PRODUCT DETAILS
20-750-ENC-1 — 755 Series Single-Channel Encoder Feedback Option Card
The 20-750-ENC-1 is a single-channel incremental encoder feedback option card for the 755 series AC drive. It installs into one of the drive's option slots and reads a standard A/B/Z incremental encoder mounted on the motor shaft, unlocking closed-loop flux vector control. Where sensorless vector mode estimates rotor speed from current and voltage, this card gives the drive a direct, measured speed reference — improving low-speed torque accuracy, speed regulation under varying load, and overall control stability for demanding applications.
Specifications
| Parameter | Value |
|---|---|
| Part Number | 20-750-ENC-1 |
| Compatible Drive | 755 Series AC Drive |
| Feedback Type | Incremental encoder (A, B, Z channels) |
| Encoder Signal Levels | TTL differential or HTL (jumper selectable) |
| Max Encoder Frequency | Up to several hundred kHz (TTL) |
| Encoder Supply Voltage | 5V DC or 12V DC (selectable) |
| Installation | 755 drive option card slot |
| Connector | 15-pin D-sub (HD15) |
| Operating Temperature | −10°C to 60°C |
Going From Sensorless Vector to Closed-Loop Control
Sensorless vector mode is adequate for most general-purpose applications, but it has practical limits: accuracy degrades at very low speeds, under rapidly changing loads, and where speed regulation tighter than roughly ±0.5% is required. Adding the 20-750-ENC-1 and a shaft-mounted encoder removes that estimation step. The drive reads actual rotor position and speed on every control cycle, which allows full rated torque at near-zero speed and speed regulation typically an order of magnitude tighter than sensorless operation.
This upgrade path matters for applications that outgrow sensorless vector after commissioning — a winder that needs tighter tension control than originally specified, or a process that's been pushed to lower minimum speeds than the original sensorless tuning could reliably hold. Installing the card and switching the drive's control mode parameter to closed-loop vector, followed by a rotating autotune, completes the transition without replacing the drive itself.
Wiring and Configuration
- Use shielded cable for the encoder feedback run, grounding the shield at the drive end only to avoid ground loops.
- Route the encoder cable away from motor power cables — parallel runs with power conductors are the most common source of encoder noise and resulting speed-hunting symptoms.
- Set the encoder line count and supply voltage jumper to match the connected encoder's specification in the drive parameters before running autotune.
- A rotating autotune (not just static) is required when moving from sensorless to closed-loop vector — this measures the encoder scaling and direction relationship to the motor's electrical rotation.
FAQ
Q: Does installing this card automatically switch the drive to closed-loop control?
No. The card provides the hardware interface; the control mode parameter must be changed to closed-loop vector manually, and a rotating autotune completed before the drive will use the feedback correctly.
Q: Can this card read an absolute encoder instead of incremental?
No. This is an incremental-only feedback card. For absolute encoder types (SSI or similar), a different feedback option card supporting that protocol is required.
Q: What happens if the encoder cable is disconnected while the drive is running in closed-loop mode?
Loss of feedback signal triggers a feedback fault, and the drive executes its configured fault response — typically a coast-to-stop or controlled fault stop, depending on parameter settings.
Q: Which option slot does this card use on the 755 drive?
The 755 has multiple option slots with specific assignments depending on frame size and other installed cards. Consult the drive's option card installation guide for the correct feedback slot for the specific frame in use.


