward LS-51 Series Technical Manual

Circuit breaker control
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LS-5 v2 Series
Technical Manual
Circuit Breaker Control
LS-5x1 (v2) 1breaker
Software Version 2.00xx
Document ID: 37649, Revision: A (Build 45901)

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Summary of Contents for Woodward LS-51 Series

  • Page 1 LS-5 v2 Series Technical Manual Circuit Breaker Control LS-5x1 (v2) 1breaker Software Version 2.00xx Document ID: 37649, Revision: A (Build 45901)
  • Page 2 This is no translation but the original Technical Manual in English. Designed in Germany. Woodward GmbH Handwerkstr. 29 70565 Stuttgart Germany Telephone: +49 (0) 711 789 54‑510 Fax: +49 (0) 711 789 54‑101 Email: stgt-info@woodward.com Internet: http://www.woodward.com © 2020 Woodward GmbH LS-5 v2 Series 37649...

  • Page 3: Brief Overview

    • RS-232 connector: DPC-RS-232 direct configuration cable – P/N 5417-557 The LS-5 Series are circuit breaker control units for engine-generator system management applications. The control units can be used stand-alone or in applications in combination with Woodward easYgen-3400/3500 or easYgen-3400XT/3500XT genset control units. 37649 LS-5 v2 Series...
  • Page 4 Brief Overview Sample application setup Fig. 2: Sample application setup A typical application mode for the control unit is the use as an external mains circuit breaker. • One or more gensets feed on a load busbar. • The easYgen(s) close and open their own generator breaker. •...

  • Page 5: Scope Of Delivery

    Brief Overview Scope of delivery The following parts are included in the scope of delivery. Please check prior to the installation that all parts are present. Fig. 3: Scope of delivery - schematic LS-5 circuit breaker control Product CD-ROM (configuration software and manual) LS-52x only: Clamp fastener installation material - 4x LS-52x only: Screw kit installation material - 8x 37649...

  • Page 6: Table Of Contents

    Table of Contents Table of Contents General Information ............About This Manual .
  • Page 7 Table of Contents 3.3.5 Current Measuring ............. . . 3.3.5.1 Current Measuring (System A) .
  • Page 8 Table of Contents 4.3.1.12 QV Monitoring ..................4.3.1.13 System A Time-Dependent Voltage .
  • Page 9 Table of Contents 4.6.2.1 CAN Interface 1 ..................4.6.2.2 Additional Server SDOs (Service Data Objects) .
  • Page 10 Table of Contents 5.2.3.12 Discrete Inputs/Outputs ................5.2.3.13 Analog Input .
  • Page 11 Table of Contents 6.4.2.7 Setup Manual Breaker Control In LS-5 Mode ............. . . 6.4.2.8 Setup LS-5 Command Bits From easYgen To LS-5 .
  • Page 12 Table of Contents 8.1.6 Housing ............... 8.1.7 Approvals .
  • Page 13 Table of Contents 9.3.4.14 Group 26(/1-2): Commands Device 33 to 48 ............. . 9.3.4.15 Group 27(/1-2): Commands Device 49 to 64 .

  • Page 14: General Information

    1 General Information General Information This manual describes the LS-5 one breaker variant: • LS-5x1 v2 series device • LS-5x2 v2 series device configured and used as LS-5x1 v2 For details please refer to chapter ╚═▷ “2 System Overview”. About This Manual 1.1.1 Revision History Rev.

  • Page 15: Depiction Of Notes And Instructions

    1 General Information 1.1 About This Manual 1.1.2 Depiction Of Notes And Instructions Safety instructions Safety instructions are marked with symbols in these instructions. The safety instructions are always introduced by signal words that express the extent of the danger. DANGER! This combination of symbol and signal word indicates an immediately-dangerous situation that could cause death or severe injuries if not avoided.

  • Page 16: Copyright And Disclaimer

    All information and instructions in this manual have been provided under due consideration of applicable guidelines and regulations, the current and known state of the art, as well as our many years of in-house experience. Woodward assumes no liability for damages due to: •...

  • Page 17: Service And Warranty

    In addition, our employees are constantly interested in new information and experiences that arise from usage and could be valuable for the improvement of our products. Warranty terms Please enquire about the terms of warranty from your nearest Woodward representative. For our contact search webpage please go to: ══▷ http://www.woodward.com/ Directory.aspx Safety 1.4.1...

  • Page 18: Personnel

    1 General Information 1.4 Safety 1.4.2 Personnel WARNING! Hazards due to insufficiently qualified personnel! If unqualified personnel perform work on or with the control unit hazards may arise which can cause serious injury and substantial damage to property. • Therefore, all work must only be carried out by appropriately qualified personnel. This manual specifies the personnel qualifications required for the different areas of work, listed below: Personnel: Qualified electrician...

  • Page 19: General Safety Notes

    1 General Information 1.4 Safety 1.4.3 General Safety Notes Electrical hazards DANGER! Life-threatening hazard from electric shock! There is an imminent life-threatening hazard from electric shocks from live parts. Damage to insulation or to specific components can pose a life-threatening hazard. •...
  • Page 20 • Make sure the charging device is turned off before disconnecting the battery from the system. Unit includes a lithium backup battery for Real Time Clock. Field replacement of the battery is not allowed. In case of battery replacement please contact your Woodward service partner. Electrostatic discharge ⚙ ᐳ...
  • Page 21 For additional information on how to prevent damage to electronic components caused by improper handling, read and observe the precautions in: • "Woodward manual 82715, Guide for Handling and Protection of Electronic Controls, Printed Circuit Boards, and Modules". Notes on marine usage...

  • Page 22: Protective Equipment And Tools

    1 General Information 1.4 Safety NOTICE! Malfunctions due to insufficient protection against electromagnetic interference Exposure electromagnetic interference may cause malfunctions or incorrect internal readings. • Install an EMI filter (i.e. SCHAFFNER - FN 2070-3-06) for the power supply inputs when using the control unit in marine applications. Some additional, independent safety and protection devices are necessary to meet safety requirements of Rules and Regulations of marine Classification Societies.

  • Page 23: System Overview

    • ╚═▷ “5 Operation” provides information on how to access the unit via the front panel or remotely using the ToolKit software provided by Woodward. • ╚═▷ “6 Application” provides application examples as well as instructions for the corresponding required configuration.

  • Page 24: Display And Status Indicators

    2 System Overview 2.1 Display And Status Indicators Display And Status Indicators LS-521 display Fig. 4: Display LS-521 The display (╚═▷ Fig. 4) as part of the LS-521 is used for direct access to status information and configuration. For information on the usage of the graphical user interface refer to ╚═▷...
  • Page 25 2 System Overview 2.1 Display And Status Indicators Fig. 5: Display LS-522 configured as LS-521 LS-511 LEDs Fig. 6: Position of LEDs LEDs representing LogicsManager states LED 'CPU OK' The LS-511 unit with metal housing and without display and buttons features 9 LEDs (╚═▷...
  • Page 26 2 System Overview 2.1 Display And Status Indicators State Indication Notes The 8 LEDs representing LogicsManager states are triggered based on the settings of parameters 12962 to 12969. The conditions printed next to the LEDs on the sheet metal housing represent the corresponding LogicsManager's parameter defaults.
  • Page 27 The LS-51x comes with a paper strip describing the default LED conditions. There is a slot behind terminal 43..59. The product CD-ROM offers a template to create own text. Please take care that the description is correct and will not mislead user. Woodward cannot assume any liability caused by your "wrong" text.

  • Page 28: Hardware Interfaces (Terminals)

    2 System Overview 2.2 Hardware Interfaces (Terminals) Hardware Interfaces (Terminals) The LS-51x/52x (╚═▷ Fig. 8) provides the following terminals. Fig. 8: LS-5 Series (housing variants) LS-52x (plastic housing with display) LS-51x (sheet metal housing) System A CT terminal System A / System B PT terminal Service port connector (USB/RS-232) Relay outputs terminal Discrete inputs terminal...

  • Page 29: Operation Modes

    2 System Overview 2.4 Operation Modes For detailed information on the application modes and special applications refer to ╚═▷ “6 Application”. LS-511/521 easYgen-3400/3500 or easYgen-3400XT/ 3500XT Mode Symbol Mode Symbol LS-5 Single LS5 LS-5 & easYgen LS5 (up to 16 units) GCB/LS5 L-MCB (max.
  • Page 30 2 System Overview 2.5 Synch. Check Functionality The Sync. Check functionality is available in every application mode, but be aware that application modes can fix parameters being relevant for this functionality. The application modes L-MCB ( ) and L-GGB ( ) fix those parameters! Synchronization mode is “Phase Matching”...
  • Page 31 2 System Overview 2.5 Synch. Check Functionality For more details refer to ╚═▷ “4.4.2.2.1 Synchronization CBA” ╚═▷ “4.4.2.1 Dead Bus Closure CB”. 37649 LS-5 v2 Series...

  • Page 32: Installation

    3 Installation 3.1 Mount Unit (Sheet Metal Housing) Installation Mount Unit (Sheet Metal Housing) Dimensions Fig. 9: Sheet metal housing - dimensions ⚙ Mounting into a cabinet ᐳ • Special tool: Torque screwdriver Proceed as follows to install the unit using the screw kit: 1. ▷...

  • Page 33: Mount Unit (Plastic Housing)

    3 Installation 3.2 Mount Unit (Plastic Housing) Ensure sufficient clearance for access to the terminals (top and bottom) and connectors located at the sides. Mount the unit to the back panel and insert the screws. 2. ▷ Tighten the screws to a torque according to the quality class of the used screws. 3. ▷...

  • Page 34: Panel Cutout

    3 Installation 3.2 Mount Unit (Plastic Housing) Dimensions Fig. 11: Plastic housing - dimensions Panel cutout Fig. 12: Cutout schematic Measure Description Tolerance Height Total 171 mm — Panel cutout 138 mm + 1.0 mm Housing dimension 136 mm Width Total 219 mm —...

  • Page 35: Clamp Fastener Installation

    3 Installation 3.2 Mount Unit (Plastic Housing) 3.2.1 Clamp Fastener Installation ⚙ ᐳ For installation into a door panel with the fastening clamps, proceed as follows: 1. ▷ Cut out the panel according to the dimensions in ╚═▷ Fig. Don't drill the holes if you want to use the clamp fasteners. If the holes are drilled into the panel, the clamp fasteners cannot be used anymore! 2. ▷...
  • Page 36 3 Installation 3.2 Mount Unit (Plastic Housing) 5. ▷ Fig. 15: Attach clamp inserts Re-install the clamp inserts by tilting the insert to a 45° angle. (╚═▷ Fig. 15/1) Insert the nose of the insert into the slot on the side of the housing. (╚═▷...

  • Page 37: Screw Kit Installation

    3 Installation 3.2 Mount Unit (Plastic Housing) 3.2.2 Screw Kit Installation The housing is equipped with 8 nut inserts (╚═▷ Fig. 16), which must all be tightened properly to achieve the required degree of protection. Fig. 18: Plastic housing - drill plan ⚙...

  • Page 38: Setup Connections

    3 Installation 3.3 Setup Connections Tighten the screws with a crosswise pattern to ensure even pressure distribution. If the thickness of the panel sheet exceeds 2.5 mm, be sure to use screws with a length exceeding the panel sheet thickness by 4 mm. Setup Connections General notes NOTICE!
  • Page 39 3 Installation 3.3 Setup Connections Terminal pin 9 is intentionally not available. Screwable terminals are part of delivery. DANGER! High Voltage! Life-threatening hazards from electric shock! Take care for installing high voltage mains connection as described in ╚═▷ “Electrical hazards”. Fig.

  • Page 40: Wiring Diagram

    3 Installation 3.3 Setup Connections 3.3.2 Wiring Diagram LS-5x1 v2 Series The following figure shows the hardware situation. The 2nd drawing offers a functional short description additionally. WARNING! Terminal connection of System A current measurement has been changed from the LS-5x1 series devices to the LS-5x1 v2 series devices.
  • Page 41 3 Installation 3.3 Setup Connections Fig. 22: Wiring diagram (LS-5x1 v2 series) 37649 LS-5 v2 Series...

  • Page 42: Power Supply

    • The conductor providing the connection must have a wire larger than or equal to 2.5 mm² (14 AWG). The connection must be performed properly. Woodward recommends to use one of the following slow-acting protective devices in the supply line to terminal 53: •...

  • Page 43: Voltage Measuring

    The control unit will not measure voltage correctly if the 120 V and 480 V inputs are utilized simultaneously. • Never use both sets of voltage measuring inputs. Woodward recommends protecting the voltage measuring inputs with slow-acting fuses rated for 2 to 6 A. 3.3.4.1 Isolation switch location The LS-5x1 v2 can be used in different applications.
  • Page 44 3 Installation 3.3 Setup Connections Isolation switch on System A side Fig. 25: LS-5x1 v2 - Isolation switch on System A side (example) LS-5 v2 Series 37649...
  • Page 45 3 Installation 3.3 Setup Connections Isolation switch on System B side Fig. 26: LS-5x1 v2 - Isolation switch on System B side (example) 37649 LS-5 v2 Series...

  • Page 46: System A Voltage

    3 Installation 3.3 Setup Connections No isolation switch Fig. 27: LS-5x1 v2 - No isolation switch (example) 3.3.4.2 System A Voltage General notes If parameter 1800 ("SyA PT secondary rated volt.") is configured with a value between 50 and 130 V, the 120 V input terminals must be used for proper measurement. If parameter 1800 ("SyA PT secondary rated volt.") is configured with a value between 131 and 480 V, the 480 V input terminals must be used for proper measurement.
  • Page 47 3 Installation 3.3 Setup Connections Schematic and terminals Fig. 28: Voltage measuring - system A - wiring Terminal Description System A voltage - L1 120 Vac 2.5 mm² 480 Vac 2.5 mm² System A voltage - L2 120 Vac 2.5 mm² 480 Vac 2.5 mm²...

  • Page 48: Measuring Inputs

    3 Installation 3.3 Setup Connections Fig. 29: System A windings - 3Ph 4W OD Measuring inputs Fig. 30: Measuring inputs - 3Ph 4W OD Terminal assignment 3Ph 4W Wiring terminals Rated voltage (range) 120 V (50 to 130 V 480 V (131 to 480 V eff.
  • Page 49 3 Installation 3.3 Setup Connections For different voltage systems, different wiring terminals have to be used. 3.3.4.2.2 Parameter Setting '3Ph 4W' (3-phase, 4-wire) System A windings Fig. 31: System A windings - 3Ph 4W Measuring inputs Fig. 32: Measuring inputs - 3Ph 4W Terminal assignment 3Ph 4W Wiring terminals...
  • Page 50 3 Installation 3.3 Setup Connections For different voltage systems, different wiring terminals have to be used. Incorrect measurements are possible, if both voltage systems use the same N terminal. 3.3.4.2.3 Parameter Setting '3Ph 3W' (3-phase, 3-wire) System A windings B2 B1 B6 B5 B2 B1 Fig.
  • Page 51 3 Installation 3.3 Setup Connections For different voltage systems, different wiring terminals have to be used. 3.3.4.2.4 Parameter Setting '1Ph 3W' (1-phase, 3-wire) System A windings A1 A2 A5 A6 Fig. 35: System A windings - 1Ph 3W Measuring inputs Fig.
  • Page 52 3 Installation 3.3 Setup Connections For different voltage systems, different wiring terminals have to be used. Incorrect measurements are possible, if both voltage systems use the same N terminal. 3.3.4.2.5 Parameter Setting '1Ph 2W' (1-phase, 2-wire) The 1-phase, 2-wire measurement may be performed phase-neutral or phase-phase. •...
  • Page 53 3 Installation 3.3 Setup Connections 1Ph 2W Wiring terminals Phase For different voltage systems, different wiring terminals have to be used. Incorrect measurements are possible if both voltage systems use the same N terminal. 3.3.4.2.5.2 '1Ph 2W' Phase-Phase Measuring System A windings A1 A2 A5 A6 Fig.

  • Page 54: System B Voltage

    3 Installation 3.3 Setup Connections 1Ph 2W Wiring terminals Phase For different voltage systems, different wiring terminals have to be used. 3.3.4.3 System B Voltage General notes If parameter 1803 ("SyB PT secondary rated volt.") is configured with a value between 50 and 130 V, the 120 V input terminals must be used for proper measurement.
  • Page 55 3 Installation 3.3 Setup Connections Terminal Description System B voltage - L3 120 Vac 2.5 mm² 480 Vac 2.5 mm² System B voltage - N 120 Vac 2.5 mm² 480 Vac 2.5 mm² Tab. 6: Voltage measuring - system B - terminal assignment 3.3.4.3.1 Parameter Setting '3Ph 4W' (3-phase, 4-wire) System B windings...
  • Page 56 3 Installation 3.3 Setup Connections For different voltage systems, different wiring terminals have to be used. Incorrect measurements are possible if both voltage systems use the same N terminal. 3.3.4.3.2 Parameter Setting '3Ph 3W' (3-phase, 3-wire) System B windings B2 B1 B6 B5 B2 B1 Fig.
  • Page 57 3 Installation 3.3 Setup Connections For different voltage systems, different wiring terminals have to be used. 3.3.4.3.3 Parameter Setting '1Ph 3W' (1-phase, 3-wire) System B windings A1 A2 A5 A6 Fig. 46: System B windings - 1Ph 3W Measuring inputs Fig.
  • Page 58 3 Installation 3.3 Setup Connections For different voltage systems, different wiring terminals have to be used. Incorrect measurements are possible, if both voltage systems use the same N terminal. 3.3.4.3.4 Parameter Setting '1Ph 2W' (1-phase, 2-wire) The 1-phase, 2-wire measurement may be performed phase-neutral or phase-phase. •...
  • Page 59 3 Installation 3.3 Setup Connections 1Ph 2W Wiring terminals Phase For different voltage systems, different wiring terminals have to be used. Incorrect measurements are possible, if both voltage systems use the same N terminal. 3.3.4.3.4.2 '1Ph 2W' Phase-Phase Measuring System B windings A1 A2 A5 A6 Fig.

  • Page 60: Current Measuring

    3 Installation 3.3 Setup Connections 1Ph 2W Wiring terminals Phase For different voltage systems, different wiring terminals have to be used. 3.3.5 Current Measuring Current measuring is available for all three phases of System A. 3.3.5.1 Current Measuring (System A) General notes WARNING! Dangerous voltages due to missing load...
  • Page 61 3 Installation 3.3 Setup Connections Schematic and terminals Fig. 52: Current measuring - system A - wiring Terminal Description System A current - L3 2.5 mm² System A current - L3 (GND) 2.5 mm² System A current - L2 2.5 mm² System A current - L2 (GND) 2.5 mm²...
  • Page 62 3 Installation 3.3 Setup Connections Wiring terminals Phase L1 L2 L3 s1 (k) L1 s2 (l) L1 s1 (k) L2 s2 (l) L2 s1 (k) L3 s2 (l) L3 Phase L1 and L3 s1 (k) L1 s2 (l) L1 — —...

  • Page 63: Power Measuring

    3 Installation 3.3 Setup Connections 3.3.6 Power Measuring Fig. 55: Power measuring - wiring If the unit's current transformers are wired according to the diagram (╚═▷ Fig. 55), the following values are displayed. Terminal Description System A current Description Sign displayed Positive real power Power flow from System B to + Positive...

  • Page 64: Phasor Diagram

    3 Installation 3.3 Setup Connections Properties Inductive Capacitive Load type Electrical load whose current waveform lags the Electrical load whose current waveform leads voltage waveform thus having a lagging power the voltage waveform thus having a leading factor. Some inductive loads such as electric power factor.

