VME 602X – Series Service Manual - Stanford University
Transcript of VME 602X – Series Service Manual - Stanford University
UEP 6000 Service Manual 10/16/06
VME 602X – Series
Service Manual
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UEP 6000 Service Manual 10/16/06
General Remarks
The only purpose of this manual is a description of the product. It must not be interpreted a declaration of conformity for this product including the product and software.
W-Ie-Ne-R (WIENER Plein & Baus Corp. and Plein & Baus GmbH) revises this product and manual without notice. Differences of the description in manual and product are possible.
W-Ie-Ne-R excludes completely any liability for loss of profits, loss of business, loss of use or data, interrupt of business, or for indirect, special incidental, or consequential damages of any kind, even if W-Ie-Ne-R has been advises of the possibility of such damages arising from any defect or error in this manual or product.
Any use of the product which may influence health of human beings requires the express written permission of W-Ie-Ne-R.
Products mentioned in this manual are mentioned for identification purposes only. Product names appearing in this manual may or may not be registered trademarks or copyrights of their respective companies.
No part of this product, including the product and the software may be reproduced, transmitted, transcribed, stored in a retrieval system, or translated into any language in any form by any means with the express written permission of W-Ie-Ne-R. W-Ie-Ne-R declines all responsibility for any damage of the VME crate or part of it and / or crate or of any equipment used inside or outside of the crate caused by improper use of it or operation / action of unauthorized not-qualified personal. This Service manual is only for qualified and authorized persons.
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UEP 6000 Power Supply Configuration and Test Software The MUH6000 program is a software for Windows based PC’s to test and set-up the configuration and calibration of WIENER power supplies of the UEP 6000 series. The communication is via RS232 using the WIENER UEP 6000 adapter cable. WIENER Plein & Baus Corp. / GmbH is not responsible for any damage of the power supply and / or crate or of any module inside the crate caused by changing the factory prepared configuration and calibration of the power supply. The test and diagnostic box and MUH 6000 software has to be used by authorized and qualified personnel only! To protect the UEP 6000 power supply for unauthorized access there is a hardware write protection. This write protection prevents unauthorized users from changing the nominal voltages, calibration values, and current limits. To override this protection you most have the Flash6.exe program.
!!!!! DANGER - HIGH VOLTAGE !!!!!
For authorized, qualified service personnel only This power supply uses high voltage up to 400V inside. Unauthorized persons are not allowed to open the UEP 6000 power supply or to connect them to AC mains or use them without completely closed chassis. Do not open while connected to AC mains, unplug first from the wall outlet. After opening the power supply discharge first all capacitors of primary side (AC input module and 3-pin primary distribution cables/connectors) as well as of the MUH AUX power supply with a load resistor. In case of questions please contact: W-IE-NE-R Plein & Baus Ltd., Dr. A. Ruben 300 East Auburn Ave. Springfield, Ohio 45505 Phone : (937) 324 2420 FAX : (937) 324 2425 E-mail: [email protected] URL : http://www.wiener-d.com
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UEP 6000 Service Manual 10/16/06
1) MUH 6000 installation and start
Please copy the RS232.DLL as well as the WIENER.INI configuration file to the Windows directory of your computer. Before starting the program make sure that the power supply is not connected to the AC-line. Connect the UEP 6000 power supply to the serial port of the PC via the WIENER adapter cable. DO NOT CHANGE THIS CONNECTION WHILE THE POWER SUPPLY IS CONNECTED TO AC MAINS!!!
Change the COM setting to fit your setup the WIENER.INI file by changing COM2 to the correct COM port of the used serial port.
Connect the power supply to the AC mains line.
During program start the software automatically detects and connects to the power supply if the RS232 connection is available through the selected COM port. The main window displays the power supply setting and status as shown in the following example. In case of any communication problem (wrong COM port, cable connection not ok, …) the „RS232 connection is interrupted” error message is shown. The main window shows further the power supply ID (serial number or part number).
The UEP 6000 power supply can be switched on or off by mouse clicking on the POWER ON / POWER OFF line or by selecting the menu item. After switching on all power supply channels should show an „OK“ status.
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2) Power supply operation and configuration file
Please save the present configuration of the connected power supply as a file to hard or floppy disk before changing any item. It is recommended to keep all configuration files to allow an easy restore of the configuration
data at a later time.
3) Power supply set-up and calibration
To access any (available) parameter point the cursor on it and click with the left mouse button.
If you do not see the parameters mentioned below, click on the “Configuration” menu. This will bring up a window that allows you to choose which parameters are shown.
WIENER Plein & Baus Corp. / GmbH is not responsible for any damage of the power supply, VME crate or of any module inside the crate caused by changing the factory prepared configuration and calibration of the power supply. To protect the UEP 602X power supply for unauthorized access there is software write protection. All parameters that are gray are write protected.
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To enable "WRITE „ you must use the WIENER flash6.exe program. This is available only to authorized personnel. Please contact WIENER for more information.
Software Parameter Descriptions: CHANNEL Module definition define channel name set voltage and current range setting (digits) Example: STBY: 31V / Ampere XXXX. / Volt XX.
Note: Wrong range settings can result in a wrong current and voltage display on the UEL 6020 display even in case of correct output values.
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Voltage Calibration Voltage Calibration
With the UEP6000.EXE software, the lines "Calibration (Kovp)", "Calibration (Ku)" and "Calibration (Kf)" are available. This values describe the module ovp voltage divider, the module sense voltage divider, and the relation between the module coarse and fine DAC. Typical values for different modules:
To find the correct calibration values for a specific module, click in the UEP6000.EXE to the Ku value. Then the following window is displayed:
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Set the Ku and Kf values to the table values of the module that is used, click OK, and click to the Ku value again. Then click on the CALIBRATE button. An automatic calibration is started. Now enter the real output voltage (measured with a voltmeter) into the "measured Voltage" field. Hit the ENTER Key or click on the CALIBRATE button again. Ready. Now you have the calibrated values for Ku and Kf. By comparing the Ku value with the table above, you could see which module you have got. Click to the Kovp value and change it to the table value. Now the calibration is ready, and you should set the Output Voltage and OVP levels. Default values Value Maximum Output Voltage [V] The voltage the customer wants Umax (module table) OVP[V] 125% of the Output Voltage OVPmax (module table) REMARKS In some cases, the MUH6 voltage measurement range is lower than the maximum module output voltage. (e.g., if you connect a 24V module to U0, which could measure max. 7.5V). During calibration, the DACu value of 255 is used by default. (This will give the best accuracy). But if the module output voltage exceeds the MUH6 measurement range, the calibration will fail. In that case, you should reduce the DACu value before pushing the "CALIBRATE" button.
Cal I-Monitor Current Calibration
The current calibration should be done for a current limit close to full load (90%) for each voltage channel. Connect the power supply output to a load and measure the actual current. The calibration factor is automatically calculated if writing the data for the measured current and monitor voltage to the computer and pressing “CALIBRATE”. If the calibration factor is known it can be typed in directly. To store the new calibration setting for the channel press “OK”.
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After a current calibration the correct current monitoring should be checked for lower loads ( ½ and ¼ of nominal current value).
