Page 1 User Manual Frequency - Inverter LS-iP5A 2.2KW - 450kW All work for connection, commissioning and regular maintenance must be carried out by qualified, responsible specialists. www.js-technik.de JS-Technik GmbH - Lether Gerwerbestrasse 10 - 26197 Großenkneten JS-Technik...
Page 2 Right choice for ultimate yield LSIS strives to maximize customers' profit in gratitude of choosing us for your partner. SV-iP5A User Manual 5.5-30 kW [200V] / 2.2-450kW [400V] Read this manual carefully before installing, wiring, operating, servicing or inspecting this equipment. Keep this manual within easy reach for quick reference.
Page 3 Thank you for purchasing LS Variable Frequency Drives! SAFETY INSTRUCTIONS To prevent injury and property damage, follow these instructions during the installation and operation of the inverter. Incorrect operation due to ignoring these instructions may cause harm or damage. The following symbols are used throughout the manual to highlight important information.
Page 4 WARNING Do not remove the cover while power is applied or the unit is in operation. Otherwise, electric shock could occur. Do not operate the inverter with the front cover removed. Otherwise, electric shock can occur due to the exposed terminals and bus bars. Do not remove the cover except for periodic inspections or wiring, even if the input power is not applied.
Page 5 Do not allow lint, paper, wood chips, dust, metallic chips or other foreign material into the drive. Otherwise, fire or accident could occur. OPERATING PRECAUTIONS (1) Handling and installation The iP5A series inverter can be heavy. Lift according to the weight of the product. Use a hoist or crane to move and install the iP5A series inverter if necessary.
Page 6 (4) Operation precautions When the Auto restart function is selected, the inverter will restart after a fault has occurred. The Stop key on the keypad can only be used to stop the inverter when keypad control is enabled. Install a separate emergency stop switch if necessary. If a fault reset is made with the run command and /or reference signal present, a sudden start will occur.
Page 7: Table Of Contents
Table of Contents CHAPTER 1 - BASIC INFORMATION ....................1-1 1.1 I .............................. 1-1 NSPECTION 1.2 B ........................... 1-2 ASIC CONFIGURATION CHAPTER 2 - SPECIFICATION ......................2-1 2.1 200~230V C (5.5~30 W / 7.5~40HP) ....................2-1 LASS 2.2 380~480V C (5.5~30 W / 7.5~40HP) ....................
Page 8 9.5 P ........................... 9-8 ARAMETER CODE LIST 9.6 T ..........................9-12 ROUBLESHOOTING 9.7 ASCII C ........................... 9-14 APPENDIX A- UL MARKING ........................... I APPENDIX B- PERIPHERAL DEVICES ....................... IV APPENDIX C- RELATED PARAMETERS ....................VI DECLARATION OF CONFORMITY ......................VII EMI / RFI POWER LINE FILTERS ......................
Page 9: Chapter 1 - Basic Information
CHAPTER 1 - BASIC INFORMATION 1.1 Inspection Remove the inverter from its packing and inspect its exterior for shipping damage. If damage is apparent notify the shipping agent and your LSIS sales representative. Remove the cover and inspect the inverter for any apparent damage or foreign objects. Ensure that all mounting hardware and terminal connection hardware is properly seated, securely fastened, and undamaged.
Page 10: Basic Configuration
Chapter 1 – Basic Information 1.2 Basic configuration The following devices are required to operate the inverter. Proper peripheral devices must be selected and correct connections made to ensure proper operation. An incorrectly applied or installed inverter can result in system malfunction or reduction in product life as well as component damage.
Page 11: Chapter 2 - Specification
CHAPTER 2 - SPECIFICATION 2.1 200~230V Class (5.5~30kW / 7.5~40HP) Model Number (SVxxxiP5A-2) Capacity [kVA] 12.2 17.5 22.9 28.2 33.5 43.8 motor Fan or rating 18.5 pump Current [A] load (110% overload) 110% 1Minute (Normal Duty) motor Output rating ratings 18.5 General load...
Page 12: Class (37~90Kw / 50~125Hp)
Chapter 2 - Specification 2.3 380 ~ 480V Class (37~90kW / 50~125HP) Model Number (SVxxxiP5A-4) Capacity [kVA] 59.8 72.5 87.6 121.1 145.8 motor Fan or rating pump Current [A] load (110% overload) 110% 1 Minute (Normal Duty) motor Output rating ratings General load...
Page 13 Chapter 2 - Specification Common Specifications Cooling method Forced air cooling 65kA, suitable for use on a circuit capable of delivering not more than 100,000 Short Circuit Rating RMS Symmetrical amperes, 240 (or 480V) volts maximum Agency Approvals UL and cUL listed, CE marked Control Method V/F, Sensorless Vector, Slip Compensation, Easy Start Selectable Frequency...
Page 14 Chapter 2 - Specification Output Frequency, Output Current, Output Voltage, Frequency Set Value, Operation Operating Speed, DC Voltage, Integrating Wattmeter, Fan ON time, Run-time, Information Last Trip Time Trip Trips Indication when the Protection Function activates. Max. 5 Faults are Information saved.
Page 15: Dimensions
Chapter 2 - Specification 2.5 Dimensions 1) SV055iP5A (200/400V Class) mm (inches) Enclosure Model Type 156.5 IP20 SV055iP5A-2/4 (5.91) (5.12) (11.18) (10.69) (6.16) (0.98) (0.98) (0.98) UL Type 1...
Page 16 Chapter 2 - Specification 2) SV075~300iP5A (200/400V Class) <SV150~300iP5A-2/4> <SV075~110iP5A-2/4> mm (inches) Enclosure Model Type IP20 SV075iP5A-2/4 (7.87) (7.09) (0.23) (11.18) (10.69) (7.16) (1.37) (0.98) (1.37) UL Type 1 IP20 SV110iP5A-2/4 (7.87) (7.09) (0.23) (11.18) (10.69) (7.16) (1.37) (0.98) (1.37) UL Type 1 IP00 SV150iP5A-2/4...
Page 17 Chapter 2 - Specification 3) SV150~300iP5A (UL Type 1 or UL Open Type with Conduit Option used, 200V/400V Class) mm (inches) Enclosure Model Type 200.8 454.2 IP20 SV150iP5A-2/4 (9.84) (9.06) (7.9) (15.16) (14.57) (17.88) (7.91) (5.74) UL Type 1 200.8 454.2 IP20 SV185iP5A-2/4...
Page 18 Chapter 2 - Specification SV150 ~ SV300 iP5A (400V Class) – Built-in DCL Type mm (inches) Enclosure Model Type IP00 SV150, 185iP5A-4L 403.5 261.2 (Built-in DCL Type) (9.84) (7.32) (0.28) (15.88) (15.43) (10.28) UL Type 1 IP20 SV220, 300iP5A-4L 468.5 268.6 (Built-in DCL Type) (10.23)
Page 19 Chapter 2 - Specification SV150 ~ SV300 iP5A (Built-in DCL Type, UL Type 1 or UL Open Type with Conduit Option used, 400V Class) mm (inches) Enclosure Model Type IP20 SV150, 185iP5A-4L 475.5 261.2 188.4 (Built-in DCL Type) (9.84) (7.32) (0.28) (18.72) (15.43)
Page 20 Chapter 2 - Specification 6) SV370 ~ SV550iP5A (400V Class) mm (inches) Enclosure Model Type IP00 265.6 SV370, 450iP5A-4 (11.81) (7.48) (0.35) (21.02) (20.28) (10.46) UL Open IP00 292.6 SV550iP5A-4 (11.81) (7.48) (0.35) (21.02) (20.28) (11.52) UL Open IP00 SV370, 450iP5A-4L 265.6 (11.81) (7.48)
Page 21 Chapter 2 - Specification 7) SV370~550iP5A (UL Type 1 or UL Open Type with Conduit Option Used, 400V Class) mm (inches) Enclosure Model Type IP20 265.6 163.4 SV370, 450iP5A-4 (11.81) (7.48) (0.35) (25.28) (20.28) (10.46) (6.43) UL Type 1 292.6 190.4 IP20 SV550iP5A-4...
Page 22 Chapter 2 - Specification 8) SV750, 900iP5A (400V Class) mm (inches) Enclosure Model Type 586.5 337.6 IP00 SV750, 900iP5A-4 (14.57) (8.66) (0.35) (24.02) (23.09) (13.29) UL Open SV750, 900iP5A-4L 736.6 337.6 IP00 (14.57) (8.66) (0.35) (29.92) (28.99) (13.29) UL Open (Built-in DCL Type) 2-12...
Page 23 Chapter 2 - Specification 9) SV750, 900iP5A (UL Type 1 or UL Open Type with Conduit Option used, 400V Class) mm (inches) Enclosure Model Type 767.5 586.5 337.6 223.4 IP20 SV750,900iP5A-4 (14.57) (8.66) (0.35) (30.22) (23.09) (13.29) (8.8) UL Type 1 SV750, 900iP5A-4L 917.5 736.5...
Page 24 Chapter 2 - Specification 10) SV1100, 1600iP5A (400V Class) mm(inches) Enclosure Model Type 768.5 422.6 IP00 SV1100,1320iP5A-4L (20.08) (15.00) (0.43) (30.26) (29.29) (16.64) UL Open 819.5 422.6 IP00 SV1600iP5A-4L (20.08) (15.00) (0.43) (33.23) (32.26) (16.64) UL Open 2-14...
Page 25 Chapter 2 - Specification 11) SV2200, 2800iP5A (400V Class) mm(inches) Enclosure Model Type 1063 1028 449.6 IP00 SV2200, 2800iP5A-4L (27.17) (22.87) (0.55) (41.85) (40.49) (17.70) UL Open 2-15...
