Carotron EP2020-000 Instruction Manual Download Page 1

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Instruction Manual

Models

EP2020-000

EP4020-000

EP2040-000

EP4040-000

EP2060-000

EP4060-000

EP2075-000

EP4075-000

EP2100-000

EP4100-000

EP2125-000

EP4125-000

EP2150-000

EP4150-000

EP2200-000

EP4200-000

EP2250-000

EP4250-000

EP2300-000

EP4300-000

EP2400-000

EP4400-000

EP2500-000

EP4500-000

EP2600-000

EP4600-000

EP2700-000

EP4700-000

Summary of Contents for EP2020-000

Page 1: ...00 EP2060 000 EP4060 000 EP2075 000 EP4075 000 EP2100 000 EP4100 000 EP2125 000 EP4125 000 EP2150 000 EP4150 000 EP2200 000 EP4200 000 EP2250 000 EP4250 000 EP2300 000 EP4300 000 EP2400 000 EP4400 000 EP2500 000 EP4500 000 EP2600 000 EP4600 000 EP2700 000 EP4700 000 V3 ...

Page 2: ... 2 B Digital Inputs 23 7 3 C Analog Inputs 29 7 4 D Digital Outputs 34 7 5 E Analog Outputs 38 7 6 F Motor Data 40 7 7 G Control Loops 44 7 8 H Start Stop Logic 52 7 9 I Setpoints 56 7 10 J Ramps 58 7 11 K Fault Logic 62 7 12 L Applications 68 7 13 M Thresholds 78 7 14 N Timers 81 7 15 O Logic Gates 83 7 16 P Switches 86 7 17 Q Internal Links 87 7 18 R Communications 88 7 19 S Zero Speed 91 7 20 T...

Page 3: ...Models 141 DXXXXX Wiring Diagram 200 400HP Non Regen Models 142 DXXXXX Wiring Diagram 200 400HP Regen Models 143 D14353 Wiring Diagram 500 700HP Non Regen Models 144 D14354 Wiring Diagram 500 700HP Regen Models 145 D14308 General Connections 146 D14306 RS422 485 Network Connections 147 C14307 Sonic Transducer Option Connections 148 D14309 Software Block Diagram 150 12 Standard Terms Conditions of ...

Page 4: ...in to 17 0 VDC max Source Mode Vih 8 0 VDC min to 30 0 VDC max Vil 5 0 VDC max Analog Inputs Qty 5 Voltage Mode Max Input 10 VDC Input Impedance 1MΩ Current Mode Max Input 20 mADC Input Impedance 250Ω Resolution 12 bit Tachometer Feedback Input Max Input 200 V AC or DC Encoder Feedback Input Frequency 200kHz max Uni directional single channel or Quadrature Single ended or differential Voltage 12 V...

Page 5: ...5 EPx075 000 thru EPx150 000 EPx020 000 thru EPx060 000 PRO 2 2 Physical PRO ...

Page 6: ...6 EPx500 000 thru EPx600 000 PRO EPx200 000 thru EPx400 000 PRO ...

Page 7: ...idental grounding Signal level wiring such as listed above should be routed separately from high level wiring such as armature field and relay control wiring When these two types of wire must cross they should cross at right angles to each other Any relays contactors starters solenoids or electro mechanical devices located in close proximity to or on the same line supply as the motor control shoul...

Page 8: ...ed to FL1 and FL2 The drive also requires a fused single phase 115VAC control power on terminals L and N Carotron recommends the use of three phase DIT drive isolation type transformers While Elite Pro controls do not require these transformers for proper operation they can be helpful in reducing the effects of line transients on this control and generated by this control on other products and can...

Page 9: ...300 426 330 510 535 Amps 0 65Ω 14600W 240 200 220 EPx400 000 500 400 555 440 688 Consult Factory Consult Factory 240 250 275 EPx500 000 500 500 694 550 850 Consult Factory Consult Factory 240 300 330 EPx600 000 500 600 832 660 1020 Consult Factory Consult Factory 240 350 385 EPx700 000 500 700 950 770 1165 Consult Factory Consult Factory Table 1 Model Rating Data x 2 for non regenerative models x ...

Page 10: ...ature leads on non regenerative models only They should NOT be used with the EP4 Series regenerative models On regenerative models the leads should not be connected and should be individually insulated On non regenerative models the series field winding polarity must be kept at the same polarity as the shunt field winding i e F1 and S1 the same F2 or F4 and S2 the same If during startup the field ...

Page 11: ... shows the typical signal connections to an Elite Pro drive When operated the Emergency Stop contacts at terminals 6 and 7 will immediately clamp all control signals The armature contactor will also de energize to disconnect the armature from the bridge output Motor stopping time is determined by inertia and friction characteristics of the load and can be decreased by use of a brake resistor Refer...

Page 12: ...12 Figure 6 Signal Connections ...

Page 13: ...ts direction In the final scheme each contact starts the drive and selects the direction Parameter H1 01 needs to be set appropriately Figure 7 The drive also has the capability to interface with either sinking or sourcing logic controls Sourcing PNP logic is selected by jumpering TB1 terminals 2 3 This places an internal pull down resistor on each input The external switch or sensor must then dri...

Page 14: ...cursor one place to the left 5 Reset Right Key Clears drive fault on a DM screen Moves cursor one place to the right 6 Local Remote Key Switches the drive between local and remote control 7 Enter Key Used to accept enter parameter values Moves cursor one place to the right 8 Up Down Keys Scrolls to the next menu display Increments decrements cursor value 9 Run LED On Drive is in run mode and has r...

Page 15: ...er is applied to the drive the HMI displays the drive s firmware version After a short timeout the Drive Monitor 1 DM1 screen is displayed Navigation through the menu is achieved by using the Up Down Escape and Enter keys Figure 10 ...

Page 16: ...e menu some parameters are hidden when they are not applicable However in some cases it may be desired to view these hidden parameters There are two ways to view these hidden parameters The first method is to change parameter A1 01 from STANDARD to ADVANCED This makes all parameters visible The second method is to use a certain keystroke while scrolling through the parameters Pressing the F2 key b...

Page 17: ...ified before using it for control After the motor data is entered in the wizard the drive should begin producing field output Depending upon the wizard data entered you may have the option to operate the field in either open or closed loop mode After the field mode is selected the wizard will display a field status screen showing the field voltage and field current Verify the displayed values corr...

Page 18: ... On the display navigate to DM10 Compare Armature feedback to Tachometer feedback The values should be approximately equal within 5 If the values have approximately the same value but the wrong polarity press the Stop button and invert the tachometer feedback by setting parameter F2 02 to On Place the drive back in the run mode and re check If the values are not equal verify the tachometer data is...

