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SERVICE MANUAL
AUTORANGING
DC POWER SUPPLY
AGILENT MODELS 6010A, 6011A,
6012B and 6015A
Agilent Part No. 5964-8275
FOR INSTRUMENTS WITH SERIAL NUMBERS
Agilent Model 6010A; Serials US37110171 and above
Agilent Model 6011A; Serials US35460156 and above
Agilent Model 6012B; Serials US35430336 and above
Agilent Model 6015A; Serials US37050146 and above
For instruments with higher serial numbers, a change page may be included.
Microfiche Part No. 5964-8276 Printed in USA: July 2001
CERTIFICATION
Agilent Technologies certifies that this product met its published specifications at time of shipment from the factory. Agilent
Technologies further certifies that its calibration measurements are traceable to the United States National Institute of
Standards and Technology, to the extent allowed by the Institute’s calibration facility, and to the calibration facilities of other International Standards Organization members.
WARRANTY
This Agilent Technologies hardware product is warranted against defects in material and workmanship for a period of three years from date of delivery. Agilent Technologies software and firmware products, which are designated by Agilent
Technologies for use with a hardware product and when properly installed on that hardware product, are warranted not to fail to execute their programming instructions due to defects in material and workmanship for a period of 90 days from date of delivery. During the warranty period Agilent Technologies will, at its option, either repair or replace products which prove to be defective. Agilent Technologies does not warrant that the operation of the software, firmware, or hardware shall be uninterrupted or error free.
For warranty service, with the exception of warranty options, this product must be returned to a service facility designated by Agilent. Technologies. Customer shall prepay shipping charges by (and shall pay all duty and taxes) for products returned to Agilent Technologies. for warranty service. Except for products returned to Customer from another country,
Agilent Technologies shall pay for return of products to Customer.
Warranty services outside the country of initial purchase are included in Agilent Technologies’ product price, only if
Customer pays Agilent Technologies international prices (defined as destination local currency price, or U.S. or Geneva
Export price).
If Agilent Technologies is unable, within a reasonable time to repair or replace any product to condition as warranted, the
Customer shall be entitled to a refund of the purchase price upon return of the product to Agilent Technologies.
LIMITATION OF WARRANTY
The foregoing warranty shall not apply to defects resulting from improper or inadequate maintenance by the Customer,
Customer-supplied software or interfacing, unauthorized modification or misuse, operation outside of the environmental specifications for the product, or improper site preparation and maintenance. NO OTHER WARRANTY IS EXPRESSED
OR IMPLIED. AGILENT TECHNOLOGIES SPECIFICALLY DISCLAIMS THE IMPLIED WARRANTIES OF
MERCHANTABILITY AND FITNESS FOR A PARTICULAR PURPOSE.
EXCLUSIVE REMEDIES
THE REMEDIES PROVIDED HEREIN ARE THE CUSTOMER’S SOLE AND EXCLUSIVE REMEDIES. AGILENT
TECHNOLOGIES SHALL NOT BE LIABLE FOR ANY DIRECT, INDIRECT, SPECIAL, INCIDENTAL, OR
CONSEQUENTIAL DAMAGES, WHETHER BASED ON CONTRACT, TORT, OR ANY OTHER LEGAL THEORY.
ASSISTANCE
The above statements apply only to the standard product warranty. Warranty options, extended support contracts, product maintenance agreements and customer assistance agreements are also available. Contact your nearest Agilent
Technologies Sales and Service office for further information on Agilent Technologies’ full line of Support Programs.
2
SAFETY SUMMARY
The following general safety precautions must be observed during all phases of operation, service and repair of this instrument. Failure to comply with these precautions or with specific warnings elsewhere in this manual violates safety standards of design, manufacture, and intended use of the instrument. Agilent Technologies, Inc. assumes no liability for the customer's failure to comply with these requirements.
BEFORE APPLYING POWER.
Verify that the product is set to match the available line voltage and the correct fuse is installed.
GROUND THE INSTRUMENT.
This product is a Safety Class 1 instrument (provided with a protective earth terminal). To minimize shock hazard, the instrument chassis and cabinet must be connected to an electrical ground. The instrument must be connected to the ac power supply mains through a threeconductor power cable, with the third wire firmly connected to an electrical ground (safety ground) at the power outlet. For instruments designed to be hard wired to the ac power lines (supply mains), connect the protective earth terminal to a protective conductor before any other connection is made. Any interruption of the protective (grounding) conductor or disconnection of the protective earth terminal will cause a potential shock hazard that could result in personal injury. If the instrument is to be energized via an external autotransformer for voltage reduction, be certain that the autotransformer common terminal is connected to the neutral (earth pole) of the ac power lines
(supply mains).
INPUT POWER MUST BE SWITCH CONNECTED.
For instruments without a built-in line switch, the input power lines must contain a switch or another adequate means for disconnecting the instrument from the ac power lines (supply mains).
DO NOT OPERATE IN AN EXPLOSIVE ATMOSPHERE.
Do not operate the instrument in the presence of flammable gases or fumes.
KEEP AWAY FROM LIVE CIRCUITS.
Operating personnel must not remove instrument covers. Component replacement and internal adjustments must be made by qualified service personnel. Do not replace components with power cable connected. Under certain conditions, dangerous voltages may exist even with the power cable removed. To avoid injuries, always disconnect power, discharge circuits and remove external voltage sources before touching components.
DO NOT SERVICE OR ADJUST ALONE.
Do not attempt internal service or adjustment unless another person, capable of rendering first aid and resuscitation, is present.
DO NOT EXCEED INPUT RATINGS.
This instrument may be equipped with a line filter to reduce electromagnetic interference and must be connected to a properly grounded receptacle to minimize electric shock hazard. Operation at the line voltage or frequencies in excess of those stated on the data plate may cause leakage currents in excess of 5.0mA peak.
SAFETY SYMBOLS.
Instruction manual symbol: the product will be marked with this symbol when it is necessary for the user to refer to the instruction manual (refer to Table of Contents) .
Indicates hazardous voltages.
Indicate earth (ground) terminal.
The WARNING sign denotes a hazard. It calls attention to a procedure, practice, or the like, which, if not correctly performed or adhered to, could result in personal injury. Do not proceed beyond a WARNING sign until the indicated conditions are fully understood and met.
The CAUTION sign denotes a hazard. It calls attention to an operating procedure, or the like, which, if not correctly performed or adhered to, could result in damage to or destruction of part or all of the product. Do not proceed beyond a CAUTION sign until the indicated conditions are fully understood and met.
DO NOT SUBSTITUTE PARTS OR MODIFY INSTRUMENT.
Because of the danger of introducing additional hazards, do not install substitute parts or perform any unauthorized modification to the instrument. Return the instrument to a Agilent Technologies, Inc. Sales and Service Office for service and repair to ensure that safety features are maintained.
Instruments which appear damaged or defective should be made inoperative and secured against unintended operation until they can be repaired by qualified service personnel.
3
Symbol
Direct current
Description
Safety Symbol Definitions
Symbol Description
Terminal for Line conductor on permanently installed equipment
Alternating current Caution, risk of electric shock
Both direct and alternating current Caution, hot surface
Three-phase alternating current
Earth (ground) terminal
Caution (refer to accompanying documents)
In position of a bi-stable push control
Protective earth (ground) terminal
(Intended for connection to external protective conductor.)
Frame or chassis terminal
Out position of a bi-stable push control
On (supply)
Terminal for Neutral conductor on permanently installed equipment
Terminal is at earth potential
(Used for measurement and control circuits designed to be operated with one terminal at earth potential.)
Off (supply)
Standby (supply)
Units with this symbol are not completely disconnected from ac mains when this switch is off. To completely disconnect the unit from ac mains, either disconnect the power cord or have a qualified electrician install an external switch.
Printing History
The edition and current revision of this manual are indicated below. Reprints of this manual containing minor corrections and updates may have the same printing date. Revised editions are identified by a new printing date. A revised edition incorporates all new or corrected material since the previous printing date. Changes to the manual occurring between revisions are covered by change sheets shipped with the manual. Also, if the serial number prefix of your power supply is higher than those listed on the title page of this manual, then it may or may not include a change sheet. That is because even though the higher serial number prefix indicates a design change, the change may not affect the content of the manual.
Edition 1 July, 2001
© Copyright 2001 Agilent Technologies, Inc.
This document contains proprietary information protected by copyright. All rights are reserved. No part of this document may be photocopied, reproduced, or translated into another language without the prior consent of Agilent Technologies,
Inc. The information contained in this document is subject to change without notice.
4
TABLE OF CONTENTS
5
6
1
Introduction
Scope
This manual contains information for troubleshooting the Agilent Models 6010A, 6011A, 6012B, or 6015A 1000W
Autoranging Power Supply to the component level. Wherever applicable, the service instructions given in this manual refer to pertinent information provided in the Operation Manual. Both manuals cover Agilent Models 6010A/11A/12B/15A; differences between models are described as required.
The following information is contained in this manual.
Calibration and Verification
Contains calibration procedures for Agilent Models 6010A/11A/12B/15A. Also contains verification procedures that check the operation of the supplies to ensure they meet the specifications of Chapter 1 in the Operating Manual.
Troubleshooting
Contains troubleshooting procedures to isolate a malfunction to a defective component on the main circuit board or to a defective assembly (front panel, power transformer, or cable assembly). Board and assembly level removal and replacement procedures are also given in this section.
Principles of Operation
Provides block diagram level descriptions of the supply's circuits. The regulation and control, protection, input power, dc power conversion and output circuits are described. These descriptions are intended as an aid in troubleshooting.
Replaceable Parts
Provides a listing of replaceable parts for all electronic components and mechanical assemblies for Agilent Models
6010A/11A/12B/15A.
Circuit Diagrams
Contains functional schematics and component location diagrams for all Agilent 6010A/11A/12B/15A circuits. The names that appear on the functional schematics also appear on the block diagrams in Chapter 4. Thus, the descriptions in Chapter 4 can be correlated with both the block diagrams and the schematics.
Safety Considerations
This product is a Safety Class 1 instrument, which means that it is provided with a protective earth terminal. Refer to the
Safety Summary page at the beginning of this manual for a summary of general safety information. Safety information for specific procedures is located at appropriate places in the manual.
7
Manual Revisions
Agilent Technologies instruments are identified by a 10-digit serial number. The format is described as follows: first two letters indicate the country of manufacture. The next four digits are a code that identify either the date of manufacture or of a significant design change. The last four digits are a sequential number assigned to each instrument.
Item Description
US The first two letters indicates the country of manufacture, where US = USA; MY = Malaysia.
3648 This is a code that identifies either the date of manufacture or the date of a significant design change.
0101 The last four digits are a unique number assigned to each power supply.
If the serial number prefix on your unit differs from that shown on the title page of this manual, a yellow Manual Change sheet may be supplied with the manual. It defines the differences between your unit and the unit described in this manual.
