Manual

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IntelliVAC™ Plus Contactor

Control Module

Bulletin 1503VC

User Manual

Summary of content (387 pages)

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IntelliVAC™ Plus Contactor Control Module Bulletin 1503VC User Manual
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Important User Information Read this document and the documents listed in the Additional Resources section about installation, configuration, and operation of this equipment before you install, configure, operate, or maintain this product. Users are required to familiarize themselves with installation and wiring instructions in addition to requirements of all applicable codes, laws, and standards.
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Table of Contents Chapter 1 Product Description Introduction ...................................................................1-1 Scope ........................................................................... 1-1 Description ................................................................... 1-2 IntelliVAC Features ................................................. 1-5 IntelliVAC Base Module Versions .............................. 1-5 Specifications .....................................................
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ii Table of Contents Chapter 4 Description of Features (cont.) Supply Voltages .......................................................... Real-Time Clock (RTC) ............................................... Time Zone Selection .................................................... Altitude/Air Pressure Compensation (400A Contactors) .... Operations Counter ...................................................... “Master” Counter ........................................................
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iii Table of Contents Chapter 4 Description of Features (cont.) Network Status (DeviceNet)........................................... No Power from IB or DeviceNet ............................... IE Determining Network Baud Rate .......................... On-line but not Allocated to Master........................... Normal Operation & Allocated to a Master................. I/O Connection Timed Out ......................................
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iv Table of Contents Chapter 6 Wiring Wiring (MC) ................................................................. 6-1 Pre Configured Logic Mode ...................................... 6-1 Wiring Diagrams for: – Full Voltage Reversing ........................................... 6-3 – SMC ................................................................... 6-4 – SMC with PFCC ................................................... 6-6 – Reduced Voltage Reactor .......................................
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Table of Contents Chapter 8 Configurations (cont.) MC RS485 Addressing ................................................... 8-6 RS485 Termination Resistor ........................................... 8-6 Programming ................................................................ 8-7 IntelliVAC Base Module Bootloader ........................... 8-7 IntelliVAC Base Module Application Code .................. 8-7 IntelliVAC Plus Bootloader .......................................
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vi Table of Contents Chapter 9 Chapter 10 DeviceLogix (cont.) Up Down Counter................................................... Offline Operations .................................................. Online Operations ................................................... Go Online.............................................................. Change Function Block Attribute Values .................... Online Animation ................................................... Change Logic.........................
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Table of Contents Appendix D Spare Parts ................................................................. D-1 Appendix E DeviceNet Information .................................................. E-1 vii Identify Object ........................................................ E-1 DeviceNet Object ..................................................... E-2 Explicit Connection .................................................. E-4 Parameter Object .....................................................
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viii Table of Contents 1503-UM054C-EN-P – June 2013
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Chapter 1 Product Description Introduction This document contains information for the Allen-Bradley Bulletin 1503VC IntelliVAC™ Plus control module. The Bulletin 1503VC is used to control the Allen-Bradley Bulletin 1502 vacuum contactors that are a significant component of the Bulletin 1500/1900 CENTERLINE Medium Voltage Motor Controllers and Bulletin 7000 Medium Voltage Drives offered by Rockwell Automation.
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1-2 Product Description Description IntelliVAC Plus is an efficient and flexible solution for controlling medium voltage vacuum contactors used in medium voltage motor control, feeder and drive applications. IntelliVAC Plus may be used to control both 400 and 800 Amp contactors. Both electrically held and mechanically latched contactor types can be controlled with IntelliVAC Plus. Figure 1.1 – IntelliVAC Plus Contactor Control Module Figure 1.
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Product Description 1-3 Figure 1.
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1-4 Product Description Description (cont.) IntelliVAC MODULE I/O BASE CONNECTOR ENHANCED CONNECTOR CLOSE/HOLD COILS CLOSE/OPEN COMMANDS TDUV CAP Inputs 8 IN (9 pin) STANDOFF (X3) BASE MODULE CUSTOMER I/O Outputs 2 OUT (4pin) Status LED's (x12) + 2 ON BASE DEVICENET (5pin) DeviceNet COMMUNICATIONS DIP SWITCHES (8pos x 2) 7 Sg.
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Product Description IntelliVAC Features IntelliVAC Base Module Versions 1-5  A wide range of supply voltage (110 – 240 V AC 50/60Hz, 110 - 250 V DC) allows implementation in multiple applications  Consistent vacuum contactor pick-up time (at a given supply voltage) ensures repeatable performance  Selectable vacuum contactor drop-out time improves coordination with upstream power fuses  Electronic altitude compensation (400 A only) eliminates mechanical compensation required for altitudes abov
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1-6 Product Description circuits to reduce thermal output and decrease sensitivity to leakage current. Refer to IntelliVAC manual 1503-UM053_ _-EN-P for catalog numbers for each version of IntelliVAC. IMPORTANT Specifications A Series C, D or Series E IntelliVAC module can be used to replace a Series A or Series B module. When replacing an older series of IntelliVAC with a newer one, note that the Module and Contactor Status outputs may function differently.
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Product Description 1-7 For further information regarding programming of firmware see Chapter 8 “Configuration Programming”.
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1-8 Product Description Through RSNetWorx, IntelliVAC Plus firmware version can be viewed in device general page and base module version can be viewed in parameter page. Series C modules use only version 2.003 application firmware. This firmware is also compatible with the Series A and B modules. Series D modules use only version 3.001 or 3.002 application firmware. This firmware is not compatible with any other Series letter modules. Series E modules use only 4.001 or newer firmware.
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Product Description 1-9 Specifications (cont.) Table 1.B – Electrical Ratings Main Input Voltage (L1 to L2/N) AC – 110 to 240 V rms, +10/-15%, 47 to 63 Hz DC – 110 to 250 V, +10/-15% Description Main Input Current (L1 to L2/N) Contactor Ratings Control Voltage (Amps) (AC or DC) 400/800 120/240 25 A peak (1/2 cy cle) 25 A peak Idle Current (Max imum w ithout contactor coil energized) 400/800 120/240 125 mA 35 mA Hold Current  (max imum) 400/800 120/240 300 mA 100 mA 120 4.6 A 3.
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1-10 Product Description Table 1.C – Altitude Derating  5.1 (0.20) Altitude Maximum Operating Ambient at the control module (°C)  -1000 to 0 60 1 to 1000 60 1001 to 2000 58 2001 to 3000 56 3001 to 4000 54 4001 to 5000 52 Derate by 2°C / 1000 m for high altitude operation 29.7 (1.17) 165.9 (6.53) 5.8 (0.228) 2 places 174.8 (6.88) 185.3 (7.29) 59.4 (2.34) Dimensions in mm (inches) Figure 1.
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Product Description 1-11 1503-UM054C-EN-P – June 2013
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Chapter 2 Receiving and Storage Receiving Upon receiving the controller, remove the packing and check for damage that may have occurred during shipping. Report any damage immediately to the claims office of the carrier. NOTE: If the IntelliVAC Plus module is an integral component of a complete MV controller (Bulletin 1500/1900/7700), special receiving and handling instructions will apply. For details, refer to the service manual provided with the equipment.
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2-2 Receiv ing and Storage 1503-UM054C-EN-P – June 2013
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Chapter 3 Installation General Precautions In addition to the precautions listed throughout this manual, the following statements, which are general to the system, must be read and understood. ATTENTION Safety and Codes The controller contains ESD (electrostatic discharge) sensitive parts and assemblies. Static control precautions are required when installing testing, servicing, or repairing the assembly. Component damage may result if ESD control procedures are not followed.
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3-2 Installation Arrangements The IntelliVAC is offered in two arrangements, Integral (part of a Bulletin 1500/1900, 7700 MV controller) or as an OEM component. Integral to an Allen-Bradley MV Controller The IntelliVAC Plus and IntelliVAC MC are available as primary components of an Allen-Bradley Bulletin 1500/1900, 7700 MV controller as shown in Figure 3.1. Figure 3.
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Installation 3-3 Figure 3.2 – Typical Mounting Configurations Note: Adjacent IntelliVAC modules may be mounted with a minimum separation of 6.4 mm (0.25 inches). Control with Solid-State Devices If control devices that employ electronic or suppressed output circuits are used in the rung(s) that control the inputs to the IntelliVAC, alternate arrangements may be required.
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3-4 Installation It is recommended the user interface with the IntelliVAC Plus using interposing relays if possible. In the event that the IntelliVAC Plus must be interfaced to a Solid State Output consult Table 3.A for allowable leakage current values. Table 3.A – Input Circuit Specifications Command Inputs AC – 70 to 240 V rms DC – 70 to 250 V Max imum on state current for input circuit: 11mAAC @ 276 V AC, 60Hz, T A = 60°C 2.4mADC @ 276 V DC, T A = 60°C Minimum on state current for input circuit: 2.
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Chapter 4 Description of Features Time Delayed Under-Voltage Ridethrough (TDUV) The IntelliVAC Plus incorporates a TDUV feature, which will keep the contactor closed during an input voltage dip or brief power loss. The TDUV time begins, this might be called as ‘low voltage’ protections – see Undervoltage with a CLOSE Command Preset on Page 4-30, once the input line voltage goes <95Vrms just before a Close command is issued or when the input line voltage goes <80Vrms when the Hold cycle is in progress.
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4-2 Description of Features TDUV Programmability With the IntelliVAC Plus unit TDUV settings will be altered via a parameter which has the following range/resolution: 0.2 Sec to Maximum 2.000 Sec. with 1 mSec. resolution Therefore for a 400A contactor this would be from 0.2 sec to 2.000 sec and for an 800A contactor this would be from 0.2 sec to 2.000 sec. The default value of the TDUV time will be dependant on the TDUV settings from the Basic module, in the following manner.
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Description of Features      Contactor Drop-Out Time 4-3 ‘IB1 TDUV time DIP setting = ‘‘0.2’ or ‘0.500’ or ‘1.000’ or ‘2.000’ ‘Sec’ ‘IB2 TDUV time DIP setting = ‘‘0.2’ or ‘0.500’ or ‘1.000’ or ‘2.000’ ‘Sec’ ‘IB3 TDUV time DIP setting = ‘‘0.2’ or ‘0.500’ or ‘1.000’ or ‘2.000’ ‘Sec’ ‘IB4 TDUV time DIP setting = ‘‘0.2’ or ‘0.500’ or ‘1.000’ or ‘2.000’ ‘Sec’ ‘IB5 TDUV time DIP setting = ‘‘0.2’ or ‘0.500’ or ‘1.000’ or ‘2.
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4-4 Description of Features      ‘IB1 Drop-Out Time = ‘ ’50 mSec’ to ‘240 mSec’ (resolution is 1mS) ‘IB2 Drop-Out Time = ‘ ’50 mSec’ to ‘240 mSec’ (resolution is 1mS) ‘IB3 Drop-Out Time = ‘ ’50 mSec’ to ‘240 mSec’ (resolution is 1mS) ‘IB4 Drop-Out Time = ‘ ’50 mSec’ to ‘240 mSec’ (resolution is 1mS) ‘IB5 Drop-Out Time = ‘ ’50 mSec’ to ‘240 mSec’ (resolution is 1mS) The Contactor Drop-Out Time values transferred from the IB units will be available on DeviceNet in the following manner:      Con
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Description of Features 4-5 Time. If the contactor did not close within 200mS then there is a major problem and it probably would not pick up any time after that. A contactor should, if it does not have any mechanical or electrical problems, close within 150mS. If a contactor requires longer than 150mS to close, then this is a sign that it is beginning to have problems. This condition, although it does not cause any faults or warnings, will be logged to the Event Log (see Event Log in Chapter 4).
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4-6 Description of Features Delayed Restart (General) The contactors are assigned rated duties, which define how frequently the contactor can be switched on and off. A timer will be used to prevent the contactor from being re-closed until the amount of time has passed, which represents the rated duty of the contactor. This delay is six (6) seconds for the electrically held contactors, and twelve (12) seconds for the mechanically latched contactors.
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Description of Features    4-7 ‘IB3 Delay Restart Wait Time = ‘ ‘x Sec’ (Note: This value, as it is being viewed, will be constantly updated as the wait time decreases.) ‘IB4 Delay Restart Wait Time = ‘ ‘x Sec’ (Note: This value, as it is being viewed, will be constantly updated as the wait time decreases.) ‘IB5 Delay Restart Wait Time = ‘ ‘x Sec’ (Note: This value, as it is being viewed, will be constantly updated as the wait time decreases.
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4-8 Description of Features Counters must be implemented to keep track of the Jog time as well as for the Jog Repetition time. When a valid Jog command is detected (Open input is active) and the close command is not active, the contactor will be given a close command. The Open input command can also originate from an Open network bit (see Appendix B).
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Description of Features 4-9 Items #30 to #49, in the Event Log, which apply to the DeviceLogix I/O, will only be logged when the DeviceLogix engine is operating. This occurs when the Logic Mask is set to #2 – DeviceLogix (see Chapter 9). All other changes of these input states which occur while Logic Mask is not set to #2, will not be logged to the Event Log. Table 4.
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4-10 Description of Features Table 4.D – Event Log Data (cont.
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Description of Features Coil Currents 4-11 The coil currents represent the average value of the particular coil that is being controlled in each of the IntelliVAC Plus/MC units. The coil current values for each of the five (5) IB units, shall be made available on DeviceNet in the following manner:      ‘IB1 Close Current = ‘ ‘xx.xxx’A (for electrically held or mechanically latched) ‘IB2 Close Current = ‘ ‘xx.xxx’A (for electrically held or mechanically latched) ‘IB3 Close Current = ‘ ‘xx.
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4-12 Description of Features Open Coil Test To check that there is a coil(s) connected to the IntelliVAC Plus unit a test is performed to confirm that the coil current is greater than 200mA. If the coil current measured is lower than this threshold then it can be assumed that the particular Coil Under Test (CUT) is open. If the coil is an open circuit then the IntelliVAC Plus Module Status LED will annunciate the fault (see Table 4.F).
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Description of Features Supply Voltages 4-13 The AC and DC supply voltage measurements represent the RMS values of the input mains for each of the IntelliVAC Plus/MC modules. The voltage values for each of the five (5) IB units, shall be made available on DeviceNet in the following manner:      ‘IB1 Line Voltage ‘IB2 Line Voltage ‘IB3 Line Voltage ‘IB4 Line Voltage ‘IB5 Line Voltage      ‘IB1 DC Bus ‘IB2 DC Bus ‘IB3 DC Bus ‘IB4 DC Bus ‘IB5 DC Bus = ‘ ‘xxx.xx’V = ‘ ‘xxx.xx’V = ‘ ‘xxx.
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4-14 Description of Features The ‘IBx Line Undervoltage’ and ‘IBx Line Undervoltage’ values are included to allow a distinction for Undervoltage conditions during different intervals of the contactor coil operation. Real-Time Clock (RTC) The IntelliVAC Plus Unit contains an RTC with an external 3V lithium battery (see Appendix D for battery replacement type) which will maintain the correct time for a period of at least 20 years when no external power is provided.
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Description of Features Time Zone Selection 4-15 To facilitate in the setting of the time of day for different world time zones, there will be a feature added, which allows the time zone of the area where the IntelliVAC Plus will be operated, to be programmed.
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4-16 Description of Features Altitude/Air Pressure Compensation (400A Contactors) The IntelliVAC Plus is adaptable to a range of atmospheric pressures and altitudes. This should eliminate the need for special return springs within the contactors, by regulating the coil current to apply the appropriate closing, holding and opening force. The range of altitudes covered is: –1,000 → 5,000 metres In this case, a simple “altitude parameter” will be used to adapt the contactor closing force.
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Description of Features “Master” Counter 4-17 The Master counter will include all operations, since initial use of the IntelliVAC Plus product. Each operation refers to the completion of a ‘Close’ operation. If a close command is initiated but the contactor does not close (i.e. due to an under-voltage condition) then the count will not be incremented. A Master Counter shall be provided for each of the IntelliVAC MC units in an MC configuration.
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4-18 Description of Features  ‘IB2 Reset Ops Since Counter’ (present ‘IB2 Ops Since 0 data/time’ saved to ‘IB2 Ops Since 1’ along with counter value and ‘IB2 Ops Since 1 data/time’ saved to ‘IB2 Ops Since 2’ along with counter value) with ‘IB2 Ops Since’ counter = ‘0’  ‘IB3 Reset Ops Since counter’ (present ‘IB3 Ops Since data/time’ saved to ‘IB3 Ops Since 1’ along with counter value and ‘IB3 Ops Since 1 data/time’ saved to ‘IB3 Ops Since 2’ along with counter value) with ‘IB3 Ops Since’ counter = ‘0’
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Description of Features 4-19  ‘IB3 Operation Since 0 Count Value =’ ‘0’ to ‘16777215’ 24 bit counter)  ‘IB3 Operation Since 0 Date =’ ‘Month-Date-Year’  ‘IB3 Operation Since 0 Time =’ ‘Hours-minutes-Seconds-10mS’  ‘IB3 Operation Since 1 Count Value =’ ‘0’ to ‘16777215’ (24 bit counter)  ‘IB3 Operation Since 1 Date =’ ‘Month-Date-Year’  ‘IB3 Operation Since 1 Time =’ ‘Hours-minutes-Seconds-10mS’  ‘IB3 Operation Since 2 Count Value =’ ‘0’ to ‘16777215’ (24 bit counter)  ‘IB3 Operation Since 2 Date =
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4-20 Description of Features “Average Operations” Counter The Average Operations counter will include Average operations per time period (selectable for hours, days or weeks), since a last reset occurred (see “Operations Since” Counter section). This parameter will calculate the average number of operations (valid Close commands) between the last reset time and the present RTC value.
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Description of Features Configuration 4-21 The IntelliVAC Plus Unit will be configured in one of two manners: HIM The standard means of configuring an IntelliVAC Plus shall be with a hand-held configurator for DeviceNet (HIM). It shall be possible to access all “Customer Use” parameters (need to define Customer Use parameters) using the HIM. When accessed via the HIM, parameters will be grouped/selected according to the following – Control, Communications, Configuration & Diagnostics, see Appendix B.
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4-22 Description of Features In an MC system all MC operation will cease and communications between the various MC modules will stop as well. A fault message will be made available on DeviceNet signifying that the IntelliVAC Plus unit is not completely functioning. This condition will indicate that the contactor will be out of order. The following fault parameter will be made available on DeviceNet in the following manner:  ‘IB1 Power Fail Status = ‘Good’ or ‘Bad’ See Table 4.
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Description of Features 4-23 Table 4.
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4-24 Description of Features The Contactor status LED is off to indicate that the contactor is in an Open condition and the Contactor status relay is open to reflect the status of the contactor thus preventing externally connected circuits from functioning. This condition is valid for both Electrically Held and Mechanically Latched contactors. Healthy Module and Contactor CLOSED This is a Normal condition and no additional action is required.
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Description of Features 4-25 Close, Jog or Trip commands are present during a power on sequence.
