Netzer VLH-35 Absolute Position Electric Encoder User Manual

June 9, 2024
Netzer

Netzer VLH-35 Absolute Position Electric Encoder User Manual
Netzer VLH-35 Absolute Position Electric Encoder

Preface

  1. Version 1.0: June 2022
  2. Applicable documents
    • VLH-35 Electric Encoder data sheet

ESD protection

As usual for electronic circuits, during product handling do not touch electronic circuits, wires, connecters or sensors without suitable ESD protection. The integrator / operator shall use ESD equipment to avoid the risk of circuit damage.

ATTENTION

OBSERVE PRECAUTIONS FOR HANDLING ELECTROSTATIC SENSITIVE DEVICES

Product overview

The VLH-35 absolute position Electric Encoder™ is a revolutionary position sensor originally developed for industrial environment applications. Currently it performs in a broad range of applications, including highend robotics, survey & mapping systems medical machines other industrial automation applications. The Electric Encoder™ non-contact technology relies on an interaction between the measured displacement and a space/time modulated electric field.

The VLH-35 Electric Encoder™ is semimodular, i.e., its rotor and stator are separate.

  1. Encoder stator
  2. Encoder rotor

Overview

Installation flow chart

Installation flow chart

Encoder mounting

Encoder mounting

Typical encoder installation includes:

  • Encoder stator mounting M1.6 screws (3 units) and rotor mounting M1.6 conical head screws (3 units).

Encoder stator / Rotor relative position
For proper performance the air gap should be 0.6 mm +/- 0.15 mm

The optimal recommended amplitude values are middle of the range according to thoseshown in the Encoder Explorer software and vary according to the encoder type.

Middle rang
0.6 mm +/- 0.15mm

Verify proper rotor mounting with the Encoder Explorer tools “Signal analyzer” or “Mechanical installation verification.
Signal analyzer

Note : for more information please read paragraph 6

Unpacking

Standard order
The package of the standard VLH-35 contains the encoder Stator & Rotor.

Optional accessories:

  1. CB-00165 – 250 mm

  2. CNV-00003, RS-422 to USB converter (with USB internal 5V power supply path).

  3. NanoMIC-KIT-01, RS-422 to USB converter. Setup & Operational modes via SSi /BiSS interface.
    Interconection
    Connector DF52-2832PF1571-28A9-300
    Interconection

  4. DKIT-VLH-35-SG-CH, Mounted SSi encoder on rotary jig, RS-422 to USB converter and cables.

  5. DKIT-VLH-35-IG-CH, Mounted BiSS encoder on rotary jig, RS-422 to USB converter and cables.

Electrical interconnection

This chapter reviews the steps required to electrically connect the encoder with digital interface (SSi or BiSS-C).

Connecting the encoder
The encoder has two operational modes:
Absolute position over SSi or BiSS-C: This is the power-up default mode

Electrical interconnection

SSi / BiSS interface wires color code

Description Color Function Pin No.
Clock + White with Blue line Clock 8
Clock – Blue with Black line 7
Data – Yellow with Red line Data 6
Data + Pink with Black line 5
GND Sky-blue with Black line Ground 4
+5V Red with Blue line Power supply 3

Setup mode over NCP (Netzer Communication Protocol)
This service mode provides access via USB to a PC running Netzer Encoder Explorer application (on MS Windows 7/10). Communication is via Netzer Communication Protocol (NCP) over RS-422 using the same set of wires. Use the following pin assignment to connect the encoder to a 9-pin D-type connector to the RS-422/USB converter CNV-0003 or the NanoMIC.

Electric encoder interface D Type 9 pin Female

Description Color Function Pin No
SSi Clock / NCP RX Grey Clock / RX + 2
Blue Clock / RX – 1
SSi Data / NCP TX Yellow Data / TX – 4
Green Data / TX + 3
Ground Black GND 5
Power supply Red +5V 8

Electrical connection and grounding
The encoder does NOT come with specified cable and connector, however, do observegrounding consideration:

  1. The cable shield does not connect to the power supply return line.
  2. Ground the host shaft to avoid interference from the host system, which could result in encoder internal noise.

Note : 4.75 to 5.25 VDC power supply required

Connection

Connect Netzer encoder to the converter, connect the converter to the computer and run the Electric Encoder Explorer Software Tool

Software installation

The Electric Encoder Explorer (EEE) software:

  • Verifies Mechanical Mounting Correctness
  • Offsets Calibration
  • Sets up general and signal analysis
    This chapter reviews the steps associated with installing the EEE software application.