The yellow change sheet may also contain information for correcting errors in the manual.
Note that because not all changes to the product require changes to the manual, there may be no update information required for your version of the supply.
Older serial number formats used with these instruments had a two-part serial number, i.e. 2701A-00101. This manual also applies to instruments with these older serial number formats. Refer to Appendix B for backdating information.
8
2
Calibration and Verification
Introduction
This section provides test and calibration procedures. The operation-verification tests comprise a short procedure to verify that the unit is performing properly, without testing all specified parameters. After troubleshooting and repair of a defective power supply you can usually verify proper operation with the turn-on checkout procedure in the Operating Manual.
Repairs to the A1 main board and the A2 control board can involve circuits which, although functional, may prevent the unit from performing within specified limits. So, after A1 or A2 board repair, decide if recalibration and operation verification tests are needed according to the faults you discover. Use the calibration procedure both to check repairs and for regular maintenance.
When verifying the performance of this instrument as described in this chapter, check only those specifications for which a performance test procedure is included.
Test Equipment Required
Table 2-1 lists the equipment required to perform the tests of this section. You can separately identify the equipment for performance tests, calibration and troubleshooting using the USE column of the table.
Operation Verification Tests
To assure that the unit is performing properly, without testing all specified parameters, first perform the turn-on checkout procedure in the Operating Manual. Then perform the following performance tests, in this section.
CV Load Effect
CC Load Effect
Calibration Procedure
Calibrate the unit twice per year and when required during repair. The following calibration procedures which follow should be performed in the sequence given. Table 2-2 describes in detail these calibration procedures and lists the expected results to which each adjustment must be made.
Note:
Some of the calibration procedures for this instrument can be performed independently, and some procedures must be performed together and/or in a prescribed order. If a procedure contains no references to other procedures, you may assume that it can be performed independently.
To return a serviced unit to specifications as quickly as possible with minimal calibration, the technician need only perform calibration procedures that affect the repaired circuit. Table 2-3 lists various power supply circuits with calibration procedures that should be performed after those circuits are serviced.
9
TYPE
Oscilloscope
Isolation Transformer 100VA 4KVA minimum
RMS Voltmeter
Table 2-1. Test Equipment Required
REQUIRED CHARACTERISTICS
Sensitivity: 1mV
Bandwidth: 20MHz & 100MHz
Input: differential, 50 Ω & 10MΩ
P,T
USE
T
P
RECOMMENDED MODEL
Agilent 1740A
Agilent 3400A
Logic Pulser
Multimeter
True rms, 10MHz bandwidth
Sensitivity: 1 mV
Accuracy: 5%
4.5 to 5.5Vdc @ 35mA
Resolution: 100nV
Accuracy: 0.0035%, 6½ digit
T
P,A,T
Agilent 546A
Agilent 3456A
CC PARD Test
Current Probe
Electronic Load*
CC PARD Test
Resistive Load
No saturation at:
6010A 20Adc
6011A 100Adc
6012B 51Adc
6015A 51Adc
Bandwidth: 20Hz to 20MHz
Power range: 1000 watts
Open and short switches
6010A
Voltage range: 200Vdc
Current range: 20Adc
6011A
Voltage range: 30Vdc
Current range: 120Adc
6012B
Voltage range: 65Vdc
Current range: 55Adc
6015A
Voltage range: 200Vdc
Current range: 5Adc
Value:
6010A
6011A
3.5 ohms >1000W
Accuracy: 1%
0.058 ohms >1000W
Accuracy 1%
6012B
0.4 ohms >1000W
Accuracy: 1%
Rheostat or Resistor Bank
P
P,A
P,A
Tektronix P6303
Probe/AM503 Amp/
TM500 Power Module
Transistor Devices Model
DLP 130-50-2500
DLR-400-15-2500
DLP 50-150-3000
DLP 130-50-2500
DLR-400-15-2500
10
(6015A)
Resistors
TYPE
Load Resistors
Current-Monitoring
Calibration and Test
Resistors
Terminating
Resistors (4)
Blocking
Capacitors (2)
Common-Mode
Toroidal Core
DC Power Supply
Table 2-1. Test Equipment Required (continued)
REQUIRED CHARACTERISTICS
40 Ω, ±1%, 1000W
250 Ω, ±1%, 1000W
Value:
6010A
100mV @ 10A (10m Ω must be capable of 20Amps)
Accuracy: 0.02% **
TC: 10ppm/ °C
6011A
50mV @100A (0.5m
Ω)
Accuracy: 0.05% **
TC: 30ppm/ °C
6012B
50mV @ 50A (1.0m
Ω)
Accuracy: 0.02% **
TC: 30ppm/ °C
6015A
0.1
Ω, 15A, ±0.04%**
Value: 50 Ω, 5%, 40W
2K Ω, 0.01%, ¼W
Value: 50 Ω ± 5%, noninductive P
USE
P,A
P,A
A,T
RECOMMENDED MODEL
Value: 0.01
µF, 600Vdc
≥3.7µH/turn 2
≅23mm I.D
.
Voltage range: 0-60Vdc
Current range: 0-50Adc
P
P
T,P
Ferrox-Cube
500T600-3C8,
Agilent 9170-0061
Agilent 6012B
Variable Voltage
Transformer
(autotransformer)
Range greater than -13% to +6% of nominal input AC voltage
4KVA
P,A
P = performance testing A = calibration adjustments T = troubleshooting
* Resistors may be substituted for test where an electronic load is not available.
** Less accurate, and less expensive, current-monitor resistors can be used, but the accuracy to which current programming and current meter reading can be checked must be reduced accordingly.
11
Initial Setup
Maintenance described herein is performed with power supplied to the instrument, and protective covers removed. Such maintenance should be performed only by service trained personnel who are aware of the hazards involved (for example, fire and electrical shock). Turn off ac power when making or removing connections to the power supply. Where maintenance can be performed without power applied, the power
should be removed.
a. Unplug the line cable and remove the top cover by removing the two screws.
b. Slide the cover to the rear.
c. Plug a control board test connector A2P7 onto the A2J7 card-edge fingers.
d. Turn OVERVOLTAGE ADJUST control A3R97 fully clockwise.
e. Disconnect all loads from output terminals.
f. Connect power supply for local sensing, and ensure that MODE switches are set as shown below.
g. Reconnect the line cable and turn on ac power.
h. Allow unit to warm up for 30 minutes.
i. At the beginning of each calibration procedure, the power supply should be in its power-off state, with no external circuitry connected except as instructed.
j. The POWER LIMIT adjustment (A2R25) must be adjusted at least coarsely before many of the calibration procedures can be performed. If you have no reason to suspect that the Power Limit circuit is out of adjustment, do not disturb its setting. Otherwise, center A2R25 before you begin to calibrate the power supply.
TEST
Meter F/S
Adjust.
Resistance
Programming
F/S
Adjust.
Table 2-2. Calibration Procedure
TESTED
VARIABLE
Meter Ref.
Voltage
TEST POINTS
6010A, 6012B
A2J3 pin 7 ( + )
A2J3 pin 10 (-)
6011A, 6015A
A2J3 pin 6 ( + )
A2J3 pin 9 (-)
Prog. Voltage VP ( + )
P ( - )
TEST SEQUENCE AND ADJUSTMENTS a. Connect DVM across test points and turn on ac power.
b. Adjust A2R24 to obtain the voltage range specified in the results.
a. Connect a 2K Ω 0.01%, ¼W resistor and
DVM between test points.
b. Set MODE switch as in Figure 2-1 and turn on ac power.
c. Adjust A2R23 to obtain the voltage range specified in the results.
EXPECTED
RESULTS
0.5V ± 50µV
2.5V ±4mV
12
TEST
V-MON
Zero
Adjust.
Common
Mode
Adjust.
I-MON
Zero
Adjust.
I-MON
F / S
Adjust.
TESTED
VARIABLE
V-MON
Residual
Output
Voltage
VM( + )
I-MON
I-MON
Table 2-2. Calibration Procedure (continued)
TEST POINTS
VM ( + )
M ( - )
VM ( + )
M ( - )
IM ( + )
M (-)
IM ( + )
M ( - )
Rm ( + )
Rm ( - )
TEST SEQUENCE AND ADJUSTMENTS a. Set voltage and current controls to minimum settings.
b. Disable power supply as in Initial Setup step i.
c. Short circuit output terminals and connect the
DVM between test points. Turn on power supply.
d. Adjust V-MON Zero trim pot A2R22 to voltage range specified in the results.
a. Set voltage and current controls to minimum and short the unit's sense terminals
( + S & - S).
b. Attach the DVM across test points and disable power supply as Initial Setup step i.
c. Turn on ac power and record the initial voltage (IR) with DVM across test points.
d. Remove the local sensing straps and connect a
1Vdc power supply between - S( + ) and –
OUT( - ). See Figure 2-1.
e. Adjust A2R21 to the voltage range specified.
f. Remove the 1V supply and replace jumpers.
a. Set voltage and current controls to minimum.
b. Disable power supply as in Initial Setup step I and short output terminals. Turn on ac power.
c. Connect DVM across test points and adjust
I-MON Zero trim pot A2R8 as shown in results.
a. Perform I-MON Zero Adjust before proceeding .
b. Connect a 0.010
Ω (6010A), 0.0005Ω (6011A)
0.0001
Ω (6012B), current monitoring resistor
Rm across the output terminals.
c. Turn on ac power and using the “Display
Setting”, set current control to 17A (6010A),
120A (6011A), 50A (6012B), 5A (6015A), and voltage control to 5V.
d. Connect DVM across test points and take an initial reading (IR).
e. Connect DVM across Rm monitoring terminals and adjust A2R9 as shown in the results.
EXPECTED
RESULTS
0 ± 80µV
IR* ±80µV
IR* ±40µV
(6015A)
0 ± 100µV
IR*
0.034 IR* ±
33.5
µV (6010A,
6015A)
0.012 IR*
±40µV (6011A,
6012B)
*IR = Initial Reading
13
TEST
Power
Limit
Adjust.
TESTED
VARIABLE
V(OUT)
I(OUT)
Table 2-2. Calibration Procedure (continued)
TEST POINTS TEST SEQUENCE AND ADJUSTMENTS a. Perform I-MON F/S Adjust before proceeding.
b. Connect the unit to the ac power line via a variable transformer. Set input power rail to
240Vdc; DVM ( + ) on rear of A1R3 and
DVM (-) to rear of A1R1. Note that power rail must be maintained at 240Vdc during calibration.