Page 26 Chapter 2 - Specification 12) SV3150, 4500iP5A (400V Class) mm(inches) Enclosure Model Type 1140.5 1110 IP00 SV3150iP5A-4 (30.39) (19.69) (0.51) (19.69) (44.90) (43.70) (17.40) UL Open 1302.5 1271.5 IP00 SV3750,4500iP5A-4 (36.30) (22.83) (0.55) (22.83) (51.28) (50.06) (19.49) UL Open 2-16...
Page 27: Chapter 3 - Installation
CHAPTER 3 - INSTALLATION 3.1 Installation precautions 1) Handle the inverter with care to prevent damage to the plastic components. Do not hold the inverter by the front cover. 2) Do not mount the inverter in a location where excessive vibration (5.9 m/sec or less) is present such as installing the inverter on a press or other moving equipment.
Page 28 Chapter 3 - Installation 6) Do not mount the inverter in direct sunlight or near other heat sources. 7) The inverter shall be mounted in a Pollution Degree 2 environment. If the inverter is going to be installed in an environment with a high probability of dust, metallic particles, mists, corrosive gases, or other contaminates, the inerter must be located inside the appropriate electrical enclosure of the proper NEMA or IP rating.
Page 29: Wiring
Chapter 3 - Installation 3.2 Wiring 3.2.1 Basic wiring 1) For 5.5~30kW (7.5~40HP) Main Power Circuit Dynamic Braking Unit DB Unit(Optional) (Optional) DB Resistor DC Bus Choke (Optional ) P N B1 B2 DC Bus Choke DB Resistor P1(+) P2(+) N(-) MCCB(Option) φ...
Page 30 Chapter 3 - Installation 2) For 37~90kW (50~125HP) / 315~450(400~600HP) Main Power Circuit Dynamic Braking Unit DB Unit(Optional) (Optional) DB Resistor DC Bus Choke (Optional ) P N B1 B2 DC Bus Choke DB Resistor P1(+) P2(+) N(-) MCCB(Option) φ R(L1) MOTOR S(L2)
Page 31 Chapter 3 - Installation 3) For 110~280kW (150~350HP) Main Power Circuit Dynamic Braking Unit DB Unit(Optional) (Optional) DB Resistor P N B1 B2 DB Resistor P2(+) DC Reactor(Built-in φ R(L1) MOTOR S(L2) AC Input T(L3) 50/60 Hz Control Circuit Analog Power Source (+12V) Programmable Digital Input 1(Speed L) Frequency reference (0~12V,V1S : -12~12V) Frequency reference common terminal...
Page 32 Chapter 3 - Installation 4) For 15~30kW (20~40HP) Built-in DCL Type P N B1 B2 DB Resistor P(+) N(-) DC Reactor φ R(L1) Motor S(L2) AC Input T(L3) 50/60 Hz 5) For 37~90kW (50~125HP) Built-in DCL Type P N B1 B2 DB Resistor P1(+) P2(+)
Page 33 Chapter 3 - Installation 6) Power Terminals: (1) 5.5 ~ 30 kW (200V/400V Class) R(L1) S(L2) T(L3) P1(+) P2(+) N(-) Jumper (2) 37~90kW (50~125HP) / 315~450kW (400~600HP) <400V Class> R(L1) S(L2) T(L3) P1(+) P2(+) N(-) Jumper (3) 15~18.5kW (20~25HP) <Built-in DC Reactor Type, 400V Class> R(L1) S(L2) T(L3)
Page 34 Chapter 3 - Installation 7) Control circuit terminal 5.5 ~ 30kW/7.5~40HP (200V/400V Class) C+ CM C- M6 24 M7 M8 A0 B0 5G 5G S0 S1 3A 3C A1 C1 A2 C2 C3 A4 C4 M1 CM M2 M3 24 M4 M5 V+ V1 5G V- I NT 37 ~ 450 kW/ 50~600HP (400V Class) C+ CM C- M6 24 M7 M8...
Page 35 Chapter 3 - Installation Type Symbol Name Description Programmable Defines Programmable Digital Inputs. M1, M2, M3 Digital Input 1, 2, 3 (Factory setting: Multi-Step Frequency 1, 2, 3) Forward Run FX [M7] Forward Run When Closed and Stopped When Open. Command Reverse Run RX [M8]...
Page 36 Chapter 3 - Installation 3.2.2 Wiring power terminals ◈ Wiring Precautions 1) The internal circuits of the inverter will be damaged if the incoming power is connected and applied to output terminals (U, V, W). 2) Use ring terminals with insulated caps when wiring the input power and motor wiring. 3) Do not leave wire fragments inside the inverter.
Page 37 Chapter 3 - Installation 3.2.3 Wires and terminal lugs Refer to below for wires, terminal lugs, and screws used to connect the inverter power input and output. Wire size Screw torque Terminal R(L1), S(L2), T(L3) U, V, W Inverter capacity screw AWG or AWG or...
Page 38 Chapter 3 - Installation Power and Motor Connection Example (5.5~30kW inverters) R(L1) S(L2) T(L3) P1(+) P2(+) N(-) Power supply must be connected to the R(L1), S(L2), Ground and T(L3) terminals. Connecting it to the U, V, and Ground Forward W terminals causes internal damages to the inverter.
Page 39 Chapter 3 - Installation 3) Sink mode(NPN mode) / Source mode(PNP mode) SV-iP5A provides Sink/Source(NPN/PNP) modes for sequence input terminal on the control circuit. The logic of the input terminal is setable to Sink mode(NPN mode) / Source mode(NPN mode) by using the J1 switch.
Page 40 Chapter 3 - Installation 3.2.5 RS485 circuit wiring TER 2 Use C+ (RS485 signal High), C- (RS485 signal LOW) in TER 2. Turn the J3 switch ON (Upward) to connect the termination resistor (120 ohm). J3 switch is on the left side of the TER2. Item Specification Transmission type...
Page 41: Chapter 4 - Operation
CHAPTER 4 - OPERATION 4.1 Programming Keypads 4.1.1 LCD Keypad LCD keypad can display up to 32 alphanumeric characters, and various settings can be checked directly from the display. The following is an illustration of the keypad. The Program Button is 32 character, background used to go into light, LCD display.
Page 42 Chapter 4 - Operation Detail description 1) LCD Keypad Display 3) Frequency Setting Source 2) Run/Stop Source 1) Parameter group 4) Output Current 0.0 A ▶ 0.00 Hz 5) Parameter Code 7) Drive Output Frequency During Run, Command Frequency During Stop 6) Operating Status Displays Description...
Page 43 Chapter 4 – Operation 4.1.2 Parameter setting and changing 1) Press [MODE] key until the desired parameter group is displayed. 2) Press [▲] or [▼] keys to move to the desired parameter code. If you know the desired parameter code, you can set the code number of each parameter group in “Jump code”, except DRV group.
Page 44: Set
Chapter 4 - Operation 4.1.3 Parameter groups The iP5A series inverter has 5 parameter groups separated according to their applications as indicated in the following table. The iP5A series inverter provides two kinds of keypad. One is 32-character alphanumeric LCD keypad and the other is 7-Segment LED keypad.
Page 45 Chapter 4 – Operation 1) Parameter Navigation (LCD Keypad) The parameter group moves directly to DRV group by pressing [SHIFT] key in any parameter code. Drive Group FU1 Group FU2 Group I/O Group MODE Jump code Jump code Jump code DRV▶T/K 0.0 A ▶...
Page 46: Operating Example
Chapter 4 - Operation 4.2 Operating Example 4.2.1 Easy Start Operation Easy Start Operation is activated by pressing STOP key on the Keypad for 2~3 seconds and inverter begins operation via Keypad (FWD/REV RUN/STOP). Drive mode is preset to V/F and reference frequency to JOG.
Page 47 Chapter 4 – Operation Operation Freq Setting via Keypad + Run/Stop via Terminal (FX/RX) Example (1) [Operation condition] -. Control mode: V/F control -. Ref. Frequency: 50[Hz] setting via keypad -. Accel/Decel time: Accel – 10 [sec], Decel – 20 [sec] -.
Page 48 Chapter 4 - Operation 4.2.3 Operation via Control Terminal Setting: DRV-03 [Drive Mode (Run/Stop method)] = 1 (Fx/Rx-1) DRV-04 [Frequency Mode (Freq. setting method)] = 2 (V1) 1) Check the LCD display when Power ON. Otherwise, change the setting correctly as shown above. DRV▶T/V 0.0 A 0.00Hz...
Page 49 Chapter 4 – Operation Operation Analog Voltage Input (V1) + Operation via Terminal (FX/RX) Example (2) [Operation condition] -. Control mode: V/F control -. Reference Frequency: 50[Hz] analog input via V1 (Potentiometer) -. Accel/Decel time: Accel – 10 [sec], Decel – 20 [sec] -.
Page 50 Chapter 4 - Operation 4.2.4 Operation via Keypad Setting: DRV-03 [Drive Mode (Run/Stop method)] = 0 (Keypad) DRV-04 [Frequency Mode (Freq. setting method)] = 0 (Keypad-1) 1) Check the LCD display when Power ON. Otherwise, change the setting as shown above. DRV▶K/K 0.0 A 0.00Hz...
Page 51: Various Function Setting & Description
Chapter 4 – Operation 4.3 Various function setting & Description 4.3.1 Basic function parameter setting It is the basic function setting. All settings are factory defaults unless users make change. It is recommended to use factory setting value unless the parameter change is necessary. 1) Common parameter setting The following table shows common parameter setting that should be checked before use regardless of control mode.