Minimum requirements

  • Operating system: MS windows 7/ 10, (32 / 64 bit)
  • Memory: 4MB minimum
  • Communication ports: USB 2
  • Windows .NET Framework, V4 minimum

Installing the software

  • Run the Electric Encoder™ Explorer file found on Netzer website: Encoder Explorer Software Tools
  • After the installation you will see Electric Encoder Explorer software icon on the computer desktop.
  • Click on the Electric Encoder Explorer software icon to start.

Mounting verification

Starting the Encoder Explorer
Make sure to complete the following tasks successfully:

  • Mechanical Mounting
  • Electrical Connection
  • Connecting Encoder for Calibration
  • Encoder Explore Software Installation

Run the Electric Encoder Explorer tool (EEE)
Ensure proper communication with the encoder: (Setup mode by defoult).
(a) The status bar indicates successful communication.
(b) Encoder data displays in the encoder data area. (CAT No., Serial No.)
(c) The position dial display responds to shaft rotation.

Runing

Perform mounting verification & rotation direction selection before calibration to ensure optimal performance. It is also reccomended to observe the instaletion at the [Tools – Signal Analizer] window.

Mechanical installation verification
The Mechanical Installation Verification provides a procedure that will ensure proper mechanical mounting by collecting raw data of the fine and coarse channels during rotation.
(d) Select [Mechanical Mounting Verification] on the main screen.

Selected

(e) Select [Start] to initiate the data collection.
(f) Rotate the shaft in order to collect the fine and coarse channels data.

Selected

(g) At the end of a successful verification, the SW will show “Correct Mechanical Installation.”

Verification

(h) If the SW indicates “Incorrect Mechanical Installation,” correct the mechanical position of the rotor, as presented in paragraph 3.3 – “Rotor Relative Position.”

Incorrect Mechanical Installation

Calibration

Full manual calibration
After successfully completing the Mounting Verification procedure: (a) Select [Calibration] on the main screen.

Calibration

(b) Start the data acquisition while rotating the shaft. The progress bar (c) indicates the collection progress. Rotate the axis consistently during data collection-covering the working sector of the application end to end-by default the procedure collects 500 points over 75 seconds. Rotation speed is not a parameter during data collection. Data collection indication shows for the fine/coarse channels, a clear “thin” circle appears in the center (d) (e) with some offset.

Data acquisition

Offset compensated fine / Corse channel
Signal analyzer
Signal analyzer

CAA calibration
The following calibration aligns the coarse/ fine channel by collecting data from each point of both channels.

Select [Continue to CAA Calibration]

In the CAA angle calibration window, select the relevant option button from the measurement range options (a):

  • Full mechanical rotation – shaft movement is over 10deg – recommended.
  • Limited section – define operation of the shaft in a limited angle defined by degrees in case of <10deg
  • Free sampling modes – define the number of calibration points in the total number of points in the text box. The system displays the recommended number of points by default. Collect a minimum of nine points over the working sector.
  • Click the [Start Calibration] button (b)
  • The status (c) indicates the next required operation; the shaft movement status; the current position, and the next target position to which the encoder should be rotated.
  • Rotate the shaft/encoder to the next position and click the [Continue] button (c) – the shaft should be in STAND STILL during the data collection. Follow the indication/ interactions during the cyclic process for positioning the shaft –> stand still –> reading calculation.
  • Repeat the above step for all defined points. Finish (d).
  • Click the [Save and Continue] button (e).

The last step saves the offsets CAA parameters, completing the calibration process.

EA offset celibration

Setting the encoder zero point
The zero position can be defined anywhere in the working sector. Rotate the shaft to the desired zero mechanical position. Go into “Calibration” button at the top menu bar, press “Set UZP”. Select “Set Current Position” as zero by using the relevant option, and click [Finish].

Zero position
Zero position

Jitter test
Perform a jitter test to evaluate the quality of the installation; the jitter test presents the reading statistics of absolute position readings (counts) over time. Common jitter should be up +/- 3 counts; higher jitter may indicate system noise.

Jitter test

In case the reading data (blue dots) are not evenly distributed on a thin circle, you may experience “noise” in your installation (check shaft/stator grounding).

Signal analyzer
Eror

Operational Mode

SSi / BiSS
Operational mode indication of the SSi / BiSS Encoder interface available by using the NanoMIC.

For more information read about NanoMIC on Netzer website
The operational mode presents the “real” SSi / BiSS interface with 1MHz clock rate.

Protocol SSi
Protocol SSi

Protocol BiSS

Protocol BiSS

Mechanical drawings

Mechanical drawings
Mechanical drawings
Mechanical drawings

Note: While using an encoder rotor adaptor (which isn’t part of the motor shaft), the adaptor should be made from a nonmetal material.

0.5-4.9: ±0.05 mm 5-30: ±0.1 mm
31-120: ±0.15 mm 121-400: ±0.2 mm

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