Netzer DS-130 Hollow Shaft Three Plate User Guide
- June 15, 2024
- Netzer
Table of Contents
- DS Encoders Introduction
- Technical Specifications
- Ordering Code
- Mechanical Drawings
- Mechanical Interface Control Drawing
- Storage and Handling
- ESD Protection
- Product Overview
- Electric Encoder Software Installation
- Mechanical Mounting
- Electrical Connection
- Signal Verification
- Calibration
- Operational Mode
- References
- Read User Manual Online (PDF format)
- Download This Manual (PDF format)
DS-130
PRODUCT GUIDE Absolute
Rotary Encoder
Hollow Shaft
Three-plate
DS Encoders Introduction
Designed to meet the requirements of the most demanding applications
The DS series of Electric Encoders™ are a line of encoders designed for harsh
environment applications.
These encoders are based on capacitive technology which have been developed
and improved for over 20 years by Netzer Precision Position Sensors.
The DS encoders are characterized by the following features that sets them
apart from other similar encoders:
- Low profile
- Hollow shaft (Stator / Rotor)
- No bearings or other contact elements
- High resolution and excellent precision
- Immunity to magnetic fields
- High tolerance to shock, moisture, EMI, RFI
- Very low weight
- Holistic signal generation and sensing
- Digital interfaces for absolute position
The holistic structure of the DS Electric Encoder™ makes it unique. Its output
reading is the averaged outcome of the entire circumference area of the
sensor. This inherent design characteristic provides the DS encoder with
outstanding precision and accuracy.
The absence of components such as ball bearings, flexible couplers, glass
discs, light sources & detectors, along with very low power consumption,
enables the DS encoders to deliver virtually failure-free performance.
Technical Specifications
General
Angular resolution | 19-21 bit |
---|---|
Nominal position accuracy | ±0.010° |
Nominal position extended accuracy (EA) | ±0.006° |
Maximum operational speed | 2,000 rpm |
Measurement range | Single turn absolute position |
Built In Test BIT | Optional |
Rotation direction | Adjustable CW/CCW* |
- Default same direction from bottom side of the encoder
Mechanical
Allowable mounting eccentricity | ±0.1 mm |
---|---|
Allowable axial mounting tolerance | ±0.1 mm |
Rotor inertia | 25,963 gr · mm2 |
Total weight | 84 gr |
Outer Ø / Inner Ø / Height | 130 / 90 / 10.5 mm |
Material (stator / rotor) | Ultem™ polymer |
Electrical
Supply voltage | 5V ± 5% |
---|---|
Current consumption | ~100 mA |
Interconnection | #30 shielded cable |
Communication | SSi, BiSS-C |
Output code | Binary |
Serial output | Differential RS-422 |
Clock frequency | 0.1- 5.0 MHz |
Position update rate | 35 kHz (Optional – up to 375 kHz) |
Environmental
EMC | IEC 6100-6-2, IEC 6100-6-4 |
---|---|
Operating temperature | -40°C to +85°C |
Storage temperature | -50°C to +100°C |
Relative humidity | 98% Non condensing |
Shock endurance / functional | 100 g for 11 ms |
Vibration functional | 20 g 10 – 2000 Hz (per MIL-STD-810G) |
Protection | IP 40 |
Ordering Code
Cable information
Netzer Cat No | CB 00014 |
---|---|
Cable type | 30 AWG twisted pair x 3 |
Wire type | 2 x 30 AWG 25/44 tinned copper Insulation: PFE Ø 0.15 OD: Ø 0.6 ± |
0.05 mm
Temp. Rating| -55°C to +150°C
Braided shield| Thinned copper braided 95% min. coverage
Jacket| 0.45 silicon rubber (NFA 11-A1)
Diameter| Ø 2.45 ± 0.16 mm
Pair# | Color |
---|---|
A1-A2 | Red / Black |
A3-A4 | Gray / Blue |
A5-A6 | Green / Yellow |
Mechanical Drawings
Unless otherwise specified
Dimensions are in: mm| Surface finish: N6
Linear tolerances
0.5-4.9: ±0.05 mm| 5-30: ±0.1 mm
31-120: ±0.15 mm| 121-400: ±0.2 mm
DS-130 Mid-Shaft installation
Unless otherwise specified
Dimensions are in: mm| Surface finish: N6
Linear tolerances
0.5-4.9: ±0.05 mm| 5-30: ±0.1 mm
31-120: ±0.15 mm| 121-400: ±0.2 mm
Mechanical Interface Control Drawing
DS-130 Shaft-End installation (step)
No | Part | Description | QT Y. |
---|---|---|---|
1 | DS-130 | Included | |
2 | MA-DS130-004 | Optional | Shaft-end installation kit |
spring | 1 | ||
3 | Screw DIN 912 M2X4 | 8 |
- Recommended height between stator and rotor mounting surfaces is 1.6 mm, despite the nominal dimension in the encoder is 1.5 mm.