Page 19: ...6 2 Once correct operation in this mode has been achieved proceed with the following steps 2 Parameters Re run the Basic Setup Wizard and set the Operating Mode to TORQUE Continue through the wizard and enter any required data 3 Test With reference at minimum place drive in run mode Navigate to DM02 to display the armature current Slowly increase reference and verify control of armature current 6 ...

Page 20: ...ain G1 16 and Current Integral Time G1 17 parameters and re apply the Step Enable until a critically damped waveform as seen in Figure 11 Increasing the proportional gain improves the response but increases the overshoot Reducing the integral time improves the response but can cause instability if set too low Once a critically damped waveform is obtained increase the Step Reference to 40 and repea...

Page 21: ... press F2 key and then the Up key to display A1 04 Once A1 04 has a value other than zero parameters can be viewed but cannot be changed Changes can only be made by first entering the password into parameter A1 05 Once all changes have been made A1 05 can be manually returned to 0 to logout The drive also has a timeout feature that automatically clears the entered password in A1 05 after 5 minutes...

Page 22: ...gulates motor speed CONST HP CROSOVER Drives regulates speed utilizing the motor s extended speed range Also known as field weakening or field crossover TORQUE Drive regulates motor torque or armature current A1 03 Initialize ICR Preset 0 9999 Re initializes the drive and returns all parameters to the factory default setting Range 0 65535 A1 04 Define Password R W Preset 0 A numeric password may b...

Page 23: ...op H1 10 Dynamic Brake Stop I1 01 Aux Reference Enable I1 02 Ref Select MSB I1 03 Ref Select LSB J1 18 Ramp 1 Bypass K1 14 External Fault K1 15 Fault Reset L1 01 PID Enable L1 02 PID Reset L6 01 MOP Increase L6 02 MOP Decrease L6 07 MOP Reset Table 4 Common Digital Input Functions The actual function is determined by the H1 01 setting B1 02 Digital Input 1 Status Terminal 31 RO Displays the status...

Page 24: ...Preset H1 03 Stop B2 02 Digital Input 2 Status Terminal 32 RO B2 03 Digital Input 2 Off Value RW B2 04 Digital Input 2 On Value RW Digital Input 2 is functionally equivalent to Digital Input 1 Refer to B1 XX B3 Digital Input 3 B3 01 Digital Input 3 Destination ICR Preset H1 04 Jog B3 02 Digital Input 3 Status Terminal 33 RO B3 03 Digital Input 3 Off Value RW B3 04 Digital Input 3 On Value RW Digit...

Page 25: ... 4 On Value RW Digital Input 4 is functionally equivalent to Digital Input 1 Refer to B1 XX B5 Digital Input 5 B5 01 Digital Input 5 Destination ICR Preset I1 02 RefSelMsb B5 02 Digital Input 5 Status Terminal 35 RO B5 03 Digital Input 5 Off Value RW B5 04 Digital Input 5 On Value RW Digital Input 5 is functionally equivalent to Digital Input 1 Refer to B1 XX Figure 18 Figure 19 ...

Page 26: ...6 On Value RW Digital Input 6 is functionally equivalent to Digital Input 1 Refer to B1 XX B7 Digital Input 7 B7 01 Digital Input 7 Destination ICR Preset K1 15 ExtFaultReset B7 02 Digital Input 7 Status Terminal 37 RO B7 03 Digital Input 7 Off Value RW B7 04 Digital Input 7 On Value RW Digital Input 7 is functionally equivalent to Digital Input 1 Refer to B1 XX Figure 20 Figure 21 ...

Page 27: ... in Hertz B8 04 Freq Input Status RO Valid only when B8 02 equals SONIC INPUT Displays the measured distance of the sonic transducer connected to terminal 18 in inches B8 05 Freq Input Filtering R W Preset 0 Sets the level of digital filtering applied to the input signal The adjustment ranges from 0 no filtering to 15 heavily filtered B8 06 Freq Input 0 Calibration R W Preset 0Hz Defines the minim...

Page 28: ...he target is out of range B8 20 Counter Destination ICR Preset 00 00 Not Set The drive has a counter associated with the frequency input This count value can control or write to any R W parameter in the drive The destination parameter contains the tag of the parameter the input will control i e the target parameter B8 21 Counter Enable R W Preset Disabled The counter is enabled when set to ENABLED...

Page 29: ...ag of the parameter the input will control i e the target parameter Refer to Table 5 for a list of commonly used functions Value Function G1 05 POSITIVE CURRENT LIMIT G1 06 NEGATIVE CURRENT LIMIT I1 04 REF A I1 05 REF B I1 06 REF C I1 07 REF D I1 08 JOG REF I2 02 SETPOINT B I2 04 SETPOINT C I2 06 SETPOINT D L1 13 AUX PID SETPOINT L1 14 AUX PID FEEDBACK L1 23 AUX PID SCALE L2 07 DIA CALC EXT DIA RA...

Page 30: ...will be ignored Refer to Figure 24 Range 0 4095 C1 07 Analog Input 1 Unipolar 100 Calibration R W Preset 4095 Defines the maximum raw signal level in UNIPOLAR mode An input value above this level will be ignored Refer to Figure 24 Range 0 4095 C1 09 Analog Input 1 Bipolar 100 Calibration R W Preset 2047 Defines the maximum raw positive and negative signal levels in BIPOLAR mode Any input value exc...

Page 31: ...g Input 2 Type ICR Preset Voltage C2 06 Analog Input 2 0 Calibration R W Preset 0 C2 07 Analog Input 2 100 Calibration R W Preset 4095 C2 08 Analog Input 2 0 Calibration R W Preset 0 C2 09 Analog Input 2 100 Calibration R W Preset 2047 C2 10 Analog Input 2 Bias R W Preset 0 00 C2 11 Analog Input 2 Gain R W Preset 100 00 Analog Input 2 is functionally equivalent to Analog Input 1 Refer to C1 XX Fig...

Page 32: ...R W Preset 100 00 Analog Input 3 is functionally equivalent to Analog Input 1 Refer to C1 XX C4 Analog Input 4 C4 01 Analog Input 4 Destination ICR Preset 00 00 Not Set C4 02 Analog Input 4 Status RO C4 03 Analog Input 4 Polarity ICR Preset Unipolar C4 04 Analog Input 4 Filtering R W Preset 0 C4 05 Analog Input 4 Type ICR Preset Voltage C4 06 Analog Input 4 0 Calibration R W Preset 0 C4 07 Analog ...

Page 33: ...Analog Input 5 Type ICR Preset Voltage C5 06 Analog Input 5 0 Calibration R W Preset 0 C5 07 Analog Input 5 100 Calibration R W Preset 4095 C5 08 Analog Input 5 0 Calibration R W Preset 0 C5 09 Analog Input 5 100 Calibration R W Preset 2047 C5 10 Analog Input 5 Bias R W Preset 0 00 C5 11 Analog Input 5 Gain R W Preset 100 00 Analog Input 5 is functionally equivalent to Analog Input 1 Refer to C1 X...