Output Voltage Define Nominal Voltage
Value is the nominal voltage of the voltage channel. Minimum Value is the minimum allowed value for the nominal voltage. Maximum Value is the maximum allowed value for the nominal voltage. Exponent gives the number of digits after the decimal.
Current Limit output current limit (Secondary programmable current limit) Standard setting: Hardware Limit
This Current Limit is the maximum current value that the module is permitted to produce. When this current limit is reached the module will enter into a constant current mode by lowering the voltage until it reaches the minimum allowed voltage. By default this value is set to the hardware limit of the module.
Monitoring:Umin Software minimum voltage limit Standard settings: 97.5% of nominal voltage Unom
The minimum voltage limit is the minimum allowed voltage for a given channel. If the voltage of that channel ever reaches or drop below the minimum value, the power supply will turn off with an “Undervoltage “ error.
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Value is the minimum allowed voltage for the channel. Minimum Value is the minimum allowed value. Maximum Value is the maximum allowed value. Exponent gives the number of digits after the decimal.
Monitoring:Umax Software maximum voltage limit Standard settings: 105% of nominal voltage Unom
The maximum voltage limit is the maximum allowed voltage for a given channel. If the voltage of that channel ever reaches or exceeds the maximum value, the power supply will turn off with an “Overvoltage “ error.
Value is the maximum allowed voltage for the channel. Minimum Value is the minimum allowed value. Maximum Value is the maximum allowed value. Exponent gives the number of digits after the decimal.
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Monitoring:Imin Software minimum current limit Standard settings: No minimum (0)
The minimum current limit is the minimum allowed current for a given channel. If the current for that channel ever reaches or drop below the minimum value, the power supply will turn off with an “Undercurrent “ error.
Value is the minimum allowed current for the channel. Minimum Value is the minimum allowed value. Maximum Value is the maximum allowed value. Exponent gives the number of digits after the decimal.
Monitoring:Umax Software maximum cuurent limit Standard settings: 100% of Hardware Limits
The maximum cuurent limit is the maximum allowed current for a given channel. If the cuurent of that channel ever reaches or exceeds the maximum value, the power supply will turn off with an “Overcurrent “ error.
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Value is the maximum allowed voltage for the channel. Minimum Value is the minimum allowed value. Maximum Value is the maximum allowed value. Exponent gives the number of digits after the decimal.
OVP OVP setting Standard settings: 125% of Unom
OVP is a secondary voltage protection. It sets the maximum voltage that a module may produce. If the module ever detects a value greater than OVP it will turn off the power supply with an “Overvoltage” error.
Value is the maximum allowed voltage for the module. Minimum Value is the minimum allowed value. Maximum Value is the maximum allowed value. Exponent gives the number of digits after the decimal.
Temperature Limit Temperature Limit settings
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Standard settings: 127
Temperature Limit settings sets the maximum internal temperature of the power supply module before turning off the power supply. The default settings allow the module to run to the maximum temperature.
Power-on Delay Delay between power-on and ramp Standard settings: 0
To allow flexibility of the voltage ramp, it is possible to set channels to begin their voltage ramp at different times. This is done by delaying the start of the ramp by some time in steps of ms.
Temperature OK or Fail Status OK Power ON - OFF by software ( mouse click or <P>) AC OK - Fail (status of AC mains) Trip off Enable - Disable (temperature and OVP control enabled - disabled)
WARNING Disable TRIP OFF only if necessary, don’t leave the power supply with TRIP OFF disabled! The power supply and crate or modules in the crate can be damaged in case of error conditions without enabled automatic trip off protection.
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Complete Test Instruction for UEP 6000 1. Visual test Power Supply surface ok? Final set-up ok? Cable mounting ok? 2. HV-Test 2.4kVDC: AC-mains - PE Short circuit test @ 50V DC: Output - PE. - since 1998 sticker: HIGH VOLTAGE TESTED - high voltage test has to be repeated if there are changes of the power configuration or set-up 3. Put into Operation (with complete function control) Configuration, calibration (trimmer) , current measurement adjustment ( I-Mon ) Measurement of current limit (short circuit current) - since 1998 sticker CALIBRATED - sequence of test steps according to test procedure 4. Burn In Long time test with full load and multiple on / off ( - since 1998 sticker LONG TIME TESTED - Attention: do not exceed the maximum total power (mains fuse!) - in case of parallel working AC inputs take care for equal load for both - power supply levels 5. Mechanical Set-up a) Mounting screws OK? b) Power terminal contacts OK? c) Mount missing mechanical parts and check all screws d) test fitting of power supply into VME bin 6. End check to be done with protocol - since 1998 sticker END CONTROLLED - sequence of test steps as for 3. Put into Operation - write protection enabled? - visual check for stickers and device label
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Test Procedure Sequence UEP6000 1. Test AC input switch AUTO/FIX for Power Supplies with auto range AC inputs - AUTO : feed 3V DC in AC mains cable, measure current (typically 0,08mA) - switch to 115V ( current typically 0,52mA). - prepare for delivery with switch position to AUTO with locking and sticker 2. Start Power Supply Operation: - disable Write protection (jumper), connect power supply to IBM-PC (RS 232) - feed AC mains in power supply - start software UEP 6000, create or copy configuration file - if the fan tray unit is connected to the power supply the write protection jumper has to be disabled during start for power supply software version MUH 1.00 3. General behavior / settings Main configuration OK ? RS 232 OK ? Channel? Module-current/limit? Module OVP? Module Unom? min/max Voltage? 4.Test each Voltage Channel Check adjustment Master-Slave Imon and CV. Coding for slave U-nom under full Load : fine tuning ? display OK ? Noise and Ripple OK ? Current calibration for 3 load values (full, half, no load):
I-nom Full load Half Load No Load
Display Fan tray ? ? ?
Signal I-nom ? ? ? At this time proof static regulation (U) ( Sense wiring) T-Hold after AC-Fail, U-Dynamic, T-Recovery have been checked within power module test 7. Adjustments Voltage Error adjusted? Current Error checked with different current values?
Reference Table for Test and Adjustment of UEP 6000
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CHANNEL Module selected Are all installed voltage channels present? Example: STBY: 31V / Ampere XXXX. / Volt XX. Cal I-Monitor Calibration measure current Enter measured current and hit “CALIBRATE” Output Voltage output voltage Nominal voltage for the channel Current Limit maximum current The max current allowed for that channel (constant current) Monitor U-min minimum voltage 90% of nominal voltage Monitor U-max maximum voltage 112.5% of nominal voltage Monitor I-min minimum current Generally 0 Monitor I-max maximum current 112.5% of nominal expected current (“Overcurrent” error) Module OVP maximum voltage 125% of nominal voltage Power on Delay ramp Delay Delay, in ms, between power-on and start of voltage ramp Temperature OK or Fail Status OK Power ON - OFF by software ( mouse click or <P>) AC OK - Fail (Status of AC mains at Elko) Trip off Enable - Disable
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UEP 6000 Module Replacement Instructions In troubleshooting WIENER crates it is very useful to substitute Fan trays and power supplies from working crates into the crate which is problematic, this is often the best way to determine which component (fan tray, power supply, or crate) is causing the failure. It is also useful to place the power supply on a bench top and use the UEP6000 software to troubleshoot power supplies. MNPFC-16 The MNPFC-16 is the primary rectifier for the UEP6000 power supply. Common symptoms of a power supply with a faulty are MNPFC are:
• No indication that the power supply is operating. • The green LED on the board is not lit. (Visible with case closed). • No “click” when power supply is plugged in. • No internal primary DC voltage from MNPFC-16 (385VDC)
If the MNPFC is found to be the problem, the following steps should be taken to replace it:
• Disconnect A/C power and remove power supply from the VME crate. • Remove the top cover from the power supply and discharge capacitors • Remove the side panel on which the MNPFC is mounted, including the nuts with which the
module is mounted. • Disconnect the A/C wires (Brown & Blue) as well as the flat ribbon cable and DC connector
from the module. • Installation is the reverse of removal. • After replacing the cover, connect the A/C input and ensure that functionality is OK.