Page 52 Chapter 4 - Operation 4) Sensorless vector control Set FU2-60 to “Sensorless” to enable Sensorless vector control. It is strongly recommended to perform Auto- tuning before starting Sensorless control in order to maximize performance. Parameter Name Code Description Control method selection FU2-60 Select Sensorless.
Page 53 Chapter 4 – Operation 2) Sensorless vector control Related parameters for starting in Sensorless vector control when FU2-60 [Control Mode Selection] is set to Sensorless. Parameter Name Code Description FU2-64 Pre-excitation time setting When starting I/O-20~27 Programmable Digital Input terminals define 3) Parameters to monitor motor and inverter status Parameter Name Code...
Page 54 Chapter 4 - Operation 6) Protection & Trip level setting Parameter Name Code Description FU1-60 Protection of the motor from overheating without the use FU1-61 Electronic thermal of external thermal relay. Refer to parameter descriptions FU1-62 for more detail. FU1-63 FU1-64 FU1-65 Warning alarm outputs and displays the trip message...
Page 55 Chapter 4 – Operation 4.3.3 Application function setting 1) PID operation Inverter can be used to exercise process control, e.g. flow rate, air volume or pressure via PID feedback control. Parameter Name Code Description PID control setting APP-02 ~ APP-17 Parameters for PID control setting ☞...
Page 56 Chapter 4 - Operation 5) Jog and Multi-speed operation Parameter Name Code Description If I/O-20 ~27 are set to Speed-H, Speed-M, Multi function input I/O-20 ~27 Speed-L, multi- speed operation up to speed 17 is terminal setting available. Filter time constant Effective for eliminating noise in the freq.
Page 57: Operation Example
Chapter 4 – Operation 4.4 Operation Example V/F Control + Analog Voltage Input (V1) + Operation via Terminal Operation (FX/RX) Example (1) [Operation condition] -. Control mode: V/F control -. Frequency command: 50[Hz] analog input via V1 terminal -. Accel/Decel time: Accel – 15 [sec], Decel – 25 [sec] -.
Page 58 Chapter 4 - Operation Operation motor operation Example (2) [Operation condition] -. Control mode: V/F control -. 1 motor + 2 motor Operation by exchange using [2 Func] (Set Value different) -. Frequency command: Using Multi-step operation 1 motor --- 50[Hz] as main speed motor --- 20[Hz] with M1 terminal set as multi- step operation) -.
Page 59 Chapter 4 – Operation Operation V/F control + Analog input (V1S) + Operation via terminal FX/RX Example (3) [Operation condition] -. Control mode: V/F control -. Frequency command: Setting 50[Hz] via Analog input (V1S) -. Accel/Decel time: Accel time 15 [sec], Decel time 25 [sec] -.
Page 60 Chapter 4 - Operation ☞ Note: If the inverter is operated without wiring a motor, trip occurs as below because the protection function is active automatically. In this case, refer to the related parameters(FU1 57 ~ 59). Trip is reset if the inverter is powered down and up once again.
Page 61: Chapter 5 - Parameter List
Chapter 5 – Parameter List CHAPTER 5 - PARAMETER LIST 5.1 Parameter groups The parameters of SV-IP5A Series are divided into 5 function groups in accordance with the application. Their names, principal contents and LCD keypad displays are shown below. Name of Group LCD Keypad Display Description...
Page 62: Parameter List
Chapter 5 – Parameter List 5.2 Parameter list [DRV Group] Adj. Comm. LCD Keypad Factory CODE Description Setting Range During Page Addr Display Default Command Frequency (Output Frequency during DRV-00 9100 Cmd. freq 0 to FU1-30[Hz] 0 [Hz] motor run, Reference Frequency during motor stop), Output Current (LCD) 5.5~90kW...
Page 63 Chapter 5 – Parameter List Adj. Comm. LCD Keypad Factory CODE Description Setting Range During Page Addr Display Default The gray-highlighted codes are hidden parameters and will appear when the related functions are to be set. (1) The speed unit is changed from [Hz] to [%] when DRV-16 is set to [Rpm]. Only User Unit will be displayed when APP-02 is set to [Yes] and when APP-06 is set to either I, V1 or Pulse and when one of I/O-86~ I/O-88 is set to either [Speed], [Percent], [Bar], [mBar], [kPa] or [Pa].
Page 64 Chapter 5 – Parameter List [FU1 GROUP] Adj. Comm. LCD Keypad Factory CODE Description Setting Range During Page Addr Display Default 1 to 74 FU1-00 9200 Jump to Desired Code # Jump code (Use Only LCD 6-10 Keypad) (None) FU1-01 9201 Run Prevention Run prevention...
Page 65 Chapter 5 – Parameter List Adj. Comm. LCD Keypad Factory CODE Description Setting Range During Page Addr Display Default FU1-34 9222 Low Limit Frequency F-limit Lo FU1-32 to FU1-35 0.5 [Hz] 6-16 FU1-34 FU1-35 9223 High Limit Frequency F-limit Hi 60 [Hz] to FU1-30 (Linear)
Page 66 Chapter 5 – Parameter List Adj. Comm. LCD Keypad Factory CODE Description Setting Range During Page Addr Display Default (0.01 sec) FU1-74 924A Accel/Decel Time Scale Time scale (0.1 sec) 1 (0.1 sec) 6-23 (1 sec) FU1-90 925A Safety STOP Inertia Rate STOP Inertia 1 to 9999 6-23...
Page 67 Chapter 5 – Parameter List [FU2 GROUP] Adj. Comm. LCD Keypad Factory CODE Description Setting Range During Page Addr Display Default 1 to 95 FU2-00 9300 Jump to desired code # Jump code (Use Only LCD 6-24 Keypad) By pressing [PROG] FU2-01 9301 Last trip 1...
Page 68 Chapter 5 – Parameter List Adj. Comm. LCD Keypad Factory CODE Description Setting Range During Page Addr Display Default 0 (0.75kW) 1 (1.5kW) 2 (2.2kW) 3 (3.7kW) 4 (5.5kW/) 5 (7.5kW/) 6 (11.0kW) 7 (15.0kW) 8 (18.5kW) 9 (22.0kW) 10 (30.0kW) * Depending Rated Motor Selection 11 (37.0kW)
Page 69 Chapter 5 – Parameter List Adj. Comm. LCD Keypad Factory CODE Description Setting Range During Page Addr Display Default 0 to (depending on * Depending 933F 6-32 Leakage Inductance of Motor Lsigma FU2-63 FU2-40) [mH] on FU2-40 * Automatically set corresponding to motor rating. If different, check the motor rating setting. FU2-64 9340 Pre-excitation Time...
Page 70 Chapter 5 – Parameter List [I/O GROUP] Adj. Comm. LCD Keypad Factory CODE Description Setting Range During Page Addr Display Default 1 to 98 9400 I/O-00 Jump to desired code # Jump code 6-37 (LCD Keypad Only) I/O-01 Filtering Time Constant for 9401 V1 filter 0 to 9999 [msec]...
Page 71 Chapter 5 – Parameter List Adj. Comm. LCD Keypad Factory CODE Description Setting Range During Page Addr Display Default 0 (Speed-L) 1 (Speed-M) 2 (Speed-H) 3 (XCEL-L) 4 (XCEL-M) 5 (XCEL-H) 6 (Dc-brake) 7 (2nd Func) 8 (Exchange) 9 (- Reserved -) 10 ( Up) 11 (Down) 12 (3-Wire)
Page 72 Chapter 5 – Parameter List Adj. Comm. LCD Keypad Factory CODE Description Setting Range During Page Addr Display Default Programmable Digital Input I/O-26 941A M7 define Same as I/O-20 30 (FX) Terminal ‘M7’ Define Programmable Digital Input I/O-27 941B M8 define Same as I/O-20 31 (RX) Terminal ‘M8’...
Page 73 Chapter 5 – Parameter List Adj. Comm. LCD Keypad Factory CODE Description Setting Range During Page Addr Display Default I/O-71 9447 S0 output adjustment S0 adjust 10 to 200 [%] 100 [%] 9448 I/O-72 S1 output selection S1 mode Same as I/O-70 2 (Voltage) 6-47 9449...
Page 74 Chapter 5 – Parameter List Adj. Comm. LCD Keypad Factory CODE Description Setting Range During Page Addr Display Default 1 (Run Fan) 9454 I/O-84 Fan Con Sel (37 ~ 90kW) Fan Mode 6-52 2 (Temper-Fan) 9455 I/O-85 Fan Temp (37 ~ 90kW) Fan Temper 0 to 70 [℃] 70 [℃]...
Page 75 Chapter 5 – Parameter List [APP GROUP] Adj. Comm. LCD Keypad Factory CODE Description Setting Range During Page Addr Display Default 1 to 99 APP-00 9700 Jump to Desired Code # Jump code 6-56 (LCD Keypad Only) APP-01 0 (None) 9701 Application Mode Selection App mode...
Page 76 Chapter 5 – Parameter List Adj. Comm. LCD Keypad Factory CODE Description Setting Range During Page Addr Display Default 2nd Electronic Thermal APP-27 971B 2nd ETH 1min FU2-28 to 200 [%] 130[%] Level for 1 minute 2nd Electronic Thermal 50 to FU2-27 6-62 APP-28 971C...
Page 77 Chapter 5 – Parameter List Adj. Comm. LCD Keypad Factory CODE Description Setting Range During Page Addr Display Default Decel time when the number APP-61 Pid DecTime 0 to 600.0 [sec] 2.0 [sec] 6-65 973D of pump increases 0 (No) APP-62 PID Bypass Selection Regul Bypass...