WARNING
The inner cover must be removed to connect the voltmeter. Disconnect the power line and wait two minutes before connecting or disconnecting the voltmeter.
c. Connect a 3.8
Ω (6010A), 0.066Ω (6011A),
0.44
Ω (6012B), 40Ω (6015A) resistor or an electronic load across the unit's output terminals.
d. Set the load for 18A (6010A), 120A (6011A),
50A (6012B), 5A (6015A), in CC mode, and turn A2R25 (lower knee) fully counter clockwise.
e. Turn on power supply and set voltage at 65V
(6010A), 8V (6011A), 22V (6012B), 204V
(6015A), and current at 17.5A (6010A), 121A
(6011A), 51A (6012B), 5.1A (6015A), using
DISPLAY SETTINGS.
f. Turn A2R25 clockwise until CV LED lights.
Output should be 65V ± 0.6V (6010A), 8
±0.08V (6011A), 22 ±0.2V (6012B), 204V
(6015A), and 17A (6010A), 120A (6011A)
51A (6012B), 5.1A (5015A) in CV mode.
g. Turn off ac power and replace the 3.8
Ω
(6010A), 0.066
Ω (6011A), 0.44Ω (6012B),
40 Ω (6015A), resistor with a 38Ω (6010A),
0.36
Ω (6011A), 3.3Ω (6012B), 250Ω
(6015A), resistor or reset electronic load for
5.5A (6010A), 55A (6011A), 18.2A (6012B) in CC mode.
EXPECTED
RESULTS
14
TEST
Power Limit
Adjust
(continued)
TESTED
VARIABLE
Table 2-2. Calibration Procedure (continued)
TEST POINTS TEST SEQUENCE AND ADJUSTMENTS h. Turn A2R26 (upper knee) fully counter clockwise. Turn on the supply and set voltage at 200V (6010A), 20V (6011A), 60V
(6012B), 500V (6015A), and current at 5.25A
(6010A), 56A (6011A), 19A (6012B) 2.25A
(6015A), using DISPLAY SETTINGS.
i. Turn A2R26 (upper knee) clockwise until CV
LED lights. Output should be 200 ± 2V
(6010A), 20 ±0.5V (6011A), 60 ±0.4V
(6012B), and 5.25A (6010A), 55A (6011A),
18.2A (6012B), 2.2A (6015A), in CV mode.
EXPECTED
RESULTS
Figure 2-1. Common Mode Setup
15
Table 2-3. Guide to Recalibration After Repair
Printed Circuit
Board
A1 Main Board
A1 Main Board
A5 Diode Board
Block Name Circuit Within Ref.
Designator
R11
R13 (6011A)
T1, T2
CR4
CR5, CR1 (6011A)
All
Perform These
Procedures*
3 then 4
5
5
A2 Control Board
A2 Control Board
A2 Control Board
A2 Control Board
Constant Voltage
(CV) Circuit
Constant Voltage
(CV) Circuit
Constant Current
(CC) Circuit
Power Limit
Comparator
All Except Current
Source
Current Source All
All
All
1 then 2
6
3 then 4
5
A2 Control Board Bias Power Supplies ± 15V Supplies All All
A2 Control Board U7, R84, R85, R24 7
1. V-MON Zero Calibration
2. Common-Mode Calibration
3. I-MON Zero Calibration
* Code To Calibration Procedure To Be Performed
4. I-MON Full Scale (F/S) Calibration
5. Power Limit Calibration
6. Resistance Programming Full Scale (F/S) Calibration
7. Meter Full Scale (F/S) Calibration
Performance Tests
The following paragraphs provide test procedures for verifying the unit's compliance with the specifications of Table 1-1 in the Operating Manual. Please refer to CALIBRATION PROCEDURE or TROUBLESHOOTING if you observe out-of-specification performance.
Measurement Techniques
Setup For All Tests. Measure the DC output voltage directly at the + S and - S terminals. Connect unit for local sensing, and ensure that MODE switches are set as shown below. Select an adequate wire gauge for load leads using the procedures given in the Operating Manual for connecting the load.
Electronic Load. The test and calibration procedures use an electronic load to test the unit quickly and accurately. If an electronic load is not available, you may substitute:
3.5
Ω 1000W load resistor (6010A)
0.4
Ω 1000W load resistor (6011A)
0.4
Ω 1000W load resistor (6012B)
250 Ω 1000W load resistor (6015A)
16
for the electronic load in the following tests:
CV Source Effect (Line Regulation)
CC Load Effect (Load Regulation)
Temperature Coefficient (6015A)
Drift (stability ) (6015A)
You may substitute:
40 Ω 1000W load resistor (6010A)
0.058
Ω 1000W load resistor (6011A)
3.4
Ω 1000W load resistor (6012B)
40 Ω 1000W load resistor (6015A) in these tests:
CV Load Effect (Load Regulation)
CV PARD (Ripple and Noise)
CC Source Effect (Line Regulation)
CC PARD (Ripple and Noise)
The substitution of the load resistor requires adding a load switch to open and short the load in the CC or CV load regulation tests. The load transient recovery time test procedure is not amenable to modification for use with load resistors.
An electronic load is considerably easier to use than a load resistor. It eliminates the need for connecting resistors or rheostats in parallel to handle the power, it is much more stable than a carbon-pile load, and it makes easy work of switching between load conditions as is required for the load regulation and load transient-response tests.
Current-Monitoring Resistor Rm. To eliminate output current measurement error caused by voltage drops in the leads and connections, connect the current-monitoring resistor between -OUT and the load as a four-terminal device. Figure 2-2 shows correct connections. Select a resistor with stable characteristics:
0.010, 0.02% accuracy, 30 ppm/ °C (6010A)
0.0005
Ω, 0.05% accuracy, 30ppm/°C (6011A)
0.0010
Ω, 0.05% accuracy, 30ppm/°C (6012B)
0.010
Ω, 0.02% accuracy, 30ppm/°C (6015A) or lower temperature coefficient and a current rating of:
17A (6010A).
120A (6011A).
50A (6012B)
>5A (6015A)
Figure 2-2. Current-Monitoring Resistor Setup
17
Constant Voltage (CV) Tests
CV Setup. If more than one meter or a meter and an oscilloscope are used, connect each to the + S and - S terminals by a separate pair of leads to avoid mutual coupling effects. Connect only to + S and -S (except for peak-to-peak PARD) because the unit regulates the output voltage between + S and - S, not between + OUT and -OUT. Use coaxial cable or shielded 2-wire cable to avoid pickup on test leads. For all CV tests set the output current at full output to assure CV operation.
Load Effect (Load Regulation). Constant-voltage load effect is the change in dc output voltage (Eo) resulting from a load-resistance change from open-circuit to full-load. Full-load is the resistance which draws the maximum rated output current at voltage Eo. Proceed as follows: a. Connect the test equipment as shown in Figure 2-3. Operate the load in constant resistance mode (Amps/Volt) and set resistance to maximum.
b. Turn the unit's power-on, and turn up current setting to full output.
c. Turn up output voltage to:
60Vdc (6010A)
7.0Vdc (6011A)
20.0Vdc (6012B)
200Vdc (6015A) as read on the digital voltmeter.
Figure 2-3. Basic Test Setup d. Reduce the resistance of the load to draw an output current of:
17.0Adc (6030A)
120Adc (6011A)
50Adc (6012B)
5.0Adc (6015A)
Check that the unit's CV LED remains lighted.
e. Record the output voltage at the digital voltmeter.
f. Open-circuit the load.
18
g. When the reading settles, record the output voltage again. Check that the two recorded readings differ no more than:
± 0.011Vdc (6010A)
± 0.0037Vdc (6011A)
± 0.007Vdc (6012B)
± 0.033Vdc (6015A)
Source Effect (Line Regulation). Source effect is the change in dc output voltage resulting from a change in ac input voltage from the minimum to the maximum value as specified in Input Power Requirements in the Specifications Table, in the Operating Manual. Proceed as follows: a. Connect the test equipment as shown in Figure 2-3. Operate the load in constant resistance mode (Amps/Volt) and set resistance to maximum.
b. Connect the unit to the ac power line through a variable autotransformer which is set for low line voltage (104Vac for
120Vac).
c. Turn the unit's power-on, and turn up current setting to full output.
d. Turn up output voltage to:
60.0Vdc (6010A)
20.0Vdc (6011A)
20.0Vdc (6012B)
500Vdc (6015A) as read on the digital voltmeter.
e. Reduce the resistance of the load to draw an output current of:
17.0Adc (6010A)
50Adc (6011A)
50Adc (6012B)
2.0Adc (6015A)
Check that the unit's CV LED remains lighted.
f. Record the output voltage at the digital voltmeter.
g. Adjust autotransformer to the maximum for your line voltage.
h. When the reading settles record the output voltage again. Check that the two recorded readings differ no more than:
± 0.011Vdc (6010A)
± 0.004Vdc (6011A)
± 0.005Vdc (6012B)
± 0.063Vdc (6015A)
PARD (Ripple And Noise). Periodic and random deviations (PARD) in the unit's output-ripple and noise-combine to produce a residual ac voltage superimposed on the dc output voltage. Constant-voltage PARD is specified as the root-mean-square (rms) or peak-to-peak (pp) output voltage in a frequency range of 20Hz to 20MHz (10MHz, 6010A).
RMS Measurement Procedure. Figure 2-4 shows the interconnections of equipment to measure PARD in Vrms. To ensure that there is no voltage difference between the voltmeter's case and the unit's case, connect both to the same ac power outlet or check that the two ac power outlets used have the same earth-ground connection.
Use the common-mode choke as shown to reduce ground-loop currents from interfering with measurement. Reduce noise pickup on the test leads by using 50 Ω coaxial cable, and wind it five turns through the magnetic core to form the common-mode choke. Proceed as follows: a. Connect the test equipment as shown in Figure 2-4. Operate the load in constant resistance mode (Amps/Volt) and set resistance to maximum.
b. Turn the unit's power-on, and turn up current setting to full output.
c. Turn up output voltage to:
60Vdc (6010A)
7Vdc (6011A)
60Vdc (6012B)
200Vdc (6015A)
19
d. Reduce the resistance of the load to draw an output current of:
17.0Adc (6010A)
120Adc (6011A)
17.5Adc (6012B)
5.0Adc (6015A)
Check that the unit's CV LED remains lighted.
e. Check that the rms noise voltage at the true rms voltmeter is no more than:
22mV rms (6010A)
8.0mV rms (6011A)
8.0mV rms (6012B)
50mV rms (6015A)
Figure 2-4. RMS Measurement Test Setup, CV PARD Test
Peak Measurement Procedure. Figure 2-5 shows the interconnections of equipment to measure PARD in Vpp. The equipment grounding and power connection instructions of PARD rms test apply to this setup also. Connect the oscilloscope to the + OUT and - OUT terminals through 0.01
µF blocking capacitors to protect the oscilloscope's input from the unit's output voltage. To reduce common-mode noise pickup, set up the oscilloscope for a differential, two-channel voltage measurement. To reduce normal-mode noise pickup, use twisted, 1 meter or shorter, 50 Ω coaxial cables with shields connected to the oscilloscope case and to each other at the other ends. Proceed as follows: a. Connect the test equipment as shown in Figure 2-5. Operate the load in constant resistance mode (Amps/Volt) and set resistance to maximum.
b. Turn the unit's power-on, and turn up current setting to full output.
c. Turn up output voltage to:
60Vdc (6010A)
7.0Vdc (6011A)
20
60Vdc (6012B)
200Vdc (6015A) d. Reduce the resistance of the load to draw an output current of:
17.0Adc (6010A)
120Adc (6011A)
17.5Adc (6012B)
5.0Adc (6015A)
Check that the unit's CV LED remains lighted.
e. Set the oscilloscope's input impedance to 50 Ω and bandwidth to 20MHz. Adjust the controls to show the 20KHz and higher frequency output-noise waveform of Figure 2-6.
f. Check that the peak-to-peak is no more than:
50mV (6010A)
50mV (6011A)
50mV (6012B)
160mV (6015A)
Figure 2-5. Peak-To-Peak Measurement Test Setup, CV PARD Test
Load Transient Recovery Time. Specified for CV operation only; load transient recovery time is the time for the output voltage to return to within a specified band around its set voltage following a step change in load.