  • Page 65: Discrete Inputs

    3 Installation 3.3 Setup Connections 3.3.8 Discrete Inputs General notes The discrete inputs are electrically isolated which permits the polarity of the connections to be either positive or negative. • All discrete inputs must use the same polarity, either positive or negative signals, due to the common ground.

  • Page 66: Relay Outputs

    3 Installation 3.3 Setup Connections Fig. 59: Discrete inputs - state N.O. In the state N.O., no potential is present during normal operation; if an alarm is issued or control operation is performed, the input is energized. Fig. 60: Discrete inputs - state N.C. In the state N.C., a potential is continuously present during normal operation;...

  • Page 67: Serial Interface

    3 Installation 3.3 Setup Connections Terminal Description Common N.O. Form A Relay output [R 02] Preconfigured to "Horn" mm² Relay output [R 03] Preconfigured to "System B not OK" mm² Relay output [R 04] Preconfigured to "System A not OK" mm²...

  • Page 68: Service Port

    Service Port Service port connector Fig. 63: Service port connector (RJ-45) The Woodward specific service port is a connector (RJ-45) to extend the interfaces of the controller. The service port can be only used in combination with an optional Woodward direct configuration cable (DPC).
  • Page 69 • DPC-USB direct configuration cable • DPC-RS-232 direct configuration cable DPC-USB direct configuration cable Use the DPC-USB direct configuration cable if you want to connect the Woodward controller to an external device (master) which is equipped with an USB port. Order item number: •...

  • Page 70: Can Bus Interface

    3 Installation 3.4 CAN Bus Interface Use the Ethernet CAT 5 cable which is supplied with the DPC-RS-232 converter. The maximum cable length must not exceed 0.5 m. For a continuous operation with the direct configuration cable DPC-RS-232 (e.g. remote control of controller), it is required to use at least revision F (P/N 5417-557 Rev.

  • Page 71: Maximum Can Bus Length

    3 Installation 3.4 CAN Bus Interface Maximum CAN bus length The maximum length of the communication bus wiring is dependent on the configured baud rate. Observe the maximum bus length. (Source: CANopen; Holger Zeltwanger (Hrsg.); 2001 VDE VERLAG GMBH, Berlin und Offenbach;...

  • Page 72: Connecting 24 V Relays

    3 Installation 3.5 Connecting 24 V Relays Woodward recommends the use of shielded, twisted-pair cables for the CAN bus (see examples). • Lappkabel Unitronic LIYCY (TP) 2×2×0.25 • UNITRONIC-Bus LD 2×2×0.22 Connecting 24 V Relays NOTICE! Damage to adjacent electronic components due to induced voltages •...
  • Page 73 3 Installation 3.5 Connecting 24 V Relays Advantages and disadvantages of different interference suppressing circuits are as follows: Connection diagram Load current / voltage Advantages Disadvantages curve Uncritical dimensioning High release delay Lowest possible induced voltage Very simple and reliable Uncritical dimensioning No attenuation below VVDR High energy absorption...

  • Page 74: Configuration

    4 Configuration Configuration All parameters are assigned a unique parameter identification number. The parameter identification number may be used to reference individual parameters listed in this manual. This parameter identification number is also displayed in the ToolKit configuration screens next to the respective parameter. If an LS-5x2 v2 is configured as an LS-5x1 v2, there are LS-5x2 v2 LogicsManager command variables available for configuration but cannot be used.
  • Page 75 4 Configuration 4.1 Basic Setup • 0 = 0th minute of the hour • 59 = 59th minute of the hour 1708 Second 0 to 59 s The second of the clock time is set here. [real-time clock] Example • 0 = 0th second of the minute •...
  • Page 76 4 Configuration 4.1 Basic Setup by one hour when the configured DST begin date and time is reached and falls back again by one hour when the configured DST end date and time is reached. If the unit is used in the southern hemisphere, the DST function will be inverted automatically, if the DST begin month is later in the year than...
  • Page 77 4 Configuration 4.1 Basic Setup [Last] DST starts on the last configured weekday of the DST begin month. LastButOne DST starts on the last but one configured weekday of the DST begin month. LastButTwo DST starts on the last but two configured weekday of the DST begin month.
  • Page 78 4 Configuration 4.1 Basic Setup DST ends on the 1st configured weekday of the DST begin month. DST ends on the 2nd configured weekday of the DST begin month. DST ends on the 3rd configured weekday of the DST begin month. DST ends on the 4th configured weekday of the DST begin month.

  • Page 79: Configure Display

    4 Configuration 4.1 Basic Setup Parameter Setting 4591 Daylight saving time 4594 DST begin time 4598 DST begin weekday Sunday 4592 DST begin nth weekday 4593 DST begin month 4597 DST end time 4599 DST end weekday Sunday 4595 DST end Sunday 4596 DST end month Tab.
  • Page 80 4 Configuration 4.1 Basic Setup Code level Code level CL0 (User Level) This code level permits for monitoring of the system and limited access to the parameters. Standard password = none Configuration of the control is not permitted. Only the parameters for setting the language, the date, the time, and the horn reset time are accessible.

  • Page 81: System Management

    4 Configuration 4.1 Basic Setup 10400 Password display 0000 to 9999 The password for configuring the control via the front panel must be [random number] entered here. 10405 Code level display (display only) This value displays the code level, which is currently enabled for access via the front panel display.
  • Page 82 4 Configuration 4.1 Basic Setup The unit must be restarted after changing the device number to ensure proper operation. No access in the application modes 4556 Configure display backlight The display backlight is always enabled. The display backlight is always disabled.
  • Page 83 This parameter is only displayed, if Factory Settings (parameter 10417) is set to "Yes". This function is used for uploading application software and may only be used by authorized Woodward service personnel! 1706 Clear eventlog The event history will be cleared.

  • Page 84: Password System

    4 Configuration 4.1 Basic Setup 4.1.5 Password System General notes The following passwords grant varying levels of access to the parameters. Each individual password can be used to access the appropriate configuration level through multiple access methods and communication protocols (via the front panel, via serial RS-232/485 interface, and via the CAN bus).

  • Page 85: Configure Measurement

    4 Configuration 4.2 Configure Measurement System A and system B text can be configured. It will be used with Status/Monitoring screen for HMI and home screen of ToolKit. The parameters of system A and system B will still come with "SysA / SyA." or "SysB / SyB." notification - the customizable text described below is just a heading.
  • Page 86 4 Configuration 4.2 Configure Measurement 1750 System rated frequency 50 / 60 Hz The rated frequency of the system is used as a reference figure for all [50 Hz] frequency related functions, which use a percentage value, like frequency monitoring, breaker operation windows or the Analog Manager.
  • Page 87 4 Configuration 4.2 Configure Measurement Notes The measurement of phase rotation with 1Ph2W is not possible. For this reason monitoring phase rotation mismatch is working with this supposed phase rotation. For information on measuring principles refer to ╚═▷ “3.3.4.2 System A Voltage”.
  • Page 88 4 Configuration 4.2 Configure Measurement "Phase - neutral" and Line-Line (Delta connected system) if parameter 1858 is configured to "Phase - phase". Measurement, display and protection are adjusted according to the rules for phase-phase systems. Monitoring refers to the following voltages: •...
  • Page 89 4 Configuration 4.2 Configure Measurement 1853 SyB. voltage measuring [3Ph 4W] Measurement is performed Line- Neutral (WYE connected system) and Line-Line (Delta connected system). The protection depends on the setting of parameter 1770. Phase voltages and the neutral must be connected for proper calculation. Measurement, display and protection are adjusted according to the rules for WYE connected systems.

  • Page 90: Configure Transformer

    4 Configuration 4.2 Configure Measurement If this parameter is configured to 1Ph 3W, the system B rated voltages (parameter 1768) must be entered as Line-Line (Delta). For information on measuring principles refer to ╚═▷ “3.3.4.2 System A Voltage”. 4.2.1 Configure Transformer General notes This controller is available in two different hardware versions with either 1A [../1] or 5A [../5] current transformer inputs.
  • Page 91 4 Configuration 4.2 Configure Measurement System A voltage: Terminals 14/16/18/20 • Rated voltage: 480 Vac (this parameter configured between 131 and 480 V) System A voltage: Terminals 15/17/19/21 Notes WARNING: Only connect the measured voltage to either the 120 Vac or the 480 Vac inputs.

  • Page 92: Configure Monitoring

    4 Configuration 4.3 Configure Monitoring [400 V] facilitate measuring the mains voltages. The rating of the secondary side of the potential transformer must be entered into this parameter. If the application does not require potential transformers (i.e. the measured voltage is 480 V or less), then the measured voltage will be entered into this parameter.

  • Page 93: System A Operating Voltage / Frequency

    4 Configuration 4.3 Configure Monitoring monitoring "system A" are referred to this value (VL-N). The phase-phase and phase-neutral voltage will be monitored and all subsequent parameters concerning voltage monitoring "system A" are referred to this value (VL-L & VL-N). This setting is only effective if "SyA. voltage measuring"...
  • Page 94 4 Configuration 4.3 Configure Monitoring out of the operating limits as soon as it falls below 45 Hz and will be considered as being within the operating limits again as soon as it exceeds 47.5 Hz (45 Hz + 2.5 Hz). Parameter Setting range Description...

  • Page 95: System A Decoupling

    4 Configuration 4.3 Configure Monitoring 5813 Lower frequency limit 50.0 to 100.0 % The maximum permissible negative deviation of the system A frequency [95.0 %] from the rated system frequency (parameter 1750) is configured here. This value may be used as a frequency limit switch.
  • Page 96 4 Configuration 4.3 Configure Monitoring If one of these protective functions is triggered, the display indicates "SyA. decoupling" (the logical command variable "07.25" will be enabled) and an active level 2 alarm. The decoupling function is optimized on the relay outputs "CBA open". In case of using a free relay output in conjunction with the command variable 07.25 an additional delay time of up to 20 ms must be considered.

  • Page 97: Phase Shift

    4 Configuration 4.3 Configure Monitoring acknowledgement" (via a discrete input or via an interface). 4.3.1.3 Phase Shift General notes A vector/phase shift is defined as the sudden variation of the voltage curve which may be caused by a major generator load change. The unit measures the duration of a cycle, where a new measurement is started with each voltage passing through zero.
  • Page 98 4 Configuration 4.3 Configure Monitoring 3053 Monitoring [1- and 3-phase] During single-phase voltage phase/ vector shift monitoring, tripping occurs if the phase/vector shift exceeds the configured threshold value (parameter 3054) in at least one of the three phases. 3-phase During three-phase voltage phase/ vector shift monitoring, tripping occurs only if the phase/vector shift exceeds the specified threshold value...

  • Page 99: Df/Dt (Rocof)

    4 Configuration 4.3 Configure Monitoring acknowledgement" (via a discrete input or via an interface). 3056 Monitoring lockable Monitoring for fault conditions is only performed if "Lock Monitoring Status 24.40" is false. [No] Monitoring for this fault condition is continuously enabled regardless of "Lock Monitoring Status 24.40".

  • Page 100: System A Overfrequency (Levels 1 & 2) Ansi# 81O

    4 Configuration 4.3 Configure Monitoring 3101 Alarm class A/B/C/D/E/F/Control Each limit may be assigned an independent alarm class that specifies what action should be taken when the limit is surpassed. Notes For additional information see ╚═▷ “9.4.1 Alarm Classes”. 3102 Self acknowledge The control unit automatically clears the alarm if the fault condition is no...
  • Page 101 4 Configuration 4.3 Configure Monitoring 2850 Monitoring [On] Overfrequency monitoring is carried out according to the following 2856 (Limit 1/Limit 2) parameters. Monitoring is performed at two levels. Both values may be configured independent from each other (prerequisite: Level 1 limit <...

  • Page 102: System A Underfrequency (Level 1 & 2) Ansi# 81U

    4 Configuration 4.3 Configure Monitoring 2853 Monitoring lockable Monitoring for fault conditions is only performed if "Lock Monitoring Status 2859 (Limit 1/Limit 2) 24.40" is false. [No] Monitoring for this fault condition is continuously enabled regardless of "Lock Monitoring Status 24.40". 4.3.1.6 System A Underfrequency (Level 1 &...

  • Page 103: System A Overvoltage (Level 1 & 2) Ansi# 59

    4 Configuration 4.3 Configure Monitoring 2905 Delay 0.02 to 99.99 s If the monitored frequency value falls below the threshold value for the 2911 (Limit 1/Limit 2) 2905: [1.50 s] delay time configured here, an alarm will be issued. 2911: [0.06 s] Notes If the monitored frequency falls below the threshold (plus the hysteresis)
  • Page 104 4 Configuration 4.3 Configure Monitoring Refer to ╚═▷ “9.1.1 Triggering Characteristics” for the triggering characteristic of this monitoring function. The system A overvoltage Level 2 limit configuration parameters are located below the "SyA. decoupling" function menu on the display. Parameter Setting range Description [Default]...

  • Page 105: System A Undervoltage (Level 1 & 2) Ansi# 27

    4 Configuration 4.3 Configure Monitoring 2953 Self acknowledge The control unit automatically clears the alarm if the fault condition is no 2959 (Limit 1/Limit2) longer detected. [No] The control unit does not automatically reset the alarm when the fault condition is no longer detected.
  • Page 106 4 Configuration 4.3 Configure Monitoring 3000 Monitoring [On] Undervoltage monitoring is carried out according to the following parameters. 3006 Limit 1/Limit 2 Monitoring is performed at two levels. Both values may be configured independent from each other (prerequisite: Level 1 limit <...

  • Page 107: System A Voltage Asymmetry

    4 Configuration 4.3 Configure Monitoring 3003 Monitoring lockable [Yes] Monitoring for fault conditions is only performed if "Lock Monitoring Status 3009 Limit 1/Limit 2 24.40" is false. Monitoring for this fault condition is continuously enabled regardless of "Lock Monitoring Status 24.40". 8844 SyA.

  • Page 108: 4.3.1.10 System A Voltage Increase

    4 Configuration 4.3 Configure Monitoring Notes This value refers to the 'SyA rated voltage' (parameter 1766). 3925 Delay 0.02 to 99.99 s If the monitored voltage asymmetry exceeds the threshold value for the [5.00 s] delay time configured here, an alarm will be issued.
  • Page 109 4 Configuration 4.3 Configure Monitoring (parameter 8849). The parameter "SyA. decoupling volt. incr." (parameter 8808) determines if a voltage increase shall trigger a system A decoupling or not. If this protective function is triggered, the display indicates "SyA. volt. increase". The alarm can be incorporated into the system A decoupling function.

  • Page 110: 4.3.1.11 Setup System A For Vde-Ar-N 4105

    4 Configuration 4.3 Configure Monitoring 8808 SyA. decoupling voltage increase Voltage increase monitoring does cause decoupling. [No] Voltage increase monitoring does not cause decoupling. 8831 Alarm class Class A/B/C/D/E/F/Control Each limit may be assigned an independent alarm class that specifies what action should be taken when the limit is surpassed.
  • Page 111 Woodward solves this requirement with the use of a minimum of two devices acting as a system (for example two LS-5 or an easYgen with VDE-AR-N 4105 functionality and an LS-5).
  • Page 112 4 Configuration 4.3 Configure Monitoring 2. Parameter Alignment VDE-AR-N 4105 The Monitoring Parameter Alignment checks whether all 4105 partner devices are configured with the same decoupling criteria. If not, an alarm is triggered and displayed. The consequence is blocking or leaving mains parallel operation, which can again be reached by changing the breaker transfer logic.
  • Page 113 4 Configuration 4.3 Configure Monitoring 3. Measurement Difference VDE-AR-N 4105 The Monitoring Measurement Difference checks whether the own mains voltage and mains frequency measurement matches with the one of the other 4105 partner. If not, there are two possible scenarios: Scenario 1 - only one 4105 partner device exists: an alarm is triggered and displayed.
  • Page 114 4 Configuration 4.3 Configure Monitoring Parameter Setting range Description [Default] 2.0 to 9.9% rated voltage measurement (refer to parameter1768). This is a part within the VDE-AR-N 4105 diagnostic. 1836 Frequency difference [1.0%] This is the frequency measurement tolerance for all participating VDE-AR- 0.5 to 9.9% N 4105 partners relating to the system rated frequency...

  • Page 115: 4.3.1.12 Qv Monitoring

    4 Configuration 4.3 Configure Monitoring Parameter Setting range Description [Default] For additional information refer to ╚═▷ “9.4.1 Alarm Classes”. 3485 Self acknowledge The control automatically clears the alarm if the fault condition is no longer detected. [No] The control device does not automatically reset the alarm when the fault condition is no longer detected.
  • Page 116 4 Configuration 4.3 Configure Monitoring QV monitoring is triggered if the following conditions are fulfilled. • QV monitoring is configured to "On" (parameter 3292) • Measured reactive power is higher than the configured “Reactive power threshold” (parameter 3291) • Measured voltages are below the configured “Limit undervoltage” (parameter 3285) As a result Timer 1 and Timer 2 are starting.
  • Page 117 4 Configuration 4.3 Configure Monitoring 3292 Monitoring [On] QV monitoring is carried out according to the following parameters. No monitoring is carried out. 3285 Limit undervoltage 45 to 150 % The percentage voltage value that is to be monitored is defined here. [85 %] If the voltages of all phases (one phase in 1Ph 2W system) are below...

  • Page 118: 4.3.1.13 System A Time-Dependent Voltage

    4 Configuration 4.3 Configure Monitoring For additional information refer to ╚═▷ “9.4.1 Alarm Classes” 3293 Self acknowledge [Yes] The control unit automatically clears the alarm if the fault condition is no longer detected. The control unit does not automatically reset the alarm when the fault condition is no longer detected.
  • Page 119 4 Configuration 4.3 Configure Monitoring The time points should always have an ascending order. The fallback threshold (parameter 4978) should always be configured to a value higher/lower than the initial threshold (parameter 4970). Fig. 73: Time-dependent voltage monitoring 0.00 s → 45.0 % 0.15 s →...
  • Page 120 4 Configuration 4.3 Configure Monitoring 4952 AND characteristics Each phase falls below/exceeds the threshold for tripping. [Off] At least one phase falls below/exceeds the threshold for tripping. 4953 Monitoring at Selects whether the system shall do over- or undervoltage monitoring. [Underrun] The undervoltage monitoring is carried out (The monitoring function...
  • Page 121 4 Configuration 4.3 Configure Monitoring 4961 Point {x} time 0.00 to 320.00 s The time values of time-dependent voltage monitoring time points are 4962 [x = 1 to 7] 4961: [0.00 s] configured here. 4963 4962: [0.15 s] 4964 4963: [0.15 s] 4965 4964: [0.70 s] 4966...

  • Page 122: 4.3.1.14 System A Phase Rotation

    4 Configuration 4.3 Configure Monitoring [No] Monitoring for this fault condition is continuously enabled regardless of "Lock Monitoring Status 24.40". 4989 SyA. decou-pling Time-dependent voltage monitoring does cause decoupling. [Off] Time-dependent voltage monitoring does not cause decoupling. 4.3.1.14 System A Phase Rotation General notes NOTICE! Damage to the control unit and/or generation equipment...
  • Page 123 4 Configuration 4.3 Configure Monitoring This monitoring function is only enabled if system A voltage measuring (parameter 1853) is configured to "3Ph 4W" or "3Ph 3W" and the measured voltage exceeds 50 % of the rated voltage (parameter 1768) or if system A voltage measuring (parameter 1853) is configured to "1Ph 2W"...

