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Overview
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Refer to https://wiki.trenz-electronic.de/display/PD/EDPS+User+Manual for online version of this manual and additional technical documentation of the product.
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The Electric Drive Power Stage (EDPS) Board, a Trenz Electronic TEC0053, is to be used together with the Controller Board for the evaluation of Motor Control.
Key Features
- Evaluation of Motor evaluation with an FPGA controller board, recommended with the Digilent Arty Z7 board
- Quick evaluation with reference motor board
- Control with a suitable Controller Board
- Power option up to 48V and 30A main supply current
Block Diagram
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- MOSFET drivers for power stage supporting 3-phase BLDC Motorsmotors
- Current measurement for on 2-phases (3 phase measurement is optional)
- Temperature sensor on board On-board temperature sensor and 1-Wire bus external optionwire bus connector for additional sensors
- Encoder input capable of receiving both single ended and differential signals
Scope of Delivery
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Figure 1: Top view of the EDPS Board PCB.
EDPS Block Diagram
Figure 2: Block diagram of the EDPS Board.
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General Safety Instructions
- This product is only allowed to be used by an should be operated by qualified electrical specialist only.
- This product is not allowed to be used Never leave an operating board unattended.
- There is a possible risk of burns due to hot surfaces while running the Board. This e.g. might be caused by an overcurrent at the motor outputswhile operating an EDPS Board because of the high currents in the power stage heating the board surfaces and the board components.
- All externally connected power sources must be SELV protected (Separated or safety extra-low voltageSafety Extra Low Voltage).
- For set up the wiring switch off or disconnect All wiring and installation should be performed only with all external power suppliessources switched OFF or disconnected.
- During operations it is not allowed to change the No wiring or mechanical setup changes should be performed while the board is operating.
- This The product is only allowed to be used in a rated for dry indoor environment use only.
- The product is only allowed intended to be used only in horizontal position on a non-conducting and non-inflammable surface.
- The mechanical setup must ensure that the whole test setup can not be dropped to the floor or moved accidentally.
- board and all of its parts are firmly fixed in place to prevent accidental or unwanted movement(e.g. sliding, falling. etc.).
Signals, Interfaces and Pins
Control Board
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Connectors
Figure 3: PCB connectors J8 and J9.
Signal names | Connector J8 | Connector J9 | Connector J17 |
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Digital Supply to EDPS | Pin 6, 12: +3.3V | Pin 6, 12: +3.3V Pin 5, 11: GND | Pin 5, 6, 21, 22: +3.3V Pin 1, 2, 25, 26: GND |
Motor Driver PWM Signals to EDPS High and Low Side control signals
| Pin 1: G1H - Ch.A HighSide | Pin 11: G1H - Ch.A HighSide | |
ADC Clock Signal to EDPS | Pin 1: SCLK | Pin 23: SCLK | |
Encoder Digital Signals from EDPS | Pin 8: ENC_A | Pin 20: ENC_A | |
Motor Current ADC "raw" Signals from EDPS (usable with FPGA IP) | Pin 2: SDI1 - Current Ch.A | Pin 19: SDI1 - Current Ch.A | |
Supply Voltage ADC "raw" Signal from EDPS (usable with FPGA IP) | Pin 7: SDIV - from DC_LINK | Pin 24: SDIV - from DC_LINK | |
1-Wire bus for temperature measurement | Pin 10: EXT1 - 1-Wire Bus 1 Pin 4: EXT2 - 1-Wire Bus 2 | Pin 4: EXT1 - 1-Wire Bus 1 | |
Not Pins not connected pins | noneNonenone | None | Pin 13, 14 |
Table 1: Description of the PCB connectors J8 and J9.
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Motor and Power Connections
There are two options available for the motor and power concept:
Detail | Option 1: Reference Motor Board with DC +12V Supply | Option 2: Customer Motor at individual DC +5..48V | Comments |
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Motor Supply | From DC +12V Input J7 via |
fuse F3 via Motor Reference Board to J5 of |
Drive board | From customer DC |
power supply to J6 via F1 on |
Drive Boad | |
Motor Connection | Motor wires connected to cage clamps on |
Motor Reference Board J5 (A), J4 (B), J3 (C) | Motor wires connected to bolt screw terminals on |
Eval
Drive Board J2 (A), J3 (B), J4 (C) | |
Encoder Connection Single Ended | From encoder pins via |
6-pin Pmod to Drive Board J10 |
(only for single ended enconders optimized for
Reference Motor Board)
: J10 |
single ended: Pin 1: GND | From motor to |
Drive Board to J11 (single |
/differential |
): |
J11 single ended |
Pin 1
: |
Pin 2: +5V Supply |
Pin 4: not connected
Pin 5: unused (100R to ENC A input)
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Pin
8: ENC B input |
10: |
ENC I input |
Pin 10: ENC I input
Jumper Settings for encoder signals.