Page 34: ...G RUN or JOG J1 22 DRIVE RAMPING K2 08 DRIVE FAULT K2 10 DRIVE READY S1 06 AT ZERO SPEED S1 07 AT STANDSTILL Table 7 Common Relay Digital Output Functions D1 02 Relay Output 1 Absolute Value R W Preset Off When TRUE the absolute value of the source parameter s value is taken before it is compared to the Dx 03 and Dx 04 D1 03 Relay Output 1 On Value R W Preset On The relay will energize turn on whe...

Page 35: ...utput 2 Status RO Relay Output 2 is functionally equivalent to Relay Output 1 Refer to D1 XX D3 Relay Output 3 D3 01 Relay Output 3 Source ICR Preset K2 08 Drive Faulted D3 02 Relay Output 3 Absolute Value R W Preset Off D3 03 Relay Output 3 On Value R W Preset No D3 04 Relay Output 3 Off Value R W Preset Yes D3 05 Relay Output 3 Status RO Relay Output 2 is functionally equivalent to Relay Output ...

Page 36: ... frequency 10kHz Range 0 300 D4 04 Freq Output Bias R W Preset 0 00 Used only in the FREQ OUT mode This adjustment is used to set a minimum frequency output level The percentage adjustment is based on the maximum frequency output level 10kHz Range 0 300 D4 05 Freq Output Status RO Used only in the FREQ OUT mode Displays the frequency output level D4 06 Digital Output Absolute Value R W Preset Off ...

Page 37: ...f the source parameter s value is taken before it is compared to the D5 03 and D5 04 D5 03 Aux LED On Value R W Preset On The LED will turn on when the source parameter s value is greater than or equal to this value The limits and units of this parameter will change to match the limits and units of the source parameter D5 04 Aux LED Off Value R W Preset Off The LED will turn off when the source pa...

Page 38: ...IELD CURRENT G3 13 MOTOR FIELD VOLTAGE I1 10 REFERENCE J1 21 RAMP OUTPUT L1 25 AUX PID OUTPUT Table 8 Common Analog Freq Output Functions E1 02 Analog Output 1 Gain R W Preset 100 00 This adjustment is used to scale the output level A gain of 100 with a source parameter value of 100 will yield maximum output level of 10V Range 300 300 E1 03 Analog Output 1 Bias R W Preset 0 00 This adjustment is u...

Page 39: ...ble 9 Analog Output Status E2 Analog Output 2 E2 01 Analog Output 2 Source ICR Preset G1 13 Filtered Current Feedback E2 02 Analog Output 2 Gain R W Preset 100 00 E2 03 Analog Output 2 Bias R W Preset 0 00 E2 04 Analog Output 2 Absolute Value R W Preset Off E2 05 Analog Output 2 Status RO Analog Output 2 is functionally equivalent to Analog Output 1 Refer to E1 XX Figure 35 ...

Page 40: ...Enter the motor nameplate armature voltage rating F1 04 Base Speed Field Amps ICR Preset 0 00A Enter the motor nameplate base speed field current rating F1 05 Extended Speed Field Amps ICR Preset 0 00A Enter the motor nameplate extended speed field current rating F1 06 Base Speed Field Volts ICR Preset 0V Enter the motor nameplate base speed field voltage rating F1 07 Base Speed ICR Preset 0 RPM E...

Page 41: ... e swap the polarity of the tachometer signal without re wiring F2 03 Tachometer Volts 1000 RPM ICR Preset 50V The tachometer feedback signal is polarity sensitive The polarity is used to determine the direction of rotation of the motor If the tachometer wires are reversed this parameter can be used to invert i e swap the polarity of the tachometer signal without re wiring Range 1 250V F2 04 Tach ...

Page 42: ...onality The count value can be written to any R W parameter in the drive The destination parameter contains the tag of the parameter the input will control i e the target parameter F3 05 Counter Enable R W Preset Disabled Enables disables the counter When ENABLED each pulse on the input causes the counter F3 11 F3 12 to increment or decrement F3 06 Counter Direction R W Preset Auto Determines whet...

Page 43: ...these two registers when F3 08 is ON F3 11 Counter Value Lo RO F3 12 Counter Value Hi RO The 32 bit counter is split into two 16 bit sections F3 11 F3 12 The counter has a maximum value of 4 294 967 295 F3 13 Divisor ICR Preset 1 The 32 bit count value is divided by this value before being written to the target parameter ...

Page 44: ...Positive current is used when the drive is motoring in the forward direction and regenerating in the reverse direction Range 0 150 G1 06 Negative Current Limit R W Preset 150 00 This parameter sets the maximum level of negative current that can be demanded Negative current is used when the drive is motoring in the reverse direction and regenerating in the forward direction Range 0 150 G1 07 Slew R...

Page 45: ...nfiguration the Ramp 1 Output is linked to this parameter Range 0 100 G1 21 Conduction RO This is the output of the current loop It is an input to the trigger board armature control G1 22 Conduction Raw RO The raw conduction value G1 23 Step Reference R W Preset 0 00 Used only when G1 01 is set to STEP Sets the level of current demand during a step level response test Range 150 150 G1 24 Step Dura...

Page 46: ...alue of the armature voltage feedback signal G2 06 Armature VFB RO This status parameter indicates the level of armature voltage on the motor The reading is a percentage of F1 03 G2 07 Armature VFB Filter RO Filtered version of G2 06 G2 08 Armature Volts RO G2 07 expressed in volts G2 09 I R Comp R W Internal Resistance losses in the motor armature can cause decreased speed regulation on loaded mo...

Page 47: ... the application process is running external conditions or variables may change diameter of a roll for example In some cases it may be desirable to switch to an alternate set of loop adjustments so that the drive can better respond to the new operating conditions When set to OFF G2 21 G2 23 are used When set to ON G2 24 G2 26 are used G2 21 Velocity Prop Gain R W Preset 9 000 Sets the loop respons...

Page 48: ... sequence G2 32 Step Reference R W Preset 0 00 Used only when G2 31 is set to STEP Sets the level of current demand during a step level response test Range 100 100 G2 33 Step Duration R W Preset 2 Secs Used only when G2 31 is set to STEP Sets the amount of time in seconds that G2 32 is applied during the step level response test Range 0 30 Secs G2 34 Step Enable R W Preset Off Used only when G2 31...

Page 49: ...indings The drive s field output can automatically be reduced when the drive is in the Stop mode after 3 minutes The field will automatically return to its normal level when the Run or Jog mode is entered Setting this parameter to ENABLED turns on this feature When G3 02 is set to OPEN LOOP and economy goes into effect the field output reduction is set by G3 06 When G3 02 is set to CLOSED LOOP and...