  • Page 124: System B

    4 Configuration 4.3 Configure Monitoring 4.3.2 System B Parameter Setting range Description [Default] 1770 SyB. voltage monitoring The unit can either monitor the phase- neutral (wye) voltages or the phase- phase (delta) voltages. If the controller is used in a compensated or isolated network, voltage protection monitoring should be configured as phase-neutral to...

  • Page 125: System B Voltage Phase Rotation

    4 Configuration 4.3 Configure Monitoring [90 %] from the system B rated voltage (parameter 1768) is configured here. This value may be used as a voltage limit switch. The conditional state of this switch may be used as a command variable for the LogicsManager (02.03).
  • Page 126 4 Configuration 4.3 Configure Monitoring Correct phase rotation of the phase voltages ensures that damage will not occur during a breaker closure to either the mains or the generator. The voltage phase rotation alarm checks the phase rotation of the voltages and the configured phase rotation to ensure they are identical.

  • Page 127: Breaker

    4 Configuration 4.3 Configure Monitoring the fault condition is no longer detected. The alarm must be acknowledged and reset by manually pressing the appropriate buttons or by activating the LogicsManager output "External acknowledgement" (via a discrete input or via an interface). 3953 Monitoring lockable Monitoring for fault conditions is only...

  • Page 128: Synchronization Cba

    4 Configuration 4.3 Configure Monitoring Monitoring is disabled. 2621 CBA alarm class Class A/B Each limit may be assigned an independent alarm class that specifies what action should be taken when the limit is surpassed. Notes For additional information refer to ╚═▷...

  • Page 129: Cba Unload Mismatch

    4 Configuration 4.3 Configure Monitoring 3073 Delay 3 to 999 s If it was not possible to synchronize the CBA within the time configured [60 s] here, an alarm will be issued. The message "CBA syn. timeout" is issued and the logical command variable "08.31"...

  • Page 130: System A / System B Phase Rotation

    4 Configuration 4.3 Configure Monitoring command will be issued together with an alarm "CBA unload mismatch" and the logical command variable "08.36" will be enabled. 8836 Alarm class Class A/B/C/D/E/F/Control Each limit may be assigned an independent alarm class that specifies what action should be taken when the limit is surpassed.

  • Page 131: Voltage Plausibility

    4 Configuration 4.3 Configure Monitoring This monitoring function is only enabled if system A voltage measuring (parameter 1851) and system B voltage measuring (parameter 1853) are configured to "3Ph 4W" or "3Ph 3W" and the measured voltage exceeds 50 % of the rated voltage (parameter 1766) or if system A voltage measuring (parameter 1851) and system B voltage measuring (parameter 1853) are configured to "1Ph 2W".
  • Page 132 4 Configuration 4.3 Configure Monitoring both systems are okay, the monitor expects to see a phase angle between both systems less than +/- 10°. The intension of this monitor is to detect wiring failures or blown fuses. An alarm will be initiated if •...

  • Page 133: Operating Range

    4 Configuration 4.3 Configure Monitoring [No] Monitoring for this fault condition is continuously enabled regardless of "Lock Monitoring Status 24.40". 4.3.5 Operating range General notes The operating range monitoring signalizes a wrong behavior of the system. The device is blocked to continue. The reason for this often is a not reached operating range or a missing breaker feedback or release.
  • Page 134 4 Configuration 4.3 Configure Monitoring Command variable Function Conditions to trigger the alarm The alarm indicates that the LS-5 • AND The CBA feedback is open is blocked, because there is a • AND A CBA dead busbar closure is detected dead busbar closure CBA situation but not allowed to execute recognized but the according...

  • Page 135: Can Interface

    4 Configuration 4.3 Configure Monitoring 2678 Monitoring lockable Monitoring for fault conditions is only performed if "Lock Monitoring Status 24.40 is false". [No] Monitoring for this fault condition is continuously enabled regardless of "Lock Monitoring Status 24.40". 4.3.6 CAN Interface General notes The CANopen interface is monitored.

  • Page 136: Battery Overvoltage (Level 1 & 2)

    4 Configuration 4.3 Configure Monitoring appropriate buttons or by activating the LogicsManager output "External acknowledgement" (via a discrete input or via an interface). 3153 Monitoring lockable Monitoring for fault conditions is only performed if "Lock Monitoring Status 24.40 is false". [No] Monitoring for this fault condition is continuously enabled regardless of...

  • Page 137: Battery Undervoltage (Level 1 & 2)

    4 Configuration 4.3 Configure Monitoring If the monitored battery voltage falls below the threshold (minus the hysteresis) before the delay expires the time will be reset. 3451 Alarm class Class A/B/C/D/E/F/Control Each limit may be assigned an independent alarm class that specifies 3457 what action should be taken when the limit is surpassed.
  • Page 138 4 Configuration 4.3 Configure Monitoring 3506 according to the following parameters. Both values may be configured independent from each other (prerequisite: Level 1 > Level 2). Monitoring is disabled for Level 1 limit and/or Level 2 limit. 3504 Limit 8.0 to 42.0 V The threshold values that are to be monitored are defined here.

  • Page 139: Free Configurable Alarms

    4 Configuration 4.3 Configure Monitoring 3503 Monitoring lockable Monitoring for fault conditions is only performed if "Lock Monitoring Status 3509 24.40 is false". [No] Monitoring for this fault condition is continuously enabled regardless of "Lock Monitoring Status 24.40". 4.3.9 Free Configurable Alarms General Notes The LS-5 v2 series devices provide 4 freely configurable alarms.

  • Page 140: Multi-Unit Missing Members

    4 Configuration 4.3 Configure Monitoring Parameter Setting range Description [Default] 5162 Self acknowledge The control automatically clears the alarm if the fault condition is no longer detected. [No] The control does not automatically clears the alarm if the fault condition is no longer detected.

  • Page 141: Global Settings

    4 Configuration 4.3 Configure Monitoring Parameter Setting range Description [Default] 4060 Monitoring Multi-unit missing members monitoring is carried out. [Off] Monitoring is disabled. Notes This parameter only applies to application mode 4063 Number of LS5 communicating 2 to 64 The number participating of LS-5 units is configured here.

  • Page 142: Configure Application

    4 Configuration 4.4 Configure Application button, the LogicsManager, or the interface. Notes If this parameter is configured to 0, the horn will remain active until it will be acknowledged. 12490 Ext. acknowledge Determined by It is possible to acknowledge all LogicsManager alarms simultaneously from remote, (External acknowledgment of alarms)

  • Page 143: Fixed Parameters

    4 Configuration 4.4 Configure Application Fixed parameters In the application modes some parameters are preconfigured to fixed values. In these modes these parameters cannot be accessed via front panel or ToolKit. • Check the following parameters if you change the application mode from Device number (parameter 1702) Variable system (parameter 8816) Node-ID CAN bus 1 (parameter 8950)

  • Page 144: Breakers

    4 Configuration 4.4 Configure Application In this application mode, the easYgen is controlling the MCB via the LS-5. The operation mode is fixed to automatic. L-GGB Application mode In this application mode, the easYgen is controlling the GGB via the LS-5. The operation mode is fixed to automatic.

  • Page 145: Configure Cba

    4 Configuration 4.4 Configure Application detect a dead bus condition of a system. Notes The delay time starts as soon as the measured voltage is below the value configured in parameter 5820. The delay time is independent of LogicsManager "Enable close CBA" (parameter 12945).
  • Page 146 4 Configuration 4.4 Configure Application 3417 CBA time pulse 0.10 to 0.50 s Breaker pulse duration to close the CBA.. [0.50 s] The time of the pulse output may be adjusted to the breaker being utilized. 5715 Closing time CBA 40 to 300 ms The inherent closing time of the CBA corresponds to the lead-time of the...
  • Page 147 4 Configuration 4.4 Configure Application higher priority the display shows "CBA request". Only in operation mode MANUAL. No access in application modes 12958 Close CBA in MAN Determined by Once the conditions of the LogicsManager LogicsManager have been fulfilled the LS-5 closes the CBA, if no other LS-5 [(0&1)&1] with higher priority likes to do the...
  • Page 148 4 Configuration 4.4 Configure Application If a close or open command is active but is blocked by another device with higher priority the display shows "CBA request". Only in operation mode AUTOMATIC. No access in application modes 4.4.2.2.1 Synchronization CBA Parameter Setting range Description...
  • Page 149 4 Configuration 4.4 Configure Application 5711 Pos. freq. differential CBA 0.00 to 0.49 Hz The prerequisite for a connect command being issued for the CBA is (Positive frequency differential CBA) [+0.18 Hz] that the differential frequency is below the configured differential frequency. This setting is always in regards of system A: •...

  • Page 150: Synchronization Configuration

    4 Configuration 4.4 Configure Application Parameter Setting range Description [Default] 5713 Max. positive phase angle CBA 0.0 to 60.0 ° The prerequisite for a connect command being issued for the CBA is [7.0 °] that the leading phase angle between system B and system A is below the configured maximum permissible angle.
  • Page 151 4 Configuration 4.4 Configure Application NOTICE! Damaged components due to incorrect settings • Validate the setting in every control unit with a differential voltage measurement. ⚙ Calculating the phase angle deviation (known transformer vector group) ᐳ The vector group states the phase angle deviation in multiples of 30°. From the vector group the phase angle deviation can be calculated as an angle between 0°...
  • Page 152 4 Configuration 4.4 Configure Application Recommendation: For safety reasons, please mark the LS-5 with a label showing the configured phase angle compensation. 8824 Phase angle -180 to 180° This parameter compensates phase angle deviations, which can be caused [0°] by transformers (e.g. a delta to wye transformer) located within the electrical system.
  • Page 153 4 Configuration 4.4 Configure Application • 3. RUN Notes The device will still perform a dead busbar closure if the conditions are valid. No access in the application modes Synchronization In some applications it can be beneficial to switch on 1-phase synchronization even a three phase measurement is maintained and configured.

  • Page 154: Configure Synchronous Network

    4 Configuration 4.4 Configure Application measurement system A to system B. 3-phase The synchronization function compares the L1-L2, L2-L3, L3- L1 measurement system A to system B. 12906 Syn. mode CHECK Determined by Once the conditions of the LogicsManager LogicsManager have been fulfilled the (Synchronization mode CHECK) CHECK synchronization mode will be [(0&1)&1]...
  • Page 155 4 Configuration 4.4 Configure Application System B are mains connected) is not allowed. Notes If no closed GCB in the relevant segment is detected, unloading will be canceled and the breaker will be opened immediately (even if the command “Open CBA with unloading” is active).

  • Page 156: Configure Segment

    4 Configuration 4.4 Configure Application 4.4.3 Configure Segment General notes The LS-5x1 v2 can be used in different applications. The following examples show the three basic ones. No isolation switch No isolation switch is installed. At the following example • Segment no. System A is 10 (parameter 8810) •...
  • Page 157 4 Configuration 4.4 Configure Application • Segment no. Isolation switch is 10 (parameter 8812) • Isolation switch is set to System A (parameter 8815) Fig. 75: LS-5x1 v2 - Isolation switch on System A side (example) Isolation switch on System B side The isolation switch is installed on System B side.
  • Page 158 4 Configuration 4.4 Configure Application Fig. 76: LS-5x1 v2 - Isolation switch on System B side (example) Parameter Setting range Description [Default] 8810 Segment number Sy.A 1 to 64 Segment number for system A. Notes No access in the application modes 8811 Segment number Sy.B 1 to 64...
  • Page 159 4 Configuration 4.4 Configure Application 8813 Mains pow. measurem. Valid The measured power is used for mains real power control. [Invalid] The measured power is not used for power control. Notes No access in the application modes 8814 Mains connection [None] No system is wired to mains directly.

  • Page 160: Automatic Run

    4 Configuration 4.4 Configure Application 12949 Variab. system A Determined by Once the conditions of the LogicsManager LogicsManager have been fulfilled the (Variable system A ) system A will be the variable one. [(0 & 1) & 1] If the conditions of the LogicsManager have not been fulfilled the system B will be the variable one.

  • Page 161: Inputs And Outputs

    4 Configuration 4.5 Inputs And Outputs If AUTOMATIC mode is selected via the LogicsManager it is not possible to change operating modes via the front panel. Notes No access in the application modes For information on the LogicsManager and its default settings see ╚═▷...
  • Page 162 4 Configuration 4.5 Inputs And Outputs In the state N.C.: • A potential is continuously present during normal operation • If an alarm is issued or control operation is performed, the input is de-energized. All reply messages from breakers are evaluated as N.C.. Alarm inputs may also be configured as control inputs and then be used as command variables in the LogicsManager.
  • Page 163 4 Configuration 4.5 Inputs And Outputs Parameter IDs The following parameters are used to configure the discrete inputs 1 through 7. The parameter IDs refer to discrete input 1. • Refer to ╚═▷ Tab. 17 for the parameter IDs of the parameters DI 2 through DI 7. DI 1 DI 2 DI 3...
  • Page 164 4 Configuration 4.5 Inputs And Outputs [N.O.] The discrete input is analyzed as "enabled" by energizing the input (normally open). N.C. The discrete input is analyzed as "enabled" by de-energizing the input (normally closed). 1200 DI {x} Delay 0.08 to 650.00 s A delay time in seconds can be assigned to each alarm or control DI 01: [0.20 s]...

  • Page 165: Discrete Outputs (Logicsmanager)

    4 Configuration 4.5 Inputs And Outputs If the DI is configured with the alarm class "Control", self acknowledgement is always active. 4.5.2 Discrete Outputs (LogicsManager) General notes The discrete outputs are controlled via the LogicsManager. For information on the LogicsManager and its default settings see ╚═▷...

  • Page 166: Configure Interfaces

    4 Configuration 4.6 Configure Interfaces 12580 Ready for op. Off Determined by The "Ready for operation OFF" relay is LogicsManager energized by default if the power (Ready for operation OFF) supply exceeds 8 V. Once the conditions of the LogicsManager have been fulfilled, the relay will be de-energized.

  • Page 167: Can Interface

    4 Configuration 4.6 Configure Interfaces This is the preferred ToolKit connection via Service port (RJ45 connector). ╚═▷ “4.6.3 RS-232 Interface” details. Serial 2 ToolKit is working at Serial #2 interface (RS-485) 4.6.2 CAN Interface General notes The CAN bus is a field bus and subject to various disturbances. Therefore, it cannot be guaranteed that every request will be answered.

  • Page 168: Can Interface 1

    4 Configuration 4.6 Configure Interfaces 4.6.2.1 CAN Interface 1 COB-ID messages Parameters 9100 and 9101 use synchronization and time messages that adhere to the following structure. UNSIGNED 32 Bits 28-11 10-0 11 bit ID all 0 (18 bit) 11 bit identifier Bit number Value Meaning...
  • Page 169 4 Configuration 4.6 Configure Interfaces Parameter Setting range Description [Default] 3156 Baudrate 20 / 50 / 100 / 125 / 250 / This parameter defines the used baud 500 / 800 / 1000 kBaud rate. Please note, that all participants on the CAN bus must use the same [250 kBd] baud rate.

  • Page 170: Additional Server Sdos (Service Data Objects)

    4 Configuration 4.6 Configure Interfaces If no "Start_Remote_node" message would be sent, the complete system would not be operational. 9120 Producer heartbeat time 0 to 65500 ms Independent from the CANopen Master configuration, the unit [2000 ms] transmits a heartbeat message with this configured heartbeat cycle time.

  • Page 171: Receive Pdo {X} (Process Data Object)

    4 Configuration 4.6 Configure Interfaces Parameter Setting range Description [Default] 33040 2. Node-ID 0 to 127 (dec) In a multi-master application, each Master needs its own identifier (Node- ID) from the unit. in order to send remote signals (i.e. remote start, stop, or acknowledge) to the unit.
  • Page 172 4 Configuration 4.6 Configure Interfaces Fig. 79: RPDO mapping principle COB-ID parameters Parameter 9300 , 9310 uses communication parameters that adhere to the following structure. UNSIGNED 32 Bits 28-11 10-0 11 bit ID all 0 (18 bit) 11 bit identifier Bit number Value Meaning...

  • Page 173: Transmit Pdo {X} (Process Data Object)

    4 Configuration 4.6 Configure Interfaces 9300 COB-ID 1 to FFFFFFFF hex This parameter contains the communication parameters for the 9310 [80000000 hex] PDOs, the device is able to receive. Complies with CANopen specification: object 1400 (for RPDO 1, 1401 for RPDO 2 and 1402 for RPDO 3), subindex 1.
  • Page 174 4 Configuration 4.6 Configure Interfaces Fig. 80: TPDO mapping CANopen allows to send 8 byte of data with each Transmit PDO. These may be defined separately if no pre-defined data protocol is used. All data protocol parameters with a parameter ID may be sent as an object with a CANopen Transmit PDO.

  • Page 175: Transmission Types

    4 Configuration 4.6 Configure Interfaces PDO valid / not valid allows to select, which PDOs are used in the operational state. Transmission types Parameters 9602 / 9612 / 9622 are used to select one of the following transmission types. Transmission PDO transmission type Cyclic...
  • Page 176 4 Configuration 4.6 Configure Interfaces or lower than 180 (hex). These IDs are reserved for internal purposes. 9602 Transmission type 0 to 255 This parameter contains the communication parameters for the 9612 [255] PDOs the unit is able to transmit. It defines whether the unit broadcasts 9622 all data automatically (value 254 or...

  • Page 177: Interface

    4 Configuration 4.6 Configure Interfaces 9605 1. Mapped Object 0 to 65535 This parameter contains the information about the mapped 9615 application variables. These entries describe the PDO contents by their 9625 index. The sub-index is always 1. The length is determined automatically. Notes Complies with CANopen specification: object 1A00 (for TPDO 1, 1A01 for...

  • Page 178: Interface

    4 Configuration 4.6 Configure Interfaces 3163 Baudrate 2.4 / 4.8 / 9.6 / 14.4 / This parameter defines the baud rate [19.2] / 38.4 / 56 / 115 for communications. Please note, that kBaud all participants on the bus must use the same baud rate.

  • Page 179: Modbus Protocol (5300 Multiple)

    4 Configuration 4.6 Configure Interfaces slave. This time is required in half- duplex mode. 4.6.5 Modbus Protocol (5300 Multiple) Parameter Setting range Description [Default] 3181 Power [W] exponent 10^x 2 to 5 This setting adjusts the format of the 16 bit power values in the data telegram.

  • Page 180: Configure Logicsmanager

    4 Configuration 4.7 Configure LogicsManager Setting Meaning Calculation Transfer value Possible display format (16Bit, max. 32767) 198500 W / 10 Voltage measurement example Refer to parameter 3182. • The measurement range is 0…480 V • Momentarily measurement value = 477.8 V Setting Meaning Calculation...