The difference is because of possible inaccuracies in a mounting assembly, as a positive error could be filled by shims, while the negative error is impossible to solve rather than by machining.
WARNING
Do not use Loctite or other glues containing Cyanoacrylate.
We recommend to use 3M glue – Scotch-Weld™ Epoxy Adhesive EC-2216 B/A.
DS-130 Mid-Shaft installation (step)
No | Part | Description | QT Y. |
---|---|---|---|
1 | DS-130 | Included | |
2 | MA-DS130-003 | Optional | Shaft-end installation kit |
2
3| DS-130 Wave spring| 1
4| DS-130 Mid-shaft rotor spring shim| 1
- Recommended height between stator and rotor mounting surfaces is 1.6 mm (2.6 include C-ring thickness), despite the nominal dimension in the encoder is 1.5 mm.
The difference is because of possible inaccuracies in a mounting assembly, as the negative error could be filled by shims, while the positive error is impossible to solve rather than by machining.
WARNING
Do not use Loctite or other glues containing Cyanoacrylate.
We recommend to use 3M glue – Scotch-Weld™ Epoxy Adhesive EC-2216 B/A.
Storage and Handling
Storage temperature: -50°C to +100°C
Humidity: Up to 98% non-condensing
ESD Protection
As usual for electronic circuits, during product handling do not touch
electronic circuits, wires, connectors 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
8.1 Overview
The DS-130 absolute position Electric Encoder™ is a rotary position sensor
originally developed for harsh environment applications. Currently it performs
in a broad range of applications, including defense, homeland security,
medical robotics and industrial automation.
The Electric Encoder™ non-contact technology provides accurate position
measurement through the modulation of an electric field.
The DS-130 Electric Encoder™ is semi-modular, i.e., its rotor and stator are
separate, with the stator securely housing the rotor.
- Encoder stator
- Encoder rotor
- Encoder mounting ears
- Encoder cable
8.2 Unpacking – Standard order
The package of the standard DS-130 contains the encoder with 250 mm shielded
cable AWG30.
Optional accessories:
8.2 Unpacking – Standard order
The package of the standard DS-130 contains the encoder with 250 mm shielded
cable AWG30.
Optional accessories:
- DS-130-R-00, Rotor shims kit (x10 stainless steel shims, 50um each)
- MA-DS130-004, Shaft-end installation kit (Shaft-end spring x 1, Screw DIN 912 M2X4 x8)
- MA-DS130-003, Mid shaft installation kit (Wave spring x1, Retaining ring x 2)
- EAPK008 Kit, encoder mounting screws (3 screws M2x6)*
- 2 kits of EAPK008 are required to mount a single encoder (6 screws) 5. CNV-00003, RS-422 to USB converter (For encoder setup via NCP interface) 6. NanoMIC-KIT-01, RS-422 to USB converter. Encoder setup & operational modes via SSi /BiSS interface 7. DKIT-DS-130-SH-S0, Mounted SSi encoder on rotary jig, RS-422 to USB converter and cables 8. DKIT-DS-130-IH-S0, Mounted BiSS encoder on rotary jig, RS-422 to USB converter and cables
8.3 Installation flow chart
Electric Encoder Software Installation
The Electric Encoder Explorer (EEE) software:
- Verifies correct mounting for an adequate signal amplitude
- Calibration of offsets
- General set up and signal analysis
This section describes the steps associated with installing the EEE software application.
9.1 Minimum requirements
- Operating system: MS windows 7/ 10, (32 / 64 bit)
- Memory: 4MB minimum
- Communication ports: USB 2
- Windows .NET Framework, V4 minimum
9.2 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.
Mechanical Mounting
10.1 Encoder mounting The encoder rotor (2) is attached to
the host shaft by pressing it against a dedicated shoulder (b), while using
screw and a washer, or a circular spring and a washer, at the top of the rotor
shoulder to maintain downward pressure. Recommended force of 0.3 Nm with M2
screw.
