Power Distribution Terminal Board GE Mark VI IS200JPDPG1A
Manufacturer: GE Fanuc
-
Part Number: IS200JPDPG1A
Condition:New with Original Package
Product Type: Power Distribution Terminal Boards
-
Country of Origin: USA
Payment:T/T, Western Union
Shipping port: Xiamen
Warranty: 12 months
GE IS200JPDPG1A Mark VI Board
The General Electric IS200JPDPG1A, also cataloged as the IS200JPDPG1A Power Distribution Terminal Board, operates as a dedicated hardware component for regulated DC power distribution within Mark VI platforms. Configured to accept a nominal 125 VDC input, the board routes electrical power across multiple localized output channels to supply control and I/O sub-systems, managing overload limits through integrated inline fuse arrays.
Hardware Specifications
| Parameter | Specification |
|---|---|
| Model | IS200JPDPG1A |
| Brand | General Electric |
| Origin | USA |
| Weight | 0.45 kg |
| Dimensions | 233 x 100 x 25 mm |
| Operating Temp | -25 to +65 deg C |
| Power Consumption | 125 VDC nominal input |
| Product Type | Power Distribution Terminal Board |
| Power Supply Capacity | Up to 20 A total distribution |
| Input Voltage | 125 VDC (nominal) |
| Output Distribution | Multiple DC channels to control and I/O boards |
| Protection | Inline fuses per individual output channel |
| Isolation | 1500 VAC system-to-board for 1 min |
| Diagnostics | Local LED indicators for power status and fault tracking |
| Redundancy | Redundant architecture supported via dual configuration |
| Humidity Range | 5 to 95% RH, non-condensing |
| Mounting | Panel or rack mounting |
Industrial Control and Drive Attributes
Operating inside the standard electrical enclosure, the IS200JPDPG1A directly impacts backplane bus communication velocity by maintaining continuous, uncorrupted power voltage levels to adjacent active processors. The physical circuit architecture features specific copper path cross-sections optimized for total I/O density scaling up to 20 A. This stabilization preserves structural signal transmission, mitigating voltage sags during load shifts that could otherwise disrupt host system firmware flash compatibility states or trigger software exceptions.
Frequently Asked Questions
Q: How is a blown fuse identified on this power distribution terminal board?
A: Each individual output distribution circuit features a dedicated diagnostic LED indicator circuit. Under standard running parameters, the loop status remains clear, but an open-circuit fault caused by a blown fuse alters the path conduction, triggering a local diagnostic fault LED state to isolate the problematic circuit.
Q: Can single output channels be serviced or re-fused while the board is actively powering other redundant I/O modules?
A: Live servicing of active fuses introduces arc hazards and potential transient voltage spikes that can disrupt parallel channels. Standard safety procedures require isolated loops to be de-energized or the redundant power branch to take full load before extracting physical fuses from the terminal board.
Q: What mechanism prevents high-voltage feedback into the lower-voltage system control logic?
A: Physical system safety depends on the 1500 VAC galvanic system-to-board isolation layout, which separates the primary 125 VDC distribution buses from low-voltage logic control signals to block ground loops and inductive feedback pathways.
Field Installation Guidelines
- Secure the terminal board chassis to the designated panel backplate or internal enclosure frame utilizing the integrated mounting screw holes, establishing metal-to-metal contact for frame grounding.
- Connect the primary 125 VDC input lines to the heavy-duty input terminals, verifying that torque ratings match standard industrial termination values to avoid resistive hot spots.
- Route all branching DC output power lines in segregated wiring ducts separate from low-voltage analog or high-frequency communication cabling to eliminate transient cross-talk.
- Perform a verification check on all output branch fuses, ensuring the correct amperage ratings are seated securely in their holders before energizing the main supply circuit.