Use the equipment setup of Figure 2-3 to display output voltage transients while switching the load between 10% with the output set at:
60Vdc (6010A)
7Vdc (6011A)
20Vdc (6012B)
(6015A)
21
6010A 6011A
NOT APPLICABLE
6012B
Figure 2-6. 20KHz Noise, CV Peak-to-Peak PARD
6015A
Proceed as follows: a. Connect the test equipment as shown in Figure 2-3. Operate the load in constant-current mode and set for minimum current.
b. Turn the unit's power-on, and turn up current setting to full output.
c. Turn up output voltage to:
60Vdc (6010A)
7.0Vdc (6011A)
20.0Vdc (6012B)
200Vdc (6015A) as read on the digital voltmeter.
d. Set the load to vary the load current between:
15 and 17Adc (6010A)
108 and 120Adc (6011A)
45 and 50Adc (6012B)
4.5 and 5.0Adc (6015A) at a 30Hz rate for the 10% RECOVERY TEST.
e. Set the oscilloscope for ac coupling, internal sync and lock on either the positive or negative load transient.
f. Adjust the oscilloscope to display transients as in Figure 2-7.
22
g. Check that the pulse width of the transient pulse is no more than:
150mV/2ms (6010A)
100mV/2ms (6011A)
100mV/2ms (6012B)
200mV/5ms (6015A)
6010A 6011A
6012B
Figure 2-7. Load Transient Recovery Waveform
6015A
Temperature Coefficient. Temperature coefficient (TC) is the change in output voltage for each °C change in ambient temperature with constant ac line voltage, constant output voltage setting and constant load resistance. Measure temperature coefficient by placing the unit in an oven, varying the temperature over a range within the unit's operating temperature range, and measuring the change in output voltage. Use a large, forced air oven for even temperature distribution. Leave the unit at each temperature measurement for half hour to ensure stability in the measured variable. Measure the output voltage with a stable DVM located outside the oven so voltmeter drift does not affect the measurement accuracy. To measure offset TC, repeat the procedure with output voltage set to 0.10Vdc.
Proceed as follows: a. Connect DVM between +S and -S.
b. Place power supply in oven, and set temperature to 30 °C.
c. Turn the unit's power-on and turn up current setting to full output.
d. Turn up output voltage to the following:
23
200Vdc (6010A)
20.0Vdc (6011A)
60.0Vdc (6012B)
500Vdc (6015A) as read on the DVM.
e. After 30 minutes stabilization, record the temperature to the nearest 0.1
°C. Record the output voltage on the DVM.
f. Set oven temperature to 50 °C.
g. After 30 minutes stabilization, record the temperature to the nearest 0.1
°C. Record output voltage.
h. Check that the magnitude of the output voltage change is no greater than
620mV.(6010A)
80mV (6011A)
176mV (6012B)
1.6V (6015A)
Drift (Stability). Drift is the change in output voltage beginning after a 30-minute warm-up during 8 hours operation with constant ac input line voltage, constant load resistance and constant ambient temperature. Use a DVM and record the output at intervals, or use a strip-chart recorder to provide a continuous record. Check that the DVM's or recorder's specified drift during the 8 hours will be no more than 0.001%. Place the unit in a location with constant air temperature preferably a large forced-air oven set to 30 °C and verify that the ambient temperature does not change by monitoring with a thermometer near the unit.
Typically the drift during 30 minute warm-up exceeds the drift during the 8-hour test. To measure offset drift, repeat the procedure with output voltage set to 0.10Vdc.
a. Connect DVM between + S and - S.
b. Turn the unit's power-on and turn up current setting to full output.
c. Turn up output voltage to:
200Vdc (6010A)
20Vdc (6011A)
60.0Vdc (6012B)
500Vdc (6015A) as read on the digital voltmeter.
d. After a 30 minute warmup, note reading on DVM.
e. The output voltage should not deviate more than
77mV (6010A)
9mV (6011A)
23mV (6012B)
190mV (6015A) from the reading obtained in step d over a period of 8 hours.
Constant Current (CC) Tests
CC Setup. Constant-current tests are analogous to constant-voltage tests, with the unit's output short circuited and the voltage set to full output to assure CC operation. Follow the general setup instructions on Page 16.
Load Effect (Load Regulation). Constant current load effect is the change in dc output current (Io) resulting from a load-resistance change from short-circuit to full-load, or full-load to short-circuit. Full-load is the resistance which develops the maximum rated output voltage at current Io. Proceed as follows: a. Connect the test equipment as shown in Figure 2-3. Operate the load in constant resistance mode (Amps/Volt) and set resistance to minimum.
b. Turn the unit's power-on, and turn up voltage setting to full output.
c. Turn up output current to:
5.0Adc (0.050Vdc across Rm) (6010A) Check that the AMPS display reads about 5 amps.
50Adc (0.25Vdc across Rm) (6010A) Check that the AMPS display reads about 50 amps.
24
17.5Adc (0.0175Vdc across Rm) (6012B) Check that the AMPS display reads about 17.5 amps.
2Adc (0.20Vdc across Rm) (6015A) Check that the AMPS display reads about 2 amps.
d. Increase the load resistance until the output voltage at +S and -S increases to:
200Vdc (6010A)
20Vdc (6011A)
60Vdc (6012B)
500Vdc (6035A)
Check that the CC LED is lighted and AMPS display still reads ≈ current setting.
e. Record voltage across Rm.
f. Short circuit the load.
g. When the reading settles ( ≈ 10s), record the voltage across Rm again. Check that the two recorded readings differ no more than:
0.105mVdc (6010A)
± 0.010mVdc (6011A)
± 0.0118mVdc (6012B)
± 3.4mVdc (6015A) h. Disconnect the short across the load.
Source Effect (Line Regulation). Constant current source effect is the change in dc output current resulting from a change in ac input voltage from the minimum to the maximum values listed in the Specifications Table in the Operating
Manual. Proceed as follows: a. Connect the test equipment as shown in Figure 2-3. Operate the load in constant resistance mode (Amps/Volt) and set resistance to minimum.
b. Connect the unit to the ac power line through a variable autotransformer set for low line voltage (e.g. 104Vac for
120Vac).
c. Switch the unit's power-on and turn up output voltage setting to full output.
d. Turn up output current to:
17.0Adc (6010A)
120Adc (6011A)
50Adc (6012B)
5.0Adc (6015A)
Check that the AMPS display reads ≈ current setting.
e. Increase the load resistance until the output voltage between + S and - S increases to:
60Vdc (6010A)
7.0Vdc (6011A)
20.0Vdc (6012B)
200Vdc (6035A)
Check that the CC LED is still on and the AMPS display still reads ≈ current setting.
f. Record the voltage across Rm.
g. Adjust autotransformer to the maximum for your line voltage.
h. When the reading settles record the voltage across Rm again. Check that the two recorded readings differ no more than:
± 0.067mVdc (6010A)
± 0.018mVdc (6011A)
± 0.015mVdc (6011A)
± 18mVdc (6015A)
PARD Ripple And Noise. Periodic and random deviations (PARD) in the unit's output (ripple and noise) combine to produce a residual ac current as well as an ac voltage super-imposed on the dc output. The ac voltage is measured as constant-voltage PARD. Constant-current PARD is specified as the root-mean-square (rms) output current in a frequency range 20Hz to 20MHz with the unit in CC operation. To avoid incorrect measurements, with the unit in CC operation, caused by the impedance of the electronic load at noise frequencies, use a:
0.4
Ω (6010A)
0.058
Ω (6011A)
0.4
Ω (6012B)
40 Ω (6015A)
25
load resistor that is capable of safely dissipating 1000 watts. Proceed as follows: a. Connect the test equipment as shown in Figure 2-8.
b. Switch the unit's power-on and turn the output voltage all the way up.
c. Turn up output current to:
17.0Adc (6010A)
120Adc (6011A)
50Adc (6012B)
5.0Adc (6015A)
Check that the unit's CC LED remains lighted.
d. Check that the rms noise current measured by the current probe and rms voltmeter is no more than:
15mA rms (6010A).
120mA rms (6011A)
25mA rms (6012B)
50mA rms (6015A)
Figure 2-8. CC PARD Test Setup
26
Troubleshooting
Maintenance described herein is performed with power supplied to the instrument, and protective covers removed. Such maintenance should be performed only by service-trained personnel who are aware of the
hazards involved (for example, fire and electrical shock). Where maintenance can be performed without
power applied, the power should be removed.
3
Introduction
Before attempting to troubleshoot this instrument, ensure that the fault is with the instrument itself and not with an associated circuit. The performance test enables this to be determined without having to remove the covers from the supply.
The most important aspect of troubleshooting is the formulation of a logical approach to locating the source of trouble. A good understanding of the principles of operation is particularly helpful, and it is recommended that Chapter 4 of this manual be reviewed before attempting to troubleshoot the unit. Often the user will then be able to isolate a problem simply by using the operating controls and indicators. Once the principles of operation are understood, refer to the following paragraphs.
Table 2-1 lists the test equipment for troubleshooting. Chapter 6 contains schematic diagrams and information concerning the voltage levels and waveforms at many of the important test points. Most of the test points used for troubleshooting the supply are located on the control board test "fingers", which are accessible close to the top of the board. See Table 3-1.
If a component is found to be defective, replace it and re-conduct the performance test. When a component is replaced, refer to Calibration Procedure (Chapter 2). It may be necessary to perform one or more of the adjustment procedures after a component is replaced.
Initial Troubleshooting Procedures
If a problem occurs, follow the steps below in sequence: a. Check that input power is available, and check the power cord and rear-panel circuit breaker.
b. Check that the settings of mode switch A2S1 are correct for the desired mode of operation. (See Operating Manual).
c. Check that all connections to the power supply are secure and that circuits between the supply and external devices are not interrupted.
d. If the power supply fails turn-on self-test or gives any other indication of malfunction, remove the unit from the operating system before proceeding with further testing.