Page 50: ...educed to the Min Field I Demand level G3 16 Range 50 95 G3 20 Field Crossover Output RO Used only when A1 02 is set to CONST HP CROSSOVER This parameter value is subtracted from the Max Field I Demand G3 15 to reduce the level of field current in the motor G3 21 Field Prop Gain R W Preset 1 2500 Sets the loop response Increasing the gain improves the response of the drive but can also increase ov...

Page 51: ...splays the status of the field over current alarm ON indicates the alarm is active Refer to K1 08 K1 10 for alarm details G3 33 Aux Field Reference R W Preset 0 00 Used only when G3 23 is set to AUX Serves as an auxiliary reference to the field loop Typically used in engineered applications Range 0 100 G3 34 Field IFB Offset ICR Preset Varies by drive typically 0 This parameter allows any offset i...

Page 52: ...as the Start command H1 03 serves as the Ramp Stop command active low H1 04 serves as the Jog command H1 05 serves as the Reverse command Drive will enter and stay in the run mode when H1 02 is momentarily ON Drive will ramp to stop when H1 03 is momentarily OFF Drive will Jog anytime H1 04 is ON Reverse is selected when H1 05 is ON MAINTAINED RUN DIR H1 02 serves as the Run command H1 03 is not u...

Page 53: ...ile NOT recommended by Carotron this feature can be disabled if other external safety logic is used H1 08 Coast Stop R W Preset On This command is active low i e when in the OFF state When OFF the drive clamps all the control loops and the motor will coast to a stop The armature contactor does not de energize until zero speed is reached The drive will enter the Stop mode when the Coast Stop comman...

Page 54: ... DISABLED while drive is ramping to a stop or stopped H1 18 Ramp Enable RO Used as an input to the Ramp 1 block J1 Its value is DISABLED during a quick stop H1 19 Loop Enable RO Used as an input to the control loops Its value is ENABLED while drive is running or jogging Exception is when drive is At Standstill S1 06 H1 20 Drive Mode RO Indicates the status of the specific drive mode Numeric Value ...

Page 55: ...e reference i e REF A D REMOTE SS LOCAL REF Starting and stopping is controlled remotely The drive reference is controlled via the keypad H2 03 Local Run Command RO ON indicates the drive is running in the local mode H2 04 Local Jog Command RO ON indicates the drive is jogging in the local mode H2 05 Local Dir Command RO Indicates the commanded direction in the local mode H2 06 Local Remote Button...

Page 56: ...s 5 and 6 control the I1 02 I1 03 respectively The table below shows the 4 input combinations used to select the different references I1 02 I1 03 Reference OFF OFF Reference A I1 04 OFF ON Reference B I1 05 ON OFF Reference C I1 06 ON ON Reference D I1 07 Table 11 Reference Select I1 04 Reference A R W Preset 0 00 I1 05 Reference B R W Preset 10 00 I1 06 Reference C R W Preset 15 00 I1 07 Referenc...

Page 57: ...he Velocity Demand G2 01 signal for the Velocity Loop Each of the four setpoints has a multiplier I2 01 Multiplier A R W Preset 100 00 Multiplier for Ramp Output signal Range 300 300 I2 02 Setpoint B R W Preset 0 00 This value is summed with the drive s reference via the Ramp 1 block Range 300 300 I2 03 Multiplier B R W Preset 100 00 Multiplier for Setpoint B Range 300 300 I2 04 Setpoint C R W Pre...

Page 58: ...s used In the factory preset configuration the A set is used in the run mode and the B set is used in the jog mode J1 01 Fwd Accel Time A R W Preset 5 0 Secs Defines the time that it takes for the reference to increase from 0 00 to 100 00 Range 0 1 600 Secs J1 02 Fwd Decel Time A R W Preset 5 0 Secs Defines the time that it takes for the reference to decrease from 100 00 to 0 00 Range 0 1 600 Secs...

Page 59: ...Preset 0 0 Secs J1 16 S Decel End Time B R W Preset 0 0 Secs Parameters J1 09 J1 16 are used when Ramp Select J1 17 is set to B Otherwise parameters J1 01 J1 08 are used J1 17 Ramp Select R W Preset A Determines which ramp parameters are used When A is selected parameters J1 01 J1 08 are used When B is selected parameters J1 09 J1 16 are used J1 18 Ramp Bypass R W Preset Off When ON the ramp is by...

Page 60: ...s the time that it takes for the ramp output to decrease from 0 00 to 100 00 Range 0 1 600 Secs J2 04 Rev Decel Time A R W Preset 5 0 Secs Defines the time that it takes for the ramp output to decrease from 100 00 to 0 00 Range 0 1 600 Secs J2 05 S Accel Begin Time A R W Preset 0 0 Secs Defines the S Curve characteristic at the beginning of the acceleration ramp Range 0 10 Secs J2 06 S Accel End T...

Page 61: ...ut J2 21 is equal to the Ramp Input J2 20 J2 19 Ramp Threshold R W Preset 1 00 The block compares the input to the output to determine if the ramp is active The Ramp Threshold sets how much difference between the input and output is required for the ramp to be considered active Range 0 100 J2 20 Ramp Input RO The input to the ramp block J2 21 Ramp Output RO The output to the block The Ramp Output ...

Page 62: ...field loss fault if the field current G3 08 drops below the level set by K1 04 K1 04 Field Loss Level R W Preset 2 00 Defines the level of field current where a field loss fault is generated Range 0 100 K1 05 Field OV Enable R W Preset Enabled When ENABLED the drive will generate a field over voltage fault if excessive field voltage is detected The over voltage level is set by K1 06 The amount of ...

Page 63: ...the armature current to exceed 105 before an over current fault is generated If the current drops below 105 the timer will reset Range 0 240 Secs K1 13 Motor Overspeed Level R W Preset 125 00 Only used if G2 15 is set to TACHOMETER or ENCODER Defines the level of an over speed fault The percentage adjustment is based on the velocity feedback G2 17 Range 0 125 K1 14 External Fault R W Preset Off Ty...

Page 64: ... Over Current Field Over Voltage External Fault Thermistor Open Undefined CT ID Board Phase Loss Heatsink Over Temp Armature Over Current Motor Over Speed Armature Over Voltage Feedback Loss Field Loss 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 Table 12 Faults 1 K2 04 Active Faults 2 RO Refer to K2 03 Undefined Undefined Undefined Undefined Undefined Undefined Undefined CN29 Unplugged Com C Timeout Motor Dat...

Page 65: ...rive has a field fault K2 10 Drive Ready RO YES indicates the drive is ready to run The drive is considered ready to run when the Run Enable H1 12 is in the ENABLED state and Drive Faulted K2 08 is NO K2 11 Active Alarms 1 RO This parameter indicates which alarms are currently active A 1 indicates the alarm is active and a 0 indicates the alarm is not active Undefined Undefined Undefined Undefined...