  • Page 181: Internal Flags

    4 Configuration 4.7 Configure LogicsManager Refer to ╚═▷ “9.3.2 Logical Symbols” for a table of symbols according to the different standards. Parameter Setting range Description [Default] {yyyyy} Flag {x} Determined by The flags may be used as auxiliary LogicsManager flags for complex combinations by using the logical output of these [(0 &...
  • Page 182 4 Configuration 4.7 Configure LogicsManager For conditions and explanation of programming please refer to ╚═▷ “9.3.1 LogicsManager Overview”. LS-5 flags Each LS-5 has five special flags (“Flag 1 LS5” to “Flag 5 LS5”) which can be defined via LogicsManager. They are transmitted via CAN bus. These flags (26.01 to 27.80) are received by the other LS-5 and easYgen devices and can be used as inputs for the LogicsManager The command parameters are listed as one entry in the parameter table below.
  • Page 183 4 Configuration 4.7 Configure LogicsManager LED {x} LED 1 LED 2 LED 3 LED 4 LED 5 LED 6 LED 7 LED 8 Parameter 12962 12963 12964 12965 12966 12967 12968 12969 ID {yyyyy} Tab. 23: LED flag parameter IDs LogicsManager Timers: Set timers Utilizing the LogicsManager it is possible to establish specific times of the day, days, hours, minutes or seconds that functions can be enabled.
  • Page 184 4 Configuration 4.7 Configure LogicsManager Daily time setpoints - Timer 1/2 Parameter Setting range Description [Default] 1652 Timer {x}: Hour 0 to 23 h Enter the hour of the daily time setpoint here. 1657 1652: [8 h] Example 1657: [17 h] •...
  • Page 185 4 Configuration 4.7 Configure LogicsManager Parameter Setting range Description [Default] The active time setpoint is enabled every hour during the indicated minute from second 0 to second 59. Example • 0 = 0th minute of the hour. • 59 = 59th minute of the hour. 1660 Active second 0 to 59 s...

  • Page 186: Configure Counters

    4 Configuration 4.8 Configure Counters Parameter Setting range Description [Default] 1676 Sunday active The switch point is enabled every Sunday. [No] The switch point is disabled every Sunday. Configure Counters Parameter Setting range Description [Default] 2515 Counter value preset 0 to 999,999.99 This value is utilized to set the following counters: •...
  • Page 187 4 Configuration 4.8 Configure Counters • If this parameter is set to "Yes", the "System A active power" counter will be set to 34.56 MWh. 2511 Set SyA. reactive energy [0.00 The current value of this counter is Mvarh] overwritten with the value configured in "Counter value preset"...

  • Page 188: Operation

    Protocols” Access Via PC (ToolKit) Version Woodward’s ToolKit software is required to access the unit via PC • Required version: 5.6.3 or higher • Please use the latest available version! • For information on how to obtain the latest version see ╚═▷...

  • Page 189: Minimum System Requirements

    The latest version of Microsoft .NET Framework (4.6.1 or higher) can be obtained from Microsoft website. ⚙ Load from the website 1. ▷ Go to ══▷ http://www.woodward.com/software 2. ▷ Search the ToolKit software by typing 'ToolKit' at 'Enter Search Term' and click the »Search« button. 3. ▷...

  • Page 190: Install Toolkit Configuration Files

    The latest version of the ToolKit software can be obtained from our website. ⚙ Load from the website 1. ▷ Go to ══▷ http://www.woodward.com/software/configfiles 2. ▷ Insert the part number (P/N) and revision of your device into the corresponding fields. 3. ▷ Select "ToolKit" in the »application type« list.

  • Page 191: Configure Toolkit

    5 Operation 5.1 Access Via PC (ToolKit) 5. ▷ Download the file displayed in the search result. The file is a *.msi file which must be installed. ▶ ToolKit files *.WTOOL File name composition: [P/N1] -[Revision]_[Language ID]_[P/N2] -[Revision]_[# of visualized gens].WTOOL Example file name: 8440-1234-NEW_US_5418-1234-NEW.WTOOL File content:...
  • Page 192 5 Operation 5.1 Access Via PC (ToolKit) ▶ Fig. 86: ToolKit Options window File locations Language setting for tools The »Options« windows is displayed. Adjust settings as required. 2. ▷ For more information on the individual settings refer to the ToolKit help. ▶...

  • Page 193: Connect Toolkit

    If the PC does not have a serial port to connect the null modem cable to, use a USB to serial adapter. 2. ▷ Open ToolKit from the Windows Start Menu path [Programs / Woodward / ToolKit 5.x]. 3. ▷ From the main ToolKit window, select [File / Open Tool...] click the »Open Tool« icon the tool bar.
  • Page 194 (including virtual ports) Active connections via bluetooth Temporarily deactivate bluetooth (including virtual ports) Additional CANopen devices Contact Woodward support or provide connected to the bus missing .sid file for additional CANopen device (╚═▷ “SID files for additional CANopen devices”)

  • Page 195: View And Set Values In Toolkit

    A cause may be that ToolKit looks for a SID file for the external device, which does not exist. A special *.sid file can be created in this case. For additional support feel free to contact Woodward. ⚙ Create a SID (text) file with the following content: <?xml version="1.0"...
  • Page 196 5 Operation 5.1 Access Via PC (ToolKit) ⚙ To change the value of a value or option field: Enter the value or select an option from the drop-down list. 1. ▷ Press »Enter « to confirm. 2. ▷ The new value is written directly to the unit. ▶...

  • Page 197: Special Screens

    5 Operation 5.1 Access Via PC (ToolKit) ▶ Fig. 91: Trending screen The trending screen opens. Click the »Start« button to initiate charting. 2. ▷ Click the »Stop« button to stop charting the values. 3. ▷ To store the tracked data select »Export« 4. ▷...
  • Page 198 5 Operation 5.1 Access Via PC (ToolKit) States easYgen Fig. 92: States easYgen Symbol Description Operating mode STOP is active. Operating mode MANUAL is active. Operating mode AUTOMATIC is active. Breaker is open. Breaker is closed. LS-5 v2 Series 37649...
  • Page 199 5 Operation 5.1 Access Via PC (ToolKit) States LS-5 Fig. 93: States LS-5 Symbol Description Voltage is below dead bus limit. Voltage is higher than dead bus limit but not in range. Voltage and frequency are in operating range. Breaker is open. Breaker is closed.
  • Page 200 5 Operation 5.1 Access Via PC (ToolKit) Segments LS-5 Fig. 94: Segments LS-5 Symbol Description Voltage is below dead bus limit. Voltage is higher than dead bus limit but not in range. Voltage and frequency are in operating range. Breaker is open. Breaker is closed.
  • Page 201 5 Operation 5.1 Access Via PC (ToolKit) CAN Interface 1 State Fig. 95: CAN interface state screen (example) Section Assignment 8954 CAN bus 1 state A TPDO has incorrect mapping parameters An RPDO has incorrect mapping parameters A TPDO has more than 8 bytes An RPDO has more than 8 bytes 8942 CAN 1 monitoring (active state)

  • Page 202: Front Panel Access

    5 Operation 5.2 Front Panel Access Front Panel Access 5.2.1 Basic Navigation Fig. 96: Front panel and display A (1..3) Button group "Hardware" B (4..6) Button group "Display" (Softkeys) LED Alarm messages present C (8..10) Button group "Navigation" (Softkeys) (11) Display D (12..15) LEDs "Breaker/system states"...
  • Page 203 5 Operation 5.2 Front Panel Access [A] Button group "Hardware" Button Function (all screens) Change into MANUAL operating mode. The LED indicates that the operation mode is active. When MANUAL is selected, breaker control is performed manually via the button (No.

  • Page 204: Display / Main Screen

    5 Operation 5.2 Front Panel Access Button Function (main screen) Function (other screens) No function. Scroll left / Enter menu (if graphic icon is assigned) No function. Return to last screen [D] LEDs "Breaker/system states" Button Function (all screens) The LED indicates three states: Off: Voltage is below dead bus limit (parameter 5820).

  • Page 205: Status Symbols

    5 Operation 5.2 Front Panel Access Display section Function Refer to ╚═▷ Chapter 5.2.3.1 for monitored values details. This display section shows the "Status Messages" and "Alarm Messages". This display section shows a symbol indicating the selected display mode. Refer to ╚═▷...

  • Page 206: Menu Structure

    5 Operation 5.2 Front Panel Access Menu screen Symbol Description Segment numbers and isolation switch closed. Indicates voltage and frequency are in range. Indicates voltage or frequency are not in range. Own LS-5 device number. Other LS-5 device numbers. Decoupling Indicates that value is part of system A decoupling.
  • Page 207 5 Operation 5.2 Front Panel Access Menu structure "Parameter" Fig. 99: Menu structure - Parameter 37649 LS-5 v2 Series...
  • Page 208 5 Operation 5.2 Front Panel Access Menu structure "Main menu" Fig. 100: Menu structure - Main menu The following chapters list notes on specific menu screens. For information on standard softkeys and status symbols refer to ╚═▷ “5.2.1 Basic Navigation”. LS-5 v2 Series 37649...

  • Page 209: Parameter Setting Screens

    5 Operation 5.2 Front Panel Access 5.2.2 Parameter Setting Screens The following chapters list standard menu screens, where all user input is handled similarly. For information on standard softkeys and status symbols refer to ╚═▷ “5.2.1 Basic Navigation”. For information on all other menu screens refer to ╚═▷...

  • Page 210: Value Setting Screens

    5 Operation 5.2 Front Panel Access Symbol/Button Description Return to the previous sub-menu screen. 5.2.2.2 Value Setting Screens Fig. 102: Value setting screen (example) Screen Notes Application mode LS-5 Set the current application mode. Application configuration Monitoring configuration Measurement configuration Interfaces configuration Counters configuration Language / clock configuration...

  • Page 211: Logicsmanager Setting Screens

    5 Operation 5.2 Front Panel Access Button/Softkey Description Confirm and store changed value. Return without any changes. 5.2.2.3 LogicsManager Setting screens Fig. 103: LogicsManager screen Some parameters of the LS-5 are configured via the LogicsManager. ⚙ Configure a logical operation using various command variables, signs, logical operators, 1. ▷...

  • Page 212: Main Menu Screens

    5 Operation 5.2 Front Panel Access 5.2.3 Main Menu Screens 5.2.3.1 Main Screen Display Fig. 104: LS-5x1 Main screen (example) The amount of information available from the system depends on how the measuring is configured in the control unit. The following values can be shown: Value Monitoring Notes...

  • Page 213: Alarm List

    5 Operation 5.2 Front Panel Access Symbol Monitoring Displayed at parameter setting Press below (lower 3Ph4W 3Ph4WOD 3Ph3W 1Ph2W 1Ph3W left) times 5× Wye L3-N — — — Tab. 27: Measuring voltage values system A page one Symbol Monitoring Displayed at parameter setting Press below (lower...

  • Page 214: System A

    5 Operation 5.2 Front Panel Access Symbol/Button Description Indicates that corresponding alarm condition is still present. Acknowledge the selected alarm message (displayed inverted). Acknowledgment is only possible, if the alarm condition is no longer present. If the Alarm LED is still flashing (an alarm is present, which has not yet been acknowledged as 'Seen'), this softkey resets the horn and acknowledges the alarm as 'Seen'.

  • Page 215: System B

    5 Operation 5.2 Front Panel Access Symbol/Button Description Reset the maximum value display. 5.2.3.4 System B Fig. 108: Measured values system B screen (example) Displays all measured AC values system B. Unit Value Voltage Frequency Tab. 30: Units of measured values 5.2.3.5 System Angles Fig.

  • Page 216: Logicsmanager Conditions

    5 Operation 5.2 Front Panel Access The frequency and voltage values of system A (left side) and system B (right side) are indicated in the display. The shown value is not the real angle between system A and system B if the phase angle compensation (parameter 8824) is active.

  • Page 217: States Easygen

    5 Operation 5.2 Front Panel Access This screen displays system events. A date/time stamp in the format mon-dd hh:mm:ss.ss is added to each entry. All alarm messages, which have not been acknowledged and cleared, are displayed. Symbol/Button Description Indicates a condition that is still active. The condition is no longer present.

  • Page 218: Segments

    5 Operation 5.2 Front Panel Access Symbol Description Segment numbers and breaker open. Segment numbers and breaker closed. Segment numbers and isolation switch open. Segment numbers and isolation switch closed. Indicates voltage and frequency are in range. Indicates voltage or frequency are not in range. Own LS-5 device number.

  • Page 219: 5.2.3.12 Discrete Inputs/Outputs

    5 Operation 5.2 Front Panel Access 5.2.3.12 Discrete Inputs/Outputs Fig. 117: Discrete inputs/outputs screen (example) This screen displays discrete inputs' and discrete outputs' status. The configured logic for the discrete input "N.O./N.C." will determine how the LS-5 reacts to the state of the discrete input. If the respective DI is configured to N.O., the unit reacts on the energized state;...
  • Page 220 5 Operation 5.2 Front Panel Access Fig. 119: Status of test (example) Softkey Description TEST ON Starts a test mode which allows a comfortable system A decoupling configuration. TEST OFF Stops a test mode which allows a comfortable system A decoupling configuration.
  • Page 221 5 Operation 5.2 Front Panel Access Fig. 121: Decoupling overvoltage (example) The following values are treated similar: • Overvoltage level 1 (╚═▷ “4.3.1.7 System A Overvoltage (Level 1 & 2) ANSI# 59”) • Overvoltage level 2 (╚═▷ “4.3.1.7 System A Overvoltage (Level 1 & 2) ANSI# 59”) •...

  • Page 222: Test System A Decoupling (Vde-Ar-N 4105)

    5 Operation 5.2 Front Panel Access Fig. 124: Decoupling breaker (example) • Breaker for decoupling [CBA], [Off] 5.2.3.15 Test System A Decoupling (VDE-AR-N 4105) VDE AR-N 4105 is asking for a test button. The system A decoupling test opens the selected breaker for decoupling. Restricted Access The function 'System A Decoupling Test' is available on Code level CL3.

  • Page 223: 5.2.3.17 Actual Date And Time

    5 Operation 5.2 Front Panel Access Displays the CBA close counter. Fig. 127: Active energy screen (example) Displays the active energy of system A. Fig. 128: Reactive energy screen (example) Displays the reactive energy of system A. 5.2.3.17 Actual Date And Time Fig.

  • Page 224: Change Operating Modes

    5 Operation 5.3 Change Operating Modes Change Operating Modes Startup The LS-5 starts in the operating mode defined by parameter 8827. Select Operating Mode The operating mode can be selected via • front panel buttons (plastic housing variant) or • LogicsManager configuration This chapter describes the manually front panel access.

  • Page 225: Operating Mode Manual

    5 Operation 5.3 Change Operating Modes 5.3.1 Operating Mode MANUAL General usage In the MANUAL operating mode (LED at mode button »MAN« illuminated) the circuit breakers can be operated via the push buttons along the bottom of the display (softkeys) at the screens listed below.

  • Page 226: Restore Language Setting

    5 Operation 5.4 Restore Language Setting ⚙ General usage Use the button »AUTO« to activate operating mode AUTOMATIC. 1. ▷ If mode change was successful the LED at the button »AUTO« is illuminated. ▶ Restore Language Setting Due to the multilingual capability of the unit, it may happen that the display language of the LS-5 is set to a language, the operator is unable to read or understand.
  • Page 227 5 Operation 5.4 Restore Language Setting 5. ▷ Press softkey to select the desired language. 6. ▷ Press softkey once to commit the language setting. The desired display language is restored. ▶ 37649 LS-5 v2 Series...

  • Page 228: Application

    The control units can be used stand-alone (╚═▷ “6.1.1 LS-5x1: Stand-Alone Application Mode”) or common applications with Woodward easYgen-3400/3500 or easYgen-3400XT/ 3500XT genset control units (╚═▷ “6.1.2 LS-5x1 & easYgen-3400/3500 or easYgen-3400XT/3500XT: Common Application Modes”,...

  • Page 229: Ls-5X1: Stand-Alone Application Mode

    6 Application 6.1 Application Modes Overview 6.1.1 LS-5x1: Stand-Alone Application Mode LS-511/521 easYgen-3400/3500 or easYgen-3400XT/ 3500XT Mode Symbol Mode Symbol Function Single LS5 None None Independent synch check relay mode. This application mode provides the following functions: • Handling of CBA (dead bus closure, synchronization, open) initiated by the corresponding command variables or by manual commands.

  • Page 230: Easygen-3400/3500 Or Easygen-3400Xt/3500Xt View

    6 Application 6.1 Application Modes Overview LS-511/LS-521 easYgen-3400/3500 or easYgen-3400XT/ 3500XT Mode Symbol Mode Symbol Function This application mode provides the following functions: GCB/GGB/L- • Handling of a MCB (dead bus closure, synchronization, open) initiated by the easYgen. • Measuring and monitoring of system A values, (mains voltage, mains frequency, mains phase rotation, mains current), transferred to easYgen.
  • Page 231 LS-5 are possible, but it requires a reduced number of easYgen devices. The amount of easYgen and LS-5 together should not exceed 48 devices, but to go sure please discuss the possible risks with your Woodward Sales Support. GCB/L-MCB L-MCB One or more easYgen in combination with one LS-5 unit, acting on the MCB in a fixed application.
  • Page 232 6 Application 6.1 Application Modes Overview easYgen-3400/3500 or LS-511/LS-521 easYgen-3400XT/ 3500XT Mode Symbol Mode Symbol Function • Measuring of generator busbar values (voltage, frequency). • Measuring and monitoring of load busbar values (voltage, frequency, phase rotation, current and power) • Indicating of mains values (voltage, frequency, phase angle) sent from the LS-5.

  • Page 233: Setup Stand-Alone Applications (Mode A01)

    6 Application 6.2 Setup Stand-Alone Applications (Mode A01) easYgen-3400/3500 or LS-511/LS-521 easYgen-3400XT/ 3500XT Mode Symbol Mode Symbol Function • Run-up synchronization, acting on the GCB or GCB/GGB, is possible. Setup Stand-Alone Applications (Mode A01) Overview The LS-5, configured to application mode ('Single LS-5'), runs as an independent unit and does not expect any other unit on the CAN bus.
  • Page 234 6 Application 6.2 Setup Stand-Alone Applications (Mode A01) General notes NOTICE! Dead bus interlocking due to incorrect setup No other LS-5 or easYgen device is expected on the CAN bus. After power-up the LS-5 can carry out a dead bus closure regardless if other devices are connected to the bus (arbitration time is ignored).
  • Page 235 6 Application 6.2 Setup Stand-Alone Applications (Mode A01) NOTICE! Component damage Incorrect settings may cause erratic system behavior and damage to the involved components . • Set the values carefully and double check with a voltmeter at the according breaker. If control to open and close the breaker should be handled by discrete inputs, use the 4. ▷...

  • Page 236: Setup Easygen & Slave Ls-5 Applications (Mode A03 & A04)

    6 Application 6.3 Setup easYgen & Slave LS-5 Applications (Mode A03 & A04) Setup easYgen & Slave LS-5 Applications (Mode A03 & A04) 6.3.1 Introduction In application modes the LS-5 runs as a slave unit. In these modes the LS-5 is guided by the easYgen and takes over directly the close and open commands coming from the easYgen(s).

  • Page 237: Single Or Multiple Easygen With One Externally Operated Mcb

    6 Application 6.3 Setup easYgen & Slave LS-5 Applications (Mode A03 & A04) 6.3.2 Single Or Multiple easYgen With One Externally Operated MCB Overview Fig. 135: Single or multiple easYgen with one externally operated MCB One or more gensets feed on a load busbar. The easYgen(s) close and open their own generator breaker.
  • Page 238 6 Application 6.3 Setup easYgen & Slave LS-5 Applications (Mode A03 & A04) • easYgen-3400/3500 or easYgen-3400XT/3500XT: • LS-5: General notes To provide mains decoupling, acting on the GCB, the mains decoupling function of the easYgen must be used. • Refer to the corresponding chapter of the easYgen manual. This application setup is predefined and allows for no variations, except the amount of easYgen-3000 or easYgen-3000XT driven generators (up to 32).
  • Page 239 6 Application 6.3 Setup easYgen & Slave LS-5 Applications (Mode A03 & A04) 3. ▷ When tapping voltages over power transformer, phase angle compensation may be required. If a phase angle compensation is required, navigate to [Configuration / Application config / Breakers config. / Configure CBA / Synchronization CBA / Phase angle compensation] NOTICE! Component damage...
  • Page 240 6 Application 6.3 Setup easYgen & Slave LS-5 Applications (Mode A03 & A04) 4. ▷ When tapping voltages over power transformer, phase angle compensation may be required. If a phase angle compensation is required, navigate to [Parameter / Configuration / Configure Application / Configure Breakers / Configure GCB / Phase angle compensation GCB].