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Encoder Connection Differential | J11 differential with 100R terminated: Pin |
Pin
2: +5V Supply Pin 3: GND Pin |
Pin
5: ENC A negativ Pin 6: ENC A positiv Pin 7: ENC B negativ Pin 8: ENC B positiv Pin 9: ENC I negativ Pin 10: ENC I positiv |
Jumper Settings for encoder signals.
Single Ended: Differential:
Internal
Temperature Sensor
Table 2: Description of the Motor and Power connector.
On-Board Temperature Sensor
There is a on-board 1-Wire temperature sensor DS18S20Z+ from Maxim Onboard is a Maxim 1-Wire Temperature sensor DS18S20Z+. This sensor is located in the middle of the PCB for optimal readings.
Addional 1-Wire temperature wire sensor(s) can be connected to the connector J16:
Figure 4: 1-wire sensors connector J16.
- Pin 1(DQ), 3 (GND),5 (+3.3V) at the same 1-wire bus as the onboard one
- Pin 2(DQ), 4 (GND),6 (+3.3V) at a separate 1-wire bus
Power and Power-On Sequence
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DC 12V
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power supply for the Motor and Driver board
The power source must be SELV (Separated or safety extra-low voltage) protected.
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The internal +5V digital supply is generated from this +12V supply.
DC 5...48V
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power supply for the Motor only
SAFETY INSTRUCTIONS:
Externally External power supply for the motor must be SELV (Separated or safety extra-low voltage) protected.
This option is
- only allowed to be used for electrical specialist for the used electrical voltage and power conditions
- only allowed to be used under electrical laboratory conditions
- only allowed to be used in horizontal position on a non-conducting and non-inflammable surface
- only allowed to be used with a wiring, which fulfills the current rating for the maximum possible currents.
- only allowed to be used with a suitable current limiting circuit The such that the maximum continuous current must does not exceed 30A as follows:
- .
- The delivered fuse "Littelfuse Tpye Type 142.5631.5302" must be used as current limiter between connector connectors J5 and J6.
- To limit the current for smaller motor loads an ADDITIONALLY ADDITIONALL appropriate current limiter can be used e.g. a current limited power source or a fuse integrated in the wiring.
- only allowed to be used with appropriate connectors at the M5 screw connectors, which means M5 cable lugs must be used and fastened according to technical standards.
only allowed to be used, if the
"Eval Boadhigh current
signals"parts conducting up to 30A nominal, are covered by isolating, mechanically stable, non-inflammable (UL V-1 or better) material
. The
"Eval Boadhigh current
signals" are theparts are shown on the following picture:
Figure 5: The high current parts on the EDPS Board, the motor outputs A, B, C
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, fuse F1 Connectors J5
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, J6 and further internal connections
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, are marked white.
Warning |
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It |
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is mandatory to use the delivered |
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isolating cover |
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of the PCB made of plexiglass as a minimum protection. Use holes H1, H9, H3 |
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and H4 with the delivered 10mm |
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spacers when mounting. |
Figure 6: Top view of the EDPS Board with isolating transparent plexiglass cover attached.
Figure 7: Side view of the EDPS Board with isolating plexiglass cover.
The cable lugs used should
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be isolated in the
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outer border area of the
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EDPS Board.
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Make sure that the
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Isolating PCB Cover
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is overlapping the conducting material by a minimum of 20 mm.
Initial
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Operation
Prepare the EDPS board as follows:
- In the case of low-powered motors and/or low-powered power supply it is recommended to use additional current limiter circuit or additional fuse.
To use a separate power supply for the motor supply perform the following steps:
- Disconnect the reference motor board TEC0060 by unmounting its screws and the encoder cable from J10
- Mount the delivered 30A fuse to the connectors J5 and J6 with the delivered M5 screws
- For lower supply current requirements, caused by the power rating of the used motor, a fuse with a lower and suitable current rating integrated in the supply wiring is recommended.
- Connect with cable lugs the +DC 5..48V to J6 and the corresponding GND to J1.
- The cable length is limited to 3m.
- .
- Use at most 3m long cable with lugs to connect the positive terminal of the motor power supply to J6 (DC +5..48V) and the negative terminal to J1 (0V).
- Use at most 3m long cable to connect Connect the three motor phases to J2 (A), J3 (B) and J4 (C).The cable length is limited to 3m
- Connect 12V power supply to J7 (12V). In the case motor power supply voltage is 12V as well, one power supply can be used.