Some circuits on the power mesh are connected directly to the ac power line. Exercise extreme caution when working on energized circuits. Energize the supply through an isolation transformer to avoid
shorting ac energized circuits through the test instrument's input leads. The isolation transformer must
have a power rating of at least 4KVA. During work on energized circuits, the safest practice is to
disconnect power, make or change the test connections, and then re-apply power.
Make certain that the supply's ground terminal (┴) is securely connected to an earth ground before applying
power. Failure to do so will cause a potential shock hazard that could result in personal injury.
27
9
10
PIN NO.
Digital-Circuits Bias & Reference Voltages
24
22
+5V
+ 20V(5V UNREG)
14
6
SIGNAL NAME
2.5V ref
0.5V ref
Table 3-1. Control Board Test Connector, A2J7
Vdc WAVEFORM/CONDITIONS
5.0
20.0
2.50
0.50
with 120Hz & 40KHz ripple
Analog-Circuits Bias Voltages
2
21
+ 15V
- 15V
15.0
-15.0
Status Signals
17
CV
16
CC
13
OV
11
DROPOUT
12
OT
TTL Lo
TTL Lo
TTL Hi
TTL Hi
TTL Hi if in CV operation if in CC operation if not OVP shutdown if ac mains okay if not overtemp shutdown
SOURCE
A2Q9 (emitter)
A1CR2, A1CR5
A2U7 (OUT)
A2R84,A2R85, A2R24
A2U11 (OUT)
A2U12 (OUT )
A2Q2 (collector)
A2Q1 (collector)
A2U15-13
A2U15-10
A4TS1,A5TS1
26
18
15
Control Signals
25 PWM OFF
PWM ON
Ip MONITOR
DOWN PROGRAM
7 OVP PROGRAM
19
PCLR
Commons & Current-Monitor
4 L COMMON
TTL Hi (6010A, 6015A)
1.2-3.0 (6011A, 6012B)
1/100 OVP (6010A)
1/10 OVP (6011A)
1/30 OVP (6012B)
1/100 OVP (6015A)
TTL Hi
10 µs TTL pulses, 20KHz
1.7
µs TTL pulses, 20KHz
A2U16-5
A2U15-1
½ sawtooth, 20KHz A2CR27 (cathode) while not down programming A2CR17, CR31(anode) e.g.: 2Vdc if OVP set to 200 voltage output (6010A) if +5V bias OK
A3R97 (wiper)
A2UQ11-4
M COMMON
I-TEST
0.0
≈0.0017 ( Iout) common return for all bias voltages, and status and control signals common return for 2.5V ref.
and 0.5V ref.
inboard-side monitoring res.
A1R11
AlR13 (6011A))
3
20
NOT USED
Ip-SET ≈0.9
A2R25 wiper
28
Electrostatic Protection
The following caution outlines important precautions which should be observed when working with static sensitive components in the power supply.
This instrument uses components which can be damaged by static charge. Most semiconductors can suffer serious performance degradation as a result of static charges, even though complete failure may not occur. The following precautions should be observed when handling static-sensitive devices.
a. Always turn power off before removing or installing printed-circuit boards.
b. Always stored or transport static-sensitive devices (all semiconductors and thin-film devices) in conductive material.
Attach warning labels to the container or bag enclosing the device.
c. Handle static-sensitive devices only at static-free work stations. These work stations should include special conductive work surfaces (such as Agilent Part No. 9300-0797) grounded through a one-megohm resistor. Note that metal table tops and highly conductive carbon-impregnated plastic surfaces are too conductive; they can act as large capacitors and shunt charges too quickly. The work surfaces should have distributed resistance of between 10 6 and 10 l2 Ω per square.
d. Ground all conductive equipment or devices that may come in contact with static-sensitive devices or subassemblies containing same.
e. Where direct grounding of objects in the work area is impractical, a static neutralizer should be used (ionized air blower directed at work). Note that this method is considerably less effective than direct grounding and provides less protection for static-sensitive devices.
f. While working with equipment on which no point exceeds 500 volts, use a conductive wrist strap in contact with skin.
The wrist strap should be connected to ground through a one-megohm resistor. A wrist strap with insulated cord and built-in resistor is recommended, such as 3M Co. No. 1066 (Agilent Part No. 9300-0969 (small) and 9300-0970
[large]).
Do not wear a conductive wrist strap when working with potentials in excess of 500 volts; the one-megohm resistor will provide insufficient current limiting for personal safety.
g. All grounding (device being repaired, test equipment, soldering iron, work surface, wrist strap, etc.) should be done to the same point.
h. Do not wear nylon clothing. Keep clothing of any kind from coming within 12 inches of static-sensitive devices.
i. Low-impedance test equipment (signal generators, logic pulsers, etc.) should be connected to static-sensitive inputs only while the components are powered.
j. Use a mildly activated rosin core solder (such as Alpha Metal Reliacor No. 1, Agilent Part No. 8090-0098) for repair.
The flux residue of this type of solder can be left on the printed circuit board. Generally, it is safer not to clean the printed-circuit board after repair. Do not use Freon or other types of spray cleaners. If necessary, the printed-circuit board can be brushed using a natural-bristle brush only. Do not use nylon-bristle or other synthetic-bristle brushes. Do not use high-velocity air blowers (unless ionized).
k. Keep the work area free of non-conductive objects such as Styrofoam-type cups, polystyrene foam, polyethylene bags, and plastic wrappers. Non-conductive devices that are necessary in the area can be kept from building up a static charge by spraying them with an anti-static chemical (Agilent Part No. 8500-3397).
l. Do not allow long hair to come in contact with static-sensitive assemblies.
m. Do not exceed the maximum rated voltages specified for the device.
Repair and Replacement
Repair and replacement of most components in the power supply require only standard techniques that should be apparent to the technician. The following paragraphs provide instructions for removing certain assemblies and components for which the procedure may not be obvious upon inspection.
29
To avoid the possibility of personal injury, remove the power supply from operation before opening the cabinet. Turn off ac power and disconnect the line cord, load, and remote sense leads before attempting
any repair or replacement.
When replacing any heatsink-mounted components except thermostat, smear a thin coating of heatsink compound between the component and heatsink. If a mica insulator is used, smear a thin coating of heatsink compound on both sides of the mica insulator.
Do not use any heatsink compound containing silicone, which can migrate and foul electrical contacts
elsewhere in the system. An organic zinc oxide cream, such as American Oil and Supply Company
Heatsink Compound #100, is recommended.
Most of thc attaching hardware in this unit is metric. The only non-metric (sometimes called English or inch) fittings are listed below. Be careful when both types of screws are removed not to get them mixed up.
a. Screws that secure the input and output capacitors to A1 main board and output bus.
b. Rear-panel circuit breaker.
c. Rear-panel ground binding post.
Top Outside Cover Removal. Remove the two top rear screws using a Size 2, Pozidriv screwdriver. A Phillips head screwdriver does not fully seat into Pozidriv screws and risks stripping the heads. Remove the top cover by sliding it to the rear and lifting at the front.
Bottom Cover Removal. Remove the handles from both sides of the unit and remove the bottom cover by sliding it to the rear. Use a Phillips head #2 screwdriver to remove the handle screws. You do not need to remove the unit's feet.
Inside Top Cover Removal. The unit includes an inside cover which secures the vertical board assemblies. Remove the inside cover for repair but not for calibration. Remove the nine mounting screws (Pozidriv, M4x7) – two in the left side, three on the right side, and four on top. Remove the inside cover by lifting at the front edge.
When installing the inside cover, insert it first at the right side. While holding it tilted up at the left, reach through the cutouts in the cover and fit the top tabs of the A2 control board into the mating slots in the cover. Then repeat the process for the A4 FET board, and the A5 Diode board. Press the inside cover down firmly while tightening screws that secure cover to chassis. Be careful when replacing printed-circuit assemblies and covers not to bend any boards or components.
A2 Control Board Removal
After removing the inside cover, unplug the W1 ribbon cable at the front edge of the A2 control board and unplug the W7 and W8 ribbon cables from the lower center of the A2 control board. Remove the A2 board by lifting first at the front edge and than pulling it up and out of the unit.
When installing the A2 board, insert it first at the rear of the unit. While holding it tilted up at the front, fit the A2TB1 terminal strip into the mating cutout in the rear panel. Then lower the A2 board's bottom tabs into the mating slots on the chassis. Re-install the W1, W7, and W8 ribbon cables.
A4 FET Board Removal
After removing the inside cover, remove the A4 FET board by lifting, using the large aluminum heatsink as a handle. One connector and one tab holds the A4 board at its bottom edge.
30
When installing the A4 power mesh board, lower it vertically, placing its tab into the A1 board slot first, align the connector and press in place.
A5 Diode Board Removal
After removing the cover, remove the A5 Diode board by first removing the two cover screws (Pozidriv) that hold heatsinks to the A1 board, then lift vertically to remove the A5 Diode board from the connector.
When installing the A5 Diode board, lower it into the mating connector on the A1 board, then install a screw between each heatsink and Al board.
A3 Front Panel Board Removal
Remove the A3 front panel board by first removing the entire front panel assembly. You do not need to remove the top cover. Follow this procedure: a. Remove the top plastic insert by prying up with a flat-blade screwdriver.
b. Remove the four front panel assembly mounting screws (Phillips 6-32) two on the top and two on the bottom.
c. Gently pull the front panel assembly away from the unit as far as permitted by the connecting cables.
d. Note the locations of the four power-wire connections to the power switch and then unplug the quick-connect plugs.
e. Unplug the W1 ribbon cable from connector A2J3 on the A2 control board.
f. Remove the A3 board from the front panel assembly by removing the six mounting screws (Pozidriv, M4x.7)
Install the A3 Board by reversing the steps above. Connect the power switch wires in the exact locations from which they were removed. See A1 Main Board Removal.
A1 Main Board Removal
Removing the A1 main board requires removing all the vertical boards except the A3 front panel board, and 17 A1 board mounting screws, four standoffs, and two bus-bar mounting screws. Component-access cutouts in the bottom inside cover allow unsoldering most A1 board components for repair without removing the A1 board.
Proceed as follows:
To remove the A1 board, proceed as follows: a. Remove the A2, A4, and A5 boards according to the above instructions.
b. Remove the AC power cord from the cooling fan and the four AC Input Power wires.
from
L6 (chassis)
RFI filter
Circuit breaker
L6 (chassis)
AC Input Wire color white white/gray white/brown/gray white c. Remove the following mounting screws:
2 (1 each) from the output bus bars
7 from the A1 board
4 from transformer AlT2
4 from transformer AlT3
2 from relay AlK1
4 inside-cover mounting posts 5/16 hex
Terminal Destination designator location
P
N
L left rear behind A1K1 behind A1K1
A1K1 front armature
31
d. Lift the A1 board up and toward the rear, then remove the wires from the front panel switch A3S1.