Page 78 Chapter 5 – Parameter List Adj. Comm. LCD Keypad Factory CODE Description Setting Range During Page Addr Display Default 0 (No) APP-95 ExtPID Output Inverse ExtOut inverse 0 (No) 6-70 975F 1 (Yes) APP-97 ExtPID Loop Time Ext Loop Time 50 to 200 [msec] 100 [msec] 6-70...
Page 79 Chapter 5 – Parameter List [EXT GROUP] Adj. Comm. LCD Keypad Factory CODE Description Setting Range During Page Addr Display Default EXT-00 9500 Jump Code Jump code 1 to 45 EXT-01 9501 Type of SUB Board Sub B/D Sub-E Frequency Current Current Output AM1 mode...
Page 80 Chapter 5 – Parameter List [COM GROUP] Adj. Comm. LCD Keypad Factory CODE Description Setting Range During Page Addr Display Default COM-00 9600 Jump Code Jump code 1 to 60 RS485 DeviceNet ProfiBus COM-01 9601 Type of SUB Board Opt B/D BACnet LonWork None...
Page 81: Chapter 6 - Parameter Description
CHAPTER 6 - PARAMETER DESCRIPTION DRV-04 [Frequency Mode] setting guide 6.1 Drive group [DRV] Name Programming Description DRV-00: Command Frequency/ Output Current 1. In DRV-00, press the [PROG] (LCD) key. DRV► Cmd. Freq 2. Set the desired freq. 0.00 Pad-1 0.00 Hz 3.
Page 82 Chapter 6 - Parameter Description [DRV] In the case of 0~12V V1 voltage input I/O-01~05 [Frequency command setting via Analog Voltage Input “ V1”] Set freq. (target value) Command Freq. setting via “V1” input terminal when I/O-05 set DRV-04 [Frequency mode] to V1, V1S, or V1+I. A User-selected unit will be displayed in [**] when one of the APP-02[PID operation selection] and APP-80 [Ext.
Page 83 Chapter 6 - Parameter Description [DRV] To drive the motor in Forward direction, press FWD Set freq (target value) key and apply 0-12V voltage as frequency command or press REV key and apply –12~0V voltage as I/O-10 frequency command. To drive the motor in Reverse direction, press FWD key and apply –12~0V or press REV key and apply 0~12V.
Page 84 Chapter 6 - Parameter Description [DRV] DRV-03: Drive Mode (Run/Stop Method) XCEL XCEL XCEL Code Name Default display DRV► Drive mode Acc time DRV-01 Acc time 20 sec Fx/Rx-1 Dec time DRV-02 Dec time 30 sec Factory Default: Fx/Rx-1 Select the source of run/stop command. Acc time I/O-50 ACC-1...
Page 85 Chapter 6 - Parameter Description [DRV] Apply the frequency reference Binary Input Combination Output Step (4~20mA) to the “I” control terminal. Speed- Speed- Speed- Frequency Speed Refer to the I/O-06 to I/O-10 for scaling the signal. DRV-00 Speed 0 Apply the frequency reference DRV-05 Speed 1 (0~12V, 4~20mA) to the “V1”,“I”...
Page 86 Chapter 6 - Parameter Description [DRV] Motor speed = 120 * (F/P) * FU2-47 [Fault Contents] Where, F= Output Frequency and P= the Number of Motor Poles Fault (Trip) LCD Keypad display Over-Current 1 Over Current 1 DRV-10: DC Link Voltage Over-Voltage Over Voltage External Trip Input...
Page 87 Chapter 6 - Parameter Description [DRV] DRV-13: Motor Direction Set (7-Segment Keypad) Ex1) When [mBar] is set DRV▶REF 500.0mBa FBK 82.1mBa Factory Default: This code sets the motor direction when using the 7- Segment keypad. DRV-14: Command/Output Frequency Display (LCD Keypad) DRV►TAR 0.00Hz 14 OUT...
Page 88 Chapter 6 - Parameter Description [DRV] DRV-16: Hz/Rpm Display R 50.00%T 45.3Hz DRV► Hz/Rpm Disp F 8.24%O 43.7Hz 0 Hz Factory Default: 0 Hz Set this parameter to 0 [Hz] to display frequency, or to 1[Rpm] to display speed. DRV-18: PID Parameter (To monitor PID controller’s Reference/Feedback value and Inverter’s Command/output frequency) Displays PID controller’s reference/feedback value...
Page 89 Chapter 6 - Parameter Description [DRV] DRV-20: EXT-PID Parameter (To monitor ExtPID controller’s reference/ feedback/ output value) Displays ExtPID controller’s reference/ feedback/ output value. When APP-80 [Ext. PID operation selection] is set to “YES,” reference and feedback are displayed in Percent unit.
Page 90: Function 1 Group [Fu1]
Chapter 6 - Parameter Description [FU1] Different combinations of acceleration and 6.2 Function 1 Group [FU1] deceleration patterns can be selected according to the FU1-00: Jump to Desired Code # application. FU1► Jump code Setting Range Description A general pattern for constant torque Linear applications.
Page 91 Chapter 6 - Parameter Description [FU1] time * Starting Curve ratio/2 + Preset decel time * Pre-heat function is activated when FU1-10 [Pre- Ending curve ratio/2 heat] is set to “Yes”, one of the Programmable digital input terminals in I/O-20~27 set to “Pre-heat” and the Output Frequency defined terminal is turned ON.
Page 92 Chapter 6 - Parameter Description [FU1] Inverter starts acceleration after FU1-21 [Starting DC FU1-20: Start Mode Magnetizing Time] while FU1-22 [Starting DC FU1-21: Starting DC Magnetizing Time Magnetizing Voltage] is operated. FU1-22: Starting DC Magnetizing Value Code LCD Display Default Setting FU1-21 DcSt time...
Page 93 Chapter 6 - Parameter Description [FU1] FU1-23: Stop Mode Output Frequency FU1► Stop mode Decel Factory Default: Decel Sets the stopping method for the inverter. Time Output Voltage Setting Range Description Inverter stops by the deceleration Decel pattern. Inverter stops with DC injection braking.
Page 94 Chapter 6 - Parameter Description [FU1] Output Frequency FU1-24: DC Injection Braking Hold Time FU1-25: DC Injection Braking Frequency FU1-26: DC Injection Braking Time FU1-27: DC Injection Braking Value [DCBr Freq] Time FU1► DcBlk time 0.10 0.10 sec Output Voltage t1: FU1-24 0.10 Factory Default:...
Page 95 Chapter 6 - Parameter Description [FU1] Stop Function, see FU1-90[Safety Stop Inertia Rate]. Output Voltage ☞ Caution: This function is effective for high Rated Voltage load inertia. FU1-29: Line Frequency FU1► Line Freq Output 60.00 Frequency 60.00 Hz FU1-32. FU1-31. FU1-30 60.00 Factory Default:...
Page 96 Chapter 6 - Parameter Description [FU1] This is the pattern of voltage/frequency ratio. Select FU1-33: Frequency Limit Selection the proper V/F pattern according to the load. The FU1-34: Low Limit Frequency motor torque is dependent on this V/F pattern. FU1-35: High Limit Frequency [Linear] pattern is used where constant torque is FU1►...
Page 97 Chapter 6 - Parameter Description [FU1] FU1-41 ~ FU1-48: User V/F Frequency and Voltage FU1-49: AC Input Voltage Adjustment FU1► VAC 440.0V FU1► User freq 1 100.0 15.00 100.0 % 15.00 Hz 100.0 Factory Default: 100.0 % 15.00 Factory Default: 15.00 Hz It should be set correctly when inverter input voltage FU1►...
Page 98 Chapter 6 - Parameter Description [FU1] FU1-51~52: Energy Save, Energy Save Level FU1-54: Integrating Wattmeter FU1► Energy save Displays both MWh and kWh in FU1-54. None Ex) 1500 kWh FU1▶KiloWattHour Factory Default: 1M 00.0kWh Max Cumulative value is displayed in FU1-54 FU1►Manual save% as shown below.
Page 99 Chapter 6 - Parameter Description [FU1] FU1-57: No Motor Sel FU1-60: Electronic Thermal (Motor i t) Selection FU1-58: No Motor Level FU1-61: Electronic Thermal Level for 1 Minute FU1-59: No Motor Time FU1-62: Electronic Thermal Level for Continuous FU1-63: Electronic Thermal Characteristic (Motor type) selection FU1►...
Page 100 Chapter 6 - Parameter Description [FU1] and accumulates the value to protect the motor. FU1► Motor type Self-cool FU1-64: Overload Warning Level Factory Default: Self-cool FU1-65: Overload Warning Time To make the ETH function (Motor i t) work correctly, FU1► OL level the motor cooling method must be selected correctly 110 % according to the motor.
Page 101 Chapter 6 - Parameter Description [FU1] FU1-66: Overload Trip Selection FU1-69: Input/Output Phase Loss Protection FU1-67: Overload Trip Level (Bit Set) FU1-68: Overload Trip Delay Time FU1► Trip select FU1► OLT select 66 --- No --- Factory Default: 1 00 Factory Default: This function is used to cut the inverter output off in case of phase loss in either input power or inverter...
Page 102 Chapter 6 - Parameter Description [FU1] Note: FU1-71 is set as the percentage of FU2-43 Output Current [Rated Motor Current]. Note: Do not set the FU1-71 higher than inverter FU1-71 [Stall Level] rated current. Time Note : Stall level will be automatically reduced if inverter is operated at the frequency higher than FU1-71 [Stall Level]...