  • Page 241: Multiple Easygen With One Ggb And One Externally Operated Mcb

    6 Application 6.3 Setup easYgen & Slave LS-5 Applications (Mode A03 & A04) 6.3.3 Multiple easYgen With One GGB And One Externally Operated MCB Overview Fig. 136: Multiple easYgen with one GGB and one externally operated MCB One or more gensets feed on a generator busbar. The easYgen(s) close and open their own generator breaker.
  • Page 242 6 Application 6.3 Setup easYgen & Slave LS-5 Applications (Mode A03 & A04) Required application modes: • easYgen-3400/3500 or easYgen-3400XT/3500XT: • LS-5: General notes For information on mains decoupling over GCB refer to the corresponding chapter of the easYgen manual. The mains measurement of the easYgen(s) are used for the load busbar measurement.
  • Page 243 6 Application 6.3 Setup easYgen & Slave LS-5 Applications (Mode A03 & A04) ᐳ • Personnel: User Configure the application mode (parameter 8840) of the LS-5 device to 1. ▷ Configure the measurement system A and B. 2. ▷ 3. ▷ When tapping voltages over power transformer, phase angle compensation may be required.
  • Page 244 6 Application 6.3 Setup easYgen & Slave LS-5 Applications (Mode A03 & A04) Parameter Undervoltage level 1 3000 Overvoltage level 2 2956 Undervoltage level 2 3006 Mains voltage increase 8806 4. ▷ When tapping voltages over power transformer, phase angle compensation may be required.

  • Page 245: Multiple Easygen With One Externally Operated Ggb In Isolated Operation

    6 Application 6.3 Setup easYgen & Slave LS-5 Applications (Mode A03 & A04) 6.3.4 Multiple easYgen With One Externally Operated GGB In Isolated Operation Overview Fig. 137: Multiple easYgen with one externally operated GGB in isolated operation One or more gensets feed on a generator busbar. The easYgen(s) close and open their own generator breaker.
  • Page 246 6 Application 6.3 Setup easYgen & Slave LS-5 Applications (Mode A03 & A04) General notes This application setup is predefined and allows for no variations, except the amount of easYgen-3000 or easYgen-3000XT driven generators (up to 32). • Check whether your application is compatible with the prerequisites listed below. Prerequisites LS-5 ⚙...
  • Page 247 6 Application 6.3 Setup easYgen & Slave LS-5 Applications (Mode A03 & A04) Configure easYgen ⚙ ᐳ • Personnel: User Configure the following parameters: Configure the application mode (parameter 3444) of each easYgen device to 1. ▷ Configure the measurement for generator and busbar according to the easYgen manual. 2. ▷...

  • Page 248: Multiple Easygen With One Externally Operated Ggb And One Externally Operated Mcb

    6 Application 6.3 Setup easYgen & Slave LS-5 Applications (Mode A03 & A04) 5. ▷ In this setup each easYgen device provides four control bits for sending information to the LS-5. These bits can be used as command variables in the LS-5.
  • Page 249 6 Application 6.3 Setup easYgen & Slave LS-5 Applications (Mode A03 & A04) One or more gensets feed on a generator busbar. The easYgen(s) close and open their own generator breaker. The LS-5 between the generator busbar and load busbar close and open the common generator group breaker (GGB).
  • Page 250 6 Application 6.3 Setup easYgen & Slave LS-5 Applications (Mode A03 & A04) Ensure the following prerequisites are met: 1. ▷ The system A voltage measurement is connected to the load busbar. 2. ▷ The system B voltage measurement is connected to the generator busbar. 3. ▷...
  • Page 251 6 Application 6.3 Setup easYgen & Slave LS-5 Applications (Mode A03 & A04) 4. ▷ Configure the breaker close and/or open relay(s) according to your MCB. Check the synchronization setting, like phase angle, frequency window and voltage. 5. ▷ Configure LS-5 (GGB) ⚙...

  • Page 252: Setup Easygen & Independent Ls-5 Applications (Mode A02)

    6 Application 6.4 Setup easYgen & Independent LS-5 Applications (Mode A02) Parameter Overfrequency level 2 2856 Underfrequency level 2 2906 Overvoltage level 1 2950 Undervoltage level 1 3000 Overvoltage level 2 2956 Undervoltage level 2 3006 Mains voltage increase 8806 4. ▷...

  • Page 253: Isolation Switch

    A rule of thumb is that the total amount of easYgens and LS-5s shall never expire 48 devices. To be on the safe side please discuss the possible risks with the Woodward Sales Support. General notes The LS-5 is expecting at least one easYgen device in the system.
  • Page 254 6 Application 6.4 Setup easYgen & Independent LS-5 Applications (Mode A02) Mains breaker The frequency and voltage are solid. A segment number is needed. The first breaker on the mains side is the MCB. The LS-5 is always connected with measurement system A on the mains side. The setting "Mains connection"...

  • Page 255: General Functions

    6 Application 6.4 Setup easYgen & Independent LS-5 Applications (Mode A02) • ╚═▷ “6.4.4 Multiple Mains/Generators With Four easYgen Units, Two Incoming Mains And Different Tie-breakers” 6.4.2 General Functions 6.4.2.1 General Preparation Prepare the easYgen – LS-5 system for configuration as follows: ⚙...

  • Page 256: Setup Mains Decoupling With Easygen

    6 Application 6.4 Setup easYgen & Independent LS-5 Applications (Mode A02) ᐳ • Personnel: User The application uses the easYgen in mode (configured in parameter 8840). 1. ▷ Configure easYgen ⚙ ᐳ • Personnel: User To prevent the easYgen measurement from causing alarms, it must be configured as follows.

  • Page 257: Setup Mains Decoupling With Ls-5

    6 Application 6.4 Setup easYgen & Independent LS-5 Applications (Mode A02) 1. ▷ The mains measurement is connected together with the busbar measurement on the generator busbar. Configure easYgen For detailed information on the easYgen configuration, refer to the easYgen-3400/3500 or easYgen-3400XT/3500XT manual.
  • Page 258 6 Application 6.4 Setup easYgen & Independent LS-5 Applications (Mode A02) Make sure not configure the range smaller than the decoupling threshold (see below). Configure the mains settling time (parameter 2801). 4. ▷ The mains settling time determines for how long the mains stay continuously stable, before the MCB is closed again.

  • Page 259: Setup Run-Up Synchronization In Ls-5 Mode

    6 Application 6.4 Setup easYgen & Independent LS-5 Applications (Mode A02) Fig. 140: LogicsManager configuration example 2 The mains decoupling function is enabled, if a "Test" key switch is activated. This helps to perform a mains decoupling test without any generator running.

  • Page 260: Setup Amf Start In Ls-5 Mode

    6 Application 6.4 Setup easYgen & Independent LS-5 Applications (Mode A02) Configure LS-5 Regarding run-up synchronization there is nothing to configure in the LS-5. 6.4.2.6 Setup AMF Start In LS-5 Mode Overview The easYgen(s) can monitor dedicated segments to cause an AMF start in case their voltage or frequency are out of operating range.
  • Page 261 6 Application 6.4 Setup easYgen & Independent LS-5 Applications (Mode A02) 4. ▷ Fig. 141: LogicsManager configuration Navigate to [Configuration / Application config. / Breakers config. / Configure CBA] and configure "Open CBA immed." as shown in the screenshot. LS-5 over the MCB: •...

  • Page 262: Setup Manual Breaker Control In Ls-5 Mode

    6 Application 6.4 Setup easYgen & Independent LS-5 Applications (Mode A02) ▶ Fig. 142: Segment configuration in ToolKit The example shows the segment configuration according to ╚═▷ “6.4.3 H-Configuration With Two easYgen And Two Incoming Mains And Tie-breaker”. 6.4.2.7 Setup Manual Breaker Control In LS-5 Mode Overview The LS-5 mode provides manual closing and opening of the circuit breaker at the particular LS-5.

  • Page 263: Setup Ls-5 Flags From Ls-5 To Ls-5 And Easygen

    6 Application 6.4 Setup easYgen & Independent LS-5 Applications (Mode A02) The design engineer can decide, if he wants to take the OR'ed LS-5 command flags coming from all easYgens or if he wants to take the individual command flag coming from a special easYgen.
  • Page 264 6 Application 6.4 Setup easYgen & Independent LS-5 Applications (Mode A02) Fig. 144: LS-5 information transport to LS-5 and easYgen LS-5 v2 Series 37649...

  • Page 265: H-Configuration With Two Easygen And Two Incoming Mains And Tie-Breaker

    6 Application 6.4 Setup easYgen & Independent LS-5 Applications (Mode A02) 6.4.3 H-Configuration With Two easYgen And Two Incoming Mains And Tie-breaker Overview Fig. 145: H-Configuration with two easYgen and two incoming mains and tie-breaker One or more genset(s) feed on a generator/load busbar (╚═▷...
  • Page 266 6 Application 6.4 Setup easYgen & Independent LS-5 Applications (Mode A02) For additional information refer to ╚═▷ “7 Interfaces And Protocols”. Amongst others, the breaker feedbacks of the single LS-5 are sent via the CAN interface and inform all other connected devices in the system, whether they are interconnected or not.
  • Page 267 6 Application 6.4 Setup easYgen & Independent LS-5 Applications (Mode A02) ᐳ • Personnel: Qualified electrician The system A voltage and current measurement is connected to the mains. 1. ▷ The system B voltage measurement is connected to the generator/load busbar. 2. ▷...
  • Page 268 6 Application 6.4 Setup easYgen & Independent LS-5 Applications (Mode A02) Parameter Value Segment No. Sy.B 8811 Segment No. isol. Switch 8812 Mains pow. Measurement 8813 Valid Mains connection 8814 System A Isol. Switch Para 8815 None Variable system 8816 System B 6. ▷...
  • Page 269 6 Application 6.4 Setup easYgen & Independent LS-5 Applications (Mode A02) Parameter Value Connect A alive to B dead 8804 Dead bus closure delay time 8805 As required Dead bus detection max. volt 5820 As required Navigate to [Configuration / Application config / Breakers config. / Configure CBA / 11. ▷...
  • Page 270 6 Application 6.4 Setup easYgen & Independent LS-5 Applications (Mode A02) 13. ▷ Fig. 147: LogicsManager configuration 'Open CBA immed.' Select [Open CBA immed. / LogicsManager] (parameter 12944) and configure the equation as follows: • The LM equation opens the MCB immediately, if the system A voltage / frequency is not within the configured operating ranges (refer to ╚═▷...
  • Page 271 6 Application 6.4 Setup easYgen & Independent LS-5 Applications (Mode A02) The same remote control bits can be used in the upper example, because each LS-5 receives its own control bits. The different device and Node-ID separates the control bits from each other. ⚙...
  • Page 272 6 Application 6.4 Setup easYgen & Independent LS-5 Applications (Mode A02) 9. ▷ Navigate to [Configuration / Application config / Breakers config. / Configure CBA / Dead bus closure CBA] and set the following parameters: Parameter Value Dead bus closure CBA 8801 Connect A dead to B dead 8802...
  • Page 273 6 Application 6.4 Setup easYgen & Independent LS-5 Applications (Mode A02) The unloading of the tie-breaker is only executed, if one side contains a variable system. Otherwise the open command is given without unloading. 13. ▷ Fig. 150: LogicsManager configuration 'Open CBA immed.' Select [Open CBA immed.
  • Page 274 6 Application 6.4 Setup easYgen & Independent LS-5 Applications (Mode A02) • The LM equation gives the release for close CBA, if the remote control bit 3 is sent by the PLC AND the CBA has no closure failure AND the system A measurement detects no phase rotation error.
  • Page 275 6 Application 6.4 Setup easYgen & Independent LS-5 Applications (Mode A02) 7. ▷ When tapping voltages over power transformer, phase angle compensation may be required. If a phase angle compensation over the GCB is required, navigate to [Configuration / Application config / Breakers config. / Configure GCB / Synchronization GCB / Phase angle compensation GCB] NOTICE! Component damage...

  • Page 276: Multiple Mains/Generators With Four Easygen Units, Two Incoming Mains And Different Tie-Breakers

    6 Application 6.4 Setup easYgen & Independent LS-5 Applications (Mode A02) 10. ▷ In this setup each easYgen device provides six control bits for sending information to the LS-5. These bits can be used as command variables in the LS-5 to initiate i.e. an alarm acknowledgement or to release the mains decoupling.
  • Page 277 6 Application 6.4 Setup easYgen & Independent LS-5 Applications (Mode A02) One or more genset(s) feed on a generator/load busbar (╚═▷ Fig. 152/Segment No. 4). One or more genset(s) feed on a generator/load busbar (╚═▷ Fig. 152/Segment No. 5). A tie-breaker is located between the both generator/load busbars. Each generator/load busbar has its own generator group breaker (╚═▷...
  • Page 278 6 Application 6.4 Setup easYgen & Independent LS-5 Applications (Mode A02) 4. ▷ Number all CAN Node-IDs (usually the same as the device number). Number all segments according to the definitions in ╚═▷ “Segment number”. 5. ▷ Unless special numbering conventions are required, count up continuously from left to right or right to left.
  • Page 279 6 Application 6.4 Setup easYgen & Independent LS-5 Applications (Mode A02) 4. ▷ The tie-breaker command(s) are connected to the LS-5 only. The LS-5 CAN bus is connected to the CAN bus #3 of the easYgen(s). 5. ▷ Prerequisites LS-5 (tie-breaker plant/load busbar) ⚙...
  • Page 280 6 Application 6.4 Setup easYgen & Independent LS-5 Applications (Mode A02) Parameter Value Variable system 8816 System B Configure the following parameters for the LS-5 ID 37, incoming mains on the right side: 6. ▷ Parameter Value Segment No. Sy.A 8810 Segment No.
  • Page 281 6 Application 6.4 Setup easYgen & Independent LS-5 Applications (Mode A02) ▶ Fig. 153: LogicsManager configuration 'Open CBA unload' 14. ▷ Select [Open CBA immed. / LogicsManager] (parameter 12944) and configure the equation as follows: • The LM equation opens the MCB immediately, if the system A voltage / frequency is not within the configured operating ranges (refer to ╚═▷...
  • Page 282 6 Application 6.4 Setup easYgen & Independent LS-5 Applications (Mode A02) The same remote control bits can be used in the upper example, because each LS-5 receives its own control bits. The different device and Node-ID separates the control bits from each other. ▶...
  • Page 283 6 Application 6.4 Setup easYgen & Independent LS-5 Applications (Mode A02) Parameter Value Segment No. Sy.A 8810 Segment No. Sy.B 8811 Segment No. isol. Switch 8812 Mains pow. Measurement 8813 Invalid (Actually system A measurement) Mains connection 8814 None Isol. Switch Para 8815 System B Variable system...
  • Page 284 6 Application 6.4 Setup easYgen & Independent LS-5 Applications (Mode A02) 14. ▷ Fig. 156: LogicsManager configuration 'Open CBA unload' Select [Open CBA unload / LogicsManager] (parameter 12943) and configure the equation as follows: • The LM equation opens the GGB with unloading, if the remote control bit 1 is sent by the PLC.
  • Page 285 6 Application 6.4 Setup easYgen & Independent LS-5 Applications (Mode A02) 16. ▷ Fig. 158: LogicsManager configuration 'Enable close CBA.' Select [Enable close CBA / LogicsManager] (parameter 12945) and configure the equation as follows: • The LM equation gives the release for close GGB, if the remote control bit 3 is sent by the PLC AND the CBA has no closure failure AND the system A measurement detects no phase rotation error.
  • Page 286 6 Application 6.4 Setup easYgen & Independent LS-5 Applications (Mode A02) Parameter Value Variable system 8816 System A Configure the measurement system A and B. 5. ▷ Configure the breaker close and/or open relay(s) according to your tie-breaker. 6. ▷ Check the synchronization settings, like phase angle, frequency window and voltage. 7. ▷...
  • Page 287 6 Application 6.4 Setup easYgen & Independent LS-5 Applications (Mode A02) Select [Open CBA unload / LogicsManager] (parameter 12943) and configure the equation as follows: • The LM equation opens the tie-breaker with unloading, if the remote control bit 1 is sent by the PLC.
  • Page 288 6 Application 6.4 Setup easYgen & Independent LS-5 Applications (Mode A02) 13. ▷ Fig. 161: LogicsManager configuration 'Enable close CBA.' Select [Enable close CBA / LogicsManager] (parameter 12945) and configure the equation as follows: • The LM equation gives the release for close CBA, if the remote control bit 3 is sent by the PLC AND the CBA has no closure failure AND the system A measurement detects no phase rotation error.
  • Page 289 6 Application 6.4 Setup easYgen & Independent LS-5 Applications (Mode A02) Parameter Value Variable system 8816 System A Configure the measurement system A and B. 5. ▷ Configure the breaker close and/or open relay(s) according to your tie-breaker. 6. ▷ Check the synchronization settings, like phase angle, frequency window and voltage. 7. ▷...
  • Page 290 6 Application 6.4 Setup easYgen & Independent LS-5 Applications (Mode A02) Select [Open CBA unload / LogicsManager] (parameter 12943) and configure the equation as follows: • The LM equation opens the tie-breaker with unloading, if the remote control bit 1 is sent by the PLC.
  • Page 291 6 Application 6.4 Setup easYgen & Independent LS-5 Applications (Mode A02) 13. ▷ Fig. 164: LogicsManager configuration 'Enable close CBA.' Select [Enable close CBA / LogicsManager] (parameter 12945) and configure the equation as follows: • The LM equation gives the release for close CBA, if the remote control bit 3 is sent by the PLC AND the CBA has no closure failure AND the system A measurement detects no phase rotation error.
  • Page 292 6 Application 6.4 Setup easYgen & Independent LS-5 Applications (Mode A02) • Switch off the following parameters: Parameter Mains decoupling 3110 Change of frequency 3058 Overfrequency level 1 2850 Underfrequency level 1 2900 Overfrequency level 2 2856 Underfrequency level 2 2906 Overvoltage level 1 2950...

  • Page 293: Setup Vde-Ar-N 4105 Applications

    Some typical applications are shown below. For more information please refer to the according FNN VDE-AR-N 4105 document. To help in these specific applications Woodward provides also an application note with more details and how to configure the devices.

  • Page 294: One Easygen-3500(Xt) (Mode Gcb/L-Mcb Or Gcb/Ggb/L-Mcb) With

    6 Application 6.5 Setup VDE-AR-N 4105 Applications In this mode the LS-521 is only used like a protective device and fulfills nothing besides the mains decoupling. The mains decoupling is enabled, if GCB and MCB are closed. So the breaker feedback signals must be provided to both devices.

  • Page 295: Multiple Easygen-3500(Xt) (Mode Gcb/L-Mcb Or Gcb/Ggb/L-Mcb) With

    6 Application 6.5 Setup VDE-AR-N 4105 Applications Fig. 166: Example: easYgen-3500(XT) (GCB/L-MCB mode) and LS-521 (L-MCB mode) 6.5.4 Multiple easYgen-3500(XT) (Mode GCB/L-MCB or GCB/GGB/L-MCB) with LS-521 This application multiple easYgen-3500(XT) serve the mains breaker via one LS-521. The principle is the same like in the chapter before. The difference it that multiple easYgens (gensets) act on one mains interchange point.