Page 66: ...cent Fault RO K3 07 7th Most Recent Fault RO K3 08 8th Most Recent Fault RO K3 09 9th Most Recent Fault RO K3 10 10th Most Recent Fault RO The fault log keeps track of the last 10 faults The newest fault is stored in K3 01 The oldest fault is stored in K3 10 K3 11 Clear Fault Log R W Preset No Clears K3 01 K3 10 to NONE when set to YES The value automatically returns to NO Figure 51 ...

Page 67: ...al Vel Demand RO The final velocity demand level G2 04 when the fault occurred K4 09 Velocity Feedback RO The velocity feedback level G2 17 when the fault occurred K4 10 Final Current Demand RO The final armature current demand level G1 08 when the fault occurred K4 11 Arm Current Feedback RO The armature current feedback level G1 12 when the fault occurred K4 12 Armature Conduction RO The armatur...

Page 68: ...s Range 0 600 L1 06 Deadband R W Preset 0 00 This adjustment is used to provide a window of tolerance in the error signal that the integral circuit will ignore This is commonly used to ignore small dancer movements Range 0 30 L1 07 Integral Clamp R W Preset Off When ON the integral signal is clamped to zero in the PID loop yielding proportional derivative control only L1 08 Integral Hold R W Prese...

Page 69: ...s RO When ON the PID output signal has saturated This may indicate that the PID Trim L1 21 may need to be increased This parameter is provided for aid in setup and tuning L1 20 Initial Output RO The initial output of the PID loop This value is the sum of parameters L1 16 L1 18 Parameters L1 10 and L1 11 also limit this value L1 21 PID Trim R W Preset 10 00 A scale that is applied to L1 20 that pro...

Page 70: ...ed to calculate the diameter LINE REVOLUTIONS Similar to the ROLL REVOLUTIONS selection above However the sensor producing the pulse train is located on a line roller instead of the winder unwinder roll The Circumference L2 06 of the line roller is also required along with the Material Thickness L2 04 to calculate the diameter LINE ROLL This method uses Line Speed L3 01 along with the Roll Speed L...

Page 71: ...L2 08 External Roll Speed R W Preset 0 00 Used only when L2 01 is set to LINE ROLL Typically the Filtered Velocity Feedback G2 18 is linked to this parameter This value informs the diameter calculator of the speed of the winder unwinder roll Range 100 100 L2 09 Core Speed R W Preset 100 00 Used only when L2 01 is set to LINE ROLL This parameter defines the maximum level of L2 08 The maximum level ...

Page 72: ...e the center drive speed reference Depending on required system response a dancer or other device may be required for limited transient compensation between the center winder unwinder and other driven parts of a line L3 01 Line Speed R W Preset 0 00 Represents the speed of the line Typically an analog or frequency input is linked to this parameter The external signal should be scaled so that 0 rep...

Page 73: ... desired tension level Range 0 100 L4 02 Taper Diameter R W Preset 600 00 The diameter level at which tapering begins Range 0 01 600 L4 03 Percent Taper R W Preset 0 00 Defines how much the tension demand is tapered reduced The amount of taper is a percentage of the setpoint Refer to Figure 59 In this example the Tension Setpoint L4 01 is set to 100 00 and the Percent Taper L4 03 is 20 00 Thus at ...

Page 74: ...vides a means to scale the Diameter Torque level so that a Tension Demand L4 04 level of 100 provides only the required torque level to achieve 100 tension Range 0 300 L5 02 Diameter Torque RO In order to provide constant tension the winder torque must increase proportionally to the increase in diameter This signal is produced with input from the Diameter Calculator and the Taper Tension Calculato...

Page 75: ...00 L5 09 Friction Torque RO Torque is required to overcome the friction in the mechanics of the drive train The torque required is proportional to the winder roll speed L5 10 Static Friction Comp R W Preset 0 00 This parameter provides a minimum or bias starting torque level Range 0 100 L5 11 Pulse Threshold R W Preset 0 00 The level that the Line Speed L3 01 signal must exceed before pulse torque...

Page 76: ...o sum in a correction signal from the output of a PID block when loadcells are used with the CTCW Calculator Range 0 100 L5 16 Total Torque RO The sum of the L5 02 L5 07 L5 09 L5 10 L5 14 L5 15 This parameter is typically used as the reference if the drive is in the torque mode If the drive is in the velocity mode it is often used as a current limit ...

Page 77: ...lock that performs this function Figure 61 L6 01 MOP Increase R W Preset Off When ON L6 09 increases at the rate defined by L6 03 up to a maximum value of L6 05 When OFF L6 09 stops increasing and holds its value L6 02 MOP Decrease R W Preset Off When ON L6 09 decreases at the rate defined by L6 04 down to a minimum value of L6 06 When OFF L6 09 stops decreasing and holds its value L6 03 Increase ...

Page 78: ... the thresholds M1 03 Threshold 1 On Level R W Preset 50 00 When M1 01 equals or exceeds this level the switch is on Range 300 300 M1 04 Threshold 1 Off Level R W Preset 40 00 When M1 01 equals or falls below this level the switch is off Range 300 300 M1 05 Threshold 1 On Val R W Preset 100 00 The ON input to the switch The value is selected when the switch is on Range 300 300 M1 06 Threshold 1 Of...

Page 79: ...its before the Upper Limit Exceeded or Lower Limit Exceeded outputs change to ON Range 0 60 Secs M7 06 Reset Mode R W Preset Manual When in Manual the Upper Limit Exceeded and or Lower Limit Exceeded outputs will latch and remain in the ON state The outputs are reset to OFF when Manual Reset is momentarily set to ON When in Automatic the outputs automatically change from ON to OFF when the input s...

Page 80: ...Preset 90 00 M8 04 Lower Limit R W Preset 10 00 M8 05 Delay Time R W Preset 0 0Secs M8 06 Reset Mode R W Preset Manual M8 07 Manual Reset R W Preset Off M8 08 Upper Limit Exceeded R O M8 09 Lower Limit Exceeded R O M8 10 Limit Exceeded R O Thresholds 8 is functionally identical to Threshold 7 Refer to M7 XX ...

Page 81: ...off The timer ignores any successive input changes while the timer is timing i e successive input changes do not reset the timing After the timer has stopped the timer can be restarted by toggling N1 02 from OFF to ON ONE SHOT RE TRIGGERABLE Performs the same as the ONE SHOT described above except that successive state changes on the input restart the timing SINGLE CYCLE When N1 02 changes to ON t...

Page 82: ...switch The value is selected when the switch is off Range 300 300 N1 07 Timer 1 Status RO Indicates the status of the timer STOPPED or TIMING N1 08 Timer 1 Value RO The value of the timer N1 09 Timer 1 Output Status RO Displays the status of the timer switch either ON or OFF N1 10 Timer 1 Output RO The output of the timer block This parameter will equal N1 05 when the switch is on It will equal N1...