Page 103 Chapter 6 - Parameter Description [FU1] Max. Frequency Accel/Decel Next target freq Change Output Frequency Frequency Certain freq DRV-01 [AccTime0] DRV-02 [DecTime0] I/O-50 [Acc Time1] I/O-51 [Dec Time1] Decel time Accel time [FU1-73: Delta Freq] [Accel/Decel Change Operation] FU1-74: Accel/Decel Time Scale FU1-73: Reference Frequency for Accel/Decel FU1►...
Page 104: Function 2 Group [Fu2]
Chapter 6 - Parameter Description [FU2] Note: There are WDOG error, EEP error, and 6.3 Function 2 Group [FU2] ADC Offset for the inverter Hardware Fault, and FU2-00: Jump to desired code # the inverter will not reset when H/W fault occurs. Repair the fault before turning on the power.
Page 105 Chapter 6 - Parameter Description [FU2] Output Frequency FU2-10 ~ FU2-16: Frequency Jump Freq. Max FU2-16 FU2-15 FU2► Jump freq 10 --- No --- FU2-14 FU2-13 Factory Default: FU2-12 FU2-11 Reference FU2► jump lo 1 Frequency 10.00 10.00 Hz [Frequency Jump] 10.00 Factory Default: 10.00 Hz...
Page 106 Chapter 6 - Parameter Description [FU2] Input Power Power On FU2-21: Restart After Fault Reset Time FU2► RST restart Output Frequency Factory Default: Time If FU2-21 is set to ‘No’, restart the inverter by Start cycling the FX or RX terminal to CM terminal after the fault has been reset.
Page 107 Chapter 6 - Parameter Description [FU2] Caution: If I gain is set too high, Overshoot FU2-22: Speed Search Selection (Bit Set) may occur, leading to OV Trip. In this case, FU2-23: P Gain During Speed Search reduce I Gain value. FU2-24: I Gain During Speed Search FU2►Speed Search Input Power...
Page 108 Chapter 6 - Parameter Description [FU2] CAUTION FU2-25: Number of Auto Retry FU2-26: Delay Time Before Auto Retry Particular attention must be directed to this function as motor restarts automatically after the FU2►Retry number fault is reset. Otherwise, it may result in personal damage.
Page 109 Chapter 6 - Parameter Description [FU2] FU2►Inertia rate This is used in ‘Slip Compensation’ control. If you set this value incorrectly, motor may stall during slip compensation control. (See motor nameplate) Factory Default: FU2► Rated-Curr 19.7 This parameter is used for sensorless control, 19.7 A Minimum Accel/Decel, Optimum Accel/Decel and Speed search.
Page 110 Chapter 6 - Parameter Description [FU2] Caution: Reducing the Carrier frequency may Code Factory Default Setting range increase noise. Display 5.5 ~ 22 kW 0.7 ~ 15 [kHz] 5 [kHz] Caution: When 2 {Low leakage} is selected 30 kW 0.7 ~ 10 [kHz] FU2- Carrier while carrier frequency is set lower than 2.0 kHz...
Page 111 Chapter 6 - Parameter Description [FU2] Use a motor capacity that is equal to or one FU2-40~46 [Motor parameters] is automatically determined by FU2-40 [Motor selection]. Most horsepower level lower than the inverter suitable motor capacity corresponding inverter capacity. capacity is set as factory setting, but the following parameters can be adjusted if necessary.
Page 112 Chapter 6 - Parameter Description [FU2] resistance] is set twice more than auto-tuned FU2-64: Pre-excitation Time value. [Detail Tuning Method for Sensorless Vector FU2► PreExTime Control] 1.0 sec Adjust the FU2–44 [No Load Motor Current Factory Default: 1.0 sec (RMS)] value larger or smaller by 5% units if the current is larger or smaller than that of V/F control under small load.
Page 113 Chapter 6 - Parameter Description [FU2] FU2-65: P Gain for Sensorless Control FU2-67: Manual/Auto Boost Selection FU2-66: I Gain for Sensorless Control FU2-68: Torque Boost in Forward Direction FU2-69: Torque Boost in Reverse Direction FU2► SL P-gain 1000 1000 FU2►Torque boost Manual 1000 Factory Default:...
Page 114 Chapter 6 - Parameter Description [FU2] FU2-80: Power On Display Note: It is possible to occur No Motor Trip in case that the torque boost value is 0 when DC Start is operated. FU2►PowerOn disp [Auto Torque Boost] Factory Default: When FU2-67 [Manual/Auto torque boost select] is set to “Auto”, inverter outputs high starting torque by This code selects the parameter to be displayed first...
Page 115 Chapter 6 - Parameter Description [FU2] FU2-82: Software Version FU2-90: Parameter Display FU2► Para. disp FU2► S/W Version Default Ver X.X Factory Default: Default Factory Default: Ver. X.X Displays the software version. This will vary It is used to change the parameters to be viewed. FU2-90 depending on software version integrated.
Page 116 Chapter 6 - Parameter Description [FU2] 1) Set FU2-91 to “Yes” and press Enter key to read FU2-94: Parameter Lock the parameters. FU2► Para. lock FU2► Para. read 91 --- Yes --- Factory Default: This function is used to lock the parameters from 2) Take the LCD being changed.
Page 117: Input/Output Group [I/O]
Chapter 6 - Parameter Description [I/O] 6.4 Input/Output Group [I/O] I/O-00: Jump to Desired Code # This is the minimum voltage of the V1 input at which inverter outputs minimum frequency. I/O► Jump code I/O► V1 freq y1 0.00 0.00 Hz Factory Default: 0.00 Factory Default:...
Page 118 Chapter 6 - Parameter Description [I/O] I/O-06 ~ I/O-10: Analog Current Input (I) Signal input on the ‘I’ terminal. Adjustment I/O► I curr x2 20.00 20.00 mA This is used to adjust the analog current input signal when the terminal ‘I’ references the frequency. This 20.00 Factory Default: 20.00 mA...
Page 119 Chapter 6 - Parameter Description [I/O] I/O-11~16: Frequency command setting via pulse Pulse information Default Setting range (A0/B0) High: +3~+12V Max A Pulse Input Low: +2.5V Max I/O► P pulse set Max Input Freq.: 100KHz High: +3~+12V Max B Pulse Input Low: +2.5V Max Factory Default: ( A)
Page 120 Chapter 6 - Parameter Description [I/O] EX) To give 60Hz (1800 rpm) command from 1000 Pulse encoder Setting Range Description None Disabled. I/O-15 [Max Freq of P Pulse Input]=Rated rpm/60 The inverter determines that the sec * Number of Encoder Pulse frequency reference is lost when the = 1800 [rpm]/60[sec]*1000=3000Hz, half of x1...
Page 121 Chapter 6 - Parameter Description [I/O] I/O-20~27: Programmable Digital Input Terminal Selection of M1, M2, M3 M4, M5, M6, M7, M8 in ‘M1, M2, M3’, ‘M4’, ‘M5’, ‘M6’, ‘M7’, ‘M8’ Define I/O-20~27 Setting Range Description I/O► M1 define Speed-L Multi-step speed - Low Speed-L Speed-M Multi-step speed - Mid...
Page 122 Chapter 6 - Parameter Description [I/O] I/O-28: Terminal Input Status I/O-31~42: Step Frequency 4, 5, 6, 7, 8, 9, 10, 11, 12, 13, 14, 15 I/O► In status 0000 00000000000 I/O► Step freq-4 40.00 40.00 Hz 0000 Factory Default: 00000000000 40.00 Factory Default: 40.00 Hz...
Page 123 Chapter 6 - Parameter Description [I/O] DRV-04 Data DRV-00 Speed 0 Freq source Step speed Spd- Spd- Spd- Spd- Code Keypad-1 Digital Freq Ref Keypad Frequency Keypad-2 Digital Freq Ref Keypad DRV- S. Freq-0 (Zero Spd) Analog Freq Ref. Terminal I/O-30 Jog Freq Analog Freq Ref.
Page 124 Chapter 6 - Parameter Description [I/O] I/O-50~63: 1 Accel/Decel Time Output Frequency Ref. I/O► Acc time-1 Freq. 20.0 20.0 sec 20.0 Factory Default: 20.0 sec Time I/O► Dec time-1 Time Time Time Time Time Time Time Time 20.0 20.0 sec Time 20.0 Factory Default:...
Page 125 Chapter 6 - Parameter Description [I/O] Note: I/O-29 [Filtering Time Constant for [3-Wire] Programmable Digital Input Terminals] must be This function is for 3-wire start/stop control. set to more than 100 [msec] to prevent chattering This function is mainly used with a momentary push button to hold the current frequency output during and momentary malfunction during this function.
Page 126 Chapter 6 - Parameter Description [I/O] [Main-drive] [Interlock 1, 2, 3, 4] When an option board or embeded RS485 This function is used for MMC operation. When communication is used for the frequency setting and MMC is selected in APP-01 and interlock is set, M1, the run/stop command setting, and the setting is ON, M2, M3 and M4 are automatically assigned for the inverter operation can be changed to Option (or...
Page 127 Chapter 6 - Parameter Description [I/O] I/O-70~73: S0, S1 terminal select S0/S1 terminal outputs External PID output. The output value is determined by, S0/S1 output voltage= (External PID output/10000) * I/O► S0 mode 10V * S0,S1 output gain(I/O-71,73) / 100 Frequency Factory Default: Note: Maximum DC Link Voltage for 200V class...
Page 128 Chapter 6 - Parameter Description [I/O] I/O-76~79: Auxiliary Contact [FDT-1] Programmable Digital Output mode 1, 2, 3, 4 define (AX-CX) When the output frequency reaches the reference frequency (target frequency), AX-CX terminal is I/O► Aux mode1 CLOSED. None Detecting Condition: Value (Ref. Freq-Output Freq)<= Freq Detection Bandwidth (I/O-75)/2 Factory Default: None...