  • Page 296: System Easygen-3500(Xt) (Mode Gcb/Ls5) With Ls-521

    6 Application 6.5 Setup VDE-AR-N 4105 Applications Fig. 167: Example: Multiple easYgen-3500(XT) (GCB/L-MCB mode) and an LS-521 (L-MCB mode) 6.5.5 System easYgen-3500(XT) (Mode GCB/LS5) with LS-521 The easYgen-3500(XT) and the LS-521 run in the 'LS5' mode. So the mains decoupling must be maintained with two breakers in series to fulfill the VDE-AR-N 4105 rule.

  • Page 297: Mains Decoupling Monitoring At The Generator Feed-In

    6 Application 6.5 Setup VDE-AR-N 4105 Applications Fig. 168: Example: Mains decoupling monitoring at the interchange point in with two LS-521 (one device in LS5 mode and one in Single LS5 mode) Both LS-521 measure the mains voltage as system A voltages. Both devices execute the mains decoupling, whereby the main device opens the MCB1 and the additional device opens the MCB2.
  • Page 298 6 Application 6.5 Setup VDE-AR-N 4105 Applications Fig. 169: Example: Mains decoupling monitoring at the generator feed-in point with LS-521 (Single LS5 mode) and easYgen-3500(XT) (GCB/LS5 mode) The easYgen-3500(XT) mains measurement and the LS-521 system A measurement are connected with the busbar. The busbar voltage is considered for the mains decoupling monitoring.

  • Page 299: Interfaces And Protocols

    7 Interfaces And Protocols 7.1 Interfaces Interfaces And Protocols Interfaces 7.1.1 Interfaces Overview LS-51x Fig. 170: LS-51x interfaces LS-52x Fig. 171: LS-52x interfaces The LS-5 (╚═▷ Fig. 170/╚═▷ Fig. 171) provides the following interfaces, which are supporting different protocols. Figure Interface Protocol Modbus, ToolKit...

  • Page 300: Can Interfaces

    LS-5s shall never expire 48 devices. To be on the safe side please discuss the possible risks with the Woodward Sales Support. 7.1.3 Serial Interfaces 7.1.3.1 Service Port (RS-232/USB) The Woodward specific service port can be used to extend the interfaces of the controller. LS-5 v2 Series 37649...

  • Page 301: Interface

    The extended serial interface provides a Modbus as well as the Woodward ToolKit protocol. Fig. 173: Service Port The service port can be only used in combination with an optional Woodward direct configuration cable (DPC), which includes a converter box to provide either an USB or a RS-232 interface.

  • Page 302: Canopen Protocol

    7 Interfaces And Protocols 7.2 Protocols • 5301: Basic Visualization • 5302: Basic Visualization • 6003: LS-5 Communication 7.2.2 CANopen Protocol CANopen is a communication protocol and device profile specification for embedded systems used in automation. The CANopen standard consists of an addressing scheme, several small communication protocols and an application layer defined by a device profile.

  • Page 303: Modbus Protocol

    (PLCs). It has become a de facto standard communications protocol in industry, and is now the most commonly available means of connecting industrial electronic devices. The Woodward controller supports a Modbus RTU Slave module. This means that a Master node needs to poll the controller slave node.
  • Page 304 7 Interfaces And Protocols 7.2 Protocols Fig. 175: Address range All addresses in this document comply with the Modicon address convention. Some PLCs or PC programs use different address conventions depending on their implementation. Then the address must be increased and the leading 4 may be omitted. Please refer to your PLC or program manual for more information.
  • Page 305 7 Interfaces And Protocols 7.2 Protocols Modbus read Description Multiplier Units addresses ..................... 450250 System B voltage L3-N Tab. 31: Address range block read ╚═▷ Tab. 31 is only an excerpt of the data protocol. It conforms to the data protocol 5300. Refer to ╚═▷...
  • Page 306 7 Interfaces And Protocols 7.2 Protocols Parameter ID < 10000 Parameter ID >= 10000 Modbus address = 40000 + (Par. ID+1) 400000 + (Par. ID+1) Tab. 32: Address calculation Block reads in this address range depend on the data type of the parameter. This makes it important to set the correct length in Modbus registers which depends on the data type (UNSIGNED 8, INTEGER 16, etc.).
  • Page 307 7 Interfaces And Protocols 7.2 Protocols Address length example Example Address length example Parameter 1766 SyA. rated voltage is a two byte data type, parameter 1754 SyA. rated current is a one byte data type: Fig. 177: ModScan to handle 1 and 2 bytes data types 37649 LS-5 v2 Series...

  • Page 308: Technical Specifications

    8 Technical Specifications 8.1 Technical Data Technical Specifications Technical Data Product label Fig. 178: Product label Item number Item revision number Serial number (numerical) Serial number (barcode) Date of production (year-month) Type Description (short) Type Description (long) Details Technical data Approval Approvals 8.1.1...

  • Page 309: Ambient Variables

    8 Technical Specifications 8.1 Technical Data Rated surge voltage (V 4.0 kV surge Linear measuring range 1.25 × V rated Measuring frequency 50/60 Hz (30.0 to 85.0 Hz) Accuracy Class 1 Input resistance per path 120 V 0.498 MΩ 480 V 2.0 MΩ...

  • Page 310: Discrete Outputs

    Not evaluated by UL. 8.1.4 Interface Service Port interface (RS232/USB) Service Port interface Not isolated Proprietary interface Connect only with Woodward DPC cable RS-485 interface RS-485 interface Galvanically isolated Insulation voltage (continuously) 100 Vac Insulation test voltage (≤ 5 s)

  • Page 311: Battery

    8 Technical Specifications 8.1 Technical Data Insulation test voltage (≤ 5 s) 1000 Vac Version CAN bus Internal line termination Not available 8.1.5 Battery Battery inside Fig. 179: Waste Disposal This device contains a battery, and therefore it is labeled with the symbol shown beside according to the EU Directive 2006/66/EC.

  • Page 312: Approvals

    8 Technical Specifications 8.2 Environmental Data Weight Plastic approx. 850 g Sheet metal approx. 840 g Protection Protection system Plastic IP54 from front with clamp fasteners IP66 from front with screw kit IP20 from back Sheet metal IP20 Front foil (plastic housing) Insulating surface 8.1.7 Approvals...

  • Page 313: Accuracy

    8 Technical Specifications 8.3 Accuracy Shock Shock 40 G, Saw tooth pulse, 11 ms Standards EN 60255-21-2 MIL-STD 810F, M516.5, Procedure 1 Temperature Cold, Dry Heat (storage) -30 °C (-22 °F) / 80 °C (176 °F) Cold, Dry Heat (operating) -20 °C (-4 °F) / 70 °C (158 °F) Standards IEC 60068-2-2, Test Bb and Bd...

  • Page 314: Reference Conditions

    8 Technical Specifications 8.3 Accuracy Measuring value Display Accuracy Measuring start Notes Actual total real power -2 to 2 GW 2 % (of 120/480 V * Measuring starts when value voltage is recognized 1/5 A) Reactive power Actual value in L1, L2, -2 to 2 Gvar 2 % (of 120/480 V * Measuring starts when...

  • Page 315: Appendix

    9 Appendix 9.1 Characteristics Appendix Characteristics 9.1.1 Triggering Characteristics Two-level overshoot monitoring Fig. 180: Two-level overshoot monitoring In the monitor above this triggering characteristic is used: System A overvoltage, System A overfrequency, Battery overvoltage, ... 37649 LS-5 v2 Series...
  • Page 316 9 Appendix 9.1 Characteristics Two-level undershoot monitoring Fig. 181: Two-level undershoot monitoring In the monitor above this triggering characteristic is used: System A undervoltage, System A underfrequency, Battery undervoltage, ... LS-5 v2 Series 37649...

  • Page 317: Data Protocols

    9 Appendix 9.2 Data Protocols One-level asymmetry monitoring Fig. 182: One-level asymmetry monitoring In the monitor above this triggering characteristic is used: System A voltage asymmetry. Data Protocols 9.2.1 CANopen 9.2.1.1 Data Protocol 5301 (Basic Visualization) Para- Description Multiplier Units Model meter Data...
  • Page 318 9 Appendix 9.2 Data Protocols Para- Description Multiplier Units Model meter Data Data byte 0 byte (Mux) System A frequency 0.01 LS-5x1 v2, LS-5x2 v2 3,4,5,6 System A average delta voltage LS-5x1 v2, LS-5x2 v2 10202 Operation modes LS-5x1 v2, LS-5x2 v2 13280 = CB A request 13264 = Unloading CB A...
  • Page 319 9 Appendix 9.2 Data Protocols Para- Description Multiplier Units Model meter Data Data byte 0 byte (Mux) internal Mask: 0200h internal Mask: 0100h internal Mask: 0080h internal Mask: 0040h internal Mask: 0020h internal Mask: 0010h internal Mask: 0008h internal Mask: 0004h internal Mask: 0002h internal...
  • Page 320 9 Appendix 9.2 Data Protocols Para- Description Multiplier Units Model meter Data Data byte 0 byte (Mux) internal Mask: 0002h internal Mask: 0004h 11.07 Active second Mask: 0008h LS-5x1 v2, LS-5x2 v2 11.06 Active minute Mask: 0010h LS-5x1 v2, LS-5x2 v2 11.05 Active hour Mask: 0020h LS-5x1 v2,...
  • Page 321 9 Appendix 9.2 Data Protocols Para- Description Multiplier Units Model meter Data Data byte 0 byte (Mux) internal Mask: 0010h internal Mask: 0008h internal Mask: 0004h internal Mask: 0002h internal Mask: 0001h 3,4,5,6 System A voltage L1-L2 LS-5x1 v2, LS-5x2 v2 10140 00.01 LM Internal flag 1 Mask: 8000h...
  • Page 322 9 Appendix 9.2 Data Protocols Para- Description Multiplier Units Model meter Data Data byte 0 byte (Mux) 01.10 Centralized alarms active (alarm B-F) Mask: 0400h LS-5x1 v2, LS-5x2 v2 01.07 All alarm classes are active Mask: 0200h LS-5x1 v2, LS-5x2 v2 01.08 Warning alarms active (alarm A, B) Mask: 0100h LS-5x1 v2,...
  • Page 323 9 Appendix 9.2 Data Protocols Para- Description Multiplier Units Model meter Data Data byte 0 byte (Mux) 10160 internal Mask: 8000h internal Mask: 4000h internal Mask: 2000h internal Mask: 1000h internal Mask: 0800h internal Mask: 0400h internal Mask: 0200h internal Mask: 0100h internal Mask: 0080h...
  • Page 324 9 Appendix 9.2 Data Protocols Para- Description Multiplier Units Model meter Data Data byte 0 byte (Mux) 3,4,5,6 System A voltage L3-N LS-5x1 v2, LS-5x2 v2 10131 internal Mask: 8000h internal Mask: 4000h internal Mask: 2000h internal Mask: 1000h internal Mask: 0800h internal Mask: 0400h...
  • Page 325 9 Appendix 9.2 Data Protocols Para- Description Multiplier Units Model meter Data Data byte 0 byte (Mux) internal Mask: 0040h internal Mask: 0020h internal Mask: 0010h internal Mask: 0008h internal Mask: 0004h internal Mask: 0002h internal Mask: 0001h 3,4,5,6 System B average wye voltage LS-5x1 v2, LS-5x2 v2 System B frequency...
  • Page 326 9 Appendix 9.2 Data Protocols Para- Description Multiplier Units Model meter Data Data byte 0 byte (Mux) 04.57 Remote control bit 14 Mask: 2000h LS-5x1 v2, LS-5x2 v2 04.56 Remote control bit 13 Mask: 1000h LS-5x1 v2, LS-5x2 v2 04.55 Remote control bit 12 Mask: 0800h LS-5x1 v2, LS-5x2 v2...
  • Page 327 9 Appendix 9.2 Data Protocols Para- Description Multiplier Units Model meter Data Data byte 0 byte (Mux) 08.04 Battery undervoltage threshold 2 Mask: 0004h LS-5x1 v2, LS-5x2 v2 08.01 Battery overvoltage threshold 1 Mask: 0002h LS-5x1 v2, LS-5x2 v2 08.03 Battery undervoltage threshold 1 Mask: 0001h LS-5x1 v2, LS-5x2 v2...
  • Page 328 9 Appendix 9.2 Data Protocols Para- Description Multiplier Units Model meter Data Data byte 0 byte (Mux) internal Mask: 1000h internal Mask: 0800h internal Mask: 0400h internal Mask: 0200h internal Mask: 0100h 02.12 System A phase rotation Mask: 0080h LS-5x1 v2, LS-5x2 v2 Counter Clock Wise (CCW, reverse, left turn) 02.13 System A phase rotation...
  • Page 329 9 Appendix 9.2 Data Protocols Para- Description Multiplier Units Model meter Data Data byte 0 byte (Mux) 3,4,5,6 System B voltage L2-N LS-5x1 v2, LS-5x2 v2 internal Mask: 8000h 04.63 Synchr. Segm Closure Pr. is act Mask: 4000h LS-5x1 v2, LS-5x2 v2 internal Mask: 2000h...
  • Page 330 9 Appendix 9.2 Data Protocols Para- Description Multiplier Units Model meter Data Data byte 0 byte (Mux) 05.15 EEPROM corrupted Mask: 0004h LS-5x1 v2, LS-5x2 v2 internal Mask: 0002h internal Mask: 0001h 3,4,5,6 System B voltage L3-N LS-5x1 v2, LS-5x2 v2 4153 04.42 Breaker transition mode alternative 2 Mask: 8000h...
  • Page 331 9 Appendix 9.2 Data Protocols Para- Description Multiplier Units Model meter Data Data byte 0 byte (Mux) System A mains connected Mask: 0800h LS-5x1 v2, LS-5x2 v2 internal Mask: 0400h internal Mask: 0200h internal Mask: 0100h internal Mask: 0080h internal Mask: 0040h internal Mask: 0020h...
  • Page 332 9 Appendix 9.2 Data Protocols Para- Description Multiplier Units Model meter Data Data byte 0 byte (Mux) internal Mask: 2000h internal Mask: 1000h internal Mask: 0800h internal Mask: 0400h internal Mask: 0200h 08.05 CB B close not successful Mask: 0100h LS-5x2 v2 08.06 CB B open not successful Mask: 0080h...
  • Page 333 9 Appendix 9.2 Data Protocols Para- Description Multiplier Units Model meter Data Data byte 0 byte (Mux) 10138 internal Mask: 8000h internal Mask: 4000h internal Mask: 2000h internal Mask: 1000h internal Mask: 0800h 06.21 System B phase rotation Mask: 0400h LS-5x1 v2, LS-5x2 v2 internal...
  • Page 334 9 Appendix 9.2 Data Protocols Para- Description Multiplier Units Model meter Data Data byte 0 byte (Mux) 07.05 System A phase rotation Mask: 0004h LS-5x1 v2, LS-5x2 v2 internal Mask: 0002h internal Mask: 0001h 4138 internal Mask: 8000h internal Mask: 4000h internal Mask: 2000h internal...

  • Page 335: Data Protocol 5302 (Basic Visualization)

    9 Appendix 9.2 Data Protocols Para- Description Multiplier Units Model meter Data Data byte 0 byte (Mux) internal Mask: 0004h internal Mask: 0002h internal Mask: 0001h 9.2.1.2 Data Protocol 5302 (Basic Visualization) Para- Description Multiplier Units Model meter Data Data byte 0 byte (Mux)
  • Page 336 9 Appendix 9.2 Data Protocols Para- Description Multiplier Units Model meter Data Data byte 0 byte (Mux) 13255 = Open CB B 13340 = CB B request 13209 = CB B Dead bus closure 3,4,5,6 System A total active power AC measurement LS-5x1 v2, LS-5x2 v2 10107...
  • Page 337 9 Appendix 9.2 Data Protocols Para- Description Multiplier Units Model meter Data Data byte 0 byte (Mux) 28.02 Command to CB-control 2 (OR'ed) Mask: 0200h LS-5x1 v2, LS-5x2 v2 28.03 Command to CB-control 3 (OR'ed) Mask: 0400h LS-5x1 v2, LS-5x2 v2 28.04 Command to CB-control 4 (OR'ed) Mask: 0800h LS-5x1 v2,...
  • Page 338 9 Appendix 9.2 Data Protocols Para- Description Multiplier Units Model meter Data Data byte 0 byte (Mux) 3,4,5,6 System A current 3 0.001 LS-5x1 v2, LS-5x2 v2 10107 00.41 LM Relay 1 Mask: 8000h LS-5x1 v2, LS-5x2 v2 00.42 LM Relay 2 Mask: 4000h LS-5x1 v2, LS-5x2 v2...
  • Page 339 9 Appendix 9.2 Data Protocols Para- Description Multiplier Units Model meter Data Data byte 0 byte (Mux) internal Mask: 0040h internal Mask: 0020h 00.15 LM External acknowledge Mask: 0010h LS-5x1 v2, LS-5x2 v2 internal Mask: 0008h 00.16 LM Operation mode AUTOMATIC Mask: 0004h LS-5x1 v2, LS-5x2 v2...
  • Page 340 9 Appendix 9.2 Data Protocols Para- Description Multiplier Units Model meter Data Data byte 0 byte (Mux) 00.30 LM Internal flag 9 Mask: 0200h LS-5x1 v2, LS-5x2 v2 00.31 LM Internal flag 10 Mask: 0100h LS-5x1 v2, LS-5x2 v2 00.32 LM Internal flag 11 Mask: 0080h LS-5x1 v2, LS-5x2 v2...
  • Page 341 9 Appendix 9.2 Data Protocols Para- Description Multiplier Units Model meter Data Data byte 0 byte (Mux) internal Mask: 2000h internal Mask: 1000h internal Mask: 0800h internal Mask: 0400h internal Mask: 0200h internal Mask: 0100h internal Mask: 0080h internal Mask: 0040h internal Mask: 0020h internal...
  • Page 342 9 Appendix 9.2 Data Protocols Para- Description Multiplier Units Model meter Data Data byte 0 byte (Mux) 3,4,5,6 2520 System A positive active energy 0.01 LS-5x1 v2, LS-5x2 v2 10132 State Discrete Input 8 latched Mask: 8000h LS-5x1 v2, LS-5x2 v2 State Discrete Input 7 latched Mask: 4000h LS-5x1 v2,...
  • Page 343 9 Appendix 9.2 Data Protocols Para- Description Multiplier Units Model meter Data Data byte 0 byte (Mux) internal Mask: 0200h internal Mask: 0100h internal Mask: 0080h internal Mask: 0040h internal Mask: 0020h internal Mask: 0010h internal Mask: 0008h internal Mask: 0004h 10.01 Analog input 1, wire break Mask: 0002h LS-5x2 v2...
  • Page 344 9 Appendix 9.2 Data Protocols Para- Description Multiplier Units Model meter Data Data byte 0 byte (Mux) 3,4,5,6 System B current 1 0.001 LS-5x2 v2 10136 internal Mask: 8000h internal Mask: 4000h internal Mask: 2000h internal Mask: 1000h internal Mask: 0800h internal Mask: 0400h internal...
  • Page 345 9 Appendix 9.2 Data Protocols Para- Description Multiplier Units Model meter Data Data byte 0 byte (Mux) internal Mask: 0080h 02.11 System A voltage and frequency in range Mask: 0040h LS-5x1 v2, LS-5x2 v2 (Ready for operation, 02.09 AND 02.10 are TRUE) internal Mask: 0020h...
  • Page 346 9 Appendix 9.2 Data Protocols Para- Description Multiplier Units Model meter Data Data byte 0 byte (Mux) internal Mask: 0800h internal Mask: 0400h internal Mask: 0200h internal Mask: 0100h 02.14 System B phase rotation Mask: 0080h LS-5x1 v2, LS-5x2 v2 Counter Clock Wise (CCW, reverse, left turn) 02.15 System B phase rotation Mask: 0040h...
  • Page 347 9 Appendix 9.2 Data Protocols Para- Description Multiplier Units Model meter Data Data byte 0 byte (Mux) 10149 08.30 Timeout synchronization CB B Mask: 8000h LS-5x2 v2 08.31 Timeout synchronization CB A Mask: 4000h LS-5x1 v2, LS-5x2 v2 internal Mask: 2000h internal Mask: 1000h 08.33 System A / System B phase rotation...
  • Page 348 9 Appendix 9.2 Data Protocols Para- Description Multiplier Units Model meter Data Data byte 0 byte (Mux) LS-5x2 v2: 04.06 CB B is closed 04.07 CB A is closed Mask: 0008h LS-5x1 v2, LS-5x2 v2 04.04 Lamp test request Mask: 0004h LS-5x1 v2, LS-5x2 v2 04.03 Operating mode MANUAL...
  • Page 349 9 Appendix 9.2 Data Protocols Para- Description Multiplier Units Model meter Data Data byte 0 byte (Mux) internal Mask: 0400h internal Mask: 0200h internal Mask: 0100h internal Mask: 0080h internal Mask: 0040h internal Mask: 0020h internal Mask: 0010h Syst. A phase rotation CW (for ToolKit) Mask: 0008h LS-5x1 v2, LS-5x2 v2...
  • Page 350 9 Appendix 9.2 Data Protocols Para- Description Multiplier Units Model meter Data Data byte 0 byte (Mux) 24.44 Flag 4 LS 5 Mask: 0800h LS-5x1 v2, LS-5x2 v2 24.43 Flag 3 LS 5 Mask: 0400h LS-5x1 v2, LS-5x2 v2 24.42 Flag 2 LS 5 Mask: 0200h LS-5x1 v2, LS-5x2 v2...
  • Page 351 9 Appendix 9.2 Data Protocols Para- Description Multiplier Units Model meter Data Data byte 0 byte (Mux) 07.08 System A underfrequency threshold 1 Mask: 2000h LS-5x1 v2, LS-5x2 v2 07.09 System A underfrequency threshold 2 Mask: 1000h LS-5x1 v2, LS-5x2 v2 07.10 System A overvoltage threshold 1 Mask: 0800h LS-5x1 v2,...