- Optional: connect Connect the encoder to J10 or J11 and set jumper field J13 according to the signal specification : either to differential or to single ended . See section TODO for details.
Power Consumption
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Test Condition:
- 25 °C ambient
- Reference motor running with no load
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- configuration.
Power-On Sequence
Any power sequence of the three supply sources is allowed:
- +3V3 Supply from the FPGA Control Board, generated by FPGA Control Board supply
- +12V and
- optional Optional +5..48V Motor Supply
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Adapter Board TEC0060
For easy connection of the reference Reference Motor and Encoder to the Driver board EDPS Board a special Motor Adapter Board TEC0060 is included in the EDDP Kit.
Figure 8: Adapter Board TEC0060 with the Reference Motor and Plastic DEMO load attached.
Reference Motor
The reference motor is Reference Motor and Encoder are manufactured by Anaheim Automation. The order code for the motor with the encoder already mounted is BLWR111D-24V-10000-1000SI. Please note that the encoder is not available separately. The nominal motor voltage is DC 24V, however, only 12V is supplied by the Reference Motor Board, which results in reduced performance.
The datasheet for the motor can be found at
http://www.anaheimautomation.com/manuals/brushless/L010234%20-%20BLWR11%20Series%20Product%20Sheet.pdf
The datasheet for the encoder can be found at
http://www.anaheimautomation.com/manuals/accessories/L010390%20-%20Single%20Ended%20Encoder%20with%20Index%20Channel.pdf
WIP section
Refer to the BLWR11 - Brushless DC Motors and Single-Ended Encoder with Index Channel for more information.
Technical Specifications
Absolute Maximum Ratings
Parameter | Min | Max | Units | Notes |
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DC +12V supply | 0 |
15 | V |
DC +5..48V supply | 0 |
50V | V |
DC +3V3 supply | -0.5 | 6 | V |
PWM Input | -0.5 | 6 |
V |
ADC Digital Input | -0.5 | 3.8 | V |
Assuming digital power supply voltage is at 3.3V |
Encoder Input | -10 | 15 | V |
Table 3: Absolute maximum ratings.
Recommended Operating Conditions
Parameter | Min | Max | Units |
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Notes
DC +12V supply | 11.5 | 12.5 | V |
DC +5..48V supply | 5 | 48 | V |
DC +3V3 supply | 3.0 | 3.6 | V |
PWM Input | 0 | DC +3V3 supply | V |
ADC Digital Input | 0 | DC +3V3 supply | V |
Encoder Input | -7 | 12 | V |
Table 4: Recommended oprating conditions.
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Electrical characteristics
DC +3V3 supply = 3.3V
Parameter | Min | Max | Units | Notes |
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PWM Input Logic High Level | 2.2 | V |
PWM Input Logic Low Level | 0.8 | V |
ADC Digital Input Logic High Level | 2.7 | V |
ADC Digital Input Logic Low Level | 0.6 | V |
ADC Digital Output Logic High Level | 3.2 | 3.3 | V | Io=-200μA |
ADC Digital Output Logic Low Level | 0 | 0.4 | V | Io=+200μA |
Encoder Input Logic High Level (Differential) | -0.2 | V |
Encoder Input Logic Low Level (Differential) | -0.01 | V |
Encoder Input Logic High Level (Single |
ended) | 2 | V |
Encoder Input Logic Low Level (Single |
ended) | 0.6 | V |
Table 5: Electrical characteristics.
Physical Dimensions
Board size: 100 mm × 166 mm. Please download the assembly diagram for the exact numbers.
PCB thickness: 1.75 mm +/-10%
Highest part on PCB: approximately 17 mm. Please download the step model for the exact numbers.
All dimensions are shown in mm. Additional sketches, drawings and schematics can be found TODO: here.millimeters.
Figure 9: Physical Dimensions of the EDPS Board.
Operating Temperature Ranges
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Weight - TODO
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0°C - 70°C, cooling might be required depending on environment and airflow.
References
All resource links for other relevant documents and websites are available from Trenz EDDP Web Hub:
Revision History
Hardware Revision History
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Date | Revision | Notes | PCN Link | Documentation Link |
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2016-03-27 | 02 | TEC0053-02 | ||
2017-08-14 | 04 | Initial public revision |
Table 6: Hardware revision history.
Hardware revision number is printed on the PCB board in the down bottom right corner.
Document Change History
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Date | Revision | Authors | Description | ||||||||
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| Jan Kumann | General formatting changes and small corrections. | |||||||||
2017-0308-3014 |
| Andreas Heidemann | Initial Versionv.10 | Antti Lukats, Andrei Errapart | Initial version. |
Table 7: Document change history.
Include Page EDPS Disclaimers EDPS Disclaimers