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MEH/MDH The MEH/MDH modules are the secondary rectifier modules that produce the voltages used by the VME crate. Common symptoms of a faulty MEH/MDH module are:
• An over/under voltage error for a certain channel (On UEL display or via UEP6000 software).
• The power supply will start up but turn itself off quickly. If an MDH/MEH module is found to faulty the following steps should be taken to replace it (valid only for standalone modules):
• Disconnect A/C power and remove power supply from the VME crate. • Remove the top cover from the power supply and discharge capacitors • Determine which power module is faulty. This is done by locating the right channel along the
top of the MUH board and following the control cable to the correct module. • Disconnect the power cables and the flat control cable(s) from the module. • Remove the screw that holds the module to the case. • Slide the module forward and remove the module. • Installation is the reverse of removal. • Calibrate the voltage and current measurements • After replacing the cover, connect the A/C input and ensure that functionality is OK.
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MUH The MUH module is the microprocessor control board for the power supply. Common symptoms of a faulty MUH module are:
• No function although internal operating voltage is present (385VDC). • Under/over voltage error for 1 or more voltage channel. • No remote interface (errors when connected to UEP6000 software).
If an MUH module is thought to be faulty the following steps should be taken to replace it:
• Disconnect A/C power and remove power supply from the VME crate. • Remove the top cover from the power supply and discharge capacitors • Remove the side panel next to the MUH module. • Disconnect the flat ribbon control cables, recording where they were plugged in. • Disconnect the sense, CAN, DC, and control cables. • Remove the 25-pin D-sub connector to gain access to the screws holding the MUH board to
the chassis. • Remove the module from the crate. • Remove the EEPROM from the module and place it into the new MUH module. This will
transfer the channel calibration information. • Installation is the reverse of removal. • Once power supply cover is replaced, check that the current and voltage calibrations are
correct.
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UEP 6000 Channel Calibration
Voltage Calibration Voltage calibration values vary depends on what kind of module you are calibrating and which nominal voltage you wish that channel to have. To calibrate a power supply channel:
• Connect the power supply to a PC and start the UEP6000 software • Start Flash6.exe and turn off “write disabled” • Click on “Voltage OVP” and enter the value specified in the table below. • Turn the power supply on and measure the channel voltage.
Current Calibration Correct current calibration ensures that the power supply reports the correct current readings. To calibrate the current values for a given channel, the following steps should be taken:
• Connect the power supply to a PC on which the UEP600 software is installed via a appropriate adapter cable.
• Connect a current sink to the channel that you wish to calibrate. • Connect A/C power and ramp the current up to 90% of the channel maximum. • Click on “Calibration [I-monitor]” and enter the measured current. • The UEP6000 will calibrate the current monitor and should now report the same value as the
measured current. The calibration procedure above only works for master modules. If you have two or more modules running in co-operation with each other, you will have to do a master-slave calibration. Please contact a WIENER representative for guidance with this task.
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Module-Data
MRP
Resistor DAC[k] 12R6[k] 20
R5[k] alpha KfVersion .B2 and below 75 0,81308 7533Version .B3 and above 750 0,97442 860
Modules
Uref(U) [10mV] 510Uref(OVP) [10mV] 250MRP: R13, R14 [k] 10MRP: R17, R18 [k] 20MRP: R4, R12 [k] 10
Module Type R4,R12 MRP :B2 MRP :B3 Umax R9,R10 Kovp OVPmax R5/8 R6/7 GND-floating[kOhm] Ku Poti[mV] Ku Poti[mV] [V] [kOhm] [V] [V]
5V-MEH, <= Index A5 13,3 34729 4,34 28978 0,59 5,92 27,4 24492 6,82 1 0 12,05V-MEH, >= Index A6 22,1 25208 5,98 21034 0,82 8,15 43,2 15534 10,76 1 0 12,0MEH10 33,2 18731 8,04 15630 1,10 10,97 56,2 11941 14,00 2,21 2,21 24,0MEH12, <= Index A1 61,9 11254 13,39 9391 1,83 18,26 82,5 8134 20,54 2,21 2,21 24,0MEH12, >= Index A2 56,2 12223 12,33 10199 1,69 16,82 82,5 8134 20,54 2,21 4,75 37,8MDH7-15, >= Index A0 56,2 12223 12,33 10199 1,69 16,82 82,5 8134 20,54MDL12/24, (MEH24) 110 6743 22,34 5627 3,06 30,48 133 5046 33,12 1 0 12,0MEH48 221 3503 43,01 2923 5,88 58,67 274 2449 68,23 4,75 30 87,8
DACovp = U[V]*Kovp/655.36 alte Module
Modul-DAC-Values.xls 27.03.0321
Connection of a Personal Computer to the Power Supply UEP6021
This connection is intended to service functions only. Because of the direct connectionbetween the PC and the power supply, the ripple and noise of the outputs willincrease!
The needed stuff is an PC running Windows, the control program UEP6 and a simpleadapter (“Dongle”). The power supply is connected to the COM port of the PC. Formore details, view the document *00461.A0.
7 1 kOhm
6 1 kOhm
5
100nF
8
3
X3, 9 Pin DSUBmale (UEP6)
9 Pin DSUB female(PC)
3
2
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PL6021 Connection Diagram
POWER CONNECTOR 18- U2 15
+12- U7 9
+6- Spare
3+
17-
14-
11-
8-
5-
2- D
-SU
B 37
U6 U5 U1 U3 U4 U0
16+
13+
10+
7+
4+
1+ D
-SU
B9
Pin 10,11,13...18: 6mm, 120A max.Pin 1...9+12: 8mm, 240A max. U0 to U7 = standard pinning only!Polarity:+ positive - negativ
FAN/CONTROL CONNECTOR D-SUB 95 CAN_H
9 CAN_L 4 CAN GND
8 RXD 3 TXD
7 +15V (for fan only) 2 +15V (for fan only)
6 -15V (for fan only) 1 -15V (for fan only)
SENSE/SIGNAL CONNECTOR D-SUB 3719 TEMP RETURN
37 TEMP 0 18 TEMP 1
36 TEMP 2 17 TEMP 3
35 TEMP 4 16 TEMP 5
34 TEMP 6 15 TEMP 7
33 BIN EEPROM: IIC SDA 14 BIN EEPROM: IIC SCL
32 BIN EEPROM:+5V 13 VME LOGIC: SYSRESET
31 BIN EEPROM: GND 12 VME LOGIC: ACFAIL
30 VME LOGIC GND 11 VME LOGIC: SYSFAIL
29 U0 SENSE - 10 U0 SENSE + (VME: +5V)
28 VW SENSE (reserved) 9 VW SENSE (reserved)
27 VX SENSE (reserved) 8 VX SENSE (reserved)
26 U4 SENSE + 7 U4 SENSE -
25 U7 SENSE + 6 U7 SENSE -
24 U2 SENSE - 5 U2 SENSE + (VME: 48V)
23 U6 SENSE + 4 U6 SENSE -
22 U1 SENSE - 3 U1 SENSE + (VME: +12V)
21 U5 SENSE + 2 U5 SENSE – (VME: -12V)
20 U3 SENSE - 1 U3 SENSE + (VME: +3.3V)
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WIENER VME Crate Temperature Sensors
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VME 6000 Series Bin EEPROM configuration WARNING!!! Changing the BIN EEPROM setting could damage modules in the VME crate. WIENER 6000 series VME crates contain an EEPROM which contains data about what power supplies to accept. This prevents users from accidentally plugging in power supplies that could damage modules within the crate. If the crates function is changed and the EEPROM needs to be reprogrammed, it can be done by following the steps below.