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4-26 Description of Features Note: Close and Jog are for an Electrically Held contactor and Close and Trip are for a Mechanically Latched contactor. The Close or Jog commands are re-applied before the contactor opening sequence can be verified. Once a Close or Jog command are issued, the commands must be removed for a period of at least 60mS, plus the Drop Out Delay time, before re-applying the commands (see Figure 5.5 for a timing representation of the contactor control commands).
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Description of Features 4-27 This is a Fault condition and the IntelliVAC Plus will not respond to other commands until this condition is restored to normal. Check the condition of the contactor or the status of the Contactor Auxiliary Input. This indicates that the Basic module within the IntelliVAC Plus unit has a fault due to a power up condition occurring with the contactor in a Closed position and the status of the contactor being controlled is in a Closed condition.
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4-28 Description of Features Contactor Drop Out During Hold This is a Warning condition and the status of the contactor coil or Contactor Auxiliary Input should be checked. This indicates that the Basic module within the IntelliVAC Plus unit has a warning due to the contactor dropping out when it should be in the hold mode after being given a Close or Jog command and the status of the contactor being controlled is in an Open or Closed condition (dependant on the status of the contactor).
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Description of Features 4-29 Microcontroller Malfunction This is a serious Fault condition and the IntelliVAC Plus will not respond to other commands. Refer all servicing to a qualified service personnel or see the trouble shooting section in Chapter 10. This indicates that the Basic module within the IntelliVAC Plus unit has a severe fault due to a microcontroller malfunction and the status of the contactor being controlled is in an Open condition.
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4-30 Description of Features Contactor Fails to Drop Out This is a Fault condition and the IntelliVAC Plus will not respond to other commands until this condition is restored to normal. Check the condition of the contactor or the Contactor Auxiliary Input.
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Description of Features 4-31 The Contactor status LED is off to indicate that the contactor is in an Open condition and the Contactor status relay is Open to reflect the status of the contactor thus preventing externally connected circuits from functioning. This condition is valid for both Electrically Held and Mechanically Latched contactors. Undervoltage with a CLOSE Command Preset This is a Warning condition and the level of the input mains voltage should be checked.
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4-32 Description of Features This condition is valid for both Electrically Held and Mechanically Latched contactors (TDUV and <80Vrms during hole conditions do not apply for Mechanically Latched contactors). IMPORTANT IE Module/Network Status LEDs On a fault occurrence, of either the IB or IE units, the contactor will be opened either by removing power to the hold coil in an electrically held contactor or by pulsing the trip coil in a mechanically latched contactor. Module Status Figure 4.
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Description of Features 4-33 Table 4.F - Plus Fault/Warning Description Fault/Warning Red LED Green LED Description None None Off Solid On Application Firmw are Running Off Flash @ 0.25Hz Application Disable Jumper In None Off Flash @ 0.
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4-34 Description of Features When a fault/warning occurs, the appropriate LED will flash and the appropriate fault/warning will be written to the Event Log. When the fault/warning goes away, the LED pattern will stop flashing but if the fault warning reappears again later, the process will repeat. If only faults or warnings exist then the latest fault or warning will be annunciated. If faults and warnings both exist, then only the last fault occurrence will be displayed.
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Description of Features 4-35 Programming Base Unit(s) This is a Normal firmware flashing condition and no additional action is required. The Basic module is in the process of being flashed from a PC over the RS485 communications link. The data rate for this process is 9600 baud. See Chapter 8 for Firmware Flashing. The Plus status LED is flashing Green at a 0.50Hz rate so that the LED is on for 1 second, then off for 1 second and then it repeats.
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4-36 Description of Features Line Undervoltage This is a Warning condition which may not be rectified by the user. Check input line voltage levels and rectify if possible. The line mains input voltage has gone to a voltage level of <95Vrms when the contactor is initiating a close cycle or the input voltage has gone below a voltage level of 80Vrms when the contactor is in a hold cycle.
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Description of Features Table 4.G – Contactor Extended Close Times CONTACTOR CONFIGURATION @ Vinput 400A Mech. 400A Elec. 800A Mech. 800A Elec. Latch (7.2 kV) Held (7.2 kV) Latch (7.2 kV) Held (7.2 kV) 4-37 Max Close Time @ 120V Max Close Time @ 240V 150 ms 150 ms 150 ms 150 ms 150 ms 150 ms 150 ms 150 ms The ‘Extended Close Time’ Warning is used to indicate that there is a potential problem with one or more of the up to five contactors in an MC system.
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4-38 Description of Features MC Altitude Setting Warning This is a Warning condition which indicates that the Altitude DIP switch settings on the Basic modules in an MC system (one [1] Basic module on the IntelliVAC Plus module and up to four [4] Basic modules on the IntelliVAC MC units) are not all set to the same value.
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Description of Features 4-39 Application Programming Error – CRC This is a Fault condition which indicates that the Application Firmware being programmed into the internal Flash did not program correctly. This error was detected by way of the CRC from the programmed memory not corresponding to the CRC of the original source file. The only functionality that the IntelliVAC Plus has is that it will run the BootLoader firmware and send out the menu over the RS485 link at a 9600 baud rate to a PC.
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4-40 Description of Features Network Status (DeviceNet) There is a Red/Green bi-color LED which is used to indicate the DeviceNet network operating status. Only the Red or Green LED should be on at any one time. Table 4.H shows the operation of the DeviceNet Network Status LED as well as the faults/warnings that it indicates. Table 4.
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Description of Features Network Status (DeviceNet) (cont.) 4-41 IE Determining Network Baud Rate The DeviceNet status LED is flashing Green. On-Line but Not Allocated to Master The DeviceNet status LED is flashing Green. Normal Operation & Allocated to a Master This is a Normal condition and indicates that the IntelliVAC Plus is on-line and has connections in the established state. As a UCMM capable device it means that it has one or more established connections.
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4-42 Description of Features Table 4.
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Description of Features 4-43 The DeviceNet status LED is solid Green.
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4-44 Description of Features Recoverable Fault This is a Warning condition and indicates that the IntelliVAC Plus has a minor recoverable fault: for example, the node MAC switch address is changed online. The DeviceNet status LED is flashing Red. Unrecoverable Fault This is a Fault condition and indicates that the IntelliVAC Plus has an unrecoverable fault. The unit may require replacement. The DeviceNet status LED is solid Red.
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Description of Features 4-45 For the 7-segment LED display, the ‘Watchdog Timeout’ and the ‘System Lock-Out State’ will have the highest priority with the ‘Watchdog Timeout’ being the higher of the two. If there are multiple MC faults, then the highest MC fault, only, will be displayed on the 7-segment display. Table 4.
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4-46 Description of Features MC Bad MC #1 This is a Fault condition and indicates that the IntelliVAC MC #1, which is contained in the IntelliVAC Plus module, has a faulty RS485 communications. The 7-segment display will display the flashing character ‘1’. MC Bad MC #2 This is a Fault condition and indicates that the IntelliVAC MC #2, which is an external module, has a faulty RS485 communications. The 7-segment display will display the flashing character ‘2’.
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Description of Features 4-47 See Table 8.K for a definition of which IntelliVAC unit is to have the termination resistor inserted. See Table 8.J for instructions detailing how to enable the termination, resistor using the DIP switches on the MC board. The 7-segment display will display the flashing character ‘6’. System Lock-Out State This is a Fault condition and indicates that in an MC system configuration, a particular fault has been reset three times without having the fault clear.
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4-48 Description of Features The 7-segment display will display the flashing character ‘7’ + ‘Decimal Point’. Watchdog Timeout – Fatal Error This is a fatal Fault condition which indicates that the Enhanced module program has crashed and is no longer executing correctly. In this case the watchdog timer has been allowed to time out. The 7-segment display will display the flashing character ‘8’ + ‘Decimal Point’.
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Chapter 5 IntelliVAC Plus Basic Wiring IntelliVAC Base Wiring Fuse Protection The IntelliVAC module requires external fuse protection to coordinate with the power supply and contactor. The fuse ratings shown in Table 5.A allow the passage of inrush currents expected when the contactor is closed, or from recommended external capacitors for the TDUV option. They will also protect the contactor coils in the event of a module malfunction.
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5-2 IntelliVAC Plus Basic Wiring Grounding The IntelliVAC module must be connected to a common ground terminal (PE) on the controller panel. The ground terminal is located on the bottom of module enclosure (refer to Figure 5.1). It is important that IntelliVAC is properly grounded using the ground connection provided. Failure to do so may result in damage to equipment or personal injury.
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IntelliVAC Plus Basic Wiring Interface Connections 5-3 Further control interface connections are made at a twelve-pole connector located on the top of the module. Refer to Figure 5.2 and Table 5.B for connections (and Table 1.B for electrical ratings). 1 2 3 4 5 6 7 8 9 10 11 12 EX. CAP. CONTACTOR INTERFACE Figure 5.2 – Top side connections Table 5.B – Terminal Assignments for IntelliVAC Base Interface Connections  Terminal No.
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5-4 IntelliVAC Plus Basic Wiring Wiring Guidelines Electrically Held Contactors When configured for basic control the IntelliVAC Plus can be applied with two- or three-wire control circuits. The control system utilized will determine the configuration of the input wiring.
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IntelliVAC Plus Basic Wiring 5-5 For Emergency Stop applications requiring removal of power, a contact should be placed in the “L1” control power rung to the IntelliVAC. If the TDUV feature is used, the contactor will not open until the programmed TDUV time has expired. ATTENTION CONTROL POWER CAPACITOR (OPTIONAL) M-IV 1 CONTROL POWER FUSE TCO EC 2 4 3 M 11 12 L1 EMERGENCY STOP (when requ ired) AUX CCO G 6 M 5 L2/N RUN OVERLOAD MOV * Refer to Appendix A for recommended sizing.
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5-6 IntelliVAC Plus Basic Wiring Wiring Guidelines Electrically Held Contactors (cont.) CONTROL POWER CAPACITOR (OPTIONAL) * CONTROL POWER FUSE M-IV 1 EC 2 + TCO 11 AUX 12 CCO 4 3 M L1 EMERGENCY STOP (when required) OVERLOAD STOP * Refer to Appendix A for recommended fuse sizing. G 6 5 MOV M L2/N START M-IV M-IV 9 + - 10 CLOSE 15 16 CONTACTOR STATUS Figure 5.4 – Three-Wire Control Figure 5.
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IntelliVAC Plus Basic Wiring Wiring Guidelines Mechanical Latch Contactors 5-7 IntelliVAC control may be used for mechanical latch contactors. A momentary control signal is needed to close the contactor, and a second momentary control signal is needed to open the contactor. The momentary open/close commands must be at least 50 milliseconds in duration. Refer to Figure 5.6 for a typical mechanical latch control scheme. Note: 1.
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5-8 IntelliVAC Plus Basic Wiring Mechanical Latch Contactors Capacitor Trip The IntelliVAC can be configured to provide capacitor trip functionality with mechanical latch contactors. A capacitor must be connected to the IntelliVAC (terminals #1 and #2) in order to provide this capability. The capacitor provides control power for the IntelliVAC as well as stored energy to trip the contactor. Maximum recommended capacitor size is 1650 µF for 120V control or 330 µF for 240V control.
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IntelliVAC Plus Basic Wiring 5-9 CONTROL POWER * CONTROL POWER FUSE OPEN M-IV OVERLOAD 7 + - 8 OPEN M MOV M-IV CAPACITOR 1 EC 2 + 4 3 TCO MOV M 11 AUX 12 L1 OVERLOAD TC CCO G 6 5 CC L2/N M-IV CLOSE * Refer to Table 3.A for recommended fuse sizing. 9 + - 10 CLOSE Figure 5.7 – Mechanical Latch Contactor with Capacitor Trip Option Time Delay Undervoltage The IntelliVAC can be configured to provide time delay undervoltage (TDUV) protection.
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5-10 IntelliVAC Plus Basic Wiring Table 5.D – Maximum TDUV Time (without Capacitor) Max. TDUV Time (secs) Control Voltage 110/120 V 220/240 V 400 A 800 A 0.2 1.0 0.2 1.0 If the undervoltage condition persists beyond the set delay time, the contactor will be opened and an undervoltage fault or warning condition will occur (see Line Undervoltage and Table 4.F in Chapter 4). Table 5.E – Maximum TDUV Time (with Capacitor) Max. TDUV Time (sec) Control Voltage 400A 2.0 2.
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IntelliVAC Plus Basic Wiring 5-11 Figure 5.
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5-12 IntelliVAC Plus Basic Wiring Figure 5.10 – Wiring Diagram for Full Voltage Non-Reversing Logic Mask (2) Note: In this configuration the user must upload appropriate control logic to the DeviceLogix Control engine.
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Chapter 6 Wiring Wiring (MC) Pre Configured Logic Mode The IntelliVAC Plus comes with five (5) preprogrammed logic programs corresponding to the five most common types of Rockwell Automation MV controllers requiring multi contactor control.
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6-2 Wiring (MC) Wiring (MC) (cont.) After selecting the desired control program, the IntelliVAC Plus module must be reset to adopt its new settings and load the logic from main memory into the DeviceLogix engine. In order to accomplish this simply cycle the control power of the unit. Note: Be sure to remove both the 120VAC power to the IntelliVAC module, and the 24VDC DeviceNet power. When power is restored to the IntelliVAC Plus the new program will be active in DeviceLogix.
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Wiring (MC) 6-3 Figure 6.2 – Wiring Diagram for Full Voltage Reversing Configuration Required: • • Gate #34 Off Delay Timer Reverse Contactor Gate #32 Off Delay Timer Forward Contactor Gates # 32 and 34 are the close command disable timers for the respective contactors, typically these timers are set to an equal value.
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6-4 Wiring (MC) Figure 6.3 – Wiring Diagram for SMC This circuit is set up for Soft Start or Current Limit Starting. Maximum two starts per hour with a minimum of five minutes between starts.
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Wiring (MC) 6-5 Figure 6.4 – Wiring Diagram for SMC (cont.) Configuration Required: None This circuit is set up for Soft Start or Current Limit Starting. Maximum two starts per hour with a minimum of five minutes between starts.
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6-6 Wiring (MC) Figure 6.5 – Wiring Diagram for SMC with PFCC This circuit is set up for Soft Start or Current Limit Starting. Maximum two starts per hour with a minimum of five minutes between starts.
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Wiring (MC) 6-7 Figure 6.6 – Wiring Diagram for SMC with PFCC (cont.) Configuration Required: None This circuit is set up for Soft Start or Current Limit Starting. Maximum two starts per hour with a minimum of five minutes between starts.
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6-8 Wiring (MC) Figure 6.
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Wiring (MC) 6-9 Incomplete Sequence Timer The Incomplete sequence timer is designed to ensure that the duty cycle of the reactor is not exceeded in a single start. It controls the maximum amount of time which the unit will pass current through the reactor. If a transition to full voltage has not been made before the incomplete sequence timer expires the start will be aborted, and the unit will be locked from beginning another start until it is manually reset using the reset push button.
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6-10 Wiring (MC) Figure 6.
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Wiring (MC) 6-11 Incomplete Sequence Timer The Incomplete sequence timer is designed to ensure that the duty cycle of the autotransformer is not exceeded in a single start. It controls the maximum amount of time which the unit will pass current through the autotransformer. If a transition to full voltage has not been made before the incomplete sequence timer expires the start will be aborted, and the unit will be locked from beginning another start until it is manually reset using the reset push button.
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6-12 Wiring (MC) 1503-UM054C-EN-P – June 2013
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Chapter 7 Communications The communications systems implemented within the IntelliVAC Plus product can be divided into three sections: 1) RS232 2) RS485 3) DeviceNet RS232 Communications This interface is used for factory programming of the CPU and is only to be used by factory authorized personnel. RS485 Communications This interface is used for three purposes: 1.
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7-2 Communications the RS485 interface, for both the IntelliVAC Base and IntelliVAC Enhanced modules. DeviceNet Communications This interface is used for two purposes: For external communications to a DeviceNet network allow the IntelliVAC Plus and IntelliVAC MC product to be controlled and monitored by an external controller unit. For Flashing the IntelliVAC Plus using ControlFLASH. i) This communications protocol operates at three different baud rates: 125K, 250K and 500K.
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Communications 7-3 If AutoBaud is enabled then the DNet Baud that was selected will be overridden with the baud rate detected on the network. If no network activity is detected, then the baud rate will be set to the default baud rate of 125k. DeviceNet MACID The address of the IntelliVAC Plus device shall be settable either through DeviceNet or through the MACID rotary switches which are accessible on the side of the IntelliVAC Plus enclosure.
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7-4 Communications DeviceNet Profile The IntelliVAC Plus is defined within the “miscellaneous device” object class; however, extended functions may be required compared to devices currently included in this class.
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Communications 7-5 Hold State In general when the hold state option is selected the unit will continue to function based on the last known state of the network commands. This will require the unit to function slightly differently dependent on the logic mask selected, and the number of IntelliVAC MC units which are connected. Mask Network Logic mask 1 is considered a direct command mask; this means that the commands are acted upon directly without the use of DeviceLogix.
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7-6 Communications Mask HIM/PC Logic mask 3 is considered a test and diagnostic state. As such if network communication is lost when operating with logic mask 3 selected the unit will always reset regardless of the selected loss of communication state parameter. Note: Logic mask 0 is not affected by a loss of communication regardless of whether the “HOLD STATE” or “RESET STATE” options are selected since this logic mask accepts commands only from local HW I/O.
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Chapter 8 Configuration/Programming Configuration IB Board DIP Switches Some of the functionality of the IntelliVAC Plus product is derived from the settings of the DIP switches on the IB board. The DIP switch settings are only read once after a power up sequence occurs. If changes are to be made to the DIP switch inputs, then control power must be recycled before the changes will take affect. Firmware Label DIP Switch Figure 8.
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8-2 Configuration/Programming Table 8.A – Altitude Settings DIP SW1 ALTITUDE (m) Contactor Drop Out Time 1 2 3 -1000 to 0 OFF OFF OFF 0 to 1000 OFF OFF ON 1001 to 2000 OFF ON OFF 2001 to 3000 OFF ON ON 3001 to 4000 ON OFF OFF 4001 to 5000 ON OFF ON Not defined ON ON OFF Not defined ON ON ON This set of switches defines the amount of time, after an OPEN command has been issued, when the contactor actually drops out.
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Configuration/Programming Contactor Type 8-3 This set of switches defines the type of vacuum contactor that is to be controlled. Note: These settings are used exclusively to determine the contactor type. These setting cannot be set on the IntelliVAC Plus module but can only be read from the IB module. Table 8.C – Contactor Type CONTACTOR CONFIGURATION 400A Mech. Latch (7.2kV) 400A Elec. Held (7.2kV) 800A Mech. Latch (7.2kV) 800A Elec. Held (7.
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8-4 Configuration/Programming Time Delay Undervoltage Configuration (TDUV) This setting controls the amount of time that the contactor maintains closed on the occurrence of an input line voltage dip. This setting may be overridden by the DeviceNet parameter TDUV Hold-Up Time Source See Section TDUV Programmability in Appendix B for a description. Table 8.E – TDUV Hold-Up Times TDUV Hold-up Time DIP SW2 4 5 0.2 Sec OFF OFF 0.5 Sec 1.0 Sec 2.