The encoder stator (1) is centered by circumferential step (a) and is mounted
to the host stator (c) by using three M2 screws, recommended force of 0.3 Nm.
Stator / rotor relative position
The rotor is floating, therefore, for proper relative axial position of both
housing (1) and rotor (2), bottom shaft and host-stator shoulders (b and a)
should be coplanar with tolerance 1.6-0.10mm towards down for the shaft.
In
an optimal mounting, the signal amplitude values generated by the encoder,
would be in the middle of the range of the signal plot shown in the Encoder
Explorer software (see plot below). This may vary according to the encoder
type.
The DS-130 amplitudes compensation
If as part of the signal validation process (section 12.2) the signal
amplitudes are not optimal, it is possible to improve/correct the mounting, by
using 50 um shims below the rotor (available as DS-130-R-00 kit).
Each will increase the amplitude level by ~ 50mV.
Verify that the rotor mounting provides a good signal amplitude, by using the
“Signal analyzer” or ”Signal verification process”, of the Encoder Explorer
tool, as part of the procedure the described in section 12.
Electrical Connection
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:
11.1 Absolute position over SSi or BiSS-C
This is the power-up default mode SSi / BiSS interface wires color
code
Clock + | Grey | Clock |
---|---|---|
Clock – | Blue | |
Data – | Yellow | Data |
Data + | Green | |
GND | Black | Ground |
+5V | Red | Power supply |
SSi / BiSS output signal parameters
Output code | Binary |
---|---|
Serial output | Differential RS-422 |
Clock | Differential RS-422 |
Clock frequency | 0.1- 5.0 MHz |
Position update rate | 35 kHz (Optional – up to 375 kHz) |
11.2 Digital SSi Interface
Synchronous Serial Interface (SSi) is a point to point serial interface
standard between a master (e.g. controller) and a slave (e.g. sensor) for
digital data transmission.Built In Test option (BIT)
The BIT indicates critical abnormality in the encoder internal signals.
‘0’ – the internal signals are within the normal limits, ‘1’ – Error The Part
Number of the encoder indicates whether the encoder includes BIT. If no BIT is
indicated in the PN, there is no additional error bit.
| Description| Recommendations
---|---|---
n| Position resolution| 21-Dec
T| Clock period|
f= 1/T| Clock frequency| 0.1- 5.0 MHz
Tu| Bit update time| 90 nsec
Tp| Pause time| 26 – ∞ μsec
Tm| Monoflop time| 25 μsec
Tr| Time between 2 adjacent requests| Tr > n*T+26 μsec
fr=1/Tr| Data request frequency|
11.3 Digital BiSS-C Interface
BiSS-C Interface is unidirectional serial synchronous protocol for digital
data transmission where the Encoder acts as “slave” transmits data according
to “Master” clock. The BiSS protocol is designed in B mode and C mode
(continuous mode). The BiSS-C interface as the SSi is based on RS-422
standards.
Built In Test option (BIT)
The BIT indicates critical abnormality in the encoder internal signals.
‘1’ – the internal signals are within the normal limits, ‘0’ – Error The Part
Number of the encoder indicates whether the encoder includes BIT. If no BIT is
indicated in the PN, the error bit is always 1.
Bit allocation per encoder-resolution | Description | Default | Length | |
---|---|---|---|---|
17bit | 18bit | 19bit | 20bit | |
27 | 28 | 29 | 30 | Ack |
position, one clock cycle | 0 | 1/clock | ||
26 | 27 | 28 | 29 | Start |
25 | 26 | 27 | 28 | “0” |
8…24 | 8…25 | 8…26 | 8…27 | AP |
7 | 7 | 7 | 7 | Error |
6 | 6 | 6 | 6 | Warn. |
0…5 | 0…5 | 0…5 | 0…5 | CRC |
data is: x° + x1 + x°. It is transmitted MSB first and inverted.
The start bit and “0” bit are omitted from the CRC calculation.| | 6 bits
| | | | Timeout| Elapse between the sequential “start”request cycle’s| | 25 ps
11.4 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 | Gray | 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 |
Connect Netzer encoder to the converter, connect the converter to
the computer and run the Electric Encoder Explorer Software Tool
11.5 Electrical connection and grounding
Observe the following grounding consideration:
- The cable shield electrically floating (unconnected) by default.