1. Remove the fantray from the crate. This will give you access to a subD 9 pin connector. Plug one end of a WIENER power supply adapter into the connector, connect the other a computer.
2. Insert a jumper on the write protect pins for the EEPROM. The pin locations are shown
below.
Write jumper
25
3. Open the UEP6000 program. The current bin settings should now be visible as highlighted below.
4. If screen does not show BIN configuration, select configuration and highlight these lines:
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5. Select bin parameter to be changed and enter new value
6. Changes are saved automatically when you hit OK
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UEL6000 Ethernet Firmware-Update
The UEL6000 Firmware is stored in a FLASH ROM and can be updated via the RS232connector.
Necessary equipment:- Computer with RS232 interface, running Microsoft Windows (98 or above)- A patch cable to connect the UEL6000 with this computer- This software
Installation Steps:1. Unzip the UEL6402.zip to your had disk.2. Connect the computers COM port to the UEL60003. Switch the UEL6000 into “Load Update” modeThe “Load Update” mode is a submenu of the “RS232 Configure” menu of theconfiguration menu.You will use the following switches of the fan tray:
P▲ Push “Power” switch up(ON)P▼ Push “Power” switch down (OFF)M▲ Push “Mode Select” switch upM▼ Push “Mode Select” switch down
Steps to get into the “Load Update” mode:
Description Switch Displayswitch the crate off P▼ ________________
enter configuration menu M▲(push and hold), P▲ Config: Wait
hold both switches up Config: Wait...
after 4 seconds you can Config: Ready !
release the switches +5V0 0.01V 0A
Now select the “RS232Configure” menu
M▲ or M▼ (until right menuis displayed)
RS232 Configure
Enter this menu P▲ Baudrate: 115.2k
Select submenu “Firmware” M▲ or M▼ (until right menuis displayed)
UEL6000 Firmware
UEL6000 4.02
Enter submenu P▲ Load Update: No
Change to yes M▲ Load Update: Yes
Accept settings and enterupdate mode
P▲ Scanning RS232..
4. Run the upload software on the computerOpen a command window, change to the folder of the unzipped file.At the prompt enter the command
C:UEL6402> F28xxConsole.exe -v -p com1 -i UEL6E.4.02.out
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Replace “com1” with the COM port which you are using.
The software now connects to the UEL6000, the following is displayed:
Installed output message callback
Loading F2810SerialFlash.outEntry point 0x003f8000Section Address = 0x003f8000, Number of words =3235.................................................................Section Address = 0x003f8ca3, Number of words = 4.Section Address = 0x003f8ca7, Number of words = 84..Section Address = 0x00000792, Number of words = 67...Boot code loadedConnected to \.\COM1 at 5 baudTarget is programmed with "UEL6000 4.01"Erase the flash ?(y/n) y
This is the last chance to interrupt the update. If you say 'y' here, the UEL6000 flash iserased. Next messages are:
Erase the flash.Program the flash ?(y/n) y
You should say 'y', too. If not, you have got an empty flash which can only bereprogrammed at the factory.
Program UEL6E.4.02.outSection Address = 0x003e8000, Number of words = 3676Section Address = 0x003e8e5c, Number of words = 253Section Address = 0x003e8f59, Number of words = 21Section Address = 0x003e8f6e, Number of words = 629Section ".stack" IGNORED (vaddr=0x8200 out of flash area)Section Address = 0x003e91e3, Number of words = 3Section ".args" IGNORED (vaddr=0x1fc out of flash area)Section "" IGNORED (vaddr=0x340 out of flash area)Section ".trace" IGNORED (vaddr=0x47c out of flash area)Section Address = 0x003e91e6, Number of words = 256Section Address = 0x003e92e6, Number of words = 32Section Address = 0x003f7ff6, Number of words = 2Section Address = 0x003f7ff8, Number of words = 8Section Address = 0x003f7f80, Number of words = 118Section Address = 0x003e9306, Number of words = 23754Section Address = 0x003eefd0, Number of words = 3628Section Address = 0x003f7f70, Number of words = 16Section Address = 0x003efdfc, Number of words = 30Section Address = 0x003efe1a, Number of words = 12Section Address = 0x003efe26, Number of words = 1539
Verify UEL6E.4.02.outSection Address = 0x003e8000, Number of words = 3676Section Address = 0x003e8e5c, Number of words = 253Section Address = 0x003e8f59, Number of words = 21Section Address = 0x003e8f6e, Number of words = 629Section ".stack" IGNORED (vaddr=0x8200 out of flash area)Section Address = 0x003e91e3, Number of words = 3Section ".args" IGNORED (vaddr=0x1fc out of flash area)Section "" IGNORED (vaddr=0x340 out of flash area)Section ".trace" IGNORED (vaddr=0x47c out of flash area)Section Address = 0x003e91e6, Number of words = 256Section Address = 0x003e92e6, Number of words = 32Section Address = 0x003f7ff6, Number of words = 2Section Address = 0x003f7ff8, Number of words = 8
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Section Address = 0x003f7f80, Number of words = 118Section Address = 0x003e9306, Number of words = 23754Section Address = 0x003eefd0, Number of words = 3628Section Address = 0x003f7f70, Number of words = 16Section Address = 0x003efdfc, Number of words = 30Section Address = 0x003efe1a, Number of words = 12Section Address = 0x003efe26, Number of words = 1539
Press [Enter] key to exit
OK, the update is ready. Now restart the crate by removing the mains cord.If there are new data items in the EEPROM, after the restart they will be initialized. Youhave to acknowledge the “CHECKSUM xxxx” messages by pushing the “SYSRES” buttonat the fan tray.
Plein & Baus GmbH 3 UEL6000E Firmware Update, 15 Jun 200430
UEL6 Ethernet Pin Description 1. CAN-Bus (X1, X2)
RJ45 Pin Signal Comment 1 CAN-H 2 CAN-L 3 GND 4 n.c. 5 n.c. 6 reserved 7 GND 8 n.c.
