The replacement boundary for FGHJ40KK-1024G-90G-NG/20P is defined by 1024 PPR standard scaling, J isolated-bearing construction, KK dual terminal-box wiring, /20P hollow-shaft fit, A/B 90° phase relationship, inverted signal pairs, N reference pulse behavior, torque bracket freedom, adapter-shaft run-out, and shield grounding. EncoderWorks can configure a custom compatible replacement solution when these electrical, mechanical, and isolation limits must remain unchanged. The main failure boundary is a hollow-shaft drive that receives clean pulses but develops wrong speed scaling, direction mismatch, reference loss, redundant-channel disagreement, bearing-current damage, or pulse jitter because the pulse count, terminal-box mapping, bore fit, or EMC path has changed. Typical production lead time: 15 working days.
This model belongs to the FGHJ 40 incremental hollow-shaft encoder platform. The 1024 PPR value is a standard square-wave pulse rate, so replacement work should focus on stable reference scaling, dual terminal-box agreement, A/B/N signal continuity, shield bonding, and controlled hollow-shaft mounting. The J construction adds an isolation boundary for applications where shaft currents or potential differences could otherwise pass through the encoder bearings. It should not be treated as an older FGHJ 4 version, a single K terminal-box unit, or an S/SS plug-connected configuration.


System Limits
The first system limit is 1024 PPR standard scaling. If either controller path is configured for 1000, 1200, 2048, or another pulse value, both feedback channels may output stable square waves while speed, travel, and synchronization values become wrong. Edge-counting mode, gear ratio, speed conversion, direction logic, and reference scaling should be checked on both terminal-box paths before startup.
The second limit is KK dual terminal-box agreement. Each terminal box must preserve A, /A, B, /B, N, and /N exactly as required by the controller or redundant comparison system. If one phase pair is swapped, one inverted signal is omitted, one shield reference differs, or the N reference pulse is assigned differently between boxes, the machine may fail during homing, direction reversal, synchronized movement, or redundant-channel comparison.
The third limit is hollow-shaft mechanics and isolated bearing protection. The /20P interface must fit the prepared shaft without forcing, and the torque bracket must remain free at the link heads. Excessive adapter-shaft run-out, axial preload, radial load, shaft shock, torque-arm binding, or loss of isolation can shorten bearing life and appear as pulse jitter, intermittent reference errors, or unstable redundant comparison.
Wiring & Installation
Before replacement, document both terminal-box connections separately. Record supply voltage, GND, shield connection, A/B/N signal sequence, inverted outputs, and any error or diagnostic output used by the control system. Confirm that both counter inputs are scaled for 1024 PPR and that both paths expect the same 0°/90° phase sequence and N reference pulse behavior.
During mechanical installation, clean the customer shaft, centering surface, bolting faces, and fastening threads. Align the adapter shaft carefully, avoid hammering the encoder, and do not pull the hollow-shaft device into position by force. The torque bracket should support housing reaction torque without transmitting bending load into the bearings.
For EMC stability, route feedback wiring away from inverter, motor, brake, contactor, and power cables. Use shielded cable, maintain large-area shield contact, and connect the grounding strap to a nearby low-impedance bare-metal grounding point. Cable glands and blanking plugs must be tightened correctly, and cable strain must not pull sideways on the terminal-box entries. After commissioning, verify pulse count, direction, N reference pulse, dual-box agreement, shielding continuity, isolation requirement, and stable operation through the required speed range.
Custom Compatible Solution
EncoderWorks can configure the replacement around the installed isolated hollow-shaft and redundant terminal-box interface:
- Match 1024 PPR square-wave incremental output with 0°/90° channel behavior and inverted signal pairs
- Preserve J isolated-bearing construction, KK dual terminal-box structure, N reference pulse behavior, supply range, and output level
- Adapt the FGHJ 40 /20P hollow-shaft interface, adapter-shaft fit, torque bracket position, sealing boundary, and cable-gland orientation
- Review 200 kHz counter margin, shielded wiring, terminal-box mapping, grounding strap, isolation requirement, bearing load, and redundant-channel agreement
Key Data
| Item | Data |
|---|---|
| Model | FGHJ40KK-1024G-90G-NG/20P |
| Encoder type | Incremental hollow-shaft encoder |
| Series | FGHJ 40 |
| Bearing construction | Isolated bearings |
| Connection structure | KK, two terminal boxes / redundant version |
| Pulses per revolution | 1024 PPR |
| Pulse-rate class | Standard pulse rate |
| Signal output | Square wave, 0° and 90° channels |
| Inverted signals | Yes, G output configuration |
| Reference pulse | NG, N reference pulse with inverted signal |
| Hollow-shaft interface | /20P |
| Supply voltage | 12–30 VDC |
| Output type | Current-limited, short-circuit-proof push-pull line driver |
| Maximum frequency | 200 kHz, higher on request |
| Protection class | IP65 standard, IP66 versions depending on sealing |
| Mechanical checks | /20P shaft fit, adapter-shaft run-out, torque bracket freedom, bearing load, isolation boundary |
| Key replacement checks | 1024 PPR scaling, isolated bearings, dual terminal-box agreement, A/B phase, N reference pulse, shield grounding |