Page 129 Chapter 6 - Parameter Description [I/O] [FDT-5] Output Frequency This is the inverted output of [FDT-4]. Detecting Condition: During Accel: Output freq >= Freq Detection During Decel: Output freq > (Freq Detection (I/O-74) - I/O-74 I/O-75/ 2 Freq Detection Bandwidth (I/O-75)/2) Output Frequency Time AX-CX...
Page 130 Chapter 6 - Parameter Description [I/O] [IOL] DC Link Voltage AX-CX is CLOSED when the output current is above OV Level (380V DC or 760V DC) the 110% of rated inverter current for 60 seconds. If this situation is continued for one minute, the inverter will cut off its output and displays ‘IOL’...
Page 131 Chapter 6 - Parameter Description [I/O] [Steady] [Ssearch] AX-CX is CLOSED when the inverter is running at AX-CX is CLOSED during the inverter is speed constant speed. searching. [INV line, COMM line] [Ready] This function is used in conjunction with ‘Exchange’ AX-CX is CLOSED when the inverter is ready to run.
Page 132 Chapter 6 - Parameter Description [I/O] I/O-81: Terminal Output Status I/O-84: Cooling Fan Control Selection I/O►Fan Con. Sel I/O► Out status 0000 PowerOn_Fan 00000000 0000 Factory Default: 00000000 Factory Default: PowerOn_Fan This code displays the output status of control I/O-84 Description terminals.
Page 133 Chapter 6 - Parameter Description [I/O] [PID operation selection], APP-80 [Ext. PID 485”. operation selection] and APP-62 [PID Bypass In this case, the LCD display shows “LOR”. selection]. Then, set one of the desired unit among I/O-93 [Communication time out] determines Percent, Bar, mBar, kPa, and Pa in I/O-86, 86, 88.
Page 134 Chapter 6 - Parameter Description [I/O] I/O-96: Input Checking Time I/O-97: Overheat Trip Selection I/O► OH Trip Sel I/O► In CheckTime 1 ms Factory Default: Factory Default: 1 ms I/O► MO Trip Temp When Multi-step speed or Multi-Accel/Decel operation is active, inverter determines the input to be 110 [ °...
Page 135 Chapter 6 - Parameter Description [I/O] Specification of External PTC/NTC Thermistor Resistance Measurable Sensor Resistance by temperature based on 25 Temp range R(T)=[1+A*(Measured temp-25)+B *( Measured temp - ( 5%) ][ ] 0~125[ ] A=7.635X10 , B=1.371 X10 2.545 ( 5%) See the table below for NTC resistance by temperature. 0~150[ ] Note : Measurable temp range varies by thermal sensors.
Page 136: Application Group [App]
Chapter 6 - Parameter Description [APP] to eliminate the deviation. In other words, this control 6.5 Application group [APP] matches the feedback amount with the target value. APP-00: Jump to desired code # For HVAC or Pump applications, the PID control can APP►...
Page 137 Chapter 6 - Parameter Description [APP] Parameter setting example for PID operation Set APP-02 [PID operation selection] to “Yes.” Set APP-06 [PID feedback selection] among I, V1 and Pulse. Set the unit to view feedback value in I/O-86~88 [User unit selection]. Then, all the unit related to inverter target frequency is changed.
Page 138 Chapter 6 - Parameter Description [APP] 6-58...
Page 139 Chapter 6 - Parameter Description [APP] In general, the PID output becomes inverter’s “Target Freq”. In this case, PID is controlling the whole system and the PID output becomes the target freq of the system and inverter is operating according to Accel/Decel Time.
Page 140 Chapter 6 - Parameter Description [APP] PID Wiring Example R(L1) Power S(L2) Supply T(L3) PUMP FWD Run/Stop REV Run/Stop PID Control Selection (Setting: Open-loop) Common Terminal Power for Speed Signal (OUT) (COM) (24V) (+12V, 10mA) Target freq Main Speed Signal Input setting V+, V1, I Common Feed back Reference...
Page 141 Chapter 6 - Parameter Description [APP] APP-03: PID F Gain APP-06: PID Feedback Signal Selection APP-04: PID Aux. Reference Mode Selection APP-07: P Gain for PID Control APP-05: PID Aux. Reference Selection APP-08: I Time for PID Control APP-09: D Time for PID Control APP-10: High Limit Frequency for PID Control APP►...
Page 142 Chapter 6 - Parameter Description [APP] 60.00 Factory Default: 60.00 Hz PID output value can be set to ‘0’ by setting a This is the frequency upper limit at which the output Programmable digital input terminals (M1 ~ M8) to frequency is limited during PID control.
Page 143 Chapter 6 - Parameter Description [APP] [MMC]: The ‘PID’ control should be selected in Description Functions Functions APP-02 to use this function. DRV-01 APP-20 Acceleration time [Acc. time] [2nd Acc time] ♦ One inverter can control multiple motors. This DRV-02 APP-21 Deceleration time function is often used when controlling the rate and...
Page 144 Chapter 6 - Parameter Description [APP] Line APP► Start freq2 49.99 Power 49.99 Hz Aux. Motor 1 49.99 Factory Default: 49.99 Hz iP5A RLY1 Aux. Motor 2 RLY2 APP► Start freq6 Aux1 49.99 49.99 Hz RLY3 Aux 2 Aux. Motor 3 Aux 3 49.99 Factory Default:...
Page 145 Chapter 6 - Parameter Description [APP] APP-58: Delay Time before Starting Aux. Motor APP-62: PID Bypass Selection APP-59: Delay Time before Stopping Aux. Motor APP-60, 61: Accel/Decel time when the number of APP► Regul Bypass pumps is increasing/decreasing Factory Default: APP►...
Page 146 Chapter 6 - Parameter Description [APP] APP-63: Sleep Delay Time To use MMC operation APP-64: Sleep Frequency A. Set MMC in APP-01 APP-65: Wake-Up Level B. Set Process PI to Yes in APP-02 APP► Sleep Delay C. Set Pre PID operation enable/disable 60.0 60.0 sec a.
Page 147 Chapter 6 - Parameter Description [APP] APP-66: Auto Change Mode Selection APP-67: Auto Change Time APP-68: Auto Change Level APP► AutoCh_Mode APP► AutoEx-intv 72:00 72:00 Factory Default: 72:00 Factory Default: 72:00 This function is used to change the running order of APP►...
Page 148 Chapter 6 - Parameter Description [APP] APP-69: Interlock Selection APP► Inter-lock 3 Phase Input R S T Factory Default: K1.1 K2.2 iP5A U V W When APP-69 [Interlock selection] is set to “Yes”, M1~M4 can be used as the same activating condition for AX1~AX4.
Page 149 Chapter 6 - Parameter Description [APP] Aux motor starting condition and output Aux motor stopping condition and output (Pressure, air volume..) adjustment (Pressure, air volume..) adjustment Inverter turns Aux motors ON automatically when it Inverter turns off the Aux motors when flow rate or is impossible for a main motor to control increased flow pressure is too large due to decreased load.
Page 150 Chapter 6 - Parameter Description [APP] APP-71: Pressure Difference for Aux Motor Stop though time set in APP-76 elapses, inverter signals system malfunction. It is also user-settable to fit for APP► Aux Pr Diff the system in use. APP-80~97: External PID operation Factory Default: APP►...
Page 151 Chapter 6 - Parameter Description [APP] APP –82 [Ext PID Ref value] is settable when APP- 81 [Ext PID Ref selection] is set to “Keypad”. APP–97 [Ext PID Loop Time] sets the time to activate Ext PID controller. Set the desired value according to system.
Page 152 Chapter 6 - Parameter Description [APP] 6-72...
Page 153 Chapter 6 - Parameter Description [APP] [Ext. PID internal block diagram] Multi-function Input Terminal Setting I/O-20~27 (M1~M8) I Term Clear P Gain2 Deviation Target Freq. Ext PID P Gain Scale APP-92 APP-85 Ext PID P Gain APP-86 Ext PID I Gain APP-87 Ext PID D Gain Ext PID P2 Gain...
Page 154 Chapter 6 - Parameter Description [APP] APP-02 , APP-80 (to use Dual PID operation) ExtPID can be used in the following three cases; controlling other system independently like an external PID controller using both PID controller in APP-02 and External PID controller using ExtPID output as an Inverter target frequency.
Page 155 Chapter 6 - Parameter Description [APP] Analog Input (V1, I, or Pulse) and perform terminal wiring for analog input. To give the digital reference, set APP-81 [Ext. Ref Sel] to “Keypad” and set proper value in APP-82 [Ext. Ref Perc]. Set the Ext. PID Feedback among V1, I, Pulse in APP-83 and perform terminal wiring for analog input.
Page 156 Notes :...
Page 157: Chapter 7 - Troubleshooting & Maintenance
CHAPTER 7 - TROUBLESHOOTING & MAINTENANCE 7.1 Fault Display When a fault occurs, the inverter turns off its output and displays the fault status in DRV-12. The last 5 faults are saved in FU2-01 through FU2-05 with the operation status at the instance of fault. Protective Keypad Display Description...
Page 158 Chapter 7 - Troubleshooting & Maintenance Protective Keypad Display Description Function According to the I/O-48 [Operating Method when the Frequency Reference is Lost] setting, there are three modes: continuous operation, decelerate to stop, and Operating free run, Method when LOP: Displayed when option frequency reference is lost (DPRAM time out) the Frequency LOR: Displayed when option frequency reference is lost (Communication Reference is...