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Configuration/Programming 8-5 This function is useful for applications that require a contactor to reclose after a voltage dip or voltage loss. This setting is used exclusively to determine the Power-up safety mode. It cannot be set on the IE module, but can be read from the IB module. Table 8.F – Power-Up Safety Configuration DIP SW2 6 OFF ON Power-up Safety Enabled Disabled Future Use These DIP switches are not used and are for future use. Table 8.
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8-6 Configuration/Programming MC RS485 Addressing This set of DIP switches defines the RS485 address of the IntelliVAC MC unit(s) within an MC system. Table 8.
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Configuration/Programming 8-7 Table 8.
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8-8 Configuration/Programming Programming the IntelliVAC Base Module The IntelliVAC base module firmware is updated using the RS-485 terminal on either an IntelliVAC MC, or an IntelliVAC Plus board. In order to perform a firmware update on the IntelliVAC Base module you will require the following: 1. Either an MC or IE board 2. An RS-485 to RS-232 converter 3. RS-232 cable 4. A personal computer with a functional serial port.
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Configuration/Programming    8-9 Move the application disable jumper to the “Program” position as noted on the printed circuit board. Connect the RS-485 to RS-232 converter to the personal computer using an RS-232 cable. Open a new connection in hyper terminal and configure the connection as shown below: Figure 8.
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8-10 Configuration/Programming Figure 8.5 – IntelliVAC Plus Bootloader Menu  Select the option “Update IntelliVAC base” which will pass control to the IntelliVAC base module, which will then flash its bootloader menu to the screen. Refer to the section Flashing IntelliVAC Base using bootloader Flashing IntelliVAC Base Module using Bootloader Code can only be flashed to the IntelliVAC base module using the RS-485 interface, and hyper terminal with any personal computer with a usable serial port.
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Configuration/Programming 8-11 Figure 8.6 – IntelliVAC Base Bootloader Menu The IntelliVAC base bootloader screen has four options: 1. 2. 3. 4. Verify current firmware Upload new firmware Power on reset IntelliVAC Run current firmware Verify Current Firmware This option performs a CRC check on the full program memory of the IntelliVAC and compares the calculated value to the correct value which is stored in the firmware. If the two CRCs match, then “OK” is displayed.
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8-12 Configuration/Programming Figure 8.7 – IntelliVAC Base Programming Completed Upload New Firmware The upload new firmware option allows the application firmware of the IntelliVAC to be updated to a new version. The file should be provided by Rockwell technical support only. When the “Upload new firmware “option is selected a prompt will appear to begin an X-MODEM-CRC transfer.
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Configuration/Programming 8-13 Figure 8.8 - Upload new firmware prompt and send file dialog box After selecting “Send” the following dialog box will appear and the progress of the transfer will be displayed Figure 8.
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8-14 Configuration/Programming Upon completion of the transfer the transfer dialog box will disappear. The CRC of the new firmware file will be calculated and displayed. If the CRC is good an “OK” will appear beside the CRC and the user will be prompted for input. Pressing any key on the keyboard will return the user to the bootloader main menu. Figure 8.10 - Transfer complete Power on Reset IntelliVAC The power on reset option allows the user to restart the IntelliVAC unit without removing power.
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Configuration/Programming 8-15 Updating the IntelliVAC Plus using Control Flash In order to update the firmware of the IntelliVAC Plus module using DeviceNet you will need the following: 1. Personal computer equipped with a DeviceNet interface such as a 1784-PCD or 1770-KFD 2. RS-Links Software 3. Control Flash Software 4. A functioning device net network including 24VDC DeviceNet power supply.
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8-16 Configuration/Programming Figure 8.12 - Select IntelliVAC Plus in Control Flash • After selecting “OK” the serial number of the device and firmware number to be flashed will be displayed select “Finish” • A progress bar will appear displaying the status of the transfer. When the transfer is complete the unit will be restarted and the following screen will be displayed after a diagnostic delay of approximately 20 seconds. The firmware update is now complete.
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Configuration/Programming 8-17 Figure 8.13 Firmware Update Complete IMPORTANT It will be necessary to cycle power on all modules in the Multi contactor network to re-establish communication between master and slave modules. IE/IB Firmware Revisions The firmware revisions for all of the IB units will be made available on DeviceNet as follows: ‘IB1 Firmware Version = ’ ‘xx.y’ ‘IB2 Firmware Version = ’ ‘xx.y’ ‘IB3 Firmware Version = ’ ‘xx.y’ ‘IB4 Firmware Version = ’ ‘xx.y’ ‘IB5 Firmware Version = ’ ‘xx.
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8-18 Configuration/Programming 1503-UM054C-EN-P – June 2013
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Chapter 9 DeviceLogix Common Acronyms and Short forms DLX – DeviceLogix refers to the integrated logic capability of the IntelliVAC Plus. IE – IntelliVAC Enhanced (IntelliVAC Plus module) refers to the module which contains both the IntelliVAC base module, and IntelliVAC Plus boards. IB – IntelliVAC base module refers to a series E or later IntelliVAC module with no additional circuit boards attached.
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9-2 Dev iceLogix Direct Commands Direct commands are specific commands such as 'open contactor 1' or 'close contactor 4' 1 – Logical Mask 0 (Mask Local) Logic mask 0 can only be selected when the system consists of a single IE/IB combination. In Logic Mask 0, commands will be accepted only from local (hardware) I/O. In Logic Mask 0, the two inputs on the IB unit will not be generic inputs as they are in all other masks.
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Dev iceLogix DeviceLogix 9-3 What is DeviceLogix DeviceLogix functionality has been added to a number of Rockwell Automation devices to control outputs and manage status information locally within a device. The configuration of the DeviceLogix functionality is accomplished through the DeviceLogix Editor.
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9-4 Dev iceLogix • • • • Device Input – A physical input of the device. Device inputs represent the actual inputs, such as sensors or switches which are attached to a particular device. Network Input – Formerly called Consumed Network Bit (CNB), network input is data sent from a master that can be used in the device’s logic. Device Status – Status inputs indicate the state of the device.
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Dev iceLogix 9-5 A connection (wire) between function blocks is defined when an input pin of one function block is bound to an output pin of another function block. A Pin can be Bound to a: • Pin of another function block. • Physical input/output. • Networked input/output. • Fault or status bit. • Miscellaneous bit. Function blocks may also have attributes that influence their function.
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9-6 Dev iceLogix Launching the DeviceLogix Editor After you configure the properties for the IntelliVAC Plus, you can launch the DeviceLogix Editor. There is an additional tab in the device properties dialog box for all DeviceLogix enabled devices. This tab is labeled DeviceLogix. The tab provides access to the start up window for the DeviceLogix Editor. You have the option to fill in your name, a revision number and a description of your configuration (all optional fields). Figure 9.
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Dev iceLogix 9-7 Selection Dialog, you are prompted to select the editor type that you want to launch. Select the Function Block editor, click “OK”.
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9-8 Dev iceLogix Figure 9.2 – Select Logic Editor Type IMPORTANT The IntelliVAC Plus is optimized for use with the Function Block Editor. It is recommended that users select the Function Block Editor at all times. Figure 9.
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Dev iceLogix 9-9 1. Upload Logic To upload logic click the Upload Logic icon or alternatively select Communications> Upload. The logic configuration in the device is read and displayed in the Function Block Editor. Any unsaved changes will be discarded and Online Animation Begins. When you upload, the uploaded information is not automatically stored into the RSNetWorx for DeviceNet software .dnt file.
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9-10 Dev iceLogix 6. Verify Logic To verify the logic’s syntax, click the Verify icon in the standard toolbar or select Tools> Verify. The verify results will be displayed in the message log window. If an error is identified, double click the error message to have the current caret jump to the error block. Tip: You can only download the logic to the device after verifying and passing the verification without an error. 7.
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Dev iceLogix 9-11 DeviceLogix Function Block Elements Function block elements consist of: • I/O components: the input and output source of the product, or I/O information from the network • Function block instructions: all types of DeviceLogix instructions.
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9-12 Dev iceLogix Digital Output Point (DOP) The following kinds of digital outputs are supported: • • Physical local Boolean output point Network Boolean output point Figure 9.
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Dev iceLogix 9-13 1503-UM054C-EN-P – June 2013
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9-14 Dev iceLogix Boolean Function Blocks The following truth table describe the boolean function blocks by listing all possible combinations of inputs and indicating the outputs for each combination. Table 9.
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9-15 Dev iceLogix Table 9.C – Bistable Function Block Output Table Function SR set dominant (A set dominant block goes to the set state if both inputs are true.) RS reset dominant (A reset dominant block goes to the false state if both inputs are true.
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9-16 Dev iceLogix timer resets the output to FALSE the pulse timer can again trigger the process by sensing a FALSE to TRUE transition on the input pin. Even if the input remains on the entire time the accumulator is counting, when the accumulator reaches the preset value the timer resets the output to FALSE. At any point during the operation of the timer, if it detects a TRUE level on the Reset input it will disable the timer and set the output to FALSE.
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Dev iceLogix 9-17 If the timer senses a TRUE level on the RESET input at any time during the operation of the timer, it resets the output to FALSE and clears the accumulator. Because the reset line is level sensitive the timer remains reset until the timer detects a false on the reset input. Also, because the input is level sensitive, the timer will again begin to increment the accumulator if the reset line goes FALSE while the input remains TRUE. Figure 9.
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9-18 Dev iceLogix output remains TRUE, and the accumulator is cleared, essentially ignoring the input. If the timer senses a true level on the reset input at any time during the operation of the timer, it resets the output to false and clears the accumulator. Because the reset line is level sensitive, the timer remains reset until the timer detects a false on the reset input.
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Dev iceLogix 9-19 Figure 9.9 – Timing Diagram for the Counter Function with a Preset Value = 3 Table 9.G – Count Up Timer Valid Data Ranges Parameters PRE ACC Data Range 0 ~ 65535 0 ~ 65535 Up Down Counter The UP/DOWN counter has three inputs called Input, Reset, and count down, and one output called output. The counter increments the accumulator any time the input changes from FALSE to TRUE and decrements the counter any time the counter down input changes from FALSE to TRUE.
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9-20 Dev iceLogix Figure 9.10 – Timing Diagram for the Up/Down Counter with a Preset Value = 3 Table 9.H – Up/Down Counter Valid Data Ranges Parameters PRE ACC Data Range 0 ~ 65535 0 ~ 65535 Offline Operations Once configured the IntelliVAC Plus can operate without a network and perform local control functions. When a network is not used, enable the Comm. Status Override Parameter on the Device Parameters Tab. This will override any errors that are generated because there is no network.
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Dev iceLogix • 9-21 Clear Latched hardware faults Go Online Once you’ve created your logic and set up your Scanlist or Override parameters, you are ready to go online. While the system is online, you can make changes (for example to the Timer and Counter values) and to the program itself. Perform the following steps to go online in RSNetWorx software: 1. Click the Online icon on the RSNetWorx software toolbar. 2.
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9-22 Dev iceLogix Figure 9.11 – Modify Function Block Attributes In order to change a value: 1. Double-Click on the face of the function block you want to change. 2. Select Parameters tab 3. Locate the value that you want to change (values which can be changed are white). Enter the new value in the box 4. Click OK. The new value takes immediate effect. If you are changing a preset, remember to Save the configuration the next time you exit from the Function Block Editor.
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Dev iceLogix 9-23 1. Select Tools>Edit so that a check mark appears on the menu, indicating that you are in Edit mode. 2. Select Communications>Download You will see a message which tells you that logic is running and asks if you would like to stop it if you:  Select NO – the logic is not downloaded to the device and the current logic continues to run on the device.  Select NO - the online toolbar displays Logic Enable Off.
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9-24 Dev iceLogix Add a digital output point (DOP) In order to add an output tab click the “Bit Output” button. Clicking the button will add an input tag to the top left of the logic currently being displayed. The user is then permitted to move the tag to the desired location. Alternatively the user can click the “Bit Output” button, hold the mouse button depressed and drag the new tag onto the screen in the desired location.
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Dev iceLogix 9-25 Note: A double arrow will appear on the connection for which data has been assumed available to indicate its status. Figure 9.13 – Assume Data Available Assume Data Available (alternate method) There is an alternate technique for creating feedback loops. It is recommended that this method be used for more complex feedback loops, or for bits which must be fed back to multiple input locations. The alternative method makes use of the dual bit functionality of the “Interim 1-5” bits.
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9-26 Dev iceLogix To apply forces, right click on the input or output element you wish to force. A pop-up appears that lists the forcing options. Figure 9.15 – Forcing Tip: You cannot use the Force Function in offline mode. Tip: If Logic Enable is Off (logic is not running in the product), the Force function has no effect. In this case, if the Force value is modified, it will not take effect until Logic Enable is On. Tip: You do not have to be in the Edit mode to use forces.
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Dev iceLogix 9-27 Figure 9.16 – Input Forced Indication Forcing Outputs The following list describes the output force options. Table 9.J – Output Forcing Ouput Force Option Force On Force Off Description Forces the input ON. Forces the input OFF. Returns control of the input to the hardw are dev ice and turns the instruction color back to w hite. When a dev ice supports latching of faults, this selection clears a hardw are output fault indication (for ex ample, offw ire or short circuit).
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9-28 Dev iceLogix Figure 9.18 – Dual Function Bit Behavior In Figure 9.18, the “Stop” output tag is connected to the hardware input “DLX input 1” and the “protection status” output tag is tied to hardware input “DLX input 2”. The associated “stop” and “protection status” bits are then used to control the status of one of the relay outputs of the IntelliVAC Plus module.
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Dev iceLogix 9-29 Customized Logic Mode: This mode allows the user to freely create control logic using all available inputs and outputs associated with the IntelliVAC Plus. Available Inputs: The input tags in DeviceLogix are divided into 4 groups: • • • • Hardware Boolean Status Input Fault Input Network Boolean Hardware Boolean inputs These are the digital input points associated with the 8 hardware inputs in the IntelliVAC Plus module.
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9-30 Dev iceLogix IBX-Input2 This bit represents the status of the corresponding “open” input on the IntelliVAC Base. When an IntelliVAC is used in a multi contactor system this input does not directly open the contactor but is simply a generic input into the DeviceLogix engine. For further information see the section detailing LOGICAL MASKS. Stop Status This is a dual function bit which can be used to describe the status of the multi contactor system.
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Dev iceLogix 9-31 JOG This is a dual function bit which can be used to represent the status of a “JOG” push button. The purpose of a jog push button is to close the contactor momentarily without having to push the stop push button to open it. This functionality will have to be implemented in the DeviceLogix control logic. Protection Status This is a dual function bit which can be used to describe the status of any protection equipment which is connected to the inputs of the IntelliVAC Plus.
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9-32 Dev iceLogix Test Mode Status This is a dual function bit which can be used to describe the status of a selector switch which chooses between normal operation, and test operation mode. IBX Out A Status This is a bit which describes the status of its respective IntelliVAC Output A (close coil) output, a “1” indicated the output is energized and the contactor closed. A “0” indicates the output is not energized and the contactor may or may not be open dependent on contactor type (Electrically held vs.
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Dev iceLogix 9-33 IBX-Mechanical latch Fail to Trip This is a fault bit which only applies to a mechanically latched contactor. The bit is set if a mechanical latch contactor fails to open after being given an open command. IBX-Power up with contactor closed This is a fault bit which applies only to an electrically held contactor. The bit is set if the module powers up and detects that a contactor is already closed before a close command is given.
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9-34 Dev iceLogix IBX-Under voltage with close command present This is a warning bit which will be set when the control voltage has dropped below nominal levels, but is either being held up temporarily using the time delay under voltage feature, or is not sufficiently low to cause the contactor to drop out. Network Boolean Inputs Net In 1-10 These are bits which are can be written to via Device-Net and the input table of the IntelliVAC Plus.
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Dev iceLogix 9-35 Output bits/tags Hardware Boolean Outputs Net out A This bit controls the status of the IntelliVAC Plus relay output A as marked on the front panel of the module. Setting this bit closes the relay output. Resetting the bit opens the relay output Net Out B This bit controls the status of the IntelliVAC Plus relay output B as marked on the front panel of the module. Setting this bit closes the relay output. Resetting the bit opens the relay output.
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9-36 Dev iceLogix Net Out9/Speed SW FWD Status This is the output portion of the Speed SW FWD Status dual function bit. Net out 10/Speed SW REV Status This is the output portion of the Speed SW REV Status dual function bit. Net Out 11/Isolation SW status This is the output portion of the Isolation SW status dual function bit. Net Out 12/Remode Mode Status This is the output portion of the Remote Mode Status dual function bit.
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Dev iceLogix 9-37 This is the output portion of the “Start” dual function bit. Net Out 28/Stop This is the output portion of the “Stop” dual function bit. Net Out 29/FWD This is the output portion of the “FWD” dual function bit. Net Out 30/REV This is the output portion of the “REV” dual function bit. Net Out 31/Jog This is the output portion of the “Jog” dual function bit.
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9-38 Dev iceLogix This is an example of a basic logical replacement for a typical relay control circuit. Pushing the start pushbutton will cause the DLX1 Input 1 to go to “1” which is then tied to the “Net out 27/Start” output tag which is a dual function bit which controls the “Start” input tag. When this goes to “1” the output gate of the “OR” gate goes to “1” and assuming the Normally closed “STOP” pushbutton is not depressed the output of the “AND” gate will got to “1” and close the contactor.
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Dev iceLogix 9-39 After selecting the desired control program the IntelliVAC Plus module must be reset to adopt its new settings and load the logic from main memory into the DeviceLogix engine. In order to accomplish this simply cycle the control power of the unit. Be sure to remove both the 120VAC power to the IntelliVAC module, and the 24VDC DeviceNet power. When power is restored to the IntelliVAC Plus the new program will be active in DeviceLogix.
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9-40 Dev iceLogix 1503-UM054C-EN-P – June 2013
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Chapter 10 Troubleshooting IB Operational Troubleshooting Procedures The following table identifies possible causes and corrective actions when troubleshooting IB related faults using the IntelliVAC Plus Module Status/Contactor Status LEDs. NOTE: All parameters indicated in this section refer to a 5IB-MC system. See the appropriate section of Appendix B for the corresponding parameter for other IB-MC version. Table 10.
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10-2 Troubleshooting Table 10.A – IB Operational Troubleshooting Procedures (cont.) LED Color Module Status Contactor Status State Yellow Yellow Warning Condition/Possible Cause The mechanical latch contactor failed to trip. Trip command not present. Contactor Aux iliary status missing Trip coil open Red 2 flash Yellow Fault Pow er up w ith contactor Closed.
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Troubleshooting 10-3 Table 10.A – IB Operational Troubleshooting Procedures (cont.