This is the standard CIA pinning. Both connectors are wired in parallel, so it’s easy to connect many crates in a daisy-chain. 2. RS232 (X2)
RJ45 Pin Signal Comment 1 n.c. 2 n.c. 3 n.c. 4 GND 5 RXD Output 6 TXD Input 7 CTS Output 8 RTS Input
This is the standard RS232D DCE pinning. Connection to DTE (e.g. computer) with a 1:1-cable. 3. Ethernet (X4)
RJ45 Pin Signal Comment 1 TX+ 2 TX- 3 RX+ 4 GND 1 75 Ohm 5 GND 1 6 RX- 7 GND 2 75 Ohm 8 GND 2
This is the standard NIC configuration. You need a 1:1-cable to connect a to a HUB, or a cross-over cable to connect to another NIC (e.g. a computer)
31
32
33
34
35
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Fri10.04.03Tue Jul 13, 2004
1407053 A5
SG;I/O-Complete
C10, C11:max. Bauhöhe 7mm, sonst legen
C2D2 D4
C12
C5
C9
C8
C6
S1
R2
S5
R3
S6 C7
C1D3
C10
C3 C4C13
D7
D8
D5
X6
S2
R1
U1 S4S3 U2D6
U6 U7D9
R4
S7C11U4
U5 U8U3
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4 X6:D6 X6:F
1 X6:A
3 X6:C
2 X6:B
5X6:E
2N2/50V
C13
2N2/50V
C12
D9
LED:5GN
100P
/63V
C8
100P
/63V
C6
100N
/63V
C4
C11
22u/
50V
100N
/63V
C2
100N
/63V
C1
100N
/63V
C5
100N
/63V
C9
C10
22u/
50V
100P
/63V
C7
100N
/63V
C3
D8
LED:3RT:F:S
D5
LED:3GN:F:S
D4
LED:3RT:F:S
D2
LED:3GN:F:S
D3
LED:3RT:F:S
D6
LED:3GE:F:S
D7
LED:3GE:F:S
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GE10.03.2004Wed Mar 10, 2004
1464212 A3
UEL6000 CPU with Ethernet
61
X8
61
X7
110
X5
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V3.3
GND
V3.3
V3.3_RS
V3.3
UEP_RXD
GND
CANRX
GND
UEP_TXD
SPI_CS
V3.3
9 X5:I
GND GND
IO_SOMI
IO_LOAD
IO_SIMO
IO_CLOCK
V5.0GND
B_CS
B_SIMO
B_CLK
GND
X_SOMI
X_CS
X_SIMO
X_CLK
V5.0GND
RTS
SCITXDA
GND
GND_RS
V3.3_RS
CTS
10.0k/0.125W
R23
CANTX
GND
7 X5:G
8 X5:H
15P/
50V
C76
15P/
50V
C77
BC84
7C
Q3
1.80
k/0.
125W
R15
V30
1U0/
50V
C5
3.30
k/0.
125W
R18
GND
GND_RS
3.30
k/0.
125W
R19
GND_RS
GND
100N
/16V
C11
220P
/50V
C15
BC847C
Q5
10.0
k/0.
125W
R21
33.0
k/0.
125W
R26
BC84
7C
Q2
100N
/16V
C9
1.80
k/0.
125W
R2
3.30k/0.125W
R1
3.30k/0.125W
R17
33.0
k/0.
125W
R25
33.0
k/0.
125W
R24
4.70
k/0.
125W
R27
5 X5:E
GND
SCITXDB
V30
UEP_CANGND CANGND
UEP_CANL CANL
UEP_CANH CANH
6X5:F
SPI_SOMI B_SOMI
4X7:DSPI_SIMO
SPI_CLK
V3.3_RS
4X8:D
SCIRXDA
GND_RS
RS232_RTS
RS232_CTS
RS232_TXD
RS232_RXD
GND_RS
D3
LL103ASCIRXDB
D4
LL103A
BC847C
Q6
Connection to CAN
15.0
k/0.
125W
R69
15.0
k/0.
125W
R72
5X7:E
1.00k/0.125W
R86
5 6
74ACT14PW
U10:C
6X7:F
1.00k/0.125W
R88
11 10
74ACT14PW
U10:E
3X7:C
Connection to I/O (HCT!!)
2X7:B1X7:A
1.80
k/0.
125W
R65
15.0
k/0.
125W
R7
5X8:E
15.0
k/0.
125W
R13
V3.3_RS
1.00k/0.125W
R676X8:F
1.00k/0.125W
R643X8:C
1X8:A2X8:B
1.80
k/0.
125W
R20
100N
/16V
C6
RS232 Transceiver
BC847C
Q9
1.00
k/0.
125W
R22
3.30k/0.125W
R34
Connection to MUH
100R
/0.1
25W
R9
10.0k/0.125W
R70
1.00k/0.125W
R87
1 2
74ACT14PW
U10:A
10.0k/0.125W
R5
1.80
k/0.
125W
R10
100N
/16V
C10
10.0k/0.125W
R12
1.00k/0.125W
R71
10.0k/0.125W
R73
BC85
7CQ1
1.80
k/0.
125W
R8
BC85
7CQ4
Die Drosseln waren bisher immer gebrückt!
3 4
74ACT14PW
U10:B
13 12
74ACT14PW
U10:F
Connection to external IF (HCT!!) DTE Pinning (we are DCE <-> 1:1-Cable)11 Bauteile (0805+SOT23) weniger, wenn statt MAX232 MAX3520 verwendet wird!
9 8
74ACT14PW
U10:D
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GND
V3.3
V3.3
CTS
GN
D
V1.8
DATA
GND
V3.3
V3.3
V3.3
GND
GN
D
V5.0
GND
GND
GND
GND
RESET
SDA
SCL
WP
V3.3
D15
D12D13
D9D10
D6D7
D3D4
D0D1
SDA
RESETWP
IOWAEN
25MHZ
FAN_PWM1
V3.3A
ADC_LOADC15
ADC12ADC13
ADC9ADC10
ADC6ADC7
ADC3ADC4
ADC1ADC0
GND
EMU0GND
TCK
TDO
TDI
TMS
B_SIMO
B_CLK
CANTXSCIRXDA
SPI_CLKSPI_CS
SPI_SIMO
V3.3
GND
GND
100N
/16V
C32
100N
/16V
C60
100N
/16V
C63
GNDA
D14
D11
D5
D2
D8
SCL
IOR
INDEX /DATA
FAN_PWM2
ADC8
ADC11
ADC14
ADC2
ADC5
GND1
GND1
100N
/16V
C38
100N
/16V
C20
100N
/16V
C42
100N
/16V
C35
10.0
k/0.
125W
R68
GND
10.0
k/0.
125W
R59
V3.3
100N
/16V
C22
100N
/16V
C64
V3.3
EMU1
TCK
TRST
0R0/
0.12
5W
R4
B_SOMI
CANRX
SCITXDA
SPI_SOMI
B_CS
100N
/16V
C43
100N
/16V
C49
V1.8
100N
/16V
C65
100N
/16V
C40
10.0
k/0.
125W
R6
10.0
k/0.
125W
R16
C50
47U
/10V
/600
mR
10.0
k/0.