Page 83: ...logical NOR between Inputs A O1 02 and Input B O1 03 The output O1 04 will be OFF when either of the inputs are ON Refer to Table 16 A XOR B Performs a logical XOR exclusive or between Inputs A O1 02 and Input B O1 03 The output O1 04 will be ON when either of the inputs are ON but not both An alternative view is the output will be ON when the inputs are different from each other Refer to Table 16...

Page 84: ...Input B O1 03 FILTER Input A O1 02 is the filter input Input B O1 03 is the filter gain The filter output is O1 04 SR FLIP FLOP Functions as a Set Reset Flip Flop Input A O1 02 functions is the Set input Input B O1 03 functions as the Reset input The flip flop output is O1 04 Refer to Table 16 POS EDGE LATCH The value of Input A O1 02 is latched into the output O1 04 when Input B O1 03 changes fro...

Page 85: ... Off On No Change Off On Off On On Off On Off Off On Off Off On On Off On Off On On On On Off On Off Off On Off Table 16 Logic Gates Truth Table O2 Logic Gate 2 O3 Logic Gate 3 O4 Logic Gate 4 O5 Logic Gate 5 O6 Logic Gate 6 Logic Gates 2 6 are functionally identical to Logic Gate 1 Refer to O1 XX ...

Page 86: ...alue is selected when the switch is on Range 327 68 327 67 P1 03 Switch 1 Off Value R W Preset 0 00 The OFF input to the switch The value is selected when the switch is off Range 327 68 327 67 P1 04 Switch 1 Output RO The output of the switch This parameter will equal P1 02 when the switch is on and P1 03 when the switch is off P2 Switch 2 P3 Switch 3 P4 Switch 4 P5 Switch 5 P6 Switch 6 Switches 2...

Page 87: ...ation Q1 Internal Link Group 1 Q1 01 Internal Link 1 Src ICR Preset J1 21 Ramp Output Defines the source parameter via its tag Q1 02 Internal Link 1 Dest ICR Preset G1 19 Open Loop Ref Defines the destination or target parameter via its tag Q1 03 Internal Link 2 Src ICR Preset J1 21 Ramp Output Defines the source parameter via its tag Q1 04 Internal Link 2 Dest ICR Preset G1 19 Torque Reference De...

Page 88: ...ors R1 05 PortA Device Message RO The total number of messages that were addressed to this drive R1 06 PortA Device No Resp RO The total number of times the drive did not respond to a message due to an error R1 07 PortA Break Detected RO The total number of times the drive detected a break condition R1 08 PortA Framing Errors RO The total number of times the drive detected a framing error R1 09 Po...

Page 89: ...ber of messages that were addressed to this drive R2 06 PortB Device No Resp RO The total number of times the drive did not respond to a message due to an error R2 07 PortB Break Detected RO The total number of times the drive detected a break condition R2 08 PortB Framing Errors RO The total number of times the drive detected a framing error R2 09 PortB Overrun Errors RO The total number of times...

Page 90: ...C Bus Exceptions RO The total number of exception errors R3 10 PortC Device Message RO The total number of messages that were addressed to this drive R3 11 PortC Device No Resp RO The total number of times the drive did not respond to a message due to an error R3 12 PortC Break Detected RO The total number of times the drive detected a break condition R3 13 PortC Framing Errors RO The total number...

Page 91: ...evel S1 03 Standstill Timer R W Preset 0 1 Secs Defines the timer period where both the Velocity Demand G2 01 and the Velocity Feedback G2 17 must be below the Zero Speed Setpoint S1 01 before At Standstill S1 06 becomes ON Range 0 10 Secs S1 04 At Zero Setpoint RO ON indicates the Reference I1 10 parameter is below the Zero Speed Setpoint S1 01 S1 05 At Zero Demand RO ON indicates the Velocity De...

Page 92: ...1 10 Phase Loss Status RO ON indicates at least one of the three phase AC lines is missing T1 11 CT ID Status RO Displays the current transformer board ID value T1 12 Heatsink Temp Raw RO Displays the raw analog to digital conversion value from the heatsink temperature sensor T1 13 Heatsink Temperature RO Displays the heatsink temperature in degrees Celsius T1 14 Heatsink OT Level RO Displays the ...

Page 93: ...ouble detecting the frequency it can be specifically set to 50 HZ or 60 HZ T2 03 Line Freq Status RO When T2 02 is set to AUTO this indicates the line frequency detected by the drive If a specific frequency is selected via T2 02 it will also be displayed here T2 04 Regenerative Enable ICR Preset Enabled Used only when T1 07 is REGENERATIVE When DISABLED the reverse bridge is disabled and forces a ...

Page 94: ...ce for the outputs U1 Auxiliary U1 01 Aux 1 R W Preset 0 00 U1 02 Aux 2 R W Preset 0 00 U1 03 Aux 3 R W Preset 0 00 U1 04 Aux 4 R W Preset 0 00 U1 05 Aux 5 R W Preset 0 00 U1 06 Aux 6 R W Preset 0 00 U1 07 Aux 7 R W Preset 0 00 U1 08 Aux 8 R W Preset 0 00 U1 09 Aux 9 R W Preset 0 00 U1 10 Aux 10 R W Preset 0 00 U1 11 Aux 11 R W Preset 0 00 U1 12 Aux 12 R W Preset 0 00 U1 13 Aux 13 R W Preset 0 00 ...

Page 95: ...8 Digital Input 5 Status RO Off On Off B5 03 4739 Digital Input 5 Off Value RW Varies 0 B5 04 4740 Digital Input 5 On Value RW Varies 1 B6 01 4865 Digital Input 6 Destination ICR A1 01 U1 20 I1 03 B6 02 4866 Digital Input 6 Status RO Off On Off B6 03 4867 Digital Input 6 Off Value RW Varies 0 B6 04 4868 Digital Input 6 On Value RW Varies 1 B7 01 4993 Digital Input 7 Destination ICR A1 01 U1 20 K1 ...

Page 96: ... 3 Unipolar 0 Cal RW 0 4095 0 C3 07 6535 Analog Input 3 Unipolar 100 Cal RW 0 4095 4095 C3 09 6537 Analog Input 3 Bipolar 100 Cal RW 0 2047 2047 C3 10 6538 Analog Input 3 Bias RW Varies by Destination 0 00 C3 11 6539 Analog Input 3 Gain RW Varies by Destination 100 00 C4 01 6657 Analog Input 4 Destination ICR A1 01 U1 20 00 00 C4 02 6658 Analog Input 4 Status RO 2048 4095 0 C4 03 6659 Analog Input...