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10-4 Troubleshooting Table 10.A – IB Operational Troubleshooting Procedures (cont.) LED Color Module Status Contactor Status State Yellow Off/Yellow Warning Underv oltage w ith a Close command present 1. Input mains v oltage low 2. Faulty contactor coil 3.
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Troubleshooting 10-5 Table 10.B - IE Operations Troubleshooting Procedures (cont.) Plus Status LED Color State Green 2 pulses Warning RTC failure RTC not responding 1. Green 3 pulses Warning Line underv oltage Input mains v oltage is too low Check the mains input line and v erify that it remains greater than 95Vrms to allow a contactor to be closed. If the input v oltage remains less than 95Vrms then improv ements to the source must be made.
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10-6 Troubleshooting Table 10.B - IE Operations Troubleshooting Procedures (cont.
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Troubleshooting 10-7 Table 10.B - IE Operations Troubleshooting Procedures (cont.
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10-8 Troubleshooting Table 10.C – IE Operational Trouble Shooting Procedures (cont.
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Troubleshooting 10-9 Table 10.C – IE Operational Trouble Shooting Procedures (cont.) 7-Segment Display State ‘6’flash Fault Incorrect MC R TERM installed 1. Incorrect R TERM selected ‘L’+MC address ‘1’flash Fault ‘3’solid Fault Sy stem lock-out state Fault present, in MC sy stem w hich will not clear Bad or no Dev iceLogix program for MC sy stem 1. The Custom Dev iceLogix module is selected and has no program entered. 2. The Custom Dev iceLogix module is selected and has errors.
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10-10 Troubleshooting Table 10.D – MC Operational Troubleshooting Procedures 7-Segment Display State Off Normal Condition/Possible Cause No input pow er on the mains input Input mains v oltage low Input mains connections faulty Failed internal fuse Off Fault Inv alid MC address selected MC address is inv alid Corrective Action Check that the mains input v oltage, on the IntelliVAC MC unit is w ithin the operating v oltage range defined in the Electrical Specification.
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Appendix A Fuse Protection Introduction The IntelliVAC module requires external fuse protection to coordinate with the power supply and contactor. The fuse ratings shown in Table 3.A allow the passage of inrush currents expected when the contactor is closed, or from recommended external capacitors for the TDUV option. They will also protect the contactor coils in the event of a module malfunction. The recommended fuses have been tested to ensure reliable protection of the module.
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A-2 Fuse Protection 1503-UM054C-EN-P – June 2013
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Appendix B Parameters Introduction This section provides a detailed description of the parameters used in the control of the IntelliVAC Plus. The parameters are arranged into functional groups. Each description begins with the full name of the parameter, followed by the name displayed in RSNetworx. The linear number of the parameter is given followed by the minimum and maximum values showing the position of the decimal point and the units, if applicable. Next is the default value for a new IntelliVAC Plus.
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B-2 Parameters Table B.
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Parameters B-3 Table B.3 – Conversion Table Parameter Numbers Binary Hex Binary Hex Binary Hex Binary Hex 0000 0001 0010 0011 0 1 2 3 0100 0101 0110 0111 4 5 6 7 1000 1001 1010 1011 8 9 A B 1100 1101 1110 1111 C D E F The parameter number value, for each parameter type, lists 5 values separated by commas.
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B-4 Parameters Auxiliary Input Status from IntelliVAC Base Unit #2 [IB 2 Module Aux. Status] Parameter Number: Access rule: Data Type: Object Mapping: Group: Units: Minimum Value: Maximum Value: Default Value: 2,2,2,2,_. Get BOOL 0x384-2-1 Control 0 = Closed 1 = Open 0 This parameter allows the user to view the status of the contactor Auxiliary input from the IntelliVAC Basic Module #2.
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Parameters B-5 Auxiliary Input Status from IntelliVAC Base Unit #4 [IB 4 Module Aux. Status] Parameter Number: Access rule: Data Type: Object Mapping: Group: Units: Minimum Value: Maximum Value: Default Value: 4,4,_,_,_. Get BOOL 0x384-4-1 Control 0 = Closed 1 = Open 0 This parameter allows the user to view the status of the contactor Auxiliary input from the IntelliVAC Basic Module #4.
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B-6 Parameters Close Input Status from IntelliVAC Base Unit #1 [IB 1 Module Close Status] Parameter Number: Access rule: Data Type: Object Mapping: Group: Units: Minimum Value: Maximum Value: Default Value: 6,5,4,3,2. Get BOOL 0x384-1-2 Control 0 = Off 1 = On 0 This parameter allows the user to view the status of the contactor Close input from the IntelliVAC Basic Module #1. An Off status refers to the Close input having no input voltage indicating an absence of a Close input.
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Parameters B-7 Close Input Status from IntelliVAC Base Unit #3 [IB 3 Module Close Status] Parameter Number: Access rule: Data Type: Object Mapping: Group: Units: Minimum Value: Maximum Value: Default Value: 8,7,6,_,_. Get BOOL 0x384-3-2 Control 0 = Off 1 = On 0 This parameter allows the user to view the status of the contactor Close input from the IntelliVAC Basic Module #3. An Off status refers to the Close input having no input voltage indicating an absence of a Close input.
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B-8 Parameters Close Input Status from IntelliVAC Base Unit #5 [IB 5 Module Close Status] Parameter Number: Access rule: Data Type: Object Mapping: Group: Units: Minimum Value: Maximum Value: Default Value: 10,_,_,_,_. Get BOOL 0x384-5-2 Control 0 = Off 1 = On 0 This parameter allows the user to view the status of the contactor Close input from the IntelliVAC Basic Module #5. An Off status refers to the Close input having no input voltage indicating an absence of a Close input.
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Parameters B-9 Open Input Status from IntelliVAC Base Unit #2 [IB 2 Module Open Status] Parameter Number: Access rule: Data Type: Object Mapping: Group: Units: Minimum Value: Maximum Value: Default Value: 12,10,8,6,_. Get BOOL 0x384-2-3 Control 0 = Off 1 = On 0 This parameter allows the user to view the status of the contactor Open input from the IntelliVAC Basic Module #2. An Off status refers to the Open input having no input voltage indicating the absence of an Open input.
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B-10 Parameters Open Input Status from IntelliVAC Base Unit #4 [IB 4 Module Open Status] Parameter Number: Access rule: Data Type: Object Mapping: Group: Units: Minimum Value: Maximum Value: Default Value: 14,12,_,_,_. Get BOOL 0x384-4-3 Control 0 = Off 1 = On 0 This parameter allows the user to view the status of the contactor Open input from the IntelliVAC Basic Module #4. An Off status refers to the Open input having no input voltage indicating the absence of an Open input.
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Parameters B-11 Close Coil Command for IntelliVAC Base Unit #1 [IB 1 Close Coil Command] Parameter Number: Access rule: Data Type: Object Mapping: Group: Units: Minimum Value: Maximum Value: Default Value: 16,13,10,7,4. Get/Set BOOL 0x384-1-4 Control 0 = Off 1 = On 0 This parameter allows the user to view as well as change the Close Coil command for the IntelliVAC Basic Module #1. An Off refers to the Close command not being present and not applying power to the Close coil.
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B-12 Parameters Close Coil Command for IntelliVAC Base Unit #3 [IB 3 Close Coil Command] Parameter Number: Access rule: Data Type: Object Mapping: Group: Units: Minimum Value: Maximum Value: Default Value: 18,15,12,_,_. Get/Set BOOL 0x384-3-4 Control 0 = Off 1 = On 0 This parameter allows the user to view as well as change the Close Coil command for the IntelliVAC Basic Module #3. An Off refers to the Close command not being present and not applying power to the Close coil.
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Parameters B-13 Close Coil Command for IntelliVAC Base Unit #5 [IB 5 Close Coil Command] Parameter Number: Access rule: Data Type: Object Mapping: Group: Units: Minimum Value: Maximum Value: Default Value: 20_,_,_,_. Get/Set BOOL 0x384-5-4 Control 0 = Off 1 = On 0 This parameter allows the user to view as well as change the Close Coil command for the IntelliVAC Basic Module #5. An Off refers to the Close command not being present and not applying power to the Close coil.
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B-14 Parameters Trip Coil Command for IntelliVAC Base Unit #2 [IB 2 Trip Coil Command] Parameter Number: Access rule: Data Type: Object Mapping: Group: Units: Minimum Value: Maximum Value: Default Value: 22,18,14,10,_. Get/Set BOOL 0x384-2-5 Control 0 = Off 1 = On 0 This parameter allows the user to view as well as change the Trip Coil command for the IntelliVAC Basic Module #2. An Off refers to the Trip command not being present and not applying power to the Trip coil.
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Parameters B-15 Trip Coil Command for IntelliVAC Base Unit #4 [IB 4 Trip Coil Command] Parameter Number: Access rule: Data Type: Object Mapping: Group: Units: Minimum Value: Maximum Value: Default Value: 24,20,_,_,_. Get/Set BOOL 0x384-4-5 Control 0 = Off 1 = On 0 This parameter allows the user to view as well as change the Trip Coil command for the IntelliVAC Basic Module #4. An Off refers to the Trip command not being present and not applying power to the Trip coil.
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B-16 Parameters Contactor Relay Status for IntelliVAC Base Unit #1 [IB 1 Contactor Status Relay Status] Parameter Number: Access rule: Data Type: Object Mapping: Group: Units: Minimum Value: Maximum Value: Default Value: 26,21,16,11,6. Get BOOL 0x384-1-6 Control 0 = Open 1 = Closed 0 This parameter allows the user to view the status of the Contactor Status relay for the IntelliVAC Basic Module #1. An Open refers to the Contactor Status relay contacts being in an Open state.
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Parameters B-17 Contactor Relay Status for IntelliVAC Base Unit #3 [IB 3 Contactor Status Relay Status] Parameter Number: Access rule: Data Type: Object Mapping: Group: Units: Minimum Value: Maximum Value: Default Value: 28,23,18,_,_. Get BOOL 0x384-3-6 Control 0 = Open 1 = Closed 0 This parameter allows the user to view the status of the Contactor Status relay for the IntelliVAC Basic Module #3. An Open refers to the Contactor Status relay contacts being in an Open state.
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B-18 Parameters Contactor Relay Status for IntelliVAC Base Unit #5 [IB 5 Contactor Status Relay Status] Parameter Number: Access rule: Data Type: Object Mapping: Group: Units: Minimum Value: Maximum Value: Default Value: 30,_,_,_,_. Get BOOL 0x384-5-6 Control 0 = Open 1 = Closed 0 This parameter allows the user to view the status of the Contactor Status relay for the IntelliVAC Basic Module #5. An Open refers to the Contactor Status relay contacts being in an Open state.
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Parameters B-19 Module Status Relay Status for IntelliVAC Base Unit #2 [IB 2 Module Status Relay Status] Parameter Number: Access rule: Data Type: Object Mapping: Group: Units: Minimum Value: Maximum Value: Default Value: 32,26,20,14,_. Get BOOL 0x384-2-7 Control 0 = Open 1 = Closed 0 This parameter allows the user to view the status of the Module Status relay for the IntelliVAC Basic Module #2. An Open refers to the Module Status relay contacts being in an Open state.
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B-20 Parameters Module Status Relay Status for IntelliVAC Base Unit #4 [IB 4 Module Status Relay Status] Parameter Number: Access rule: Data Type: Object Mapping: Group: Units: Minimum Value: Maximum Value: Default Value: 34,28,_,_,_. Get BOOL 0x384-4-7 Control 0 = Open 1 = Closed 0 This parameter allows the user to view the status of the Module Status relay for the IntelliVAC Basic Module #4. An Open refers to the Module Status relay contacts being in an Open state.
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Parameters B-21 Close Coil Current for IntelliVAC Base Unit #1 [IB 1 Close Current] Parameter Number: Access rule: Data Type: Object Mapping: Group: Units: Minimum Value: Maximum Value: Default Value: 36,29,22,15,8. Get FLOAT 0x384-1-8 Control Amperes 00.000A 99.999A 00.000A This parameter allows the user to view the average value for the Close coil current on the IntelliVAC Basic Module #1. This coil current is only valid for the first 200mS after the Close coil is energized.
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B-22 Parameters Close Coil Current for IntelliVAC Base Unit #3 [IB 3 Close Current] Parameter Number: Access rule: Data Type: Object Mapping: Group: Units: Minimum Value: Maximum Value: Default Value: 38,31,24,_,_. Get FLOAT 0x384-3-8 Control Amperes 00.000A 99.999A 00.000A This parameter allows the user to view the average value for the Close coil current on the IntelliVAC Basic Module #3. This coil current is only valid for the first 200mS after the Close coil is energized.
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Parameters B-23 Close Coil Current for IntelliVAC Base Unit #5 [IB 5 Close Current] Parameter Number: Access rule: Data Type: Object Mapping: Group: Units: Minimum Value: Maximum Value: Default Value: 40_,_,_,_. Get FLOAT 0x384-5-8 Control Amperes 00.000A 99.999A 00.000A This parameter allows the user to view the average value for the Close coil current on the IntelliVAC Basic Module #5. This coil current is only valid for the first 200mS after the Close coil is energized.
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B-24 Parameters Hold Coil Current for IntelliVAC Base Unit #2 [IB 2 Hold Current] Parameter Number: Access rule: Data Type: Object Mapping: Group: Units: Minimum Value: Maximum Value: Default Value: 42,34,26,18,_. Get FLOAT 0x384-2-9 Control Amperes 00.000A 99.999A 00.000A This parameter allows the user to view the average value for the Hold coil current on the IntelliVAC Basic Module #2.
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Parameters B-25 Hold Coil Current for IntelliVAC Base Unit #4 [IB 4 Hold Current] Parameter Number: Access rule: Data Type: Object Mapping: Group: Units: Minimum Value: Maximum Value: Default Value: 44,36,_,_,_. Get FLOAT 0x384-4-9 Control Amperes 00.000A 99.999A 00.000A This parameter allows the user to view the average value for the Hold coil current on the IntelliVAC Basic Module #4.
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B-26 Parameters Trip Coil Current for IntelliVAC Base Unit #1 [IB 1 Trip Current] Parameter Number: Access rule: Data Type: Object Mapping: Group: Units: Minimum Value: Maximum Value: Default Value: 46,37,28,19,10. Get Float 0x384-1-10 Control Amperes 00.000A 99.999A 00.000A This parameter allows the user to view the average value for the Trip coil current on the IntelliVAC Basic Module #1. This coil current is only valid for the first 200mS after the Trip coil is energized.
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Parameters B-27 Trip Coil Current for IntelliVAC Base Unit #3 [IB 3 Trip Current] Parameter Number: Access rule: Data Type: Object Mapping: Group: Units: Minimum Value: Maximum Value: Default Value: 48,39,30,_,_. Get FLOAT 0x384-3-10 Control Amperes 00.000A 99.999A 00.000A This parameter allows the user to view the average value for the Trip coil current on the IntelliVAC Basic Module #3. This coil current is only valid for the first 200mS after the Trip coil is energized.
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B-28 Parameters Trip Coil Current for IntelliVAC Base Unit #5 [IB 5 Trip Current] Parameter Number: Access rule: Data Type: Object Mapping: Group: Units: Minimum Value: Maximum Value: Default Value: 50,_,_,_,_. Get FLOAT 0x384-5-10 Control Amperes 00.000A 99.999A 00.000A This parameter allows the user to view the average value for the Trip coil current on the IntelliVAC Basic Module #5. This coil current is only valid for the first 200mS after the Trip coil is energized.
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Parameters B-29 Input Line Voltage for IntelliVAC Base Unit #2 [IB 2 Line Voltage] Parameter Number: Access rule: Data Type: Object Mapping: Group: Units: Minimum Value: Maximum Value: Default Value: 52,42,32,22,_. Get FLOAT 0x384-2-11 Control Volts 00.000V 399.999V 00.000V This parameter allows the user to view the RMS value for the Input Line voltage on the IntelliVAC Basic Module #2. The input voltage may be either AC or DC.
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B-30 Parameters Input Line Voltage for IntelliVAC Base Unit #4 [IB 4 Line Voltage] Parameter Number: Access rule: Data Type: Object Mapping: Group: Units: Minimum Value: Maximum Value: Default Value: 54,44,_,_,_. Get FLOAT 0x384-4-11 Control Volts 00.000V 399.999V 00.000V This parameter allows the user to view the RMS value for the Input Line voltage on the IntelliVAC Basic Module #4. The input voltage may be either AC or DC.
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Parameters B-31 DC Bus Voltage for IntelliVAC Base Unit #1 [IB 1 DC Bus Voltage] Parameter Number: Access rule: Data Type: Object Mapping: Group: Units: Minimum Value: Maximum Value: Default Value: 56,45,34,23,12. Get FLOAT 0x384-1-12 Control Volts 00.000V 399.999V 00.000V This parameter allows the user to view the DC value for the DC Bus voltage on the IntelliVAC Basic Module #1.
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B-32 Parameters DC Bus Voltage for IntelliVAC Base Unit #3 [IB 3 DC Bus Voltage] Parameter Number: Access rule: Data Type: Object Mapping: Group: Units: Minimum Value: Maximum Value: Default Value: 58,47,36,_,_. Get FLOAT 0x384-3-12 Control Volts 00.000V 399.999V 00.000V This parameter allows the user to view the DC value for the DC Bus voltage on the IntelliVAC Basic Module #3.
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Parameters B-33 DC Bus Voltage for IntelliVAC Base Unit #5 [IB 5 DC Bus Voltage] Parameter Number: Access rule: Data Type: Object Mapping: Group: Units: Minimum Value: Maximum Value: Default Value: 60,_,_,_,_. Get FLOAT 0x384-5-12 Control Volts 00.000V 399.999V 00.000V This parameter allows the user to view the DC value for the DC Bus voltage on the IntelliVAC Basic Module #5.
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B-34 Parameters Enhanced Module Hardware Output State [IE Hardware Outputs] Parameter Number: Access rule: Data Type: Object Mapping: Group: Units: Minimum Value: Maximum Value: Default Value: 62,50,38,26,14. Get/Set BYTE 0x4-2-3 Control None This parameter allows the user to view, as well as to control, the state of the two (2) hardware output relays. Each bit position of the parameter defines the state of one of the hardware outputs.
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Parameters B-35 DeviceNet Voltage [24V DeviceNet Voltage] Parameter Number: Access rule: Data Type: Object Mapping: Group: Units: Minimum Value: Maximum Value: Default Value: 64,52,40,28,16. Get FLOAT 0x3-1-100 Control Volts 0V 50.000V 0V This parameter allows the user to view the DeviceNet DC voltage level. 15V Supply Voltage from the IB [15V IB Voltage] Parameter Number: Access rule: Data Type: Object Mapping: Group: Units: Minimum Value: Maximum Value: Default Value: 65,53,41,29,17.
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B-36 Parameters Table B.6 – DeviceLogix Programs Bit Enum Text Description 1 2 User customized Dev iceLogix Prog.