Page 159: Fault Remedy
Chapter 7 - Troubleshooting & Maintenance Fault Remedy Protective Cause Remedy Function Acceleration/Deceleration time is too short compared 1) Increase Accel/Decel time. to the GD of the load. 2) Increase inverter capacity. Load is larger than the inverter rating. 3) Operate after motor has stopped. Inverter turns output on when the motor is free 4) Check output wiring.
Page 160 Chapter 7 - Troubleshooting & Maintenance Protective Cause Remedy Function Operating LOP (Loss of reference from the Option), Method when LOR (Remote) the Speed LOV (V1), Eliminate cause of fault. Reference is LOI (I), Lost LOX (Sub-V2, ENC) Inverter Load is larger than inverter rating. Increase motor and/or inverter capacity.
Page 161: Troubleshooting
Chapter 7 - Troubleshooting & Maintenance 7.2 Troubleshooting Condition Checking Point 1) Main circuit inspection: Is the input (line) voltage normal? (Is the LED in the inverter is lit?) Is the motor connected correctly? 2) Input signal inspection: Check the operating signal input to the inverter. Check the forward and the reverse signal input simultaneously to the inverter? Check the command frequency signal input to the inverter.
Page 162: How To Check Power Components
Chapter 7 - Troubleshooting & Maintenance 7.3 How to Check Power Components 1) Diode module and IGBT module check (5.5~ 30kW) Before checking the power components, be sure to disconnect AC Input supply and wait until the Main Electrolytic Capacitors (DCP-DCN) is discharged. Charge resistor D2 D3 Electrolytic...
Page 163 Chapter 7 - Troubleshooting & Maintenance 2) Diode module and IGBT module check (37~ 90kW) Charge Charge resistor diode SCR2 SCR3 SCR1 Electrolytic capacitor Turn the power off and disconnect RST/UVW wiring. Determine whether inverter terminals (R,S,T, U, V, W, P1(or P2),N) are energized or not using a tester. Wait until the Main Electrolytic Capacitors (DCP-DCN) is discharged to a safe level.
Page 164: Maintenance
Chapter 7 - Troubleshooting & Maintenance 7.4 Maintenance The iP5A series is an industrial electronic product with advanced semiconductor elements. However, temperature, humidity, vibration and aging parts may still affect it. To avoid this, it is recommended to perform routine inspections. 7.4.1 Precautions Be sure to remove the drive power input while performing maintenance.
Page 165 Chapter 7 - Troubleshooting & Maintenance 7.4.5 Daily and Periodic Inspection Items Period Measuring Inspection Inspection Method Criterion Instrument Is there any dust? Refer to the precautions. Temperature: Thermometer, Ambient Is the ambient temperature and -10~+40 no Hygrometer, Ο Environ- humidity adequate? freezing.
Page 166 Chapter 7 - Troubleshooting & Maintenance 7.4.6 Parts replacement Part name Period Comments Exchange for a new part after consulting Cooling fan 2-3 years LS A/S center. Check for the periodic inspection for 1 year. Exchange for a new part after consulting LS A/S center.
Page 167: Chapter 8 - Options
CHAPTER 8 - OPTIONS 8.1 Option List 32 character display Keypad All units keypad Download and Upload available 2m, 3m and 5m long keypad cable enables Remote Remote cable users to control the inverter from a distant Optional area. DB resistor Enables inverter to decelerate rapidly.
Page 168: External Options
Chapter 8 - Options 8.2 External options 8.2.1 Keypad dimensions 1) LCD Keypad (Weight: 140 g)
Page 169 Chapter 8 - Options 8.2.2 Remote cable Ordering No. Description 051050025 Remote cable – 2m 051050026 Remote cable – 3m 051050027 Remote cable – 5m 8.2.3 DB (Dynamic Braking) Unit Refer to DB Unit option manual for details. 1) DBU Models Inverter Applicable motor rating DB Unit...
Page 170 Chapter 8 - Options 3) Wiring for DB unit and DB resistor (for 5.5~90kW/7.5~125HP inverters) DB Unit DB Resistor Max distance between P & P2: 5m Short P1(+) P2(+) N(-) MCCB(Option) φ R(L1) MOTOR S(L2) AC Input T(L3) 50/60 Hz Programmable Digital Input : Ext Trip Output Frequency Meter Output Voltage Meter...
Page 171 Chapter 8 - Options 4)Dimensions Group 1 (Unit: mm) ynamic raking WIRING (P2)
Page 172 Chapter 8 - Options Group 2 (Unit: mm) Ø Dynamic Braking Unit...
Page 173 Chapter 8 - Options Group 3 (Unit: mm) ynamic raking WIRING (P2) 5) Monitoring LEDs * Group 1 Description When heat sink is overheated and the level exceeds its (GREEN, setting limit, overheat protection is activated and OHT LEFT) LED is turned ON after DBU’s signal is shut off. POWER POWER LED is turned ON upon inverter Power ON (RED)
Page 174 Chapter 8 - Options * Group 2 Description Press this switch to release OCT FAULT status. Pressing RESET this turns the OCT LED off. RESET POWER POWER LED is turned ON upon inverter Power ON POWER (GREEN) because normally it is connected to the inverter. RUN LED is blinking while DBU is operating normally (GREEN) by motor regenerating energy.
Page 175 Chapter 8 - Options 8.2.4 DB Resistor 1) External DB Resistor SV-iP5A inverters do not built-in DB resistor on Power stack as factory installation. External DB Unit and Resistor (Optional) should be installed. See the following table for more details (ED: 5%, Continuous Braking Time: 15 sec).
Page 176 Chapter 8 - Options * Type 1 (Max 400 Watt) * Type 2 (Max 600 Watt) * Type 8-10...
Page 177 Chapter 8 - Options 8.2.5 Micro surge filter (Designed for Inverter-driven 400V Class motor) In the PWM type inverter, a surge voltage attributable to wiring constants is generated at the motor terminals. Especially for a 400V class motor, the surge voltage may deteriorate the insulation. When the 400V class motor is driven by the inverter, consider the following measures: Rectifying the motor insulation For the 400V class motor, use an insulation-rectified motor.
Page 178 Chapter 8 - Options 8.2.6 NEMA TYPE 1 Optional Conduit Box 1) NEMA TYPE 1 Enclosure for conduit connection General NEMA TYPE 1 Conduit Box: This kit enables an inverter to be installed on the wall without the inverter panel and meets NEMA Type 1. It should be installed to meet NEMA 1 for 15~90kW UL Open Type inverters.
Page 179 Chapter 8 - Options [Conduit box for 370~550iP5A] [Conduit box for 750~900iP5A] 8-13...
Page 180 Chapter 8 - Options Conduit Hole Size mm(inches) Conduit hole for control terminal Inverter Trade Size of the Conduit Conduit hole for power terminal 24 (0.98) 16 (1/2) SV055iP5A-2/4 24 (0.98) 16 (1/2) 24 (0.98) 16 (1/2) SV075iP5A-2/4 35 (1.37) 27 (1) 24 (0.98) 16 (1/2)
Page 181: Chapter 9 - Rs485 Communication
CHAPTER 9 - RS485 COMMUNICATION 9.1 Introduction Inverter can be controlled and monitored by the sequence program of the PLC or other master module. Drives or other slave devices may be connected in a multi-drop fashion on the RS-485 network and may be monitored or controlled by a single PLC or PC.
Page 182: Specification
Chapter 9 – RS485 Communication 9.2 Specification 9.2.1 Performance specification Item Specification Transmission form Bus method, Multi-drop Link System Applicable inverter SV-iP5A series Connectable drives Max 31 Transmission distance Max. 1,200m (Within 700m Recommended) Recommended wire 0.75mm (12AWG), Shield Type Twisted-Pare Wire 9.2.2 Hardware specification Item Specification...
Page 183: Operation
Chapter 9 – RS485 Communication Communication parameters Code Display Name Set value Unit Default DRV_03 Drive mode Drive mode Int. 485 Fx/Rx-1 DRV_04 Freq mode Freq mode Int. 485 KeyPad-1 KeyPad DRV_91 Drive mode2 Drive mode 2 Fx/Rx-1 Fx/Rx-1 Fx/Rx-2 KeyPad-1 KeyPad-2 DRV_92...
Page 184: Communication Protocol (Rs485)
Chapter 9 – RS485 Communication 9.4 Communication protocol (RS485) The configuration of RS485 is that PC or PLC is the Master and Inverter Slave. Inverter responds the Master’s Read/Write Requests. When master sends Write Request to Inverter address # 255, all inverters perform Write action but do not return a Acknowledge response.
Page 185 Chapter 9 – RS485 Communication SUM= ASCII-HEX format of lower 8 bit of (Inverter No. + CMD + DATA) Ex) Command Message (Request) for reading one address from address “9000” Inverter Number of Address address to read “01” “R” “9000” “1”...
Page 186 Chapter 9 – RS485 Communication 2.2) Negative response: Inverter No. Error code “01” ~ “FA” “W” “**” “XX” 1 byte 2 byte 1 byte 2 byte 2 byte 1 byte Total byte = 9 3) Request for Monitor Register: This is useful when constant parameter monitoring and data updates are required.
Page 187 Chapter 9 – RS485 Communication 5) Error code Error Description code ILLEGAL FUNCTION When master is sending codes other than Function code (R, W, X, Y). ILLEGAL ADDRESS - When parameter address does not exist ILLEGAL VALUE - When Data contains an out of range value for an inverter parameter during ‘W’...