- Make sure the chassis is grounded.
- It’s highly recommended to keep the motor PWM wires electrically shielded and/or kept away from the encoder.
Note: 4.75 to 5.25 VDC power supply required
Signal Verification
12.1 Starting the Encoder Explorer
Make sure to complete the following tasks successfully:
- Mechanical Mounting
- Electrical Connection to the encoder
- Encoder Explore Software Installation
Run the Encoder Explorer tool (EE)
Ensure proper communication with the encoder: (Setup mode by default).
The Encoder position-dial is colored blue when in Setup Mode, either through
the NanoMic or the BlueBox (a).
Note that the operational mode is not available through the BlueBox (b).
The Signal amplitude bar indicates whether the signal is within the acceptable
tolerance (c) . Note that prior to performing the Signal Verification process
the bar could indicate an out of tolerance signal (d).
Encoder data is displayed in the encoder data area (CAT No., Serial No.) (e).
The position dial display responds to shaft rotation (f ).It
is important to perform the Signal Verification process prior to the
calibration of the encoder to ensure optimal performance.
12.2 Signal verification process
The Signal Verification process ensures that the encoder is mounted correctly
and provides good signal amplitudes. This is performed by collecting raw data
of the fine and coarse channels during rotation.
- Select
on the main screen (a). - Select
to initiate the process (b). - Rotate the shaft in order to collect the fine and coarse channels data (c).
If the process is successful, the status “Signal verification successful”
would appear (d).
The ‘amplitude circle’ would be centered between the two green circles,
preferably in the middle of the tolerance (e). Note however, that
mounting the encoder towards the extreme mechanical tolerances might cause the
amplitude circle to be offset from the exact middle of the nominal position.
If the signal is out of tolerance the Error notification “Amplitude is
lower/higher than the min/max limit of XXX” would appear (g).
In Addition, the status “Signal verification failed – perform calibration
amplitude” would appear at the top (h).
- Stop the process and re-mount the encoder, making sure that the mechanical installation tolerances are not exceeded, removing or adding shims as required.
- Repeat the Signal Verification process after the remount.
Once the signal verification process is successfully completed, proceed to the encoder calibration phase, Section 13
Calibration
It is important that upon every installation of the encoder, the Signal
Verification process is completed prior to attempting calibration of the
encoder.
For encoders with FW 4 version 4.1.3 or higher, it is possible to select
either a fully automated calibration process, or a manual phase-by-phase
calibration process.
13.1 Auto-calibration
Auto Calibration is supported by encoders with FW 4 version 4.1.3 or higher.
For these encoders an additional “Auto-calibration” button is
displayed. 13.1.1 Auto-calibration process
The Auto-calibration process consists of three stages:
-
Jitter test – evaluates the electric noise for the Fine, Medium, and Coarse encoder channels. During the jitter test, the shaft must be stationary.
Attention! The Pass/Fail criteria of the Jitter test is according to very strict factory criteria and failing it would abort the Auto Calibration process.
However, the manual Jitter test as part of the Manual Calibration process in section 13.4, would enable the user to decide whether the jitter is acceptable to its needs. -
Offset calibration – performs the offset calibration, the shaft must rotate continuously.
-
Absolute Position (AP) calibration – performs Coarse Amplitude Alignment (CAA) and Medium Amplitude Alignment (MAA) are calculated.
During Auto-Calibration process the encoder’s Zero-Position remain in the
factory default zero position for new encoders. It is possible to set the Zero
Point through the top menu bar, by selecting “Calibration” tab, and clicking
“Set UZP” as defined in section 13.3.
13.1.2 Performing Auto-calibration
Press the
The main auto-calibration window opens.
- Select the appropriate measurement range applicable to your application (a).
- Make sure to keep the shaft still and press the
The Noise test would be performed and upon successful completion the “Noise
test” label will be marked with a green check mark.
The Offset calibration would automatically start upon completion of the Noise
test. This calibration requires that the shaft be rotated continuously.
The AP calibration would automatically start upon completion of the Accuracy
Calibration. Continue rotating the shaft in this phase until the AP
calibration is completed, and the encoder is reset.