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Parameters B-37 IntelliVAC Plus Action on Loss of DeviceNet Communications [Loss Communication Action] Parameter Number: Access rule: Data Type: Object Mapping: Group: Units: Minimum Value: Maximum Value: Default Value: 68,56,44,32,19. Get/Set BOOL 0xB4-1-125 Control Hold Reset Hold This parameter allows the user to view, as well as to select, the control action which occurs after a loss of DeviceNet communications occurs. There are two different actions that can be selected, either Hold or Reset.
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B-38 Parameters Table B.
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Parameters B-39 Produced Network Bits [Produced Network Bits] Parameter Number: Access rule: Data Type: Object Mapping: Group: Units: Minimum Value: Maximum Value: Default Value: 71,59,47,35,22. Get/Set DWORD 4-12-3 Control None This parameter allows the user to view and set the conditions of the five (5) DeviceNet Network commands. Each bit position of the parameter defines the state of one of the network command bits.
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B-40 Parameters Discrete Output Point Fault Action [DOP Fault Action] Parameter Number: Access rule: Data Type: Object Mapping: Group: Units: Minimum Value: Maximum Value: Default Value: 72,60,48,36,23. Get/Set BOOL 0x1E-1-7 Control 0 = Go to Fault Value 1 = Hold Last State 0 Describes the action on the occurrence of a DOP fault.
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Parameters B-41 Discrete Output Point Idle Value [DOP Idle Value] Parameter Number: Access rule: Data Type: Object Mapping: Group: Units: Minimum Value: Maximum Value: Default Value: 75,63,51,34,26. Get/Set BOOL 0x1E-1-10 Control 0 = Off 1 = On 0 Dictates if any extra action will be performed on the existence of a DOP idle condition.
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B-42 Parameters DeviceNet Media Access Carrier Identification [DNet MAC ID] Parameter Number: Access rule: Data Type: Object Mapping: Group: Units: Minimum Value: Maximum Value: Default Value: 77,65,53,41,28. Get/Set SINT 0x3-1-1 Communication 0 63 0 This parameter allows the user to view and set the MAC ID of the DeviceNet communications network. The value can be anywhere in the range of 0 to 63.
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Parameters B-43 Enabling of the AutoBaud Rate Feature [Autobaud Enable] Parameter Number: Access rule: Data Type: Object Mapping: Group: Units: Minimum Value: Maximum Value: Default Value: 79,67,55,43,30. Get/Set BOOL 0xB4-1-15 Communication 0 = Enabled 1 = Disabled 0 This parameter allows the user to view and set the AutoBaud Rate Enable feature. If it is enabled then the baud rate will be set by the network traffic rate, if network traffic is found.
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B-44 Parameters Status of the Change Of State Mask [Status COS Mask] Parameter Number: Access rule: Data Type: Object Mapping: Group: Units: Minimum Value: Maximum Value: Default Value: 82,70,58,46,33. Get/Set DWORD 0xB4-1-111 Communication 0 0xFFFFFFFF 0 This parameter allows the user to view and set the status of the COS Mask. When a bit is set, that bit will not trigger a status COS message. Table B.
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B-45 Parameters Status of the Change Of State Mask [Set to Defaults] Parameter Number: Access rule: Data Type: Object Mapping: Group: Units: Minimum Value: Maximum Value: Default Value: 83,71,59,47,34. Get/Set USINT 0xB4-1-19 Communication 0 = No Operation 1 = Set DNet & DLX Defaults 0 This parameter allows the user to view and set the IntelliVAC Plus to the factory default values. The parameters which are set to defaults and their values are listed below. Table B.
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B-46 Parameters Selects the Format of the I/O Data Consumed [Consumed IO Assy] Parameter Number: Access rule: Data Type: Object Mapping: Group: Units: Minimum Value: Maximum Value: Default Value: 84,72,60,48,35. Get/Set USINT 0xB4-1-16 Communication 1 3 1 This parameter allows the user to view and set the format of the IO Data consumed. Table B.
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Parameters B-47 Table B.14 – Format of I/O Data Produced Value Enum Text 10 Default Produced Assembly : # 10 11 Hardw are Input Only Assembly : # 11 12 Netw ork Input Only Assembly : # 12 13 IE and IB Hardw are Input Assembly : #13 Description Assembly corresponds to sev eral parameters and depends on product option. See Assem10 part in EDS for specific option. Assembly corresponds to 1 parameter and depends on product option. See Assem11 part in EDS for specific option.
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B-48 Parameters Table B.15 – Network Output COS Mask Definition (cont.
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Parameters Configuration Parameters B-49 Altitude Above Sea Level [Altitude] Parameter Number: Access rule: Data Type: Object Mapping: Group: Units: Minimum Value: Maximum Value: Default Value: 87,75,63,51,38. Get/Set USINT 0xB4-1-116 Configuration Meters 0 5 0 This parameter allows the user to view and set the altitude of the contactor relative to sea level For each of the Altitude Values listed, the corresponding altitude is indicated. Table B.
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B-50 Parameters Real Time Clock Time [RTC Time] Parameter Number: Access rule: Data Type: Object Mapping: Group: Units: Minimum Value: Maximum Value: Default Value: 89,77,65,53,40. Get/Set TIME_OF_DAY 0xB4-1-113 Configuration Meters 0 0x05265BFF 0 This parameter allows the user to view and set the Time of Day on the internal Real Time Clock. To set/set this valve, please use RSNetWorx. For reference 0=00:00:00:00ms.
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Parameters B-51 Table B.17 – RTC World Time Zone Selection Local (cont.
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B-52 Parameters Override the Loss of an IO Connection [Comm Override] Parameter Number: Access rule: Data Type: Object Mapping: Group: Units: Minimum Value: Maximum Value: Default Value: 92,80,68,56,43. Get/Set BOOL 0x1E-1-105 Configuration 0 = Disabled 1 = Enabled 1 This parameter allows the user to view and set the condition where the local logic (DeviceLogix will override a DeviceNet Communications Fault (ie. Communication loss or time out).
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Parameters B-53 Type of Contactor Selected for IB2 [IB 2 Contactor Type] Parameter Number: Access rule: Data Type: Object Mapping: Group: Units: Minimum Value: Maximum Value: Default Value: 94,82,70,58,_. Get USINT 0x384-2-14 Configuration 0 3 0 This parameter allows the user to view the status of the type of contactor that is being controlled by the IB2 module. This value is set by the DIP switches on the IB2 module only (see Table 8.C). Table B.
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B-54 Parameters Type of Contactor Selected for IB4 [IB 4 Contactor Type] Parameter Number: Access rule: Data Type: Object Mapping: Group: Units: Minimum Value: Maximum Value: Default Value: 96,84,_,_,_. Get USINT 0x384-4-14 Configuration 0 3 0 This parameter allows the user to view the status of the type of contactor that is being controlled by the IB4 module. This value is set by the DIP switches on the IB4 module only (see Table 8.C). Table B.
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Parameters B-55 Time Delay UnderVoltage Setting for IB1 [IB 1 TDUV Configure] Parameter Number: Access rule: Data Type: Object Mapping: Group: Units: Minimum Value: Maximum Value: Default Value: 98,85,72,59,45. Get/Set BOOL 0x384-1-15 Configuration 0 = Disable 1 = Enable 0 This parameter allows the user to view and set the status of the Time Delay UnderVoltage setting for the IB1 contactor module. If it is disabled then the TDUV feature for the IB1 contactor is disabled.
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B-56 Parameters Time Delay UnderVoltage Setting for IB3 [IB 3 TDUV Configure] Parameter Number: Access rule: Data Type: Object Mapping: Group: Units: Minimum Value: Maximum Value: Default Value: 100,87,74,_,_. Get/Set BOOL 0x384-3-15 Configuration 0 = Disable 1 = Enable 0 This parameter allows the user to view and set the status of the Time Delay UnderVoltage setting for the IB3 contactor module. If it is disabled then the TDUV feature for the IB3 contactor is disabled.
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Parameters B-57 Time Delay UnderVoltage Setting for IB5 [IB 5 TDUV Configure] Parameter Number: Access rule: Data Type: Object Mapping: Group: Units: Minimum Value: Maximum Value: Default Value: 102,_,_,_,_. Get/Set BOOL 0x384-5-15 Configuration 0 = Disable 1 = Enable 0 This parameter allows the user to view and set the status of the Time Delay UnderVoltage setting for the IB5 contactor module. If it is disabled then the TDUV feature for the IB5 contactor is disabled.
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B-58 Parameters Power-Up Safety Setting for IB2 [IB 2 Power-Up Safety Setting] Parameter Number: Access rule: Data Type: Object Mapping: Group: Units: Minimum Value: Maximum Value: Default Value: 104,90,76,62,_. Get BOOL 0x384-2-16 Configuration 0 = Enable 1 = Disable 0 This parameter allows the user to view the status of the Power-Up Safety setting for the IB2 module. If it is enabled then the IB2 contactor will not close the contactor if the unit powers up with a Close command present.
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Parameters B-59 Power-Up Safety Setting for IB4 [IB 4 Power-Up Safety Setting] Parameter Number: Access rule: Data Type: Object Mapping: Group: Units: Minimum Value: Maximum Value: Default Value: 106,92,_,_,_. Get BOOL 0x384-4-16 Configuration 0 = Enable 1 = Disable 0 This parameter allows the user to view the status of the Power-Up Safety setting for the IB4 module. If it is enabled then the IB4 contactor will not close the contactor if the unit powers up with a Close command present.
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B-60 Parameters Learn Mode Setting From IB1 [IB 1 Learn Mode Setting] Parameter Number: Access rule: Data Type: Object Mapping: Group: Units: Minimum Value: Maximum Value: Default Value: 108,93,78,63,47. Get BOOL 0x384-1-17 Configuration 0 = Off 1 = On 0 This parameter allows the user to view the status of the Learn Mode setting for the IB1 module. If it is Off, then the IB1 contactor will not try to determine the type of contactor that it is connected to.
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Parameters B-61 Learn Mode Setting From IB3 [IB 3 Learn Mode Setting] Parameter Number: Access rule: Data Type: Object Mapping: Group: Units: Minimum Value: Maximum Value: Default Value: 110,95,80,_,_. Get BOOL 0x384-3-17 Configuration 0 = Off 1 = On 0 This parameter allows the user to view the status of the Learn Mode setting for the IB3 module. If it is Off, then the IB3 contactor will not try to determine the type of contactor that it is connected to.
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B-62 Parameters Learn Mode Setting From IB5 [IB 5 Learn Mode Setting] Parameter Number: Access rule: Data Type: Object Mapping: Group: Units: Minimum Value: Maximum Value: Default Value: 112,_,_,_,_. Get BOOL 0x384-5-17 Configuration 0 = Off 1 = On 0 This parameter allows the user to view the status of the Learn Mode setting for the IB5 module. If it is Off, then the IB5 contactor will not try to determine the type of contactor that it is connected to.
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Parameters B-63 Drop Out Time Setting for IB2 [IB 2 Drop Out Time] Parameter Number: Access rule: Data Type: Object Mapping: Group: Units: Minimum Value: Maximum Value: Default Value: 114,98,82,66,_. Get/Set USINT 0x384-2-13 Configuration Milliseconds 50 240 50 This parameter allows the user to view and set the Drop Out Time setting for the IB2 module.
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B-64 Parameters Drop Out Time Setting for IB4 [IB 4 Drop Out Time] Parameter Number: Access rule: Data Type: Object Mapping: Group: Units: Minimum Value: Maximum Value: Default Value: 116,100,_,_,_. Get/Set USINT 0x384-4-13 Configuration milliseconds 50 240 50 This parameter allows the user to view and set the Drop Out Time setting for the IB4 module.
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Parameters B-65 Drop Out Time Setting From IB1 DIP Switches [IB 1 Drop Out Time DIP Setting] Parameter Number: Access rule: Data Type: Object Mapping: Group: Units: Minimum Value: Maximum Value: Default Value: 118,101,84,67,49. Get USINT 0x384-1-49 Configuration milliseconds 0 7 0 This parameter allows the user to view the Drop Out Time Setting set from the IB1 DIP switches.
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B-66 Parameters Table B.24 – Drop Out Time Settings from IB2 DIP Switches Value Enum Text 0 1 2 3 4 5 6 7 50 ms 75 ms 100 ms 130 ms 150 ms 175 ms 200 ms 240 ms Description 50 ms from IB2 DIP sw itches 75 ms from IB2 DIP sw itches 100 ms from IB2 DIP sw itches 130 ms from IB2 DIP sw itches 150 ms from IB2 DIP sw itches 175 ms from IB2 DIP sw itches 200 ms from IB2 DIP sw itches 240 ms from IB2 DIP sw itches Note: The drop off time would be 6mS longer if the close command is applied on IB.
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Parameters B-67 Drop Out Time Setting From IB4 DIP Switches [IB 4 Drop Out Time DIP Setting] Parameter Number: Access rule: Data Type: Object Mapping: Group: Units: Minimum Value: Maximum Value: Default Value: 121,104,_,_,_. Get USINT 0x384-4-49 Configuration see table 0 7 0 This parameter allows the user to view the Drop Out Time Setting set from the IB4 DIP switches.
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B-68 Parameters Table B.
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Parameters B-69 Contactor Pick Up Time for IB3 [IB 3 Pick Up Time] Parameter Number: Access rule: Data Type: Object Mapping: Group: Units: Minimum Value: Maximum Value: Default Value: 125,107,89,_,_. Get USINT 0x384-3-18 Configuration mSeconds 0 255 0 This parameter allows the user to view the Pick Up Time for the IB3 contactor.
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B-70 Parameters Contactor Pick Up Time for IB5 [IB 5 Pick Up Time] Parameter Number: Access rule: Data Type: Object Mapping: Group: Units: Minimum Value: Maximum Value: Default Value: 127,_,_,_,_. Get USINT 0x384-5-18 Configuration mSeconds 0 255 0 This parameter allows the user to view the Pick Up Time for the IB5 contactor. The Pick Up Time is the interval from when a Close or Trip command is issued to the time that the Contactor Auxiliary contact on IB5 opens, indicating that the contactor is closed.
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Parameters B-71 TDUV Time Setting from IB2 DIP Switches [IB 2 TDUV Time DIP Setting] Parameter Number: Access rule: Data Type: Object Mapping: Group: Units: Minimum Value: Maximum Value: Default Value: 129,110,91,72,_. Get USINT 0x384-2-58 Configuration see table 0 3 0 This parameter allows the user to view the Time Delay Undervoltage Setting set from the IB2 DIP switches.
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B-72 Parameters Table B.30 – TDUV Time Setting From IB3 DIP Switches Value Enum Text 0 1 2 3 0.2 Sec 0.5 Sec 1.0 Sec 2.0 Sec Description 0.2 Sec 0.5 Sec 1.0 Sec 2.
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Parameters B-73 TDUV Time Setting from IB5 DIP Switches [IB 5 TDUV Time DIP Setting] Parameter Number: Access rule: Data Type: Object Mapping: Group: Units: Minimum Value: Maximum Value: Default Value: 132,_,_,_,_. Get USINT 0x384-5-58 Configuration see table 0 3 0 This parameter allows the user to view the Time Delay Undervoltage Setting set from the IB5 DIP switches.
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B-74 Parameters TDUV Time Setting for IB2 [IB 2 TDUV Time] Parameter Number: Access rule: Data Type: Object Mapping: Group: Units: Minimum Value: Maximum Value: Default Value: 134,114,94,74,_. Get/Set UINT 0x384-2-50 Configuration Seconds error in EDS file 0.2 2.0 0.2 This parameter allows the user to view and set the Time Delay Undervoltage setting for the IB2 module.
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Parameters B-75 TDUV Time Setting for IB4 [IB 4 TDUV Time] Parameter Number: Access rule: Data Type: Object Mapping: Group: Units: Minimum Value: Maximum Value: Default Value: 136,116,_,_,_. Get/Set UINT 0x384-4-50 Configuration Seconds error in EDS file 0.2 2.0 0.2 This parameter allows the user to view and set the Time Delay Undervoltage setting for the IB4 module.
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B-76 Parameters Delay Restart Time for IB1 [IB 1 Delay Restart Time] Parameter Number: Access rule: Data Type: Object Mapping: Group: Units: Minimum Value: Maximum Value: Default Value: 138,117,96,75,53. Get/Set UINT 0x384-1-19 Configuration Seconds 6 3600 12 This parameter allows the user to view and set the Delay Restart Time between successive Open/Trip and Close commands for contactor IB1. This sets a maximum repetition time for the cycling of the contactor.
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Parameters B-77 Delay Restart Time for IB3 [IB 3 Delay Restart Time] Parameter Number: Access rule: Data Type: Object Mapping: Group: Units: Minimum Value: Maximum Value: Default Value: 140,119,98,_,_. Get/Set UINT 0x384-3-19 Configuration Seconds 6 3600 12 This parameter allows the user to view and set the Delay Restart Time between successive Open/Trip and Close commands for contactor IB3. This sets a maximum repetition time for the cycling of the contactor.
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B-78 Parameters Delay Restart Time for IB5 [IB 5 Delay Restart Time] Parameter Number: Access rule: Data Type: Object Mapping: Group: Units: Minimum Value: Maximum Value: Default Value: 142,_,_,_,_. Get/Set UINT 0x384-5-19 Configuration Seconds 6 3600 12 This parameter allows the user to view and set the Delay Restart Time between successive Open/Trip and Close commands for contactor IB5. This sets a maximum repetition time for the cycling of the contactor.
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Parameters B-79 Delay Restart Wait Time for IB2 [IB 2 Delay Restart Wait Time] Parameter Number: Access rule: Data Type: Object Mapping: Group: Units: Minimum Value: Maximum Value: Default Value: 144,122,100,78,_. Get UINT 0x384-2-20 Configuration Seconds 0 3600 0 This parameter allows the user to view the Delay Restart Wait Time for IB2. It shows the time left, as a constantly updated real time, after the contactor has closed, before it is permitted to close again.
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B-80 Parameters Delay Restart Wait Time for IB4 [IB 4 Delay Restart Wait Time] Parameter Number: Access rule: Data Type: Object Mapping: Group: Units: Minimum Value: Maximum Value: Default Value: 146,124,_,_,_. Get UINT 0x384-4-20 Configuration Seconds 0 3600 0 This parameter allows the user to view the Delay Restart Wait Time for IB4. It shows the time left, as a constantly updated real time, after the contactor has closed, before it is permitted to close again.
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Parameters B-81 Jog Time for IB1 [IB 1 Jog Time] Parameter Number: Access rule: Data Type: Object Mapping: Group: Units: Minimum Value: Maximum Value: Default Value: 148,125,102,79,55. Get/Set USINT 0x384-1-21 Configuration Seconds 0 30 12 This parameter allows the user to view and set the Jog Time for contactor IB1. It indicates the amount of time that a contactor can be Jogged (momentarily closed) for. This is only for Electrically Held contactors and makes use of the Open command.