Page 188: Parameter Code List
Chapter 9 – RS485 Communication 9.5 Parameter code list <Common area>: Area accessible regardless of inverter models (Note 3) Address Parameter Unit Unit R/W Data value 0x0000 Inverter model R 9 : SV-iP5A 4: 5.5kW(7.5HP), 5: 7.5kW(10HP), 6: 11kW(15HP), 7: 15kW(20HP), 8: 18.5kW(25HP), 9: 22kW(30HP), A: 30kW(40HP),...
Page 189 Chapter 9 – RS485 Communication 9.5 Parameter code list <Common area>: Area accessible regardless of inverter models (Note 3) Address Parameter Unit Unit R/W Data value 0x0000 Inverter model R 9 : SV-iP5A 4: 5.5kW(7.5HP), 5: 7.5kW(10HP), 6: 11kW(15HP), 7: 15kW(20HP), 8: 18.5kW(25HP), 9: 22kW(30HP), A: 30kW(40HP),...
Page 190 Chapter 9 – RS485 Communication Address Parameter Unit Unit R/W Data value BIT 6: speed arrival BIT 7: DC Braking BIT 8: Stopping Bit 9: not Used BIT10: Brake Open 0x000E Operating status of Inverter BIT11: Forward run command BIT12: Reverse run command BIT13: REM.
Page 191 Chapter 9 – RS485 Communication Address Parameter Unit Unit R/W Data value 0x0015 0x001A Unit display R 0 : Hz, 1 : Rpm 0x001B Pole number 0x001C Custom Version Note 1) Detail description on Common area address 0x0006 Value Name Description 0x01 Stop...
Page 192 Chapter 9 – RS485 Communication 9.5.1 iP5A operating status in Address E, Common area Output frequency Forward Run command Reverse Run command Accelerating Decelerating Speed arrival Stopping Stop Forward running Reverse running < Address usage area by groups > 9100 - 91FF 9200 –...
Page 193: Troubleshooting
Chapter 9 – RS485 Communication 9.6 Troubleshooting Refer to the below chart when RS485 communication error occurs. Status LEDs (TXD, RXD) are not blinking. Apply the power to the Is RS232-485 converter. converter power supply ON? (see converter manual.) is the wiring of Check for the inverter and correct wiring.
Page 194 Chapter 9 – RS485 Communication Set the inverter Is BPS setting and PC bps the between inverter same in I/O 91. and PC matching? Is User program's Make correction to data format the User program correct? to fit for protocol Are Status LEDs Is there an on the control...
Page 195: Ascii Code List
Chapter 9 – RS485 Communication 9.7 ASCII Code List Character Character Character space " & < > 9-14...
Page 196: Appendix A- Ul Marking
APPENDIX A- UL MARKING 1. SHORT CIRCUIT RATING “Suitable For Use On A Circuit Capable Of Delivering Not More Than Table1 RMS Symmetrical Amperes, 240V for 240V rated inverters, 480V for 480V rated inverters Volts Maximum,” Table 1. RMS Symmetrical Amperes for iP5A series. Model Rating SV055iP5A-2, SV055iP5A-4, SV075iP5A-2, SV075iP5A-4, SV110iP5A-2,...
Page 197 3. OVER LOAD PROTECTION IOLT: IOLT(inverter Overload Trip) protection is activated at 110% of the inverter rated current for 1 minute and greater. OLT : Inverter shuts off its output when inverter output current exceeds its overload trip level for overload trip time.
Page 198 6. BASIC WIRING Main Power Circuit Dynamic Braking Unit DB Unit(Optional) (Optional) DB Resistor DC Bus Choke (Optional ) P N B1 B2 DC Bus Choke DB Resistor P1(+) P2(+) N(-) MCCB(Option) φ R(L1) MOTOR S(L2) AC Input T(L3) 50/60 Hz Analog Power Source (+12V) Control Circuit Programmable Digital Input 1(Speed L)
Page 199: Appendix B- Peripheral Devices
APPENDIX B- PERIPHERAL DEVICES 1. MCCB (Molded Case Circuit Breaker) and MC (Magnetic Contactor) Motor Inverter MCCB Voltage [kW] Model (LS Industrial Systems) (LS Industrial Systems) SV055iP5A-2 ABS53b/50A GMC-40 SV075iP5A-2 ABS63b/60A GMC-40 SV110iP5A-2 ABS103b/100A GMC-50 200V SV150iP5A-2 ABS103b/100A GMC-85 Class 18.5 SV185iP5A-2 ABS203b/125A...
Page 200 2. AC Input Fuse and AC / DC Reactor AC Reactor DC Reactor Motor Inverter AC Input Fuse Voltage [kW] Model [mH] [mH] SV055iP5A-2 0.39 1.37 SV075iP5A-2 0.28 1.05 SV110iP5A-2 0.20 0.74 200V SV150iP5A-2 0.15 0.57 Class 18.5 SV185iP5A-2 0.12 0.49 SV220iP5A-2 0.10...
Page 201: Appendix C- Related Parameters
APPENDIX C- RELATED PARAMETERS Related parameter codes DRV-01 [Acceleration Time], DRV-02 [Deceleration Time], Accel/Decel time, Pattern Adjustment FU1-02 [Acceleration Pattern], FU1-03 [Deceleration Pattern] Reverse Rotation Prevention FU1-01 [Forward/Reverse Prevention] Accel/Decel at Continuous Rating Range FU1-02 [Acceleration Pattern], FU1-03 [Deceleration Pattern] FU1-20 [Starting Mode], FU1-21~22 [DC Injection Braking Braking Operation Adjustment at Starting]...
Page 202: Declaration Of Conformity
DECLARATION OF CONFORMITY Council Directive(s) to which conformity is declared: CD 73/23/EEC and CD 89/336/EEC Units are certified for compliance with: EN 61800-3/A11 (2000) EN 61000-4-2/A2 (2001) EN 61000-4-3/A2 (2001) EN 61000-4-4/A2 (2001) EN 61000-4-5/A1 (2001) EN 61000-4-6/A1 (2001) EN 55011/A2 (2002) IEC/TR 61000-2-1 (1990) EN 61000-2-4 (2002) EN 60146-1-1/A1 (1997...
Page 203 TECHNICAL STANDARDS APPLIED The standards applied in order to comply with the essential requirements of the Directives 73/23/CEE "Electrical material intended to be used with certain limits of voltage" and 89/336/CEE "Electromagnetic Compatibility" are the following ones: • EN 50178 (1997) “Electronic equipment for use in power installations”.
Page 204: Emi / Rfi Power Line Filters
EMI / RFI POWER LINE FILTERS LS inverters, iP5A series RFI FILTERS THE L.S. RANGE OF POWER LINE FILTERS FF ( Footprint ) - FE ( Standard ) SERIES, HAVE BEEN SPECIFICALLY DESIGNED WITH HIGH FREQUENCY LS INVERTERS. THE USE OF L.S. FILTERS, WITH THE INSTALLATION ADVICE OVERLEAF HELP TO ENSURE TROUBLE FREE USE ALONG SIDE SENSITIVE DEVICES AND COMPLIANCE TO CONDUCTED EMISSION AND IMMUNITY STANDARS TO EN 50081 ->...
Page 205 iP5A series Footprint Filters LEAKAGE DIMENSIONS MOUNTING OUTPUT INVERTER POWER CODE CURRENT VOLTAGE WEIGHT MOUNT CURRENT CHOKES THREE PHASE NOM. MAX. SV055iP5A-2 5.5kW FFP5-T030-(x) 250VAC 0.3mA 18mA 329x149.5x50 315x120 2 Kg. FS – 2 SV075iP5A-2 7.5kW FFP5-T050-(x) 250VAC 0.3mA 18mA 329x199.5x60 315x160 2.5 Kg.
Page 206 FS SERIES ( output chokes ) CODE Ø 28. 5 125 x 30 180 x 45 Ø DIMENSIONS FF SERIES ( Footprint ) FFP5-T030-( x ) ~ FFP5-T070-( x ) FE SERIES ( Standard ) FE-T030-( x ) ~ FE-T230-( x ) FE-T400-( x ) ~ FE-T1600-( x )
Page 207 Warranty Installation LS Industrial Systems Co., Ltd. Maker (Start-up) Date Warranty Model No. SV-iP5A Period Name Customer Address Information Tel. Name Sales Office Address (Distributor) Tel. Warranty period is 12 months after installation or 18 months after manufactured when the installation date is unidentified.
Page 208 Revision History Date Edition Changes October, 2004 First Release June, 2005 Edition CI changed June, 2006 Edition Revised for new kW(HP) ratings November, 2006 Edition S/W Version up (V0.4) December, 2006 Edition Contents added and revised November, 2008 Edition Contents added and revised xiii...
Page 209 LS values every single customer. Quality and service come first at LSIS. Always at your service, standing for our customers. 10310000487 ■ HEAD OFFICE ■ LS Industrial Systems (Shanghai) Co., Ltd. >> China Yonsei Jaedan Severance Bldg. 84-11 5 ga, Namdaemun-ro, Address: Room E-G, 12th Floor Huamin Empire Plaza, Jung-gu Seoul 100-753, Korea http://eng.lsis.biz...

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JS Technik LS-iP5A User Manual

Chapter 1 - Basic Information

Chapter 2 - Specification

Chapter 3 - Installation

Chapter 4 - Operation

Chapter 5 - Parameter List

Chapter 6 - Parameter Description

Chapter 7 - Troubleshooting & Maintenance

Chapter 8 - Options

Chapter 9 - Rs485 Communication

Appendix A- Ul Marking

Appendix B- Peripheral Devices

Appendix C- Related Parameters

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