A1 Designator
A
B
C
D
Wire color white/gray gray white/brown/gray white/red/gray
A3S1 Position (Rear View)
Upper right
Upper left
Lower left
Lower right
REAR VIEW
A3 FRONT PANEL ASSEMBLY
S1
B-- | --A
C-- | --D
Install the A1 board by reversing the above steps. Be careful to follow the wire color code mentioned above.
Overall Troubleshooting Procedure
Perform the troubleshooting and repair procedures which follow only if you are trained in equipment service and are aware of the danger from fire and electrical-shock hazards. Some of the procedures include
removing the unit's protective covers which may expose you to potentially lethal electrical shock.
Whenever possible, make test connections and perform service with the power removed.
After performing the Initial Troubleshooting Procedures, focus on developing a logical approach to locating the source of the trouble. The underlying strategy for the troubleshooting procedures here is to guide you to the faulty circuit nodes which have improper signals or voltages. It relies on you to identify the particular functional circuit to troubleshoot from symptom tables and by understanding how the unit works. It then relies on you to discover the defective component or components which cause the faulty circuit nodes. So, read the BLOCK DIAGRAM overview in Chapter 4 and read the functional circuit descriptions for the circuits that you suspect may be defective. Then return to this section for help finding the faulty circuit nodes.
Table 3-1 gives the signals for each of the test points on the control board test connector. This connector is provided in service kit P/N 5060-2865. The measurements given here include bias and reference voltages as well as power supply status signals and waveform information. To troubleshoot the power supply the A4 power FET board and A2 control board can be raised out of the unit using extender boards and cables provided in service kit P/N 5060-2865.
The A4 power FET board should only be raised on its extender when using the Main Troubleshooting
Setup; NEVER when the unit is operated with its normal ( ≈ 300Vdc ) bus voltage. To do so can cause
damage to the unit and is a shock hazard.
Table 3-2 provides troubleshooting information based on the status of the PWM-ON and PWM-OFF signals which drive the PFETs. This table is used for no-output failures.
Tables 3-3 and 3-4 give measurements for the test points on the A3 front panel board and possible failure symptoms respectively.
Table 3-5 describes possible symptoms for overall performance failures of the power supply. It is necessary to have a properly working front panel before using this table.
Chapter 6 contains schematic diagrams and voltage levels, and component location diagrams to help you locate components and test points.
32
Make most voltage measurements (except DC-to-DC Converter and ac mains-connected circuits) referenced to the unit's output common. The output common is accessible at rear-panel M terminal. All voltages are ± 5% unless a range is given.
Using the Tables
Typically there will be two types of power supply failures; no-output and performance failures.
1. NO-OUTPUT FAILURE: Start with the TROUBLESHOOTING NO-OUTPUT FAILURES section which references Tables 3-1 and 3-3.
2. PERFORMANCE FAILURE: If the power supply produces an output but does not perform to specifications, begin by verifying the measurements at the A2J7 test connector using Table 3-1. Next, verify the front panel by doing the procedure outlined in the FRONT PANEL TROUBLESHOOTING section. After the front panel has been verified consult Table 3-5 for the performance failure symptom which seems closest to the one observed and proceed to the functional circuit given for that failure.
The circuits referenced in Tables 3-2 and 3-5 are derived from functional blocks of circuits in the power supply. These
include a brief description of the circuit involved. The columns provided in each block are as follows:
NODE: This column lists the nodes where the measurements should be taken. In some cases this will be stated as NODE ( + ) and NODE (- ) where the first is the test node and the second is the reference.
SETUP: If a certain setup is required for the measurement, it will be given in this column.
MEASUREMENT: This column indicates what the expected measurement is for the given node.
SOURCE: If applicable, the components which generate the signal will be provided in this column .
Some blocks will have Input and Output sections. The input section will have a source column to indicate which components generated the measured signal. The output section will list all the important output signals from that block.
However, because the outputs of one block are the inputs to another, the schematic should be consulted if an output measurement is incorrect. This will indicate the next circuit block to be trouble shot.
Main Troubleshooting Setup
Figure 3-1 shows the troubleshooting setup for troubleshooting all of the unit except the front panel and initial no output failures (see page 36). The external power supply provides the unit's internal bus voltage. The ac mains cord connects to the unit's A1T3 bias transformer via an isolation transformer, thereby energizing the bias supplies, but it does not connect to the input rectifier and filter because that would create the bus voltage. With the external supply the unit operates as a dc-to-dc converter. The supply biases the A4Q1, A4Q2, A4Q3 and A4Q4 PFETs with a low voltage rather than the 320Vdc bus voltage. This protects the PFETs from failure from excess power dissipation if the power-limit comparator or the off-pulse circuitry are defective. It also reduces the possibility of electrical shock to the troubleshooter.
33
Figure 3-1. Main Troubleshooting Setup
An isolation transformer provides ac voltage that is not referenced to earth ground, thereby reducing the possibility of accidentally touching two points having high ac potential between them. Failure to use an
isolation transformer as shown in Figure 3-1 will cause the ac mains voltage to be connected directly to
many components and circuits within the power supply, including the FET heatsinks, as well as to the
terminals of the external dc power supply. Failure to use an isolation transformer is a definite
personal-injury hazard.
The troubleshooting setup of Figure 3-1 connects high ac voltage to relay K1, fan B1, fuseholder A1F1, and
other components and circuits along the front of the A 1 main board.
As a convenience in implementing the troubleshooting setup, prepare cord sets as shown in Figure 3-2. This facilitates connecting the unit's input power rail to the external supply and connecting the bias transformer to the isolation transformer.
34
Figure 3-2. Modified Mains Cord Set For Troubleshooting
With the mains cord unplugged proceed as follows: a. Remove the top cover and the inside cover as described on page 30. Remove fuse A1F1.
Failure to remove fuse AlF1 will result in damage to the unit; damage to the external DC supply and a shock hazard to you.
b. Install control board test connector onto the A2J7 card edge fingers.
c. Connect a 50 Ω, 40W, load resistor to the unit's output terminals.
35
d. Place the front panel power-on switch in the off position. Remove the ac input cover from the rear panel and connect the
"L" and "N" screws on the barrier block to the output of the external DC supply. If a line cord is already connected to these terminals, construct an adapter as shown in Figure 3-2 (a), which allows you to connect the cord to the DC supply.
In either case ignore polarity as the unit's rectifying diodes steer the dc power to the correct nodes.
e. Complete the setup of Figure 3-1 by attaching an ac mains cord to test points J8 (L, black wire) and J7 (N, white wire) and connect the green ground wire to the unit's case ground terminal or a suitably grounded cabinet screw. See Figure
3-2 (b). Plus the mains cord into an isolation transformer.
Troubleshooting No-Output Failures
Note
The main troubleshooting setup is not used for the No Output Failures and Front Panel troubleshooting tests.
No-output failures often include failure of the A4Q1 through A4Q4 PFETs and their fuses, A4F1 and A4F2. When either the off-pulses or the power-limit comparator fails, the PFETs can fail from excessive power dissipation. The strategy for localizing no-output failures is to check the voltages and waveforms at the control board test connector to predict if that circuit failure would cause the PFETs to fail. This makes it possible to develop your troubleshooting approach without an extensive equipment setup. Proceed as follows: a. With the mains cord unplugged remove the A4 FET Driver board as described on page 30. Plug in the mains cord and switch on power.
b. Using Table 3-1 check the bias voltages, the PWM-OFF, PWM-ON and Ip MONITOR Control signals and other signals of interest at the A2 control board test fingers, A2J7.
c. Check for the presence of program voltages, VP and IP, at the rear panel.
d. Check for presence of the 320Vdc rail voltage between the rear facing end of AlR3 and the rear facing end of AlR1. If there is no rail voltage, check diode Assembly A1U1.
A1R1, A1R3, and AlU1 connect to the ac mains voltage. Use a voltmeter with both input terminals floating to measure the rail voltage.
e. Select the functional circuit for troubleshooting based on your measurements and Table 3-2, which provides direction based on the status of the PWM OFF and PWM ON signals .
Front Panel Troubleshooting
Troubleshoot the A3 front panel board by first doing the following setup: a. Remove the top plastic insert from the front frame by prying up with a flat-blade screwdriver.
b. Remove the 4 front panel assembly mounting screws (Phillips 6-32), two on top and two on the bottom.
c. Detach the A3 board from the front panel assembly by removing the 6 mounting screws (Pozidriv, M4x7).
d. Place the A3 board vertically against the supply with a piece of insulating material between. The test connector can then be attached to the A3 board. The rest of the front panel assembly can stand vertically so that the pots and the switches can be accessed while troubleshooting.
e. Plug in the mains cord and switch on power.
The ac mains voltage connects directly to the LINE switch and to components and traces at the front of the
A1 main board. Be extremely careful to avoid touching the ac mains voltage.
Start troubleshooting by performing the tests given in Table 3-3. This table provides the measurements for the test points on the test connector as well as the source components for that measurement. Table 3-4 gives front panel symptoms as well as the circuits or components that may cause the supply to exhibit those symptoms. Both Tables 3-3 and 3-4 should be used to check out and troubleshoot the front panel.
36
Table 3-2. No-Output Failures
(Bias supplies and AC turn-on circuit functioning)
Status of PFET on/off-Pulses
PWM-ON PWM-OFF
A2J7-26 lo
A2J7-25 lo
DEFECTIVE
BOARD
A2 lo hi A2 & A4 hi hi lo
N hi
N
N lo= TTL low lo hi
N lo
N hi
N hi= TTL high
A2 & A4
A2 & A4
A2
A2 & A4
A2 & A4
A2 & A4
A2 & A4
CHECK FUNCTIONAL CIRCUITS
Control ckts: CV & CC thru on- & off-Pulse Oneshots *
PWM and DC-to-DC Converter: A4Q1, A4Q2, A4Q3 and A4Q4 probably failed
PWM and DC-to-DC Converter: A4Q1, A4Q2, A4Q3 and A4Q4 probably failed
PWM and DC-to-DC Converter: A4Q1, A4Q2, A4Q3 and A4Q4 probably failed
A2U15A,on-Pulse Oneshot and A2Q11
Off-Pulse Oneshot and DC-to-DC: A4Q1, A4Q2, A4Q3 and A4Q4 probably failed
A2U15A, on-Pulse Oneshot & DC-to-DC: A4Q1, A4Q2, A4Q3, and
A4Q4 probably failed off-Pulse Oneshot and DC-to-DC: A4Q1, Q4Q2, A4Q3 and A4Q4 probably failed
Power-Limit Comparator and DC-to-DC: A4Q1, A4Q2, A4Q3 and
A4Q4 probably failed
N = normal 20KHz pulse train, TTL levels
* Decide which to troubleshoot -- the CV Circuit, the CC Circuit, or the PWM and Off-Pulse & On-Pulse Oneshots -- by measuring the CV CONTROL (A2CR24, cathode) and the CC CONTROL (A2CR11 cathode) voltages. Troubleshoot whichever is negative, and if neither is negative, troubleshoot the PWM. Make these voltage measurements after you have implemented the Main Troubleshooting Setup.