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B-82 Parameters Jog Time for IB3 [IB 3 Jog Time] Parameter Number: Access rule: Data Type: Object Mapping: Group: Units: Minimum Value: Maximum Value: Default Value: 150,127,104,_,_. Get/Set USINT 0x384-3-21 Configuration Seconds 0 30 12 This parameter allows the user to view and set the Jog Time for contactor IB3. It indicates the amount of time that a contactor can be Jogged (momentarily closed) for. This is only for Electrically Held contactors and makes use of the Open command.
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Parameters B-83 Jog Time for IB5 [IB 5 Jog Time] Parameter Number: Access rule: Data Type: Object Mapping: Group: Units: Minimum Value: Maximum Value: Default Value: 152,_,_,_,_. Get/Set USINT 0x384-5-21 Configuration Seconds 0 30 12 This parameter allows the user to view and set the Jog Time for contactor IB5. It indicates the amount of time that a contactor can be Jogged (momentarily closed) for. This is only for Electrically Held contactors and makes use of the Open command.
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B-84 Parameters Jog Repetition Time for IB2 [IB 2 Jog Repetition Time] Parameter Number: Access rule: Data Type: Object Mapping: Group: Units: Minimum Value: Maximum Value: Default Value: 154,130,106,82,_. Get/Set UINT 0x384-2-22 Configuration Seconds 0 60 6 This parameter allows the user to view and set the Jog Repetition Time for contactor IB2. It indicates the amount of time between successive Jog intervals.
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Parameters B-85 Jog Repetition Time for IB4 [IB 4 Jog Repetition Time] Parameter Number: Access rule: Data Type: Object Mapping: Group: Units: Minimum Value: Maximum Value: Default Value: 156,132,_,_,_. Get/Set UINT 0x384-4-22 Configuration Seconds 0 60 6 This parameter allows the user to view and set the Jog Repetition Time for contactor IB4. It indicates the amount of time between successive Jog intervals.
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B-86 Parameters Diagnostics Parameters Invalid Command on IB1 Level [IB 1 Invalid Command] Parameter Number: Access rule: Data Type: Object Mapping: Group: Units: Minimum Value: Maximum Value: Default Value: 158,133,108,83,57. Get BOOL 0x384-1-23 Diagnostics 0 = Not Present 1 = Present 0 This parameter allows the user to view the status of the Invalid Command warning from the IB1 module. If the bit is ‘0’ then the warning is not present. If the bit is ‘1’ then the warning is present.
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Parameters B-87 Invalid Command on IB3 Level [IB 3 Invalid Command] Parameter Number: Access rule: Data Type: Object Mapping: Group: Units: Minimum Value: Maximum Value: Default Value: 160,135,110,_,_. Get BOOL 0x384-3-23 Diagnostics 0 = Not Present 1 = Present 0 This parameter allows the user to view the status of the Invalid Command warning from the IB3 module. If the bit is ‘0’ then the warning is not present. If the bit is ‘1’ then the warning is present.
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B-88 Parameters Invalid Command on IB5 Level [IB 5 Invalid Command] Parameter Number: Access rule: Data Type: Object Mapping: Group: Units: Minimum Value: Maximum Value: Default Value: 162,_,_,_,_. Get BOOL 0x384-5-23 Diagnostics 0 = Not Present 1 = Present 0 This parameter allows the user to view the status of the Invalid Command warning from the IB5 module. If the bit is ‘0’ then the warning is not present. If the bit is ‘1’ then the warning is present.
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Parameters B-89 Mechanical Latch Fails to Trip on IB2 [IB 2 Mechanical Latch Fail to Trip] Parameter Number: Access rule: Data Type: Object Mapping: Group: Units: Minimum Value: Maximum Value: Default Value: 164,138,112,86,_. Get BOOL 0x384-2-24 Diagnostics 0 = Not Present 1 = Present 0 This parameter allows the user to view the status of the Mechanical Latch Fail to Trip warning from the IB2 module. If the bit is ‘0’ then the warning is not present. If the bit is ‘1’ then the warning is present.
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B-90 Parameters Mechanical Latch Fails to Trip on IB4 [IB 4 Mechanical Latch Fail to Trip] Parameter Number: Access rule: Data Type: Object Mapping: Group: Units: Minimum Value: Maximum Value: Default Value: 166,140,_,_,_. Get BOOL 0x384-4-24 Diagnostics 0 = Not Present 1 = Present 0 This parameter allows the user to view the status of the Mechanical Latch Fail to Trip warning from the IB4 module. If the bit is ‘0’ then the warning is not present. If the bit is ‘1’ then the warning is present.
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Parameters B-91 Contactor Fails to Pick-Up on IB1 [IB 1 Contactor Fails to Pick-Up] Parameter Number: Access rule: Data Type: Object Mapping: Group: Units: Minimum Value: Maximum Value: Default Value: 168,141,114,87,59. Get BOOL 0x384-1-25 Diagnostics 0 = Not Present 1 = Present 0 This parameter allows the user to view the status of the Contactor Fails to Pick-Up warning from the IB1 module. If the bit is ‘0’ then the warning is not present. If the bit is ‘1’ then the warning is present.
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B-92 Parameters Contactor Fails to Pick-Up on IB3 [IB 3 Contactor Fails to Pick-Up] Parameter Number: Access rule: Data Type: Object Mapping: Group: Units: Minimum Value: Maximum Value: Default Value: 170,143,116,_,_. Get BOOL 0x384-3-25 Diagnostics 0 = Not Present 1 = Present 0 This parameter allows the user to view the status of the Contactor Fails to Pick-Up warning from the IB3 module. If the bit is ‘0’ then the warning is not present. If the bit is ‘1’ then the warning is present.
PAGE 268
Parameters B-93 Contactor Fails to Pick-Up on IB5 [IB 5 Contactor Fails to Pick-Up] Parameter Number: Access rule: Data Type: Object Mapping: Group: Units: Minimum Value: Maximum Value: Default Value: 172,_,_,_,_. Get BOOL 0x384-5-25 Diagnostics 0 = Not Present 1 = Present 0 This parameter allows the user to view the status of the Contactor Fails to Pick-Up warning from the IB5 module. If the bit is ‘0’ then the warning is not present. If the bit is ‘1’ then the warning is present.
PAGE 269
B-94 Parameters Contactor Drop-Out during Hold on IB2 [IB 2 Contactor Drop-out During Hold] Parameter Number: Access rule: Data Type: Object Mapping: Group: Units: Minimum Value: Maximum Value: Default Value: 174,146,118,90,_. Get BOOL 0x384-2-26 Diagnostics 0 = Not Present 1 = Present 0 This parameter allows the user to view the status of the Contactor Drop-Out during Hold warning from the IB2 module. If the bit is ‘0’ then the warning is not present. If the bit is ‘1’ then the warning is present.
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Parameters B-95 Contactor Drop-Out during Hold on IB4 [IB 4 Contactor Drop-out During Hold] Parameter Number: Access rule: Data Type: Object Mapping: Group: Units: Minimum Value: Maximum Value: Default Value: 176,148,_,_,_. Get BOOL 0x384-4-26 Diagnostics 0 = Not Present 1 = Present 0 This parameter allows the user to view the status of the Contactor Drop-Out during Hold warning from the IB4 module. If the bit is ‘0’ then the warning is not present. If the bit is ‘1’ then the warning is present.
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B-96 Parameters Contactor Long Drop Out Time on IB1 [IB 1 Contactor Long Drop Out Time] Parameter Number: Access rule: Data Type: Object Mapping: Group: Units: Minimum Value: Maximum Value: Default Value: 178,149,120,91,61. Get BOOL 0x384-1-60 Diagnostics 0 = Not Present 1 = Present 0 This parameter allows the user to view the status of the Contactor Long Drop Out Time warning from the IB1 module. If the bit is ‘0’ then the warning is not present. If the bit is ‘1’ then the warning is present.
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Parameters B-97 Contactor Long Drop Out Time on IB3 [IB 3 Contactor Long Drop Out Time] Parameter Number: Access rule: Data Type: Object Mapping: Group: Units: Minimum Value: Maximum Value: Default Value: 180,151,122,_,_. Get BOOL 0x384-3-60 Diagnostics 0 = Not Present 1 = Present 0 This parameter allows the user to view the status of the Contactor Long Drop Out Time warning from the IB3 module. If the bit is ‘0’ then the warning is not present. If the bit is ‘1’ then the warning is present.
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B-98 Parameters Contactor Long Drop Out Time on IB5 [IB 5 Contactor Long Drop Out Time] Parameter Number: Access rule: Data Type: Object Mapping: Group: Units: Minimum Value: Maximum Value: Default Value: 182,_,_,_,_. Get BOOL 0x384-5-60 Diagnostics 0 = Not Present 1 = Present 0 This parameter allows the user to view the status of the Contactor Long Drop Out Time warning from the IB5 module. If the bit is ‘0’ then the warning is not present. If the bit is ‘1’ then the warning is present.
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Parameters B-99 Contactor Fails to Drop Out on IB2 [IB 2 Contactor Fails To Drop Out] Parameter Number: Access rule: Data Type: Object Mapping: Group: Units: Minimum Value: Maximum Value: Default Value: 184,154,124,94,_. Get BOOL 0x384-2-27 Diagnostics 0 = Not Present 1 = Present 0 This parameter allows the user to view the status of the Contactor Fails to Drop Out fault from the IB2 module. If the bit is ‘0’ then the warning is not present. If the bit is ‘1’ then the warning is present.
PAGE 275
B-100 Parameters Contactor Fails to Drop Out on IB4 [IB 4 Contactor Fails To Drop Out] Parameter Number: Access rule: Data Type: Object Mapping: Group: Units: Minimum Value: Maximum Value: Default Value: 186,156,_,_,_. Get BOOL 0x384-4-27 Diagnostics 0 = Not Present 1 = Present 0 This parameter allows the user to view the status of the Contactor Fails to Drop Out fault from the IB4 module. If the bit is ‘0’ then the warning is not present. If the bit is ‘1’ then the warning is present.
PAGE 276
Parameters B-101 Long Close Time on IB1 [IB 1 Long Close Time] Parameter Number: Access rule: Data Type: Object Mapping: Group: Units: Minimum Value: Maximum Value: Default Value: 188,157,126,95,63. Get BOOL 0x384-1-54 Diagnostics 0 = Not Present 1 = Present 0 This parameter allows the user to view the status of the Long Close Time warning from the IB1 module. If the bit is ‘0’ then the warning is not present. If the bit is ‘1’ then the warning is present.
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B-102 Parameters Long Close Time on IB3 [IB 3 Long Close Time] Parameter Number: Access rule: Data Type: Object Mapping: Group: Units: Minimum Value: Maximum Value: Default Value: 190,159,128,_,_. Get BOOL 0x384-3-54 Diagnostics 0 = Not Present 1 = Present 0 This parameter allows the user to view the status of the Long Close Time warning from the IB3 module. If the bit is ‘0’ then the warning is not present. If the bit is ‘1’ then the warning is present.
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Parameters B-103 Long Close Time on IB5 [IB 5 Long Close Time] Parameter Number: Access rule: Data Type: Object Mapping: Group: Units: Minimum Value: Maximum Value: Default Value: 192,_,_,_,_. Get BOOL 0x384-5-54 Diagnostics 0 = Not Present 1 = Present 0 This parameter allows the user to view the status of the Long Close Time warning from the IB5 module. If the bit is ‘0’ then the warning is not present. If the bit is ‘1’ then the warning is present.
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B-104 Parameters Power Up with Contactor Closed on IB2 [IB 2 Power-up with Contactor Closed] Parameter Number: Access rule: Data Type: Object Mapping: Group: Units: Minimum Value: Maximum Value: Default Value: 194,162,130,98,_. Get BOOL 0x384-2-29 Diagnostics 0 = Not Present 1 = Present 0 This parameter allows the user to view the status of the Power Up with Contactor Closed fault from the IB2 module. If the bit is ‘0’ then the warning is not present. If the bit is ‘1’ then the warning is present.
PAGE 280
Parameters B-105 Power Up with Contactor Closed on IB4 [IB 4 Power-up with Contactor Closed] Parameter Number: Access rule: Data Type: Object Mapping: Group: Units: Minimum Value: Maximum Value: Default Value: 196,164,_,_,_. Get BOOL 0x384-4-29 Diagnostics 0 = Not Present 1 = Present 0 This parameter allows the user to view the status of the Power Up with Contactor Closed fault from the IB4 module. If the bit is ‘0’ then the warning is not present. If the bit is ‘1’ then the warning is present.
PAGE 281
B-106 Parameters Power Up with Invalid DIP Switch Configuration on IB1 [IB 1 Power-up with Invalid DIP Switch Configuration] Parameter Number: Access rule: Data Type: Object Mapping: Group: Units: Minimum Value: Maximum Value: Default Value: 198,165,132,99,65. Get BOOL 0x384-1-30 Diagnostics 0 = Not Present 1 = Present 0 This parameter allows the user to view the status of the Power Up with Invalid DIP Switch Configuration fault from the IB1 module. If the bit is ‘0’ then the warning is not present.
PAGE 282
Parameters B-107 Power Up with Invalid DIP Switch Configuration on IB3 [IB 3 Power-up with Invalid DIP Switch Configuration] Parameter Number: Access rule: Data Type: Object Mapping: Group: Units: Minimum Value: Maximum Value: Default Value: 200,167,134,_,_. Get BOOL 0x384-3-30 Diagnostics 0 = Not Present 1 = Present 0 This parameter allows the user to view the status of the Power Up with Invalid DIP Switch Configuration fault from the IB3 module. If the bit is ‘0’ then the warning is not present.
PAGE 283
B-108 Parameters Power Up with Invalid DIP Switch Configuration on IB5 [IB 5 Power-up with Invalid DIP Switch Configuration] Parameter Number: Access rule: Data Type: Object Mapping: Group: Units: Minimum Value: Maximum Value: Default Value: 202,_,_,_,_. Get BOOL 0x384-5-30 Diagnostics 0 = Not Present 1 = Present 0 This parameter allows the user to view the status of the Power Up with Invalid DIP Switch Configuration fault from the IB5 module. If the bit is ‘0’ then the warning is not present.
PAGE 284
Parameters B-109 Under Voltage with Close Command Present on IB2 [IB 2 U/V with Close Command Present] Parameter Number: Access rule: Data Type: Object Mapping: Group: Units: Minimum Value: Maximum Value: Default Value: 204,170,136,102,_. Get BOOL 0x384-2-31 Diagnostics 0 = Not Present 1 = Present 0 This parameter allows the user to view the status of the Under Voltage with Close Command Present warning from the IB2 module. If the bit is ‘0’ then the warning is not present.
PAGE 285
B-110 Parameters Under Voltage with Close Command Present on IB4 [IB 4 U/V with Close Command Present] Parameter Number: Access rule: Data Type: Object Mapping: Group: Units: Minimum Value: Maximum Value: Default Value: 206,172,_,_,_. Get BOOL 0x384-4-31 Diagnostics 0 = Not Present 1 = Present 0 This parameter allows the user to view the status of the Under Voltage with Close Command Present warning from the IB4 module. If the bit is ‘0’ then the warning is not present.
PAGE 286
Parameters B-111 Module not Healthy on IB1 [IB 1 Module not Healthy] Parameter Number: Access rule: Data Type: Object Mapping: Group: Units: Minimum Value: Maximum Value: Default Value: 208,173,138,103,67. Get BOOL 0x384-1-28 Diagnostics 0 = Not Present 1 = Present 0 This parameter allows the user to view the status of the Module not Healthy fault from the IB1 module. If the bit is ‘0’ then the warning is not present. If the bit is ‘1’ then the warning is present. See Table 4.
PAGE 287
B-112 Parameters Module not Healthy on IB3 [IB 3 Module not Healthy] Parameter Number: Access rule: Data Type: Object Mapping: Group: Units: Minimum Value: Maximum Value: Default Value: 210,175,140,_,_. Get BOOL 0x384-3-28 Diagnostics 0 = Not Present 1 = Present 0 This parameter allows the user to view the status of the Module not Healthy fault from the IB3 module. If the bit is ‘0’ then the warning is not present. If the bit is ‘1’ then the warning is present. See Table 4.
PAGE 288
Parameters B-113 Module not Healthy on IB5 [IB 5 Module not Healthy] Parameter Number: Access rule: Data Type: Object Mapping: Group: Units: Minimum Value: Maximum Value: Default Value: 212,_,_,_,_. Get BOOL 0x384-5-28 Diagnostics 0 = Not Present 1 = Present 0 This parameter allows the user to view the status of the Module not Healthy fault from the IB5 module. If the bit is ‘0’ then the warning is not present. If the bit is ‘1’ then the warning is present. See Table 4.
PAGE 289
B-114 Parameters Contactor not Healthy on IB3 [IB 3 Contactor Not Healthy] Parameter Number: Access rule: Data Type: Object Mapping: Group: Units: Minimum Value: Maximum Value: Default Value: 215,179,143,_,_. Get BOOL 0x384-3-56 Diagnostics 0 = Not Present 1 = Present 0 This parameter allows the user to view the status of the Contactor not Healthy fault from the IB3 module. If the bit is ‘0’ then the warning is not present. If the bit is ‘1’ then the warning is present. See Table 4.
PAGE 290
Parameters B-115 Input Line Undervoltage during Close on IB1 [IB 1 Line Undervoltage Close] Parameter Number: Access rule: Data Type: Object Mapping: Group: Units: Minimum Value: Maximum Value: Default Value: 218,181,144,107,69. Get USINT 0x384-1-45 Diagnostics 0 = Not Present 1 = Present 0 This parameter allows the user to view the status of the Input Line Undervoltage during a Close period fault from the IB1 module. If the bit is ‘0’ then the warning is not present.
PAGE 291
B-116 Parameters Input Line Undervoltage During Close on IB3 [IB 3 Line Undervoltage Close] Parameter Number: Access rule: Data Type: Object Mapping: Group: Units: Minimum Value: Maximum Value: Default Value: 220,183,146,_,_. Get USINT 0x384-3-45 Diagnostics 0 = Not Present 1 = Present 0 This parameter allows the user to view the status of the Input Line Undervoltage during a Close period fault from the IB3 module. If the bit is ‘0’ then the warning is not present.
PAGE 292
Parameters B-117 Input Line Undervoltage during Close on IB5 [IB 5 Line Undervoltage Close] Parameter Number: Access rule: Data Type: Object Mapping: Group: Units: Minimum Value: Maximum Value: Default Value: 222,_,_,_,_. Get USINT 0x384-5-45 Diagnostics 0 = Not Present 1 = Present 0 This parameter allows the user to view the status of the Input Line Undervoltage during a Close period fault from the IB5 module. If the bit is ‘0’ then the warning is not present.
PAGE 293
B-118 Parameters Input Line Undervoltage during Hold on IB2 [IB 2 Line Undervoltage Hold] Parameter Number: Access rule: Data Type: Object Mapping: Group: Units: Minimum Value: Maximum Value: Default Value: 224,186,148,110,_. Get BOOL 0x384-2-59 Diagnostics 0 = Not Present 1 = Present 0 This parameter allows the user to view the status of the Input Line Undervoltage during a Hold period fault from the IB2 module. If the bit is ‘0’ then the warning is not present.