  • Page 352: Protocol 6003 (Ls-5 Communication)

    9 Appendix 9.2 Data Protocols Para- Description Multiplier Units Model meter Data Data byte 0 byte (Mux) 08.36 CB A unload mismatch Mask: 0004h LS-5x1 v2, LS-5x2 v2 07.29 QV Monitoring step 1 tripped Mask: 0002h LS-5x1 v2, LS-5x2 v2 07.30 QV Monitoring step 2 tripped Mask: 0001h LS-5x1 v2,...
  • Page 353 9 Appendix 9.2 Data Protocols Time [ms] 1000 1050 1100 1150 Sent message Mux # CAN bus load share line The maximum length of the CAN bus load share line depends on this parameter as well. The values in ╚═▷ Tab. 34 are valid for 32 participants and a bus load of approximately 40 [ms] [ms]...
  • Page 354 9 Appendix 9.2 Data Protocols Load share bus communication - "fast" refreshed data Byte Function Remark Phase angle compensation is incorporated System A in range System B in range System A is black System B is black Breaker 1 closed Isolation switch closed Synchronous networks detected Between system A an B...
  • Page 355 9 Appendix 9.2 Data Protocols Load share bus communication - "fast" refreshed data Byte Function Remark 1 = Phase matching Synchronization with separate slip frequency Notes offset In application mode LS5 (multiple LS5) only: • This bit will be send together with bit 3 »Execution of the wish«...
  • Page 356 9 Appendix 9.2 Data Protocols Load share bus communication - "slow" refreshed data Byte Function Remark Mux identifier Protocol-Identifier 6003 Not used Not used Mux identifier Mains wiring 0 = No mains wiring 1 = Mains wiring at system A 2 = Mains wiring at system B 3 = Mains wiring at isolation switch Not used for 1breaker...

  • Page 357: Modbus

    9 Appendix 9.2 Data Protocols Load share bus communication - "slow" refreshed data Byte Function Remark Segment number system A 1 to 32 Extended bit for segment number system A Max. 64 nodes possible Not used Segment number system B Max.
  • Page 358 9 Appendix 9.2 Data Protocols Modbus Para- Description Multiplier Units Model meter Modicon Start addr. start addr. (*1) 450009 450008 reserved AC System A Values 450010 450009 System A frequency 0.01 LS-5x1 v2, LS-5x2 450011 450010 Total system A active power AC scaled defined LS-5x1 v2, LS-5x2 measurement...
  • Page 359 9 Appendix 9.2 Data Protocols Modbus Para- Description Multiplier Units Model meter Modicon Start addr. start addr. (*1) 450025 450024 reserved 450026 450025 reserved 450027 450026 reserved 450028 450027 reserved 450029 450028 reserved AC System B Values 450030 450029 System B frequency 0.01 LS-5x1 v2, LS-5x2 450031...
  • Page 360 9 Appendix 9.2 Data Protocols Modbus Para- Description Multiplier Units Model meter Modicon Start addr. start addr. (*1) 450044 450043 reserved AC System Values 450045 450044 reserved 450046 450045 reserved 450047 450046 reserved 450048 450047 reserved 450049 450048 reserved DC Analogue Values 450050 450049 10110...
  • Page 361 9 Appendix 9.2 Data Protocols Modbus Para- Description Multiplier Units Model meter Modicon Start addr. start addr. (*1) 28.04 Command to CB-control 4 Mask: 0800h LS-5x1 v2, LS-5x2 (linked by logic 'OR') 28.05 Command to CB-control 5 Mask: 1000h LS-5x1 v2, LS-5x2 (linked by logic 'OR') 28.06 Command to CB-control 6 Mask: 2000h...
  • Page 362 9 Appendix 9.2 Data Protocols Modbus Para- Description Multiplier Units Model meter Modicon Start addr. start addr. (*1) internal Mask: 0080h internal Mask: 0100h internal Mask: 0200h 00.46 LM Relay 6 Mask: 0400h LS-5x1 v2, LS-5x2 internal Mask: 0800h 00.44 LM Relay 4 Mask: 1000h LS-5x1 v2, LS-5x2 00.43 LM Relay 3...
  • Page 363 9 Appendix 9.2 Data Protocols Modbus Para- Description Multiplier Units Model meter Modicon Start addr. start addr. (*1) internal Mask: 0002h internal Mask: 0004h internal Mask: 0008h internal Mask: 0010h internal Mask: 0020h internal Mask: 0040h internal Mask: 0080h 01.08 Warning alarms are active Mask: 0100h LS-5x1 v2, LS-5x2 (alarm class A, B)
  • Page 364 9 Appendix 9.2 Data Protocols Modbus Para- Description Multiplier Units Model meter Modicon Start addr. start addr. (*1) internal Mask: 4000h internal Mask: 8000h 450067 450066 10162 LogicsManagerBits6 00.40 LM Synchronization mode Mask: 0001h LS-5x1 v2, LS-5x2 00.39 LM Synchronization mode Mask: 0002h LS-5x1 v2, LS-5x2 PERMISSIVE...
  • Page 365 9 Appendix 9.2 Data Protocols Modbus Para- Description Multiplier Units Model meter Modicon Start addr. start addr. (*1) internal Mask: 2000h internal Mask: 4000h internal Mask: 8000h 450069 450068 4139 Monitoring operation windows internal Mask: 0001h internal Mask: 0002h internal Mask: 0004h internal Mask: 0008h...
  • Page 366 9 Appendix 9.2 Data Protocols Modbus Para- Description Multiplier Units Model meter Modicon Start addr. start addr. (*1) internal Mask: 0008h internal Mask: 0010h internal Mask: 0020h 02.13 System A phase rotation Mask: 0040h LS-5x1 v2, LS-5x2 Clock Wise (CW, forward, right turn) 02.12 System A phase rotation Mask: 0080h LS-5x1 v2, LS-5x2...
  • Page 367 9 Appendix 9.2 Data Protocols Modbus Para- Description Multiplier Units Model meter Modicon Start addr. start addr. (*1) 450072 450071 reserved 450073 450072 4153 ControlBits1 04.01 Operating mode AUTOMATIC Mask: 0001h LS-5x1 v2, LS-5x2 04.03 Operating mode MANUAL Mask: 0002h LS-5x1 v2, LS-5x2 04.04 Lamp test request Mask: 0004h...
  • Page 368 9 Appendix 9.2 Data Protocols Modbus Para- Description Multiplier Units Model meter Modicon Start addr. start addr. (*1) 28.04 Command 4to LS5 (OR'ed) cf. Mask: 0040h LS-5x1 v2, LS-5x2 ID8018 28.05 Command 5to LS5 (OR'ed) cf. Mask: 0080h LS-5x1 v2, LS-5x2 ID8018 28.06 Command 6to LS5 (OR'ed) cf.
  • Page 369 9 Appendix 9.2 Data Protocols Modbus Para- Description Multiplier Units Model meter Modicon Start addr. start addr. (*1) 24.31 Enable mains decoupling Mask: 0001h LS-5x1 v2, LS-5x2 24.32 Open CB A Mask: 0002h LS-5x1 v2, LS-5x2 24.33 Immediate open CB A Mask: 0004h LS-5x1 v2, LS-5x2 24.34 Enable to close CB A...
  • Page 370 9 Appendix 9.2 Data Protocols Modbus Para- Description Multiplier Units Model meter Modicon Start addr. start addr. (*1) internal Mask: 4000h internal Mask: 8000h 450078 450077 10135 Monitoring System A internal Mask: 0001h internal Mask: 0002h 07.05 System A phase rotation Mask: 0004h LS-5x1 v2, LS-5x2 07.26 System A voltage asymmetry...
  • Page 371 9 Appendix 9.2 Data Protocols Modbus Para- Description Multiplier Units Model meter Modicon Start addr. start addr. (*1) 07.15 df/dt (ROCOF) Mask: 0080h LS-5x1 v2, LS-5x2 internal Mask: 0100h internal Mask: 0200h internal Mask: 0400h internal Mask: 0800h internal Mask: 1000h internal Mask: 2000h internal...
  • Page 372 9 Appendix 9.2 Data Protocols Modbus Para- Description Multiplier Units Model meter Modicon Start addr. start addr. (*1) internal Mask: 0002h internal Mask: 0004h internal Mask: 0008h internal Mask: 0010h internal Mask: 0020h internal Mask: 0040h internal Mask: 0080h internal Mask: 0100h internal Mask: 0200h...
  • Page 373 9 Appendix 9.2 Data Protocols Modbus Para- Description Multiplier Units Model meter Modicon Start addr. start addr. (*1) Relay-Output 6 Mask: 0400h LS-5x1 v2, LS-5x2 internal Mask: 0200h internal Mask: 0100h internal Mask: 0080h internal Mask: 0040h internal Mask: 0020h internal Mask: 0010h internal...
  • Page 374 9 Appendix 9.2 Data Protocols Modbus Para- Description Multiplier Units Model meter Modicon Start addr. start addr. (*1) internal Mask: 4000h internal Mask: 2000h internal Mask: 1000h internal Mask: 0800h internal Mask: 0400h internal Mask: 0200h internal Mask: 0100h internal Mask: 0080h internal Mask: 0040h...
  • Page 375 9 Appendix 9.2 Data Protocols Modbus Para- Description Multiplier Units Model meter Modicon Start addr. start addr. (*1) internal Mask: 4000h internal Mask: 2000h internal Mask: 1000h internal Mask: 0800h internal Mask: 0400h internal Mask: 0200h 08.05 CB B close not successful Mask: 0100h LS-5x2 v2 08.06 CB B open not successful...
  • Page 376 9 Appendix 9.2 Data Protocols Modbus Para- Description Multiplier Units Model meter Modicon Start addr. start addr. (*1) 450113 450112 10132 Alarms discrete inputs 1 latched (unacknowledged) 10608 State Discrete Input 8 (reply CB A) Mask: 8000h LS-5x1 v2, LS-5x2 10607 State Discrete Input 7 Mask: 4000h...
  • Page 377 9 Appendix 9.2 Data Protocols Modbus Para- Description Multiplier Units Model meter Modicon Start addr. start addr. (*1) internal Mask: 0100h internal Mask: 0200h internal Mask: 0400h internal Mask: 0800h internal Mask: 1000h internal Mask: 2000h internal Mask: 4000h internal Mask: 8000h 450119 450118...
  • Page 378 9 Appendix 9.2 Data Protocols Modbus Para- Description Multiplier Units Model meter Modicon Start addr. start addr. (*1) Busbar voltage and frequency ok Mask: 0002h LS-5x1 v2, LS-5x2 Mains voltage and frequency ok Mask: 0004h LS-5x1 v2, LS-5x2 4th system voltage and frequency Mask: 0008h LS-5x1 v2, LS-5x2 Busbar 1 dead busbar detection...
  • Page 379 9 Appendix 9.2 Data Protocols Modbus Para- Description Multiplier Units Model meter Modicon Start addr. start addr. (*1) 29.03 Command to CB-control 3 Mask: 0400h LS-5x1 v2, LS-5x2 29.04 Command to CB-control 4 Mask: 0800h LS-5x1 v2, LS-5x2 29.05 Command to CB-control 5 Mask: 1000h LS-5x1 v2, LS-5x2 29.06 Command to CB-control 6...
  • Page 380 9 Appendix 9.2 Data Protocols Modbus Para- Description Multiplier Units Model meter Modicon Start addr. start addr. (*1) Mains voltage and frequency ok Mask: 0004h LS-5x1 v2, LS-5x2 4th system voltage and frequency Mask: 0008h LS-5x1 v2, LS-5x2 Busbar 1 dead busbar detection Mask: 0010h LS-5x1 v2, LS-5x2 Busbar 2 dead busbar detection...
  • Page 381 9 Appendix 9.2 Data Protocols Modbus Para- Description Multiplier Units Model meter Modicon Start addr. start addr. (*1) 29.04 Command to CB-control 4 Mask: 0800h LS-5x1 v2, LS-5x2 29.05 Command to CB-control 5 Mask: 1000h LS-5x1 v2, LS-5x2 29.06 Command to CB-control 6 Mask: 2000h LS-5x1 v2, LS-5x2 internal...
  • Page 382 9 Appendix 9.2 Data Protocols Modbus Para- Description Multiplier Units Model meter Modicon Start addr. start addr. (*1) 4th system voltage and frequency Mask: 0008h LS-5x1 v2, LS-5x2 Busbar 1 dead busbar detection Mask: 0010h LS-5x1 v2, LS-5x2 Busbar 2 dead busbar detection Mask: 0020h LS-5x1 v2, LS-5x2 internal...
  • Page 383 9 Appendix 9.2 Data Protocols Modbus Para- Description Multiplier Units Model meter Modicon Start addr. start addr. (*1) 29.05 Command to CB-control 5 Mask: 1000h LS-5x1 v2, LS-5x2 29.06 Command to CB-control 6 Mask: 2000h LS-5x1 v2, LS-5x2 internal Mask: 4000h internal Mask: 8000h 450130...
  • Page 384 9 Appendix 9.2 Data Protocols Modbus Para- Description Multiplier Units Model meter Modicon Start addr. start addr. (*1) Busbar 1 dead busbar detection Mask: 0010h LS-5x1 v2, LS-5x2 Busbar 2 dead busbar detection Mask: 0020h LS-5x1 v2, LS-5x2 internal Mask: 0040h internal Mask: 0080h 29.01 Command to CB-control 1...
  • Page 385 9 Appendix 9.2 Data Protocols Modbus Para- Description Multiplier Units Model meter Modicon Start addr. start addr. (*1) 29.06 Command to CB-control 6 Mask: 2000h LS-5x1 v2, LS-5x2 internal Mask: 4000h internal Mask: 8000h 450133 450132 Status of Device 13 Generator voltage and frequency ok Mask: 0001h LS-5x1 v2, LS-5x2 Busbar voltage and frequency ok...
  • Page 386 9 Appendix 9.2 Data Protocols Modbus Para- Description Multiplier Units Model meter Modicon Start addr. start addr. (*1) Busbar 2 dead busbar detection Mask: 0020h LS-5x1 v2, LS-5x2 internal Mask: 0040h internal Mask: 0080h 29.01 Command to CB-control 1 Mask: 0100h LS-5x1 v2, LS-5x2 29.02 Command to CB-control 2 Mask: 0200h...
  • Page 387 9 Appendix 9.2 Data Protocols Modbus Para- Description Multiplier Units Model meter Modicon Start addr. start addr. (*1) internal Mask: 4000h internal Mask: 8000h 450136 450135 Status of Device 16 Generator voltage and frequency ok Mask: 0001h LS-5x1 v2, LS-5x2 Busbar voltage and frequency ok Mask: 0002h LS-5x1 v2, LS-5x2...
  • Page 388 9 Appendix 9.2 Data Protocols Modbus Para- Description Multiplier Units Model meter Modicon Start addr. start addr. (*1) internal Mask: 0080h 29.01 Command to CB-control 1 Mask: 0100h LS-5x1 v2, LS-5x2 29.02 Command to CB-control 2 Mask: 0200h LS-5x1 v2, LS-5x2 29.03 Command to CB-control 3 Mask: 0400h LS-5x1 v2, LS-5x2...
  • Page 389 9 Appendix 9.2 Data Protocols Modbus Para- Description Multiplier Units Model meter Modicon Start addr. start addr. (*1) Generator voltage and frequency ok Mask: 0001h LS-5x1 v2, LS-5x2 Busbar voltage and frequency ok Mask: 0002h LS-5x1 v2, LS-5x2 Mains voltage and frequency ok Mask: 0004h LS-5x1 v2, LS-5x2 4th system voltage and frequency...
  • Page 390 9 Appendix 9.2 Data Protocols Modbus Para- Description Multiplier Units Model meter Modicon Start addr. start addr. (*1) 29.02 Command to CB-control 2 Mask: 0200h LS-5x1 v2, LS-5x2 29.03 Command to CB-control 3 Mask: 0400h LS-5x1 v2, LS-5x2 29.04 Command to CB-control 4 Mask: 0800h LS-5x1 v2, LS-5x2 29.05 Command to CB-control 5...
  • Page 391 9 Appendix 9.2 Data Protocols Modbus Para- Description Multiplier Units Model meter Modicon Start addr. start addr. (*1) Busbar voltage and frequency ok Mask: 0002h LS-5x1 v2, LS-5x2 Mains voltage and frequency ok Mask: 0004h LS-5x1 v2, LS-5x2 4th system voltage and frequency Mask: 0008h LS-5x1 v2, LS-5x2 Busbar 1 dead busbar detection...
  • Page 392 9 Appendix 9.2 Data Protocols Modbus Para- Description Multiplier Units Model meter Modicon Start addr. start addr. (*1) 29.03 Command to CB-control 3 Mask: 0400h LS-5x1 v2, LS-5x2 29.04 Command to CB-control 4 Mask: 0800h LS-5x1 v2, LS-5x2 29.05 Command to CB-control 5 Mask: 1000h LS-5x1 v2, LS-5x2 29.06 Command to CB-control 6...
  • Page 393 9 Appendix 9.2 Data Protocols Modbus Para- Description Multiplier Units Model meter Modicon Start addr. start addr. (*1) Mains voltage and frequency ok Mask: 0004h LS-5x1 v2, LS-5x2 4th system voltage and frequency Mask: 0008h LS-5x1 v2, LS-5x2 Busbar 1 dead busbar detection Mask: 0010h LS-5x1 v2, LS-5x2 Busbar 2 dead busbar detection...
  • Page 394 9 Appendix 9.2 Data Protocols Modbus Para- Description Multiplier Units Model meter Modicon Start addr. start addr. (*1) 29.04 Command to CB-control 4 Mask: 0800h LS-5x1 v2, LS-5x2 29.05 Command to CB-control 5 Mask: 1000h LS-5x1 v2, LS-5x2 29.06 Command to CB-control 6 Mask: 2000h LS-5x1 v2, LS-5x2 internal...
  • Page 395 9 Appendix 9.2 Data Protocols Modbus Para- Description Multiplier Units Model meter Modicon Start addr. start addr. (*1) 4th system voltage and frequency Mask: 0008h LS-5x1 v2, LS-5x2 Busbar 1 dead busbar detection Mask: 0010h LS-5x1 v2, LS-5x2 Busbar 2 dead busbar detection Mask: 0020h LS-5x1 v2, LS-5x2 internal...
  • Page 396 9 Appendix 9.2 Data Protocols Modbus Para- Description Multiplier Units Model meter Modicon Start addr. start addr. (*1) 29.05 Command to CB-control 5 Mask: 1000h LS-5x1 v2, LS-5x2 29.06 Command to CB-control 6 Mask: 2000h LS-5x1 v2, LS-5x2 internal Mask: 4000h internal Mask: 8000h 450150...
  • Page 397 9 Appendix 9.2 Data Protocols Modbus Para- Description Multiplier Units Model meter Modicon Start addr. start addr. (*1) Busbar 1 dead busbar detection Mask: 0010h LS-5x1 v2, LS-5x2 Busbar 2 dead busbar detection Mask: 0020h LS-5x1 v2, LS-5x2 internal Mask: 0040h internal Mask: 0080h 29.01 Command to CB-control 1...
  • Page 398 9 Appendix 9.2 Data Protocols Modbus Para- Description Multiplier Units Model meter Modicon Start addr. start addr. (*1) 29.06 Command to CB-control 6 Mask: 2000h LS-5x1 v2, LS-5x2 internal Mask: 4000h internal Mask: 8000h 450153 450152 reserved 450154 450153 reserved 450155 450154 reserved...
  • Page 399 9 Appendix 9.2 Data Protocols Modbus Para- Description Multiplier Units Model meter Modicon Start addr. start addr. (*1) 450185 450184 Total system A active power LS-5x1 v2, LS-5x2 450187 450186 Total system A reactive power LS-5x1 v2, LS-5x2 450189 450188 Total system A apparent power LS-5x1 v2, LS-5x2 450191...