Table 3-3. Front Panel Board Tests
.
3
4
5
Pin
No
1
2
6
7
8
Signal Name
+7.5V
-1V
CV VOLTAGE
CC VOLTAGE
VOLTS test
AMPS test
Measurement
7.5V
-1.0V
0-5V
0-5V
-1888 on volts display
-1888 on amps
VOLTS input display
0-1V
VOLTS low range TTL high
Description
Derived from + 15V bias.
Derived from –15V bias.
For 0 to full scale output voltage.
For 0 to full scale output current.
Jumper to + 5V on A3 board.
Jumper to + 5V on A3 board.
A3VR2, A3R93
A3R89, A3R94, A3C17
A3U6-6, A3R88, A3CR1
A3U7-1, A3R58
A3U1-37
A3U2-37
A3U4-2,3,10
A3U5-13
Source
9
10
11
12
13
DISPLAY
SETTINGS
DISPLAY OVP
AMPS input
-5V buffered OVP
TTL lo
TTL high
0-600mV
-5.0V
0-2.2V
For 0 to full scale output voltage.
If VOLTS display is below 20 volts
(press DISPLAY SETTINGS).
If DISPLAY SETTINGS switch on front panel is depressed.
If DISPLAY OVP switch on front panel is depressed.
For 0 to full scale output current.
Derived from -15V bias.
1/30 of OVP voltage setting when
DISPLAY OVP switch is depressed varies with OVP ADJUST pot.
A3S1,A3R85
A3S2,A3R64
A3R56,A3R58
A3VR1, A3R90
A3U7-7,A3CR5
37
Troubleshooting Bias Supplies
+5V on A2 Control Board . The PWM A2U22 includes a clock generator (40KHz set by A2R170, A2C79, and A2Q10), and a current limit (2Adc set by 0.15Vdc across A2R172). It turns off each output pulse using the difference between the voltage at voltage divider A2R161-A2R163 and the 2.5Vdc set by voltage regulator A2U21.
Circuit Included . + 5Vdc bias supply circuitry from connector pin A1J5-1,3 (1,3 both pins) through jumper A2W3 on A2 control board.
Setup.
external supply to 0Vdc.
Input:
NODE +
A2J7-22
NODE -
A2J4-4.
MEASUREMENT
≈ 20Vdc
Outputs
NODE
A2U22-6
A2U22-12,13
A2Q9 (emit)
A2U21 -2
A2R161, A2R163
MEASUREMENT
≈ 2 to 4Vdc sawtooth, 40KHz
≈ 19Vpk, 15µs pulses, 40KHz
≈ 20Vpk, 5µs pulses, 40KHz
2.5Vdc
2.5Vdc
To check if load on + 5V is shorted, remove jumper A2W3
Unexplained OVP shutdowns
No current limit
Max current < 17Adc
Max power < specified
Max voltage < 200Vdc
Cycles on & off randomly
SOURCE
A1CR2,AlCR5
Table 3-4. A3 Front Panel Board Failure Symptoms
SYMPTOMS DEFECTIVE CIRCUIT
Error when pressing DISPLAY SETTINGS Limits display.
Error in VOLTS or AMPS
CHECK COMPONENTS
A3U5, A3U8
Input ranging or DVMS.
A3U8,A3U6,A3U4,A3U1,A3U2,
A3U7
* One or more display digits out
Unable to adjust VOLTAGE or CURRENT or always max
VOLTS decimal point error
Display LEDs.
Potentiometers.
Decimal drivers.
A3DS1 through A3DS8
A3R99, A3R100
A3U3
* Note that the Volts and Amps tests (Table 3-3 pins 5 and 6) verify that all the current and voltage display segments light except for the decimal points.
SYMPTOMS
Table 3 5. Performance Failure Symptoms
DEFECTIVE
BOARD
A2
A2
A2
A2, A1
A2, A1
A2, A1
CHECK FUNCTIONAL CIRCUITS
OVP Circuit, CV Circuit
CC Circuit
CC Clamp, CC Circuit
Power Limit, 20KHz clock, transformer A1T2
CV Circuit, diodes A1U1, mains voltage select jumper A1W1
AC-Surge-&-Dropout Detector, Mains Voltage
Select switch A1S2
38
Table 3 5. Performance Failure Symptoms (continued)
SYMPTOMS
CV overshoots
Output noise ( < 1KHz)
Output noise ( > 1KHz)
CV regulation, transient response, programming time
CC regulation
CV oscillates with capacitive loads
CC oscillates with inductive loads
DEFECTIVE
BOARD
A2
A2, A1
A1, A4
A2, A1
A2
A2
A2
CHECK FUNCTIONAL CIRCUITS
A2U5A, A2CR19, A2R62
CV Circuit, Input Filter
Transformer A1 T2, output Filter, snubbers A4R1 to A4R11, A4R13 to A4R19, A4C1 to A4C4,
A4CR1 to A4CR4
Wrong sensing (paragraph 3-40), low ac mains voltage, CV Circuit
Low ac mains voltage, CC circuit
A2R61, A2R60, A2R58, A2R59, A2C33, A2R64,
A2R68, A2C36, A2C37, A2U5, A2R65
A2R61, A2R60, A2R58, A2R57, A2C33, A2R19,
A2C11, A2R58, A2C12, A2U4, A2R35, A2C20,
A2R37, A2C17, A2R29, A2C18, A2R31
+15V on A2 Control Board . Voltage regulator A2U11 regulates the voltage across resistor A2R99 to be 1.25Vdc. That sets the current through zener diode A2VR3 at 7.5mAdc. The output voltage is 1.25Vdc plus 11.7Vdc across A2VR3 plus the voltage across A2R100.
Circuit Included.
+ 15Vdc bias supply circuitry from connector pin A2J5-5 through test point A2J7-2 on A2 control board.
Setup
external supply to 0Vdc.
Input:
NODE (+ )
A2C52(+)
NODE ( - )
A2C52(-)
MEASUREMENT
≈ 27Vdc
SOURCE
A1U4 ,AlC15 (+)
A1U4,A1C17 (+) (6011A)
Outputs:
NODE ( + )
A2J7-2
A2J7-2
A2J7-2
A2C50 ( + )
N0DE ( - )
A2U11 (ADJ)
A2VR3 (Anode)
A2VR2 (Anode)
A2C50 ( - )
To check if load on + 15V is shorted, remove jumper A2W1 .
MEASUREMENT
1.25Vdc
12.9Vdc
6.2Vdc
13.8Vdc
-15V on A2 Control Board . Voltage regulator A2U12 regulates the voltage across resistor A2R103 to be 1.25Vdc.
Circuit Included.
-15Vdc bias supply circuitry from connector pin A2J5-6 through test point A2J7-21 on A2 control board.
Setup
external supply to 0Vdc.
39
Input:
NODE ( + )
A2C55(+)
NODE ( - )
A2C55(-)
MEASUREMENT
≈ 27Vdc
SOURCE
A1U4, AlC16 ( - )
A1U4, AlC18 ( - ) (6011A)
Outputs:
NODE ( + )
A2J7-21
A2J7-21
A2C54 ( + )
N0DE ( - )
A2U12-3 (ADJ)
A2VR4 (Anode)
A2C54 ( - )
MEASUREMENT
-1.25Vdc
-12.9Vdc
13.8Vdc
To check if load on -15V is shorted, remove jumper A2W3.
supply.
Power Section Blocks
This section contains the blocks referenced in Tables 3-2 and 3-5.
Troubleshooting AC-Turn-on Circuits
Relay A1K1 closes at 2.5 seconds and DROPOUT goes high at 2.9 seconds after 20V (5V UNREG) reaches about 13Vdc.
DROPOUT high enables the PWM if OVERVOLTAGE, and OVERTEMPERATURE are also high.
Circuits Included.
AC-Surge-&-Dropout Detector, Bias Voltage Detector, Delay Circuits, and Relay Driver--all on A2 control board.
Setup.
external supply to 0Vdc.
Inputs:
NODE ( + ) *
A2J7-24
A2J7-22
A2U11-16
A2U20-13
Outputs:
NODE ( + ) *
A2U17-9
A2U17-14
A2Q11-14
A2Q11-4
A2U9-10
A2U9-15
A2U9-14
A2U9-1
SETUP
SETUP cycle power cycle power cycle power cycle power cycle power cycle power cycle power
MEASUREMENT
5.0Vdc
≈ 21Vdc f.w.rect.,0.8Vpk
TTL sq wave,20KHz
MEASUREMENT
≈ 13.5Vdc
≈ 1.4Vdc
transition 0 to 5Vdc at 2.5 sec hi (5Vdc)
2.9 s burst 1.25KHz sq. wave one 840ms pulse then hi at 2.5 sec three 420ms pulses then hi at 2.9 sec transition lo to hi at 1.7 sec
SOURCE
A2Q9 (emit.)
A1CR2,AlCR5
A1CR3,AlCR4
A2U20-6
40
Outputs:
NODE ( + )
A2U20-1
A2U20-5
A2U20-6
A2U19-5
A2U19-6
A2U16-5
A2U16-5
A2U16-4
A2U16-4
A2U15-1
A2U15-1
+ OUT
A2U15-10
( AC FAULT
A2Q7-C
)
( RELAY ENABLE )
* NODE ( - ) = A2J7-4 cycle power cycle power
Troubleshooting PWM & Clock
transition lo to hi at 2.9 sec transition 5.0 to 0.3Vdc at 2.5 sec
The inputs to inhibit Gate A2U18A and PWM gate A2U18B are the keys to PWM troubleshooting. The 20KHz clock starts each PWM output pulse, and the pulse stops when any of the inputs to A2U18A or A2U18B goes low. The PWM is inhibited and prevented from initiating output pulses as long as any of the seven inputs is low.
Circuit Included . Pulse Width Modulator (PWM), Off-Pulse Oneshot, On-Pulse one-Shot, 20KHz Clock.
Setup
current setting above 1.0Adc. Set the external supply (EXTERNAL) and adjust the unit's voltage setting (INTERNAL) as instructed below. Use the "DISPLAY SETTINGS" switch to make adjustments to the unit's current or voltage setting.