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Parameters B-119 Input Line Undervoltage during Hold on IB4 [IB 4 Line Undervoltage Hold Parameter Number: Access rule: Data Type: Object Mapping: Group: Units: Minimum Value: Maximum Value: Default Value: 226,188,_,_,_. Get BOOL 0x384-4-59 Diagnostics 0 = Not Present 1 = Present 0 This parameter allows the user to view the status of the Input Line Undervoltage during a Hold period fault from the IB4 module. If the bit is ‘0’ then the warning is not present.
PAGE 295
B-120 Parameters Input Line Overvoltage on IB1 [IB 1 Line Overvoltage] Parameter Number: Access rule: Data Type: Object Mapping: Group: Units: Minimum Value: Maximum Value: Default Value: 228,189,150,111,71. Get USINT 0x384-1-46 Diagnostics 0 = Not Present 1 = Present 0 This parameter allows the user to view the status of the Input Line Overvoltage fault from the IB1 module. If the bit is ‘0’ then the warning is not present. If the bit is ‘1’ then the warning is present.
PAGE 296
Parameters B-121 Input Line Overvoltage on IB3 [IB 3 Line Overvoltage] Parameter Number: Access rule: Data Type: Object Mapping: Group: Units: Minimum Value: Maximum Value: Default Value: 230,191,152,_,_. Get USINT 0x384-3-46 Diagnostics 0 = Not Present 1 = Present 0 This parameter allows the user to view the status of the Input Line Overvoltage fault from the IB3 module. If the bit is ‘0’ then the warning is not present. If the bit is ‘1’ then the warning is present.
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B-122 Parameters Input Line Overvoltage on IB5 [IB 5 Line Overvoltage] Parameter Number: Access rule: Data Type: Object Mapping: Group: Units: Minimum Value: Maximum Value: Default Value: 232,_,_,_,_. Get USINT 0x384-5-46 Diagnostics 0 = Not Present 1 = Present 0 This parameter allows the user to view the status of the Input Line Overvoltage fault from the IB5 module. If the bit is ‘0’ then the warning is not present. If the bit is ‘1’ then the warning is present.
PAGE 298
Parameters B-123 Loss of Input Line Power on IB2 [IB 2 Line Loss] Parameter Number: Access rule: Data Type: Object Mapping: Group: Units: Minimum Value: Maximum Value: Default Value: 234,194,154,114,_. Get USINT 0x384-2-47 Diagnostics 0 = Not Present 1 = Present 0 This parameter allows the user to view the status of Loss of Input Line Power fault from the IB2 module. If the bit is ‘0’ then the warning is not present. If the bit is ‘1’ then the warning is present.
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B-124 Parameters Loss of Input Line Power on IB5 [IB 5 Line Loss] Parameter Number: Access rule: Data Type: Object Mapping: Group: Units: Minimum Value: Maximum Value: Default Value: 237,_,_,_,_. Get USINT 0x384-5-47 Diagnostics 0 = Not Present 1 = Present 0 This parameter allows the user to view the status of Loss of Input Line Power fault from the IB5 module. If the bit is ‘0’ then the warning is not present. If the bit is ‘1’ then the warning is present.
PAGE 300
Parameters B-125 Main Coil Open on IB3 [IB 3 Main Coil Open] Parameter Number: Access rule: Data Type: Object Mapping: Group: Units: Minimum Value: Maximum Value: Default Value: 240,199,158,_,_. Get USINT 0x384-3-48 Diagnostics 0 = Not Present 1 = Present 0 This parameter allows the user to view the status of Main Coil Open fault from the IB3 module. If the bit is ‘0’ then the warning is not present. If the bit is ‘1’ then the warning is present.
PAGE 301
B-126 Parameters Trip Coil Open on IB1 [IB 1 Trip Coil Open] Parameter Number: Access rule: Data Type: Object Mapping: Group: Units: Minimum Value: Maximum Value: Default Value: 243,201,159,117,74. Get BOOL 0x384-1-57 Diagnostics 0 = Not Present 1 = Present 0 This parameter allows the user to view the status of Trip Coil Open fault from the IB1 module. If the bit is ‘0’ then the warning is not present. If the bit is ‘1’ then the warning is present.
PAGE 302
Parameters B-127 Trip Coil Open on IB4 [IB 4 Trip Coil Open] Parameter Number: Access rule: Data Type: Object Mapping: Group: Units: Minimum Value: Maximum Value: Default Value: 246,204,_,_,_. Get BOOL 0x384-4-57 Diagnostics 0 = Not Present 1 = Present 0 This parameter allows the user to view the status of Trip Coil Open fault from the IB4 module. If the bit is ‘0’ then the warning is not present. If the bit is ‘1’ then the warning is present.
PAGE 303
B-128 Parameters Extended Close Time on IB2 [IB 2 Extended Pick up Time] Parameter Number: Access rule: Data Type: Object Mapping: Group: Units: Minimum Value: Maximum Value: Default Value: 249,206,163,120,_. Get BOOL 0x384-2-55 Diagnostics 0 = Not Present 1 = Present 0 This parameter allows the user to view the status of Extended Pick up Time warning from the IB2 module. If the bit is ‘0’ then the warning is not present. If the bit is ‘1’ then the warning is present.
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Parameters B-129 Extended Close Time on IB4 [IB 4 Extended Pick up Time] Parameter Number: Access rule: Data Type: Object Mapping: Group: Units: Minimum Value: Maximum Value: Default Value: 251,208,_,_,_. Get BOOL 0x384-4-55 Diagnostics 0 = Not Present 1 = Present 0 This parameter allows the user to view the status of Extended Pick up Time warning from the IB4 module. If the bit is ‘0’ then the warning is not present. If the bit is ‘1’ then the warning is present.
PAGE 305
B-130 Parameters Average Number of Operations per Time Unit on IB1 [IB 1 Average Operations per Time Unit] Parameter Number: Access rule: Data Type: Object Mapping: Group: Units: Minimum Value: Maximum Value: Default Value: 253,209,165,121,76. Get/Set USINT 0x384-1-43 Diagnostics 0 2 0 This parameter allows the user to view and set the status of the Average Number of Operations per Unit Time for IB1.
PAGE 306
Parameters B-131 Average Number of Operations per Time Unit on IB2 [IB 2 Average Operations per Time Unit] Parameter Number: Access rule: Data Type: Object Mapping: Group: Units: Minimum Value: Maximum Value: Default Value: 255,211,167,123,_. Get/Set USINT 0x384-2-43 Diagnostics 0 2 0 This parameter allows the user to view and set the status of the Average Number of Operations per Unit Time for IB2.
PAGE 307
B-132 Parameters Average Number of Operations per Time Unit on IB3 [IB 3 Average Operations per Time Unit] Parameter Number: Access rule: Data Type: Object Mapping: Group: Units: Minimum Value: Maximum Value: Default Value: 257,213,169,_,_. Get/Set USINT 0x384-3-43 Diagnostics 0 2 0 This parameter allows the user to view and set the status of the Average Number of Operations per Unit Time for IB3.
PAGE 308
Parameters B-133 Average Number of Operations per Time Unit on IB4 [IB 4 Average Operations per Time Unit] Parameter Number: Access rule: Data Type: Object Mapping: Group: Units: Minimum Value: Maximum Value: Default Value: 259,215,_,_,_. Get/Set USINT 0x384-4-43 Diagnostics 0 2 0 This parameter allows the user to view and set the status of the Average Number of Operations per Unit Time for IB4. The Time Unit is used to set the period over which the Average number of Operations is to be calculated for.
PAGE 309
B-134 Parameters Average Number of Operations per Time Unit on IB5 [IB 5 Average Operations per Time Unit] Parameter Number: Access rule: Data Type: Object Mapping: Group: Units: Minimum Value: Maximum Value: Default Value: 261,_,_,_,_. Get/Set USINT 0x384-5-43 Diagnostics 0 2 0 This parameter allows the user to view and set the status of the Average Number of Operations per Unit Time for IB5. The Time Unit is used to set the period over which the Average number of Operations is to be calculated for.
PAGE 310
Parameters B-135 Total Number of Close Operations on IB1 [IB 1 Master Counter] Parameter Number: Access rule: Data Type: Object Mapping: Group: Units: Minimum Value: Maximum Value: Default Value: 263,217,171,125,78. Get UDINT 0x384-1-32 Diagnostics Total number of Close operations for IB1 0 0xFFFFFF 0 This parameter allows the user to view the Total Number of Close Operations that has occurred on IB1 since its initial use. This value cannot be reset.
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B-136 Parameters Total Number of Close Operations on IB3 [IB 3 Master Counter] Parameter Number: Access rule: Data Type: Object Mapping: Group: Units: Minimum Value: Maximum Value: Default Value: 265,219,173,_,_. Get UDINT 0x384-3-32 Diagnostics Total number of Close operations for IB3 0 0xFFFFFF 0 This parameter allows the user to view the Total Number of Close Operations that has occurred on IB3 since its initial use. This value cannot be reset.
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Parameters B-137 Total Number of Close Operations on IB5 [IB 5 Master Counter] Parameter Number: Access rule: Data Type: Object Mapping: Group: Units: Minimum Value: Maximum Value: Default Value: 267,_,_,_,_. Get UDINT 0x384-5-32 Diagnostics Total number of Close operations for IB5 0 0xFFFFFF 0 This parameter allows the user to view the Total Number of Close Operations that has occurred on IB5 since its initial use. This value cannot be reset.
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B-138 Parameters highest level will contain the data that was in the second highest level. This system will provide that there will always be three sets of Counter operation records for three discrete times. Thus, this feature allows the user to monitor the number of Close operations that have occurred over three discrete time periods for historical operation of the contactor or for maintenance reasons. See “Operations Since” Counter in Chapter 4 for a more detailed description of this feature.
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Parameters B-139 Average Number of Operations per Time Unit on IB3 [IB 3 Reset Operations Since Counter] Parameter Number: Access rule: Data Type: Object Mapping: Group: Units: Minimum Value: Maximum Value: Default Value: 270,223,176,_,_. Get/Set BOOL 0x384-3-33 Diagnostics 0 = No Operation 1 = Reset 0 This parameter allows the user to view and set the status of the Reset “Operations Since” Counter for IB3. If the bit is a ‘0’ then No Operation is performed on the Average Counting vs.
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B-140 Parameters Average Number of Operations per Time Unit on IB4 [IB 4 Reset Operations Since Counter] Parameter Number: Access rule: Data Type: Object Mapping: Group: Units: Minimum Value: Maximum Value: Default Value: 271,224,_,_,_. Get/Set BOOL 0x384-4-33 Diagnostics 0 = No Operation 1 = Reset 0 This parameter allows the user to view and set the status of the Reset “Operations Since” Counter for IB4. If the bit is a ‘0’ then No Operation is performed on the Average Counting vs.
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Parameters B-141 Average Number of Operations per Time Unit on IB5 [IB 5 Reset Operations Since Counter] Parameter Number: Access rule: Data Type: Object Mapping: Group: Units: Minimum Value: Maximum Value: Default Value: 272,_,_,_,_. Get/Set BOOL 0x384-5-33 Diagnostics 0 = No Operation 1 = Reset 0 This parameter allows the user to view and set the status of the Reset “Operations Since” Counter for IB5. If the bit is a ‘0’ then No Operation is performed on the Average Counting vs.
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B-142 Parameters Operations since 0 Count Value on IB1 [IB 1 Operations Since 0 Count Value] Parameter Number: Access rule: Data Type: Object Mapping: Group: Units: Minimum Value: Maximum Value: Default Value: 273,225,177,129,80. Get UDINT 0x384-1-34 Diagnostics 0 0xFFFFFF 0 This parameter allows the user to view the number of Operations since a Reset Counter on IB1 event occurred. See “Operations Since” Counter in Chapter 4 for a more detailed description of this feature.
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Parameters B-143 Time of Operations Since 0 Count Value on IB1 [IB 1 Operations since 0 Time] Parameter Number: Access rule: Data Type: Object Mapping: Group: Units: Minimum Value: Maximum Value: Default Value: 275,227,179,131,82. Get TIME 0x384-1-36 Diagnostics 0 0xFFFF 0 This parameter allows the user to view the Time for which the Operations since a Reset Counter on IB1 event occurred. See “Operations Since” Counter in Chapter 4 for a more detailed description of this feature.
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B-144 Parameters Date of Operations Since 1 Count Value on IB1 [IB 1 Operations Since 1 Date] Parameter Number: Access rule: Data Type: Object Mapping: Group: Units: Minimum Value: Maximum Value: Default Value: 277,229,181,133,84. Get DATE 0x384-1-38 Diagnostics 0 0xFFFF 0 This parameter allows the user to view the Date for which the Operations since a Reset Counter on IB1 event occurred and transferred the Since 0 count value to the Since 1 count value.
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Parameters B-145 Operations Since 2 Count Value on IB1 [IB 1 Operations Since 2 Count Value] Parameter Number: Access rule: Data Type: Object Mapping: Group: Units: Minimum Value: Maximum Value: Default Value: 279,231,183,135,86. Get UDINT 0x384-1-40 Diagnostics 0 0xFFFFFF 0 This parameter allows the user to view the number of Operations since a Reset Counter on IB1 event occurred and transferred the Since 1 count value to the Since 2 count value.
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B-146 Parameters Time of Operations Since 2 Count Value on IB1 [IB 1 Operations Since 2 Time] Parameter Number: Access rule: Data Type: Object Mapping: Group: Units: Minimum Value: Maximum Value: Default Value: 281,233,185,137,88. Get TIME 0x384-1-42 Diagnostics 0 0xFFFF 0 This parameter allows the user to view the Time for which the Operations since a Reset Counter on IB1 event occurred and transferred the Since 1 count value to the Since 2 count value.
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Parameters B-147 Date of Operations Since 0 Count Value on IB2 [IB 2 Operations Since 0 Date] Parameter Number: Access rule: Data Type: Object Mapping: Group: Units: Minimum Value: Maximum Value: Default Value: 283,235,187,139,_. Get DATE 0x384-2-35 Diagnostics 0 0xFFFF 0 This parameter allows the user to view the Date for which the Operations since a Reset Counter on IB2 event occurred. See “Operations Since” Counter in Chapter 4 for a more detailed description of this feature.
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B-148 Parameters Operations Since 1 Count Value on IB2 [IB 2 Operations Since 1 Count Value] Parameter Number: Access rule: Data Type: Object Mapping: Group: Units: Minimum Value: Maximum Value: Default Value: 285,237,189,141,_. Get UDINT 0x384-2-37 Diagnostics 0 0xFFFFFF 0 This parameter allows the user to view the number of Operations since a Reset Counter on IB2 event occurred and transferred the Since 0 count value to the Since 1 count value.
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Parameters B-149 Time of Operations Since 1 Count Value on IB2 [IB 2 Operations Since 1 Time] Parameter Number: Access rule: Data Type: Object Mapping: Group: Units: Minimum Value: Maximum Value: Default Value: 287,239,191,143,_. Get TIME 0x384-1-39 Diagnostics 0 0xFFFF 0 This parameter allows the user to view the Time for which the Operations since a Reset Counter on IB2 event occurred and transferred the Since 0 count value to the Since 1 count value.
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B-150 Parameters Date of Operations Since 2 Count Value on IB2 [IB 2 Operations Since 2 Date] Parameter Number: Access rule: Data Type: Object Mapping: Group: Units: Minimum Value: Maximum Value: Default Value: 289,241,193,145,_. Get DATE 0x384-2-41 Diagnostics 0 0xFFFF 0 This parameter allows the user to view the Date for which the Operations since a Reset Counter on IB2 event occurred and transferred the Since 1 count value to the Since 2 count value.
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Parameters B-151 Operations Since 0 Count Value on IB3 [IB 3 Operations Since 0 Count Value] Parameter Number: Access rule: Data Type: Object Mapping: Group: Units: Minimum Value: Maximum Value: Default Value: 291,243,195,_,_. Get UDINT 0x384-3-34 Diagnostics 0 0xFFFFFF 0 This parameter allows the user to view the number of Operations since a Reset Counter on IB3 event occurred. See “Operations Since” Counter in Chapter 4 for a more detailed description of this feature.
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B-152 Parameters Time of Operations Since 0 Count Value on IB3 [IB 3 Operations Since 0 Time] Parameter Number: Access rule: Data Type: Object Mapping: Group: Units: Minimum Value: Maximum Value: Default Value: 293,245,197,_,_. Get TIME 0x384-3-36 Diagnostics 0 0xFFFF 0 This parameter allows the user to view the Time for which the Operations since a Reset Counter on IB3 event occurred. See “Operations Since” Counter in Chapter 4 for a more detailed description of this feature.
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Parameters B-153 Date of Operations Since 1 Count Value on IB3 [IB 3 Operations Since 1 Date] Parameter Number: Access rule: Data Type: Object Mapping: Group: Units: Minimum Value: Maximum Value: Default Value: 295,247,199,_,_. Get DATE 0x384-3-38 Diagnostics 0 0xFFFF 0 This parameter allows the user to view the Date for which the Operations since a Reset Counter on IB3 event occurred and transferred the Since 0 count value to the Since 1 count value.
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B-154 Parameters Operations Since 2 Count Value on IB3 [IB 3 Operations Since 2 Count Value] Parameter Number: Access rule: Data Type: Object Mapping: Group: Units: Minimum Value: Maximum Value: Default Value: 297,249,201,_,_. Get UDINT 0x384-3-40 Diagnostics 0 0xFFFFFF 0 This parameter allows the user to view the number of Operations since a Reset Counter on IB3 event occurred and transferred the Since 1 count value to the Since 2 count value.
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Parameters B-155 Time of Operations Since 2 Count Value on IB3 [IB 3 Operations Since 2 Time] Parameter Number: Access rule: Data Type: Object Mapping: Group: Units: Minimum Value: Maximum Value: Default Value: 299,251,203,_,_. Get TIME 0x384-3-42 Diagnostics 0 0xFFFF 0 This parameter allows the user to view the Time for which the Operations since a Reset Counter on IB3 event occurred and transferred the Since 1 count value to the Since 2 count value.
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B-156 Parameters Date of Operations Since 0 Count Value on IB4 [IB 4 Operations Since 0 Date] Parameter Number: Access rule: Data Type: Object Mapping: Group: Units: Minimum Value: Maximum Value: Default Value: 301,253,_,_,_. Get DATE 0x384-4-35 Diagnostics 0 0xFFFF 0 This parameter allows the user to view the Date for which the Operations since a Reset Counter on IB4 event occurred. See “Operations Since” Counter in Chapter 4 for a more detailed description of this feature.
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Parameters B-157 Operations Since 1 Count Value on IB4 [IB 4 Operations Since 1 Count Value] Parameter Number: Access rule: Data Type: Object Mapping: Group: Units: Minimum Value: Maximum Value: Default Value: 303,255,_,_,_. Get UDINT 0x384-4-37 Diagnostics 0 0xFFFFFF 0 This parameter allows the user to view the number of Operations since a Reset Counter on IB4 event occurred and transferred the Since 0 count value to the Since 1 count value.