Page 97: ...7 Analog Output 2 Source ICR A1 01 U1 20 G1 13 E2 02 10498 Analog Output 2 Gain RW 300 00 300 00 100 00 E2 03 10499 Analog Output 2 Bias RW 300 00 300 00 0 00 E2 04 10500 Analog Output 2 Absolute Value RW Off On Off E2 05 10501 Analog Output 2 Status RO 4095 4095 0 F1 01 12417 AC Line Voltage ICR 0 510V 0V F1 02 12418 Armature Current ICR Varies 0A F1 03 12419 Armature Voltage ICR 0 500V 0V F1 04 ...

Page 98: ...G2 07 14599 Armature Feedback Filtered RO 120 00 120 00 0 00 G2 08 14600 Armature Voltage RO 600 600V 0V G2 09 14601 IR Compensation RW 0 00 30 00 0 00 G2 10 14602 Tach Feedback Raw RO 0 4095 0 G2 11 14603 Tach Feedback RO 125 00 125 00 0 00 G2 12 14604 Tach Feedback Filtered RO 125 00 125 00 0 00 G2 13 14605 Encoder Feedback RO 125 00 125 00 0 00 G2 14 14606 Encoder Feedback Filtered RO 125 00 12...

Page 99: ...rrent Alarm Status RO Off On Off G3 33 14753 Auxiliary Field Reference RW 0 00 100 00 0 00 G3 34 14754 Field Current Feedback Offset ICR 10 00 10 00 0 00 H1 01 16513 Logic Select ICR Mom MainRD MainFR MainRD H1 02 16514 Start Run Forward RW Off On Off H1 03 16515 Stop Run Reverse RW Off On On H1 04 16516 Jog Jog Forward RW Off On Off H1 05 16517 Reverse Jog Reverse RW Off On Off H1 06 16518 Jog De...

Page 100: ...0Secs J1 15 20623 B S Decel Start Time RW 0 0 10 0Secs 0 0Secs J1 16 20624 B S Decel End Time RW 0 0 10 0Secs 0 0Secs J1 17 20625 Ramp Select RW A B A J1 18 20626 Ramp Bypass RW Off On Off J1 19 20627 Ramp Threshold RW 0 00 100 00 1 00 J1 20 20628 Ramp Input RO 300 00 300 00 0 00 J1 21 20629 Ramp Output RO 300 00 300 00 0 00 J1 22 20630 Ramping Status RO Off On Off J1 23 20631 Reserved J2 01 20737...

Page 101: ...Recent Fault RO Refer to page 109 None K3 02 22914 2nd Most Recent Fault RO Refer to page 109 None K3 03 22915 3rd Most Recent Fault RO Refer to page 109 None K3 04 22916 4th Most Recent Fault RO Refer to page 109 None K3 05 22917 5th Most Recent Fault RO Refer to page 109 None K3 06 22918 6th Most Recent Fault RO Refer to page 109 None K3 07 22919 7th Most Recent Fault RO Refer to page 109 None K...

Page 102: ... 0 00 100 00 0 00 L2 11 24843 Diameter Memory RW Disabled Enabled Disabled L2 12 24844 Core Dia Ratio RO 0 00 100 00 0 00 L2 13 24845 Diameter Max Ratio RO 0 00 100 00 0 00 L2 14 24846 Diameter RO 0 00 600 00 1 00 L3 01 24961 Line Speed RW 100 00 100 00 0 00 L3 02 24962 Line Speed Sum RW 100 00 100 00 0 00 L3 03 24963 Roll Speed Sum RW 100 00 100 00 0 00 L3 04 24964 Roll Speed RO 100 00 100 00 0 0...

Page 103: ...8 Threshold 4 Absolute Value RW Off On Off M4 03 27139 Threshold 4 On Level RW 300 00 300 00 50 00 M4 04 27140 Threshold 4 Off Level RW 300 00 300 00 40 00 M4 05 27141 Threshold 4 On Value RW 300 00 300 00 100 00 M4 06 27142 Threshold 4 Off Value RW 300 00 300 00 0 00 M4 07 27143 Threshold 4 Status RO Off On Off M4 08 27144 Threshold 4 Output RO 300 00 300 00 0 00 M5 01 27265 Threshold 5 Input RW ...

Page 104: ...0 0Secs 0 0Secs N2 09 28937 Timer 2 Output Status RO Off On Off N2 10 28938 Timer 2 Output RO 300 00 300 00 0 00 N3 01 29057 Timer 3 Mode RW Refer to page 81 OnDelay N3 02 29058 Timer 3 Input RW Off On Off N3 03 29059 Timer 3 Delay Time 1 RW 0 1 600 0Secs 5 0Secs N3 04 29060 Timer 3 Delay Time 2 RW 0 1 600 0Secs 5 0Secs N3 05 29061 Timer 3 On Value RW 300 00 300 00 100 00 N3 06 29062 Timer 3 Off V...

Page 105: ...de RW Refer to page 83 A and B O6 02 31490 Logic Gate 6 Input A RW Varies by Mode False O6 03 31491 Logic Gate 6 Input B RW Varies by Mode False O6 04 31492 Logic Gate 6 Output RO Varies by Mode False P1 01 32897 Logic Switch 1 Coil RW Off On Off P1 02 32898 Logic Switch 1 Input A RW 327 68 327 68 0 00 P1 03 32899 Logic Switch 1 Input B RW 327 68 327 68 0 00 P1 04 32900 Logic Switch 1 Output RO 32...

Page 106: ... 00 Q2 15 35087 Internal Link 18 Source ICR A1 01 U1 20 00 00 Q2 16 35088 Internal Link 18 Destination ICR A1 01 U1 20 00 00 Q2 17 35089 Internal Link 19 Source ICR A1 01 U1 20 00 00 Q2 18 35090 Internal Link 19 Destination ICR A1 01 U1 20 00 00 Q2 19 35091 Internal Link 20 Source ICR A1 01 U1 20 00 00 Q2 20 35092 Internal Link 20 Destination ICR A1 01 U1 20 00 00 Q3 01 35201 Internal Link 21 Sour...

Page 107: ...7 37265 Timeout Period RW 0 0 20 0Secs 0 5Secs R3 18 37266 Timeout Action RW None Alarm Fault None R3 19 37267 Timeout Status RO Error OK Error R4 01 37377 Port ID RO 0 65535 0 S1 01 39041 Zero Speed Setpoint RW 0 50 25 00 2 00 S1 02 39042 Standstill Enable RW Disabled Enabled Enabled S1 03 39043 Standstill Timer RW 0 0 10 0Secs 0 1Secs S1 04 39044 At Zero Set RO Off On Off S1 05 39045 At Zero Dem...