Once the reset is over, the Auto-calibration process is successfully
finished.The user can review the calibration results by
clicking the
13.1.3 Auto-calibration failures
If a test fails (for example the Noise test) – the result will be marked with
in red X.If the calibration process failed, corrective
recommendations will be displayed, corresponding to the element which had
failed the test.It is possible to review detailed information
regarding the failure, by clicking the
The Manual calibration process consists of the following stages:
- Offset calibration – performs the offset calibration, the shaft must rotate continuously.
- CAA / MAA Calibration – performs Coarse Amplitude Alignment (CAA) and Medium Amplitude Alignment (MAA) are calculated
- Zero Position Set – Used to determine a Zero Position other than the factory default.
- Jitter Test – Used to determine the amount of jitter and allow the user to decide if acceptable.
- Select
on the main screen (a).
13.2.1 Offset calibration
In this process, the DC offset of the sine and cosine signals are compensated
over the operational sector (offset calibration).
-
Click
(b). -
Rotate the shaft continuously during data collection, covering the whole working sector of the application from end to end. The progress bar (c) indicates the progress of the data collection.
Rotation speed is not a parameter during data collection. By default, the procedure collects 500 points. The collected data for the fine / coarse channels, should be a clear “thin” circle which appears in the center of the plots (d) (e) with a possible slight offset. -
When offset calibration is completed, click on <Continue to CAA/MAA Calibration> button (f ).
13.2.2 Calibration of Coarse Amplitude Alignment (CAA) & Medium Amplitude
Alignment (MAA)
The following calibration aligns the coarse channel, and medium channel in
certain encoders, with the fine channel by collecting data from each point in
both channels. This is performed to make sure that every time the encoder is
turned on, it would provide an accurate absolute position.
-
Select the relevant option from the Measurement Range options (a):
Full mechanical rotation – shaft movement is over a full 360 degrees rotation – (that is the recommended calibration).
Limited section – shaft has a limited rotation angle which is less than 360 degrees. In this mode you need to input the rotation range by degrees.
Free sampling mode – sets the number of calibration points in accordance with the total number of points in the text box. The system displays the recommended number of points by default. The minimum points over the working sector is nine.
Note that the Total number of points would change to the optimal default according to the selected measurement range above. -
Click the
button (b).The Calibration process control (c) indicates the current position, and the next target position to which the shaft should be rotated. -
Rotate the shaft to the next position, stop and click the
button to sample the position (d).
The shaft should be at STAND STILL when clicking the button.The Shaft movement status (e) indicates the shaft movement status. -
Complete the sampling process using the following routine: positioning the shaft –> stand still –> clicking
(d) to sample the position. -
When the process is completed click the
button (f ).
13.3 Setting the zero-position of the encoder
- Select one of the options for setting the zero point and click
.
It is possible to set either current position or rotate the shaft to any other position to be set as the zero point.![Netzer DS 130 Hollow Shaft Three Plate
- Calibration 11](https://manuals.plus/wp-content/uploads/2023/12/Netzer- DS-130-Hollow-Shaft-Three-Plate-Calibration-11.jpg)It is also possible to set the Zero Point through the top menu bar, by selecting “Calibration” tab, and clicking “Set UZP”.
13.4 Jitter test
The jitter test is used evaluate the level of electric noise.
Common jitter should be up +/- 3 counts; higher jitter may indicate system
noise and would require better grounding or shielding of the electric noise
source.
- Select “Calibration” tab, and click “Jitter Test”
- Select the Jitter test mode (a).
- Set the Timing and Sampling parameters (b).
- Click
button (c) and check if the results (d) are within acceptable tolerances for the intended application.Another indication of excessive jitter/noise when the blue dots in signal amplitude circle are not evenly distributed on a thin circle as appears below.
Operational Mode
14.1 SSi / BiSS
Operational Mode indication of the SSi / BiSS encoder interface is available
by using the NanoMIC to connect with the encoder. When in Operational Mode the
color of the position dial is orange.
For more information read about NanoMIC on Netzer
website
The operational mode is using SSi / BiSS interface with 1MHz clock rate.
The encoder position-dial is colored orange when in Operational Mode. The bar
below the dial, is the corresponding binary word output for the current shaft
position (a).
Corporate Headquarters
Netzer Precision Position Sensors A.C.S. Ltd.
Misgav Industrial Park, P.O. Box 1359
D.N. Misgav, 2017400 Israel
Tel: +972 4 999 0420
www.netzerprecision.com
DS-130-PG-V01
Copyright © 2023 Netzer Precision Position Sensors A.C.S. Ltd.
All rights reserved.