  • Page 400: Additional Data Identifier

    9 Appendix 9.2 Data Protocols Modbus Para- Description Multiplier Units Model meter Modicon Start addr. start addr. (*1) 450233 450232 Total system B reactive power LS-5x2 v2 450235 450234 Av. system B wye-voltage LS-5x1 v2, LS-5x2 450237 450236 Av. system B delta-voltage LS-5x1 v2, LS-5x2 450239 450238...

  • Page 401: Logicsmanager Reference

    9 Appendix 9.3 LogicsManager Reference Bit 14 = 1 (ID 542) Remote control bit 15 (command variable 04.58) Bit 13 = 1 (ID 543) Remote control bit 14 (command variable 04.57) Bit 12 = 1 (ID 544) Remote control bit 13 (command variable 04.56) Bit 11 = 1 (ID 545) Remote control bit 12 (command variable 04.55) Bit 10 = 1 (ID 546)
  • Page 402 9 Appendix 9.3 LogicsManager Reference Structure and description of the LogicsManager Fig. 183: LogicsManager - function overview • Command (variable) A list of parameters and functions is provided for the command inputs. Examples of the parameters that may be configured into these commands are generator undervoltage thresholds 1 and 2, start fail, and cool down.

  • Page 403: Logical Symbols

    9 Appendix 9.3 LogicsManager Reference [Ox] - Operator {x} NAND Logical negated AND Logical OR Logical negated OR Exclusive OR NXOR Exclusive negated OR Tab. 37: Operators For the various display formats of the corresponding logical symbols refer to ╚═▷ “9.3.2 Logical Symbols”.
  • Page 404 9 Appendix 9.3 LogicsManager Reference Fig. 185: Logical symbols ... according to standard: LS-5 (default: DIN 40 700) US MIL IEC617-12 Meaning of the columns NAND NXOR NAND NXOR Tab. 38: Truth table LS-5 v2 Series 37649...

  • Page 405: Logical Outputs

    9 Appendix 9.3 LogicsManager Reference 9.3.3 Logical Outputs The logical outputs or combinations may be grouped into three categories: • Internal logical flags • Internal functions • Relay outputs The numbers of the logical outputs in the third column may again be used as input variable for other outputs in the LogicsManager.

  • Page 406: Internal Functions

    9 Appendix 9.3 LogicsManager Reference Name Function Number Flag 2 LS5 LS5 flag 2 24.42 Flag 3 LS5 LS5 flag 3 24.43 Flag 4 LS5 LS5 flag 4 24.44 Flag 5 LS5 LS5 flag 5 24.45 Internal functions The following logical functions may be used to activate/deactivate functions. Name Function Number...
  • Page 407 9 Appendix 9.3 LogicsManager Reference Name Terminal Function Number [R2] If this logical output becomes true, the relay output 2 will be activated Relay 3 34/35 LogicsManager; pre-assigned with 'System B not OK' 00.43 [R3] If this logical output becomes true, the relay output 3 will be activated Relay 4 36/37 LogicsManager;...

  • Page 408: Logical Command Variables

    9 Appendix 9.3 LogicsManager Reference Name Default value Function Number The default value indicates that a breaker close failure is active. LED 8 Communication failure (08.17 Missing See LogicsManager "LED 8" 24.58 LS-5) (parameter 12969). The default value indicates that the multi-unit missing members monitoring function (parameter 4060) has tripped.
  • Page 409 9 Appendix 9.3 LogicsManager Reference 'LM' means that these logical command variables are the result of a LogicsManager condition. Name Function Note 00.01 LM Flag 1 Internal flag 1 Internal calculation; refer to ╚═▷ “ Internal flags” 00.02 LM Flag 2 Internal flag 2 Internal calculation;...

  • Page 410: Group 01: Alarm System

    9 Appendix 9.3 LogicsManager Reference Name Function Note 00.43 LM Relay 3 00.44 LM Relay 4 00.45 Reserved 00.46 LM Relay 6 00.95 LM Lock keypad Lock keypad is active 9.3.4.2 Group 01: Alarm System • Alarm system • Logic command variables 01.01-01.12 Alarm classes may be configured as command variables for all logical outputs in the LogicsManager.
  • Page 411 9 Appendix 9.3 LogicsManager Reference The status of the system may be used as command variable in a logical output to set parameters for customized operations. Name Function Note 02.03 SyB. voltage ok SyB. voltage within operating TRUE as long as the SyB. voltage range is within the operating range 02.04...

  • Page 412: Group 04: Applications Condition

    9 Appendix 9.3 LogicsManager Reference Name Function Note 02.30 Dead bus cl. cond. Indicates Dead Bus conditions TRUE if Dead Bus conditions are TRUE defined by parameters 8801, 5820, 8805, 8802, 8803 and 8804. Warning No dead bus interlocking. 9.3.4.4 Group 04: Applications Condition •...

  • Page 413: Group 05: Device Related Alarms

    9 Appendix 9.3 LogicsManager Reference Name Function Note 04.50 Remote Ctrl.Bit7 Free control bit 7 is activated 04.51 Remote Ctrl.Bit8 Free control bit 8 is activated 04.52 Remote Ctrl.Bit9 Free control bit 9 is activated 04.53 Remote Ctrl.Bit10 Free control bit 10 is activated 04.54 Remote Ctrl.Bit11 Free control bit 11 is activated...

  • Page 414: Group 06: System B Related Alarms

    9 Appendix 9.3 LogicsManager Reference These device alarms may be used as command variable in a logical output to set parameters for customized operations. Name / Function Note 05.15 EEPROM failure TRUE = alarm latched (triggered) FALSE = alarm acknowledged 9.3.4.6 Group 06: System B Related Alarms •...

  • Page 415: Group 08: System Related Alarms

    9 Appendix 9.3 LogicsManager Reference Name / Function Note 07.29 SyA. QV mon. (limit) 1 07.30 SyA. QV mon. (limit) 2 9.3.4.8 Group 08: System Related Alarms • System related alarms • Logic command variables 08.01-08.51 These system alarms may be used as command variable in a logical output to set parameters for customized operations.

  • Page 416: 9.3.4.10 Group 11: Clock And Timer

    9 Appendix 9.3 LogicsManager Reference Name / Function Note condition is not present anymore, if Control is 09.05 DI 5 (Discrete input [DI 05]) configured as alarm class) 09.06 DI 6 (Discrete input [DI 06]) 09.07 DI 7 (Discrete input [DI 07]) 09.08 DI 8 (Discrete input [DI 08]) 9.3.4.10 Group 11: Clock And Timer...

  • Page 417: Group 24: Flags Condition 2

    9 Appendix 9.3 LogicsManager Reference These command variables may be used as command variable in a logical output. Name / Function Note 17.01 Missing member 4105 17.02 Parameter alignment 4105 17.03 Measurement difference 4105 17.11 Free alarm 1 17.12 Free alarm 2 17.13 Free alarm 3 17.14...

  • Page 418: Group 26(/1-2): Commands Device 33 To 48

    9 Appendix 9.3 LogicsManager Reference Name / Function Note 24.57 LM LED 7 (Breaker close failure) 24.58 LM LED 8 (Communication failure) Note: Indicates that the multi-unit missing members monitoring function (parameter 4060) has tripped. See also LogicsManager "LED 8" (parameter 12969).
  • Page 419 9 Appendix 9.3 LogicsManager Reference Name / Function Note 26.25 Flag 5 LS5 device 37 26.26 Flag 1 LS5 device 38 26.27 Flag 2 LS5 device 38 26.28 Flag 3 LS5 device 38 26.29 Flag 4 LS5 device 38 26.30 Flag 5 LS5 device 38 26.31 Flag 1 LS5 device 39...

  • Page 420: Group 27(/1-2): Commands Device 49 To 64

    9 Appendix 9.3 LogicsManager Reference Name / Function Note 26.63 Flag 3 LS5 device 45 26.64 Flag 4 LS5 device 45 26.65 Flag 5 LS5 device 45 26.66 Flag 1 LS5 device 46 26.67 Flag 2 LS5 device 46 26.68 Flag 3 LS5 device 46 26.69 Flag 4 LS5 device 46...
  • Page 421 9 Appendix 9.3 LogicsManager Reference Name / Function Note 27.12 Flag 2 LS5 device 51 27.13 Flag 3 LS5 device 51 27.14 Flag 4 LS5 device 51 27.15 Flag 5 LS5 device 51 27.16 Flag 1 LS5 device 52 27.17 Flag 2 LS5 device 52 27.18 Flag 3 LS5 device 52...

  • Page 422: 9.3.4.16 Group 28: Ls-5 System Conditions

    9 Appendix 9.3 LogicsManager Reference Name / Function Note 27.50 Flag 5 LS5 device 58 27.51 Flag 1 LS5 device 59 27.52 Flag 2 LS5 device 59 27.53 Flag 3 LS5 device 59 27.54 Flag 4 LS5 device 59 27.55 Flag 5 LS5 device 59 27.56 Flag 1 LS5 device 60...

  • Page 423: Group 29(/1-3): Commands Device 1 To 16

    9 Appendix 9.3 LogicsManager Reference Name / Function Note 28.01 Command 1 to LS5 easYgen (OR) TRUE if at least one easYgen sets the command variable to TRUE (OR operation) 28.02 Command 2 to LS5 easYgen (OR) 28.03 Command 3 to LS5 easYgen (OR) 28.04 Command 4 to LS5 easYgen (OR) 28.05...
  • Page 424 9 Appendix 9.3 LogicsManager Reference Name / Function Note 29.26 Command 2 easYgen 5 29.27 Command 3 easYgen 5 29.28 Command 4 easYgen 5 29.29 Command 5 easYgen 5 29.30 Command 6 easYgen 5 29.31 Command 1 easYgen 6 29.32 Command 2 easYgen 6 29.33 Command 3 easYgen 6...

  • Page 425: Group 30(/1-3): Commands Device 17 To 32

    9 Appendix 9.3 LogicsManager Reference Name / Function Note 29.64 Command 4 easYgen 11 29.65 Command 5 easYgen 11 29.66 Command 6 easYgen 11 29.67 Command 1 easYgen 12 29.68 Command 2 easYgen 12 29.69 Command 3 easYgen 12 29.70 Command 4 easYgen 12 29.71 Command 5 easYgen 12...
  • Page 426 9 Appendix 9.3 LogicsManager Reference Name / Function Note 30.01 Command 1 easYgen 17 30.02 Command 2 easYgen 17 30.03 Command 3 easYgen 17 30.04 Command 4 easYgen 17 30.05 Command 5 easYgen 17 30.06 Command 6 easYgen 17 30.07 Command 1 easYgen 18 30.08 Command 2 easYgen 18...
  • Page 427 9 Appendix 9.3 LogicsManager Reference Name / Function Note 30.39 Command 3 easYgen 23 30.40 Command 4 easYgen 23 30.41 Command 5 easYgen 23 30.42 Command 6 easYgen 23 30.43 Command 1 easYgen 24 30.44 Command 2 easYgen 24 30.45 Command 3 easYgen 24 30.46 Command 4 easYgen 24...

  • Page 428: Factory Settings

    9 Appendix 9.3 LogicsManager Reference Name / Function Note 30.77 Command 5 easYgen 29 30.78 Command 6 easYgen 29 30.79 Command 1 easYgen 30 30.80 Command 2 easYgen 30 30.81 Command 3 easYgen 30 30.82 Command 4 easYgen 30 30.83 Command 5 easYgen 30 30.84 Command 6 easYgen 30...
  • Page 429 9 Appendix 9.3 LogicsManager Reference Simple (function) Extended (configuration) Result If TRUE, flag {y} becomes TRUE. FALSE Deactivated by default. Internal Functions Simple (function) Extended (configuration) Result [00.15] External acknowledgment If TRUE, all alarms are acknowledged from an dependent on external source.
  • Page 430 9 Appendix 9.3 LogicsManager Reference Simple (function) Extended (configuration) Result If TRUE, synchronization mode CHECK is FALSE enabled. Deactivated by default. Only available in application mode [00.39] Synchronization Mode PERM If TRUE, synchronization mode PERMISSIVE is FALSE enabled. Deactivated by default. Only available in application mode [00.40] Synchronization Mode RUN If TRUE, synchronization mode RUN is...
  • Page 431 9 Appendix 9.3 LogicsManager Reference Simple (function) Extended (configuration) Result Relay will be de-energized if unit is not ready FALSE for operation or the logics manager output is TRUE. LM output is deactivated by default The unit is only ready for operation after a start-up delay following the power supply connection.

  • Page 432: Event And Alarm Reference

    9 Appendix 9.4 Event And Alarm Reference Simple (function) Extended (configuration) Result In two relay mode fixed to "close CBA". FALSE Otherwise the relay energizes if "All alarm classes" is TRUE Discrete inputs Alarm class Pre-assigned to CONTROL freely configurable LogicsManager 'Lock monitoring' CONTROL freely configurable...

  • Page 433: Status Messages

    9 Appendix 9.4 Event And Alarm Reference Alarm class Visible in the display LED "Alarm" & horn Relay "Command: open CBA" immediately Shutdown With this alarm the CBA is opened immediately. Alarm • Alarm text + flashing LED "Alarm" + Relay centralized alarm (horn) + CBA open immediately. immediately Shutdown With this alarm the CBA is opened immediately.

  • Page 434: Event History

    9 Appendix 9.4 Event And Alarm Reference Message text Meaning 13267 Synchronization mode is set to Off (parameter 5728) Synch. PERMISSIVE Synchronization mode Permissive (twinkling) 13265 Synchronization mode is set to Permissive (parameter 5728) Synchronization CBA The CBA will be synchronized 13260 The control tries to synchronize the CBA.

  • Page 435: Alarm Messages

    9 Appendix 9.4 Event And Alarm Reference Message text Meaning 14701 Feedback CBA open Reply CBA open became active 14700 MAN mode Manual mode became active 14355 Open command CBA CBA open command became active 14731 Start up power Power up cycle happened 14778 System A is ok System A became ok (Voltage and frequency in range)
  • Page 436 9 Appendix 9.4 Event And Alarm Reference Message text Meaning 10005 The battery voltage has fallen below the limit value 1 for battery undervoltage for at least the configured time and has not exceeded the value of the hysteresis. Bat. undervoltage 2 Battery undervoltage, limit value 2 10006 The battery voltage has fallen below the limit value 2 for battery undervoltage for at least...
  • Page 437 9 Appendix 9.4 Event And Alarm Reference Message text Meaning A single measurement value does not match with the values of the majority of the VDE-AR-N 4105 device partners within a time of 3.5 s. Missing LS5 Missing LS-5 members detected 4064 The LS-5 has detected that the number of available units at the CAN bus does not correspond with the configured application mode.
  • Page 438 9 Appendix 9.4 Event And Alarm Reference Message text Meaning The system A frequency has exceeded the limit value 2 for system A overfrequency for at least the configured time and did not fall below the value of the hysteresis. Triggering this monitoring function causes the mains decoupling function to trigger.

  • Page 439: Additional Application Information

    9 Appendix 9.5 Additional Application Information Message text Meaning SyB. phase rotation System B rotating field 3955 The system A rotating field does not correspond with the configured direction. Voltage mism. Voltage mismatch 2996 The flags of System A (02.09 'SyA. Voltage ok') and System B (02.03 'SyB. Voltage ok') do not have the same status or the phase angle between both systems is +/-10°...
  • Page 440 9 Appendix 9.5 Additional Application Information Fig. 186: LS-5 Synchronization Table - Two Systems A-B LS-5 v2 Series 37649...

  • Page 441: Glossary And List Of Abbreviations

    Discrete (Relay) Output Engine Control Unit Graphical Application Programming (GAP™) Generator Circuit Breaker Woodward device series (Genset Control) - not preferred for new design! Generator Group Breaker (speed) Governor; rpm regulator Human Machine Interface e.g., a front panel with display and buttons for interaction Islanded Operation in Parallel ("Islanded Parallel Operation")
  • Page 442 Load-Dependent Start/Stop operation Voltage Current Real power Reactive power Apparent power Sequencer A sequencer file is carrying specific settings e.g. to enable communication with and/or control of an expansion module. Such files can be prepared by Woodward. LS-5 v2 Series 37649...

  • Page 443: Index

    Index Index 2 breaker .............. 23 Alarms .
  • Page 444 Index Operating Range Monitoring ............ 133 Personnel .
  • Page 445 Index VDE-AR-N 4105 .............. 110,  111 Variants .
  • Page 446 Woodward GmbH Handwerkstraße 29 — 70565 Stuttgart — Germany Phone +49 (0) 711 789 54-510 +49 (0) 711 789 54-101 stgt-info@woodward.com...

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Ls-5 v2 seriesLs-5 seriesLs-52 seriesLs-511Ls-521Ls-522

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