Page 108: ... 0 00 U1 07 43143 Aux 7 RW 327 68 327 67 0 00 U1 08 43144 Aux 8 RW 327 68 327 67 0 00 U1 09 43145 Aux 9 RW 327 68 327 67 0 00 U1 10 43146 Aux 10 RW 327 68 327 67 0 00 U1 11 43147 Aux 11 RW 327 68 327 67 0 00 U1 12 43148 Aux 12 RW 327 68 327 67 0 00 U1 13 43149 Aux 13 RW 327 68 327 67 0 00 U1 14 43150 Aux 14 RW 327 68 327 67 0 00 U1 15 43151 Aux 15 RW 327 68 327 67 0 00 U1 16 43152 Aux 16 RW 327 68...

Page 109: ...erly at TB3 on the regulator board EEPROM READ FAULT The drive was unable to read the parameters from the EEPROM Power down the drive for one minute and then re apply power If fault is still present re initialize drive by setting A1 02 9999 Note that this will reset all parameters to factory defaults If fault persists replace processor and or control board EEPROM WRITE FAULT An error occurred when...

Page 110: ...or armature voltage rating and ensure F1 03 is set properly If an armature contactor is used ensure contactor is energizing and contacts are working properly G3 02 Open Loop Ensure Field Economy is enabled G3 04 Ensure motor blowers are functioning properly Reduce the Field Open Loop Reference G3 03 FIELD OVERCURRENT The motor field current exceeded the K1 09 overcurrent trip level for the amount ...

Page 111: ...meter signal G2 11 and invert if necessary F2 02 FEEDBACK LOSS The tachometer or encoder speed feedback signal was not detected by the drive This fault is only applicable when the drive is in tachometer or encoder feedback G2 15 Encoder Verify encoder rating and F3 01 and F3 02 are set properly Ensure proper polarity of encoder signal G2 13 and invert if necessary F3 03 FIELD LOSS The motor field ...

Page 112: ...t operate the drive in the constant horsepower mode OL CONFIG FAULT A1 02 Const HP and G3 02 Open Loop When the drive is in the constant horsepower mode of operation the field loop must be operated in closed loop Set G3 02 Closed Loop Don t operate the drive in the constant horsepower mode COM PORT C TIMEOUT No activity was detected on the Com C RS422 485 Port during the R3 17 time period Verify p...

Page 113: ... need to be activated on one of the slave units Refer to master documentation Terminator Terminating resistors are required at each end of a daisy chained RS 485 network in order to provide clean error free signal transmissions If the Elite Pro is at one end of the daisy chained network activate the terminating resistor by placing position 3 in the closed position down 2 Wire RS 485 networks can o...

Page 114: ...epending upon its method of access read write or read only The Elite Pro makes no distinction between read write and read only with respect to the command For example any register can be read by using Function Code 3 or 4 and any bit can be read using Function Codes 1 or 2 Attempts to write a value to a read only parameter are ignored Since all of the Elite Pro s parameters are implemented interna...

Page 115: ...14166 006 Models EPx200 000 C14166 007 Models EPx250 000 C14166 008 Models EPx300 000 C14166 009 Models EPx400 000 C14166 010 Models EPx500 000 C14166 011 Models EPx600 000 C14166 012 Models EPx700 000 C14166 013 Control Board All models D14171 000 Regulator Board All models D14177 000 Snubber Board All models C14188 000 10 2 Fuses Terminal Block Field Fuses Fast Acting 600VAC Model Amps Carotron ...

Page 116: ...50S175 EPx100 000 250 FUS1009 05 Bussmann FWH250 Littelfuse L50S250 EPx125 000 300 FUS1009 06 Bussmann FWH300 Littelfuse L50S300 EPx150 000 350 FUS1009 04 Bussmann FWH350 Littelfuse L50S350 EPx200 000 450 FUS1009 07 Bussmann FWH450 Littelfuse L50S450 EPx250 000 600 FUS1009 08 Bussmann FWH600 Littelfuse L50S600 EPx300 000 700 FUS1009 09 Bussmann FWH700 Littelfuse L50S700 EPx400 000 1000 FUS1009 12 ...

Page 117: ...Px040 000 56 PMD1026 00 Eupec TT56N14KOF Semikron SKKT57 14E IR IRKT56 14A EPx060 000 92 PMD1027 00 Eupec TT92N14KOF Semikron SKKT92 14E IR IRKT91 14A EPx075 000 105 PMD1019 00 Eupec TT105N14KOF Semikron SKKT106 14E IR IRKT105 14A EPx100 000 131 PMD1029 00 Eupec TT131N14KOF IR IRKT136 14 EPx125 000 EPx150 000 162 PMD1021 00 Eupec TT162N14KOF IR IRKT162 14 EPx200 000 EPx250 000 EPx300 000 251 PMD10...

Page 118: ...118 Prints 11 11 11 11 HUNDREDS J2 TENS J3 ONES J1 CN2A SW1 CN4A CN1A CN3A CN5A CN6A TB1 SW4 CN10 J4 OPTION BD CN12 CN9A TB2 D14171 CONTROL BOARD ASSEMBLY ...

Page 119: ...119 CN6B CN8B CN22 CN28 CN27 CN24 CN20 CN21 CN23 CN25B CN26 CN29B D14163 TRIGGER BOARD ASSEMBLY ...

Page 120: ...120 CN8A TB3 CN50 CN1B D14177 REGULATOR BOARD ASSEMBLY ...

Page 121: ...121 CN40 C14188 SNUBBER BOARD ASSEMBLY ...

Page 122: ...122 CN25A C14166 CT ID BOARD ASSEMBLY ...

Page 123: ...123 C14145 PROCESSOR BOARD ASSEMBLY ...

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Page 126: ...126 Assembly Drawing 200 400HP Models ...

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Page 132: ...132 Assembly Heatsink Chassis 200 300HP Non Regen Models ...

Page 133: ...133 Assembly Heatsink Chassis 400HP Non Regen Model ...

Page 134: ...134 Assembly Heatsink Chassis 200 300HP Non Regen Models ...

Page 135: ...135 Assembly Heatsink Chassis 400HP Regen Model ...

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Page 142: ...142 Wiring Diagram 200 400HP Non Regen Models ...

Page 143: ...143 Wiring Diagram 200 400HP Regen Models ...

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Page 150: ...150 PRO V3 FIRMWARE ...

Page 151: ...151 BLOCK DIAGRAM ...

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Page 154: ...154 Notes ...

Page 155: ...ained perform in compliance with such system s written specifications for a period of one 1 year from the date of shipment of such system As the Purchaser s sole and exclusive remedy under said warrant in regard to such systems including but not limited to remedy for consequential damages the Company will at its option cause without charges any such system to so perform which system is found to th...

Page 156: ...3204 Rocky River Road Heath Springs SC 29058 Phone 803 286 8614 Fax 803 286 6063 Email saleserv carotron com Web www carotron com MAN1063 00 Rev B Issued 02 01 2017 ...

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Summary of Contents for EP2020-000

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Carotron EP2020-000, Instruction Manual, Page: 1 / 156

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Summary of Contents for EP2020-000

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