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B-158 Parameters Time of Operations Since 1 Count Value on IB4 [IB 4 Operations Since 1 Time] Parameter Number: Access rule: Data Type: Object Mapping: Group: Units: Minimum Value: Maximum Value: Default Value: 305,257,_,_,_. Get TIME 0x384-4-39 Diagnostics 0 0xFFFF 0 This parameter allows the user to view the Time for which the Operations since a Reset Counter on IB4 event occurred and transferred the Since 0 count value to the Since 1 count value.
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Parameters B-159 Date of Operations Since 2 Count Value on IB4 [IB 4 Operations Since 2 Date] Parameter Number: Access rule: Data Type: Object Mapping: Group: Units: Minimum Value: Maximum Value: Default Value: 307,259,_,_,_. Get DATE 0x384-4-41 Diagnostics 0 0xFFFF 0 This parameter allows the user to view the Date for which the Operations since a Reset Counter on IB4 event occurred and transferred the Since 1 count value to the Since 2 count value.
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B-160 Parameters Operations Since 0 Count Value on IB5 [IB 5 Operations Since 0 Count Value] Parameter Number: Access rule: Data Type: Object Mapping: Group: Units: Minimum Value: Maximum Value: Default Value: 309,_,_,_,_. Get UDINT 0x384-5-34 Diagnostics 0 0xFFFFFF 0 This parameter allows the user to view the number of Operations since a Reset Counter on IB5 event occurred. See “Operations Since” Counter in Chapter 4 for a more detailed description of this feature.
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Parameters B-161 Time of Operations Since 0 Count Value on IB5 [IB 5 Operations Since 0 Time] Parameter Number: Access rule: Data Type: Object Mapping: Group: Units: Minimum Value: Maximum Value: Default Value: 311,_,_,_,_. Get TIME 0x384-5-36 Diagnostics 0 0xFFFF 0 This parameter allows the user to view the Time for which the Operations since a Reset Counter on IB5 event occurred. See “Operations Since” Counter in Chapter 4 for a more detailed description of this feature.
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B-162 Parameters Date of Operations Since 1 Count Value on IB5 [IB 5 Operations Since 1 Date] Parameter Number: Access rule: Data Type: Object Mapping: Group: Units: Minimum Value: Maximum Value: Default Value: 313,_,_,_,_. Get DATE 0x384-5-38 Diagnostics 0 0xFFFF 0 This parameter allows the user to view the Date for which the Operations since a Reset Counter on IB5 event occurred and transferred the Since 0 count value to the Since 1 count value.
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Parameters B-163 Operations Since 2 Count Value on IB5 [IB 5 Operations Since 2 Count Value] Parameter Number: Access rule: Data Type: Object Mapping: Group: Units: Minimum Value: Maximum Value: Default Value: 315,_,_,_,_. Get UDINT 0x384-5-40 Diagnostics 0 0xFFFFFF 0 This parameter allows the user to view the number of Operations since a Reset Counter on IB5 event occurred and transferred the Since 1 count value to the Since 2 count value.
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B-164 Parameters Time of Operations Since 2 Count Value on IB5 [IB 5 Operations Since 1 Time] Parameter Number: Access rule: Data Type: Object Mapping: Group: Units: Minimum Value: Maximum Value: Default Value: 317,_,_,_,_. Get TIME 0x384-5-42 Diagnostics 0 0xFFFF 0 This parameter allows the user to view the Time for which the Operations since a Reset Counter on IB5 event occurred and transferred the Since 1 count value to the Since 2 count value.
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Parameters B-165 Length of Event Log on IB2 [IB 2 Event Present Length] Parameter Number: Access rule: Data Type: Object Mapping: Group: Units: Minimum Value: Maximum Value: Default Value: 319,262,205,148,_. Get UINT 0x384-2-52 Diagnostics 0 100 0 This parameter allows the user to view the Length of the Event Log for IB2. Up to a maximum of 100 Events can be stored, for IB2, in the Event Log before older Events are overwritten with newer Events.
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B-166 Parameters Length of Event Log on IB4 [IB 4 Event Present Length] Parameter Number: Access rule: Data Type: Object Mapping: Group: Units: Minimum Value: Maximum Value: Default Value: 321,264,_,_,_. Get UINT 0x384-4-52 Diagnostics 0 100 0 This parameter allows the user to view the Length of the Event Log for IB4. Up to a maximum of 100 Events can be stored, for IB4, in the Event Log before older Events are overwritten with newer Events.
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Parameters B-167 Module Status of IB1 [IB Status] Parameter Number: Access rule: Data Type: Object Mapping: Group: Units: Minimum Value: Maximum Value: Default Value: 323,265,207,149,90. Get BYTE 0xB4-1-120 Diagnostics 0 0xFF 0 This parameter allows the user to view the Module Status of IB1. Table B.
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B-168 Parameters Invalid DeviceLogix Program Loaded [Invalid DeviceLogix Program] Parameter Number: Access rule: Data Type: Object Mapping: Group: Units: Minimum Value: Maximum Value: Default Value: 325,267,209,151,92. Get BOOL 0xB4-1-115 Diagnostics 0 = Invalid DLX Prog. 1 = Valid or No DLX Prog. 1 This parameter allows the user to view the status of the DeviceLogix Program that has been selected for operation. If the bit is a ‘0’ then the DeviceLogix Program is invalid.
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Parameters B-169 Altitude Settings on MC Units Inconsistent [MC Altitude Set Warning] Parameter Number: Access rule: Data Type: Object Mapping: Group: Units: Minimum Value: Maximum Value: Default Value: 327,269,211,153,94. Get BOOL 0xB4-1-122 Diagnostics 0 = Not Fault 1 = MC Altitude setting inconsistent 0 This parameter allows the user to view the status of the Altitude settings from the various IntelliVAC MC units.
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B-170 Parameters Drop Out Time Source [Drop Out Time Source] Parameter Number: Access rule: Data Type: Object Mapping: Group: Units: Minimum Value: Maximum Value: Default Value: 329,271,213,155,96. Get/Set BOOL 0xB4-1-124 Diagnostics 0 = From IB 1 = From IE 0 This parameter allows the user to view and set the status of the Drop Out Time Source. If this bit is a ‘0’ then the IB DIP switch setting is used as the Drop Out Time Source.
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Parameters B-171 Contactor Coil Current for IB2 [IB 2 Contactor Coil Current] Parameter Number: Access rule: Data Type: Object Mapping: Group: Units: Minimum Value: Maximum Value: Default Value: 331,273,215,157,_. Get FLOAT 0x384-2-61 Diagnostics Amperes 00.000A 99.999A 00.000A This parameter allows the user to view the real time operating Coil Current for IB2.
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B-172 Parameters Contactor Coil Current for IB4 [IB 4 Contactor Coil Current] Parameter Number: Access rule: Data Type: Object Mapping: Group: Units: Minimum Value: Maximum Value: Default Value: 333,275,_,_,_. Get FLOAT 0x384-4-61 Diagnostics Amperes 00.000A 99.999 A 00.000A This parameter allows the user to view the real time operating Coil Current for IB4.
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Parameters B-173 Status Word for IB1 [IB 1 Status Word] Parameter Number: Access rule: Data Type: Object Mapping: Group: Units: Minimum Value: Maximum Value: Default Value: 335,276,217,158,98. Get WORD 0x384-1-62 Diagnostics 0 0xFFFF 0 This parameter allows the user to view the IB1 Status Word. If a bit is ‘0’ then the fault or warning is not present. If a bit is a ‘1’ then the fault or warning is present. Table B.
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B-174 Parameters Status Word for IB2 [IB 2 Status Word] Parameter Number: Access rule: Data Type: Object Mapping: Group: Units: Minimum Value: Maximum Value: Default Value: 336,277,218,159,_. Get WORD 0x384-2-62 Diagnostics 0 0xFFFF 0 This parameter allows the user to view the IB2 Status Word. If a bit is ‘0’ then the fault or warning is not present. If a bit is a ‘1’ then the fault or warning is present. Table B.
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Parameters B-175 Status Word for IB3 [IB 3 Status Word] Parameter Number: Access rule: Data Type: Object Mapping: Group: Units: Minimum Value: Maximum Value: Default Value: 337,278,219,_,_. Get WORD 0x384-3-62 Diagnostics 0 0xFFFF 0 This parameter allows the user to view the IB3 Status Word. If a bit is ‘0’ then the fault or warning is not present. If a bit is a ‘1’ then the fault or warning is present. Table B.
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B-176 Parameters Status Word for IB4 [IB 4 Status Word] Parameter Number: Access rule: Data Type: Object Mapping: Group: Units: Minimum Value: Maximum Value: Default Value: 338,279,_,_,_. Get WORD 0x384-4-62 Diagnostics 0 0xFFFF 0 This parameter allows the user to view the IB4 Status Word. If a bit is ‘0’ then the fault or warning is not present. If a bit is a ‘1’ then the fault or warning is present. Table B.
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Parameters B-177 Status Word for IB5 [IB 5 Status Word] Parameter Number: Access rule: Data Type: Object Mapping: Group: Units: Minimum Value: Maximum Value: Default Value: 339,_,_,_,_. Get WORD 0x384-5-62 Diagnostics 0 0xFFFF 0 This parameter allows the user to view the IB5 Status Word. If a bit is ‘0’ then the fault or warning is not present. If a bit is a ‘1’ then the fault or warning is present. Table B.
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B-178 Parameters Correct Termination Resistor Installed in MC System [Correct MC Termination Resistor] Parameter Number: Access rule: Data Type: Object Mapping: Group: Units: Minimum Value: Maximum Value: Default Value: 340,280,220,160,99. Get BOOL 0x384-1-63 Diagnostics 0 = Not Present 1 = Present 0 This parameter allows the user to view the status of the MC Termination Resistor installation. If this bit is ‘0’, then the correct MC Termination Resistor is not installed in the MC system.
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Parameters B-179 Termination Resistor Installed in IB3 [IB3 Termination Resistor] Parameter Number: Access rule: Data Type: Object Mapping: Group: Units: Minimum Value: Maximum Value: Default Value: 342,282,222,_,_. Get BOOL 0x384-3-63 Diagnostics 0 = Not Present 1 = Present 0 This parameter allows the user to view the status of the MC Termination Resistor installation on IB3. If this bit is ‘0’, then the MC Termination Resistor is not installed on the IB3 unit.
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B-180 Parameters Termination Resistor Installed in IB5 [IB5 Termination Resistor] Parameter Number: Access rule: Data Type: Object Mapping: Group: Units: Minimum Value: Maximum Value: Default Value: 344,_,_,_,_. Get BOOL 0x384-5-63 Diagnostics 0 = Not Present 1 = Present 0 This parameter allows the user to view the status of the MC Termination Resistor installation on IB5. If this bit is ‘0’, then the MC Termination Resistor is not installed on the IB5 unit.
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Parameters B-181 Status Word for the MC System [MC System Status] Parameter Number: Access rule: Data Type: Object Mapping: Group: Units: Minimum Value: Maximum Value: Default Value: 346,285,224,163,101. Get/Set WORD 0xB4-1-127 Diagnostics 0 0xFFFF 0 This parameter allows the user to view the MC System Status Word. If a bit is ‘0’ then the fault or warning is not present. If a bit is a ‘1’ then the fault or warning is present. See Table 4.
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B-182 Parameters MC System Ready Status [MC System Ready Status] Parameter Number: Access rule: Data Type: Object Mapping: Group: Units: Minimum Value: Maximum Value: Default Value: 347,286,225,164,102. Get BOOL 0xB4-1-126 Diagnostics 0 = False 1 = True 0 This parameter allows the user to view the Ready Status of the MC System. If this bit is False then there is an MC System fault or warning present. If this bit is True, then there is no MC System fault or warning present. See Table 4.
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Parameters B-183 MC System Locked [MC System Locked] Parameter Number: Access rule: Data Type: Object Mapping: Group: Units: Minimum Value: Maximum Value: Default Value: 349,288,227,166,104. Get SINT 0xB4-1-130 Diagnostics 0 1 0 This parameter allows the user to view the status of the MC System Locked state. If a bit is a ‘1’ then the fault or warning is present. If a bit is a ‘1’ then the fault or warning is present. See Table 4.J in Chapter 4 for a detailed description of the MC System Locked feature.
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B-184 Parameters IB1 Firmware Version [IB1 Firmware Version] Parameter Number: Access rule: Data Type: Object Mapping: Group: Units: Minimum Value: Maximum Value: Default Value: 351,290,229,168,106. Get FLOAT 0x384-1-64 Diagnostics 0.00 3.17 0.01 This parameter allows the user to view the Version of the Firmware in IB1. See IE/IB Firmware Revisions in Chapter 8 for a detailed description of the format for the Firmware Version.
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Parameters B-185 IB4 Firmware Version [IB4 Firmware Version] Parameter Number: Access rule: Data Type: Object Mapping: Group: Units: Minimum Value: Maximum Value: Default Value: 354,293,_,_,_. Get FLOAT 0x384-4-64 Diagnostics 0.00 3.17 0.01 This parameter allows the user to view the Version of the Firmware in IB4. See IE/IB Firmware Revisions in Chapter 8 for a detailed description of the format for the Firmware Version.
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B-186 Parameters 1503-UM054C-EN-P – June 2013
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Appendix C Maintenance Introduction The IntelliVAC Plus product has is a very robust device which contains only two user serviceable parts. These parts are:  the fuse for the mains input line and  the battery used by the Real Time Clock (RTC) circuitry. Mains Input Fuse This fuse is designed to protect the IntelliVAC Plus unit in the event of the failure of a contactor coil or failure of an internal electronic component.
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C-2 Maintenance IMPORTANT RTC Battery The cause of the fuse failure should be identified before the fuse is replaced otherwise it may fail again once the IntelliVAC Plus module is powered up. The RTC battery should have a lifetime of at least 10 years so that its replacement should not be necessary. However, if the RTC should show to not be operating correctly and resetting the date/time through RSNetworx does not function correctly, then the battery may be in need of changing.
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Appendix D Spare Parts Table D.1 – Spare Parts Item Description Part Number Internal Fuse 6.3A, 250V (Littlefuse 21506.
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D-2 Spare Parts 1503-UM054C-EN-P – June 2013
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Appendix E DeviceNet Information Identify Object Table E.1 - Class Attributes Attribute ID Access Rule Name DeviceNet Data Type Data Value 1 2 Get Get Rev ision Max Instance  UINT UINT 1.0 1 DeviceNet Data Type Data Value  Only valid when flash instance is supported. Number of Instances: 1 Table E.
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E-2 Dev iceNet Information Table E.3 – Device Status Bit No.
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E-3 Dev iceNet Information Table E.
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E-4 Dev iceNet Information Explicit Connection Table E.9 - Instance Attributes (predefined slave explicit connection) 1503-UM054C-EN-P – June 2013 Attribute ID Access Rule 1 Get state USINT 2 3 Get Get instance_ty pe transportClass_trigger USINT BYTE 4 Get UINT 10x x xxxx011 x x xxxx=node address 5 Get UINT 10x x xxxx100 x x xxxx=node address 6 Get produced_connection_id CAN header field 11 bit message consumed_connection_id CAN header field 11 bit message initial_comm.
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Dev iceNet Information E-5 Parameter Object The parameter object and parameter object are all for mainly for 193-HIM to get online parameters. Table E.
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E-6 Dev iceNet Information Common Service Table E.12 - Service Codes Implementation for Service Code Class Yes No No No 0E hex 10 hex 0x 01 0x 4B Instance Yes Yes Yes Yes Service Name Get_Attribute_Single Set_Attribute_Single Get_Attribute_All Get_Enum_String Here is the list of parameters with detail attribute values: Table E.
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Dev iceNet Information E-7 Output (Consumed) Assembly and Layout Output assembly instances attribute and format (produced by DeviceNet Master, consumed by IE)   IB OutA=close coil command IB OutB=open coil command Table E.
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E-8 Dev iceNet Information Input (Produced) Assembly and Layout Table E.
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E-9 Dev iceNet Information Important Notes: *About PNBnn/IBx-Outy: this is IntelliVAC assembly’s unique feature: some produced network bits are used in 2 purposes, depends on the control mask and if there is DeviceLogix program:  If the control mask is mask local or mask network, these bits are normal PNB  If mask DeviceLogix and there is no DeviceLogix program, they are normal produced network data, when there is DeviceLogix program, they (the 10 IB-Out) are DeviceLogix result (same as same name in Con
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E-10 Dev iceNet Information Table E.
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Dev iceNet Information E-11 Table E.22 – Instance Attributes (cont.
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E-12 Dev iceNet Information Table E.25 - Instance Attribute Parameter No.
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Dev iceNet Information E-13 Table E.25 - Instance Attribute (cont.) Parameter No.
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E-14 Dev iceNet Information Table E.25 - Instance Attribute (cont.) Parameter No. Control Parameter Access Rule Type Description 58 59 TDUV base Time (from DIP)* Line Underv oltage Hold Get Get USINT BOOL 60 Contactor Long Drop Out Time Get BOOL 61 62 63 Coil Current trend*** IB module status**** Correct MC Termination resistor@ Ibx Termination resistor IB rev ision Get Get/Set Get LONG INT* UINT BOOL Get LONG INT* 64 0.2/0.5/1.0/2.
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Dev iceNet Information E-15 PCP Object (Motor Control Center Object) Class Attributes: None Number of Instances: 1 Table E.
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E-16 Dev iceNet Information Data Table Layout Table E.29 shows the data table layout. Table E.
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Dev iceNet Information E-17 Table E.29 – DeviceLogix Data Table Layout (cont.
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E-18 Dev iceNet Information 1503-UM054C-EN-P – June 2013
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Appendix F IntelliVAC Plus Firmware Introduction In order to update the firmware of the IntelliVAC Plus module using DeviceNet you will need the following: 1. Personal computer equipped with a DeviceNet interface such as a 1784-PCD or 1770-KFD 2. IntelliVAC Plus Event Browser Software 3. A functioning DeviceNet network including 24VDC DeviceNet power supply Browsing the Events: • Start the IntelliVAC Plus Event Browser Software • Select a DeviceNet driver Figure F.
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F-2 IntelliVAC Plus Firmw are • Configure the selected DeviceNet driver Figure F.2 – DeviceNet Drive Configuration • • • Set the MacID of the IntelliVAC Plus Select the Base Module Click ‘Update’ button, the events of the selected base module will be shown in the list Figure F.
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Medium Voltage Products, 135 Dundas Street, Cambridge, ON, N1R 5X1 Canada, Tel: (1) 519.740.4100, Fax: (1) 519.623.8930, www.ab.com/mvb Publication 1503-UM054C-EN-P – June 2013 Supersedes Publication 1503-UM054B-EN-P – April 2011 Copyright © 2013 Rockwell Automation, Inc. All rights reserved.