125W
R46
DATA
C54
47U
/10V
/600
mR
RESET
SCIRXDBSCITXDB
12X6:1213X6:13
10X6:109X6:9
7X6:76X6:6
3X6:34X6:4
1X6:1
100N
/16V
C51
C71
47U/10V/600mR10
0N/1
6V
C47
100N
/16V
C62
24.9k/0.125W
R66C72
47U/10V/600mR
INTE
RTS
100N
/16V
C23
100N
/16V
C39
100N
/16V
C45
100N
/16V
C66
JTAG Interface
11X6:11
14X6:14
8X6:8
5X6:5
15P/50V
C19
2X6:2
1.00
k/0.
125W
R11
10.0
k/0.
125W
R48
100N
/16V
C21
100N
/16V
C52
100R
/0.1
25W
R52
C29
47U
/10V
/600
mR
1.80
k/0.
125W
R45
10.0
k/0.
125W
R47
1.80
k/0.
125W
R39
15P/50V
C18
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V30
V5.0
V30
LF2.
2LF
2.1
GND
PE
V30-10V
V0
V3.3
V3.3
V0
V30
GND
V30
Trennstellen
GNDA
V3.3A
GND
X20:1
GND
GNDA
ADC14
GND
ADC6
X19:1
ADC0
ADC7
ADC1
ADC8
ADC2
ADC9
ADC3
ADC10
ADC4
ADC11
X15:1
ADC5
D8
LL103A
4.70
k/0.
125W
R28
Q10
:B
IRF7
341
D10
LL103A
GND
1U0/
50V
C33
C36
330u
/35V
LF1.
2LF
1.1
10N
/50V
C2
ADC12
C57
330u
/35V
1U0/
50V
C74
ADC14
1.00
k/0.
125W
R62
ADC130R
47/1
W
R79
X14:1X14:2
X20:2
0R47
/1W
R78
ADC_LO
X13:2X13:1
X19:2
0R47
/1W
R77
0R47
/1W
R76
10N
/500
V
C78
GND
PE
X9:1X9:2
X15:2
1U0/
50V
C25
4.70
k/0.
125W
R30
Q10
:A
IRF7
341
10M
EG/0
.125
W
R41
D9
LL103A
1U0/
50V
C12
C37
330u
/35V
C1
330u
/35V
1U0/
50V
C31
D1
MBR
S340
T3
33.0
k/0.
125W
R61
1.80
k/0.
125W
R60
C56
330u
/35V
1U0/
50V
C70
C3
330u
/35V
R57
1k0/
25°C
1.00
k/0.
125W
R63
0R47
/1W
R85
0R47
/1W
R84
0R47
/1W
R83
0R47
/1W
R82
3.30
k/0.
125W
R31
3.30
k/0.
125W
R89
FAN_PWM1
1 X5:A2 X5:B
V30-10V
3 X5:C
Connect at one point!
X16:1X17:1X18:1
1.00k/0.125W
R32FAN_PWM2
1U0/
50V
C17
BC84
7C
Q8
4 X5:D
Q11:B
IRF7342
3R9/0.125W
R43
C16
330u
/35V
D6
MBR
S340
T3
1.50k/0.125W
R3
4.70k/0.125W
R14
5V-Converter
0R47
/1W
R74
0R47
/1W
R75
X10:1X10:2
X11:1X11:2X12:2
X12:1
X16:2X17:2X18:2
10N
/500
V
C79
BC84
7C
Q7
1.00k/0.125W
R33
10M
EG/0
.125
W
R40
22N
/50V
C73
C13
330u
/35V
D7
MBR
S340
T3
Q11:A
IRF7342
3R9/0.125W
R44
R90
1k0/
25°C
1U0/
50V
C4
100N
/16V
C61
0R47
/1W
R80
0R47
/1W
R81
3.30
k/0.
125W
R29
6
3
4 5
TPS2812D
U5:B
Softstart (Hot-Swap)
6
3
2 7
TPS2812D
U5:A
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GND
V3.3GND
GNDGND
V3.3
GND
GND
V3.3E
V3.3
GND
V3.3
V3.3
EEC
S
EEDI
EEDO
EEC
K
GN
D
GN
D
V3.3
D16
IO32 D17
D18
D19
GNDE
GNDE
IOR
IOW AE
N
V3.3 D0
D2
D3
D1
D5
D6
D4
GN
DR
ESETD
7
V3.3
GN
D
V3.3
V3.3
GN
D
25M
HZ
GN
D
INTE
D10D9
D12D13
D15
INT low
V3.3E
RX-RX+
TX+
V3.3V3.3E
D29D30
GNDD27
D24D25
GNDD22
D20
GNDE GNDE
RX+
RX-
TX-
GND
GND
V3.3
D11
D8
D14
RESET
LED mode 1
100M
LINK
330/0.125W
R35
6.80
k/0.
125W
R58
V3.3E
TX-
D28
D31
D21
D23
D26
GNDE
51R
/0.1
25W
R55
51R
/0.1
25W
R56
100N
/16V
C46
TX+
10N/500V
C14
100N
/16V
C8
100N
/16V
C68
100N
/16V
C28
100N
/16V
C69
330/0.125W
R36
100N
/16V
C41
100N
/16V
C26
100N
/16V
C48
100N
/16V
C58
51R
/0.1
25W
R53
51R
/0.1
25W
R54
C30
47U
/10V
/600
mR
100N
/16V
C53
75R
/0.1
25W
R50
10N
/500
V
C24
75R
/0.1
25W
R37
75R
/0.1
25W
R38
V3.3
V3.3
V3.3
V3.3
RJ45_TM8
RJ45_TM8
RJ45_TM5
RJ45_TM5
RJ45_TX-
RJ45_TX+
DATA
INDEX /DATA
4.70k/0.125W
R49
H2
LED:3GE
GNDE
V3.3E
100N
/16V
C34
DATA32
RJ45_RX-
RJ45_RX+
100N
/16V
C7
100N
/16V
C27
100N
/16V
C67
H1
LED:3GN
4.70k/0.125W
R42
100N
/16V
C44
100N
/16V
C55
100N
/16V
C59
75R
/0.1
25W
R51
42
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Title
D-51399 Burscheid +49-2174-678-0 www.wiener-d.com
muh6.PCB
Koe / Ge25.01.2005Tue Feb 07, 2006
1437008 B6
MUH6000 (low Noise)
Mut
ter
Alu
-Oxi
d
Sch
raub
e
Kue
hlko
erpe
r
Cho
-The
rm
Fede
rsch
eibe
Q7,
Q8
Iso-
Rol
le
D1,
D2,
U1
Iso-
Buc
hse
Fede
rsch
eibe
Kue
hlko
erpe
r
U-S
chei
be
Isos
chla
uch
Sch
raub
e
Montage D1, D2, U1 Montage Q7, Q8
C62C61
C64
C81
R75
C95
2
1
R7
L3
R6
C34
RP
0R
P4
R15
R13
D6
C38
RM
3R
P3
R22
R20
RM
1R
M5
R30
R27
R29
R26
L6
RM
7R
P7
R39
R37
C51
C50
RP
2R
P6
R46
R43
C55
C54
R52
R50
C59
R51
C57
R63
R61
C66
U12
C63
C60
Q6
L8D
16
C82
U16
U15
C80
D23
D21
R76
Q11
D24
R77
C91
C90
D33
D31
R84
R83
D37
D35
R91
R88
H1
C10
3C
101
H3
D48
D46
C10
6C
105
D53
D51
C10
9C
108
C35
J1J2
C44
C48
C58
R62
C65
R60
D17
D22
C89
U20
D32
D36
D47
D52
R65
R66
C15
C12
C9
C6
C3
C17
C33C32
C30C29
C27C26
Q3
R19
R8
U2
Q5
R34
R57
R55
C47
C52
C75
C72
C70
C76
C88
R81
R80
U23C94
R86R87
X16
D49
110
X1
C16
C14C13
C11C10
C8C7
C5C4
Q1
C2C1
D2
C111
C31
C28
RM
0
RP
5
RM
4
R24
R17
R11
R9R5
Q2
C37
U5D5
C42C41
JC1
L5L1
C36
C39
R59
RP
1
RM
2
RM
6
R54
R48
R41
R35
R33C
56
C53
C49
R56R45
U10
U9
R58R
32
R64
C71
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D10
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C77
3
D28
D26
C85
R67
C83
X4
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D18
D14
D44
R82R79
D42
U21
R85
D41D40
C99
C92
C11
0
H2
D59
X12C10
7
C10
4
D56
D57
R10
0
F1 X14
X15
S2S1
U1
D1
C40
U6
U4
L2
C43
U11
U8
U7
R53
Q4
Q8
C74
C73
C68
D15
1
20X
5
1
20X
3
D27
C84
XTE
MP
1
1
20X
8
1
20X
7
U19
D43
C10
0
C93
U22
R92
1
20X
11
1
20X
10
1
20X
13
D55
D58
U26
D11
C86
C24
C18
C67
R98
R73
K2
K1
R94
R10
D9
C23
C45
R97R74
R96
U25U17
R95
C78
Q10
Q9
C102
D13D12
C46
C25
U3
X2
1
20X
9
1
20X
6
U24U18
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4R7/
5.1A
R19
22N/630V
C30
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33k2/0.6W
6R81
/0.6
W
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1
2
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0/B:
1
1
6
L3:A
C5
1n/4
00V/
Y2
SD10
3AD
1
169K
/0.6
W
R9
DSEP30-06B
D5
332K
/0.6
W
R11
220P
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C23
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C16
C7
47U
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V
R26
33k2/0.6W
12K1
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W/1
%
R13
C11
47U
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V
C9
47U
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V
C2
47U
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V
C8
47U
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VC
3
47U
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V
C10
47U
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V
C31
4N7/
250V
AC
C28
4N7/
250V
AC
1K50/0.6W
R2
C29
2U2/
275V
AC/X
2
10K0
/0.6
W
R3
100n
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C20
3
2
L3:B
5
4
L3:C
1N41
48
D16
SD10
3A
D4
3
4
L1:B
A:30
0/B:
1
182K
/0.6
W
R10
332K
/0.6
W
R12
C13
22N
/630
V2K
05/0
.6W
R14
C21
39u/
50V
100n
/100
V
C18
1K50/0.6W
R27
C25
1000
U/3
5V
R25
9k09/0.6W
R5
{Value}
C22
47u/35V
L5:B
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1n/4
00V/
Y2
C17
22N
/630
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C24
2X2:B
1K11/0.6W
R36
1K11/0.6W
R35
1K11/0.6W
R33
4R7/
5.1A
R20
4R7/
5.1A
R18
1K11/0.6W
R31
1K11/0.6W
R30
1K11/0.6W
R22 22N
/630
V
C27
C4
4N7/
250V
AC
R8
4R75/0.6W
10R0/0.6W
R28Q4
HGTG30N60A40
1N0/
500V
C14
BAV21
D1020 X4:20
R7
20K0
/0.6
W
4R75/0.6W
R4
332K
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W
R23
DSE
C15
-06A
D3
470P
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V
C15
C1
47U
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V
DSEC15-06A
D6
D7 DSEC15-06A
Q5
IRFB11050A
392R
/0.6
W
R15
BZX85C6V2
D14 D17
BYV27-150
2X3:B
3X2:C
3X3:C
C6
47U
/450
V
1X3:A
1X2:A
BYV2
6C
D13
1K11/0.6W
R34
1K11/0.6W
R32
1K11/0.6W
R29
D18
GBPC3506N
R24
275V
AC/0
.6W
Q7
BC547B/RM5.08
BD138-16
Q1
1 10
300U/23AL:300U/23A:E65H
L6
10P/
500V
C19
6R81/0.6W
R16
BZX8
5C18
D12
R17
2K43
/0.6
W
C12
4N7/
250V
AC
P6KE
200A
D15
L5:A
Q6
IRFB11050A
6521 43
K1:B
1U16A/24V=
Q8
BC557B/RM5.08
BD138-16
Q3
BD138-16
Q2
7
8
K1:A
1U16A/24V=
51
52
53
54
STVHD90
Q3
BZX83C3V9 D14
10K0
R28
BD139-16
Q6
BD139-16
Q7
1N41
48
D10
1N41
48
D12
1K00
R35
1K00
R36
X213
X27
X211
X25
X28
X218
X217
X26
T
OP62
-100
S11
2
T
OP62
-100
S31
2
1N5
C1
ZKB409-019
L16
1
3
25
4
BF247
Q4
1K00
R27
10N
C19
10N
C2BZ
X83C
15
D8
BF247
Q5
BZX83C3V9
D15
1N4148
D11
1N4148D13
100R
R2
100K
R1
CIRCUIT DIAGRAM11:1314.03.97PLOT
CHECK
DRAWN
NAMEDATE DESCRIPTION
SHEETSHEETSREV.DRAWING NUMBERwienerPlein & Baus GmbH 02A31409266
03.12.93 Fri MEH_2-5V/100APower
COMP-I
GPH+
PWM+
TEMP+
CV
U-
PWM0
GPH0
GPL0
UD+COMP-U
OVP
GPL+
TEMP0
LOW
SIDE
DRI
VEHI
GH S
IDE
DRIV
E
0255
220P
C17
220P
C15
220P
C22
IRFP450
Q2
IRFP450
Q1
MUR460
D5
MUR460
D6
0R10
R34
1N0
C8
10U
C4
10U
C3
2200UF
C33
2200UF
C25
2200UF
C30
2200UF
C26
2200UF
C29
2200UF
C31
2200UF
C27
2200UF
C35
2200UF
C34
2200UF
C32
2200UF
C28
150P
C18
X11
X13
3R3
R32
3R3
R29
3R3
R33
3R3
R30
ZKB472-120
L28
7
43
27K4
R9
27K4
R10
5K
R3
L
S
R
EF32/RM14
L4A4E4
EF32/RM14
L4A1E1 M1
M2
10N
C23
220UF
C5
220UF
C6
1U
C9
4N7
C20
4N7
C21
4AF-TR5 F1
3R32
R25
3R32
R22
3R32
R24
3R32
R23
500uR
R311
23
4
10N
C11
10R0
R7
10R0
R21
10R0
R6
STPS24045TVD9
K1
A1
STPS24045TV
D9K2A2
X2 14X2 12
X215
X216
X2 10
X2 4
X2 9
X2 3
X2 2
X2 1
22K1
R20
100P
C16
1N4148
D7
1U0
C24
100K
R5
100K
R8
ETD44/500W/5V
L3
25
26 19202110
18222324
100R
R13
100R
R11
13K3
R12
13K3
R4
CIRCUIT DIAGRAM11:1114.03.97PLOT
CHECK
DRAWN
NAMEDATE DESCRIPTION
SHEETSHEETSREV.DRAWING NUMBERwienerPlein & Baus GmbH
Single_Module_500WMEHFri03.12.93
1409266 A3/1 02
GPL+
US+*
U+
U-*
ISMON-US+
UP+
IPMON0
IPMON0
ISMON+
GPH0
UP0 US-*
PE
GPL0
IPMON+
GPH+
US-
U-
U+*
UD+
0156
C1
M1M2
D8
C2
C19
R27
R35
R36
L1
S1S3
R9R10
Q5
Q4
R28
R24 R22R23
Q3
C18
R5R8
R1
D7
D10
D11D12
D13
C16R20
C3C4
R21
R6R7
Q2
Q1
D5
D6
C20C21
C11
C24
D14
D15
R3
F1
C9
L4
C8
X2321
X1
Q7
L5
C25
C30
C26
C29
C31
C27
C35
C34
C32
C33
C28
L2
C15
C17
C22
R25
R34
C5
D9 R31 C23
R4
R12
L3
R2
R11R13
R32
R29
R30
R33
PARTS LAYOUT
DESCRIPTION
SHEETSHEETSREV.DRAWING NUMBER
09.07.98 21:24PLOT
CHECK
DRAWN
NAMEDATE
Nutzen:
Plein & Baus GmbH
M 1:1Oberflaeche:
Bestueckungsaufdruck:
Lagen:Durchkontaktierungen:
Loetstop:
Kupferstaerke:Platinenmaterial:Platinenmasse [mm]:
01 01wiener
REFERENCE NO.nein
ja
part.verzinntbeidseitignein
2250umFR405_1.5mm199.64x99.82
Fri03.12.93
Single_Module_500WMEH
1409266 A6
C6
Q6
R37
Transistoren Q4,Q5
D und S sind tauschbar
NSPHILIPS
MOTOROLA
S
SD
D
GG BF247A
BF247ABF246A
G
S D D
DS
S
G
G
57
w-ie-ne-r Plein & Baus GmbH
Filename
Plot Date Drawn by
RevNumber
Title
D-51399 Burscheid +49-2174-678-0 www.wiener-d.com
Mdl.pcb
GE02.02.02Tue Oct 08, 2002
1460193 A3
MDH Modul Double Highpower
58
of
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Plot
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Title
Date
+49-2174-678-0
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D-51399 Burscheid
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1460193
w-ie-ne-r Plein & Baus GmbH
59
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Title
Date
+49-2174-678-0
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D-51399 Burscheid
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1460193
w-ie-ne-r Plein & Baus GmbH
60
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Filename
Plot Date Drawn by
RevNumber
Title
D-51399 Burscheid +49-2174-678-0 www.wiener-d.com
mrp SMD.pcb
GE18.05.06Thu May 18, 2006
1409657 BC
MRP-DA
U6
U920
1X1
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Title
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D-51399 Burscheid
mrp SMD.sch
1409657
w-ie-ne-r Plein & Baus GmbH
of
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Plot
Number
Title
Date
+49-2174-678-0
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mrp SMD.sch
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R16
10.0k/0.125W
R17
R74
500R
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k/0.
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R64
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k/0.
125W
R34
C31
47u/
35V
reserved
R13
C30
47u/
35V
1U0/
50V
C54
Q7
BSH114
17X5:17
18X5:18
100N/50V
C26
6X1:6
100N
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C22
X6
3SMDL1:SA
220P
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C49
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R10
10.0
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125W
R78
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C4
5.10
k/0.
125W
R39
1.00
k/0.
125W
R65
2.00
k/0.
125W
R75
220P
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C37
220P
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C42
47N/50V
C3
100N
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C45
100N
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C47
47N/50V
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1U0/
50V
C29
15P
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33.0
k/0.
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R48
22.0k/0.125W
R47
10.0
k/0.
125W
R42
2.70
k/0.
125W
R40
100N/50V
C23
2 X1:2
1 X1:1
9 X1:9
5 X1:5
10 X5:10
10.0k/0.125W
R7 1.00k/0.125W
R62
10.0
k/0.
125W
R12
4 X1:4
3 X1:3
C8
100P/50V9 X5:9
8X1:8
10X1:10
3 X5:3
4 X5:4
R11
2.20
k/0.
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BC857C
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15.0k/0.125W
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reservedC6 1U0/
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470/0.125W
R31
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BSH114
2.70k/0.125W
R30
reserved
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10.0k/0.125W
R4613 X5:13
2.00
k/0.
125W
R45
220P
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5.60k/0.125W
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510R/0.125W
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Q3
BC857C
Q6
Q9
BSH114
1U0/
50V
C43
100K/0.125W
R8
24k/
0.12
5W
R21
10N
/500
V
C24
15P
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C5
24k/0.125W
R20
1U0/
50V
C41
100N
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C44
15P
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C34
10.0
k/0.
125W
R41
15P
/50V
C9
0R0/0.125W
R18
1.60k/0.125W
R23
R15
330R/0.125W
10.0
k/0.
125W
R60
10.0
k/0.
125W
R61
1.00
k/0.
125W
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Rev
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Title
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18.05.06Mon Jun 12, 2006
D-51399 Burscheid
mrp SMD.sch
1409657
w-ie-ne-r Plein & Baus GmbH
of
Rev
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Title
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+49-2174-678-0
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D-51399 Burscheid
mrp SMD.sch
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13X1:1310.0k/0.125W
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rese
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100N
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18X1
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17X1
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100N
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750k
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R82
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Q1BC847C
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24k/
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10.0k/0.125W
R32
510/
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R80
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100N/50V
24k/0.125W
R28
100P
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C25
160/
0.12
5W
R71
100N
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C28
5.10
k/0.
125W
R51
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0.12
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R86
100N/50V
C17
2 X5:2
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12 X5:12
19 X1:19
7X1:7
1.00k/0.125W
R33
1 X5:1
rese
rved
R70
1.0n
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V
C40
14 X5:14
10N
/50V
C39
10.0k/0.125W
R68 1.0n
F/50
V
C38
510/
0.12
5W
R83
510/
0.12
5W
R85
20 X1:20
10.0k/0.125W
R52
5.10k/0.125W
R54
11X1:11
1.0n
F/50
V
C33
10R
0/0.
125W
R63
2.00k/0.125W
R5712X1:12
750k/0.125W
R56
1.00k/0.125W
R36
R72reserved
10.0k/0.125W
R69
500R
R73
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C27
100P
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C20
1.00
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125W
R79
100K/0.125W
R50
10.0
k/0.
125W
R55
5.10
k/0.
125W
R58
1
6
8U8
TL431CD
100N
/50V
C52
10N
/50V
C1
1ME
G/0
.125
W
R2
X10
3SM
DL1
:SA
20.0k/0.125W
R53
6 X5:6
63