Inputs:
NODE ( - ) = A2J7-4
NODE ( + )
A2J7-24
A2U18-10
A2U18-12
A2U18-13
A2U18-5
A2U18-2
A2U18-1
SETUP
Set OUTPUT ADJUST for 1Vdc
MEASUREMENT
5.0Vdc
hi hi hi hi hi hi
SOURCE
A2Q9, A2W3
A2U15-10
A2U15-13
A5TS1, A4TS1
A2U18-8
A2U8-2
A2U10-7
+ OUT
SET VOLTAGE (Vdc)
EXTERNAL INTERNAL
0
0
0
0
0
0
0
2
0
40
40
40
2
2
0
20
40
40
40
40
0
20
0
20
40 2
MEASUREMENT
TTL sq wave, 320KHz
TTL sq wave, 40KHz (80KHz, 6015A)
TTL sq wave, 20KHz
20KHz
20KHz
10 µ s pulse, 20KHz lo
48 µ s pulse, 20KHz hi
1.7
µ s pulse, 20KHz (80Vdc, 6015A) lo
≈ 40Vdc (UNREGULATED)
14Vdc (6011A, 6012B)
80Vdc (6015A)
20Vdc (CV)
2.0Vdc (6011A, 6012B, 6015A)
41
Troubleshooting DC-To-DC Converter
Parallel NOR gates A4U1, A4U2 and A4U3A act as drivers and switch on FETs A4Q1, Q2, Q3 and Q4 through pulse transformer A4T1. NOR gate A4U3B turns off the FETs through pulse transformer A4T2 and transistors A4Q5 and A4Q6.
Circuits Included.
On-Pulse Driver, Off-Pulse Driver, FET Switches and Drivers on A4 FET board.
Setup.
external supply to 40Vdc. Set the unit's output voltage to 20Vdc and current to above 1Adc using "DISPLAY SETTINGS" switch. Verify that the UNREGULATED LED lights. See Figure 3-3 for waveforms.
Inputs:
NODE ( + )
A2J7-26
(PWM-ON)
A2J7-25
(PWM-OFF)
A4P1-C1
A4Q2-D
NODE ( - )
M
M
MEASUREMENT
1.7
µ s 20KHz pulse
(see Waveform 1)
10 µ s 20KHz pulse
(see Waveform 2)
10.6Vdc
39Vdc
SOURCE
A2J5-11, A2U15-1, A4P1-A3
A2U16-5, A2J5-13, A4P1-A2
M
A4Q4-S
A1U3-2
A1C5 (+), A4P1-22 to 25
A1C1(-), A4P1-16 to 18
Outputs:
NODE ( + )
A4Q1/Q2-G
A4Q3/Q4-G
A4Q2-S
A2J7-18
NODE ( - )
A4Q2-S
A4Q4-S
A4Q4-D
A2J7-4
MEASUREMENT
(see Waveform 3)
(see Waveform 3)
(see Waveform 4)
(see Waveform 5)
If you replace the FETs, replace both the FETs and associated drive components as furnished in FET Service Kit, Agilent
Part No. 5060-2866.
The FETs are static sensitive and can be destroyed by relatively low levels of electrostatic voltage.
Handle the A4 FET board and the FETs only after you, your work surface and your equipment are properly grounded with appropriate resistive grounding straps. Avoid touching the FET's gate and
source pins.
Troubleshooting Down Programmer
The down programmer discharges the output when either PWM OFF is generated or CV ERROR is more negative than about - 3Vdc. Comparator A5U1 triggers down programming when the voltage at A5U1-5 is less than about 4Vdc.
Circuit Included.
Down programmer and 10.6V bias supply on A1 main board.
Setup.
( - ) terminals. Apply the ac mains voltage to the isolation transformer. Set the external supply for an output voltage of
10Vdc and set current limit for 2.5 Amps. Set the power supply under test for a voltage setting of 8.0Vdc and current setting of 2.0Adc using "DISPLAY SETTINGS".
42
Figure 3-3. Waveforms
43
Outputs:
NODE ( + )
A5C3 (+)
A5VR1(K)
A5U1-3
A5CR2(K)
A5CR2(K)
A5U1-1
A5U1-1
+R20
+R20
NODE ( - ) = A2J7-4
EXTERNAL SUPPLY
ON/OFF
ON/OFF
ON/OFF
OFF
ON
OFF
ON
OFF
ON
MEASUREMENT
10Vdc
6.5Vdc
0.2Vdc
1.8Vdc
0.2Vdc
0.5Vdc
5.0Vdc
<0.001Vdc
1.5Vdc
Troubleshooting CV Circuit
V-MON, the output of CV Monitor Amp A2U2, is 1/40 (1/4, 6011A, 6012B) the voltage between + S and - S. CV Error
Amp A2U3 compares V-MON to CV PROGRAM. Innerloop Amp A2U5A stabilizes the CV loop with input from A2U5B.
The measurements below verify that the operational amplifier circuits provide expected positive and negative dc voltage excursion when the CV loop is open and the power mesh shut down.
Circuits Included.
Constant Voltage (CV) Circuit and buffer amplifier A2U5B.
Setup.
the external supply Remove the + S jumper and connect A2J7-2 ( + 15V) to + S. Set mode switch settings B4, B5 and B6 all to 0. Set VP to 0Vdc by connecting to P or set VP to + 5Vdc by connecting to A2J7-24 according to SETUP below.
VP and P are on rear-panel terminal block.
Outputs:
NODE ( + )
VM
A2U5-1
A2U3-6
A2U5-1
A2U3-6
A2U5-7
NODE ( - )
A2J7-4
A2J7-4
A2J7-4
A2J7-4
A2J7-4
A2J7-4
SETUP
VP = 0
VP = 0
VP = 5
VP = 5 short A2J7-24 to A2U5-5
MEASUREMENT
3.75Vdc
-14Vdc
-14Vdc
13Vdc
4.7Vdc (6011A, 6012B, 6015A)
≈ 0Vdc
5.1Vdc (6011A, 6012B, 6015A)
+ 7.5Vdc
If the failure symptoms include output voltage oscillation, check if the CV Error Amp circuit is at fault by shorting A2U3-6 to A2U3-2. If oscillations stop, the CV Error Amp circuit is probably at fault.
Troubleshooting CC Circuit
I-MON, the output of CC Monitor Amp A2U1, in volts is ≈ 1/3 (1/24, 6011A) the output current in amperes. CC Error
Amp A2U4C compares I-MON to CC PROGRAM. Differentiator circuit A2U4A differentiates the inboard voltage sense to stabilize the CC loop. Its output is summed with I-MON at CC Error Amp A2U4C.
The measurements below verify that the operational amplifier circuits provide expected positive and negative do voltage gain when the CC loop is open and the power mesh shut down.
44
Circuits Included.
Constant Current (CC) Circuit on A2 control board.
Setup.
OUT ( - ) and - OUT ( + ) terminals. Apply the ac mains voltage to the isolation transformer. Set the external supply to
3.0Adc constant current with a voltage limit in the range 5 to 20Vdc. Set mode switches B1, B2 and B3 to 0. Set IP to 0Vdc by connecting to P or set IP to + 5Vdc by connecting to A2J7-24 according to SETUP below.
Outputs:
NODE ( + )
IM
A2U4-8
A2U4-8
NODE ( - )
A2J7-4
A2J7-4
A2J7-4
SETUP
IP = 5 (6015A)
IP = 0
IP = 5
MEASUREMENT
0.125Vdc (0.88Vdc, 6015A)
-14Vdc
+14Vdc
If the failure symptoms include output current oscillation, check if the differentiator circuit is at fault by removing resistor
A2R35 ( 1M ohm) (3.3M ohm, 6011A). If oscillations stop, the differentiator is probably at fault.
Troubleshooting OVP Circuit
Flip-flop A2U8A-A2U8D is set by comparator A2U8C and reset by PCLR . TTL low at A2U18-12 inhibits the PWM.
OVP Program Voltage on A2J7-7 is equal to Eout/10.
Circuit included . OVP Circuit and 2.5V bias supply on A2 control board.
Setup.
( - ) terminals. Apply the ac mains voltage to the isolation transformer. Adjust the unit's OVP limit to 10Vdc. Set the external supply (EXTERNAL) as instructed below.
Outputs:
NODE ( - ) = A2J7-4
NODE ( + )
A2U7-2
A2J7-7
A2J7-13
A2J7-13
A2J7-13
A2J7-13
SET VOLTAGE
EXTERNAL (Vdc)
-
-
5
15
5
5
* Front panel OVP control turned fully cw.
SETUP cycle power
MEASUREMENT hi lo lo hi
2.5Vdc
1.0Vdc
≈ 2.2Vdc (6015A)*
Note
Connecting a test probe to either input of either comparator in the OV Flip flop (pins A2U8-1, 6, 7, 10, 11 or 13) may cause the flip flop to change states and cause the probed input to be low.
45
4
Principles of Operation
Autoranging Power
Autoranging allows the unit to be compact and light weight and yet to deliver a range of output voltage/current combinations which would otherwise require the use of more than one supply or a higher rated power supply. Autoranging is a name for circuitry which automatically makes full power available at all but low rated output voltages and currents. By comparison, a conventional constant voltage/constant current (CV/CC) power supply can provide full output power only at maximum rated output voltage and current.
Overview
The Simplified Schematic, Figure 4-1, shows how the major circuits are connected. Segmenting the Simplified schematic into functional circuit blocks will highlight how these blocks work and illustrate overall system function.
Table 4-1 briefly describes the major circuits employed in the design of this unit. When used in conjunction with the
Simplified Schematic, the reader is provided with a quick overall appreciation of the unit's operation.
Power flows from the ac mains at the left of the schematic through circuit blocks connected by heavy lines to the output terminals at the right. Follow the schematic from right to left to see how the output voltage is regulated during CV mode of operation, The output voltage is monitored both at the output sense terminals + S and - S; OVS (Outerloop Voltage Sense) and also before the two stages of output filter IVS (InnerLoop Voltage Sense).
Sensing with output sense terminals provides accurate load-voltage control and sensing before the output filter stabilizes the supply and permits it to power reactive loads. The CV monitor amplifier buffers the OVS voltage to produce the V-MON output monitoring voltage. A buffer amplifier monitors the voltage before the output filter to produce the IVS voltage.
When in CC operation, the output current is regulated in a similar manner. Output current is sensed as the OCS outerloop voltage across a current monitoring resistor. OCS is buffered to produce l-MON. IVS is differentiated to produce an innerloop current sensing voltage.
System Description
The Agilent 6010A /6011A/6012B/6015A are power supplies which utilizes the principle of switching to achieve regulation. Basically, the power supply employs five major functional sub-systems together with the Front Panel to achieve its overall objective of delivering a maximum of 17A or 200V (6010A); 120A or 20V (6011A); 50A or 60V (6012B); 5A or 500V (6015B), at the power output of 1000W.
These sub-systems are
1.
Regulation & Control
2.
Protection
3.
Input Power
4.
DC Power Conversion
5.
Output
47
Regulation & Control Subsystem
This sub-system may be considered to be the brains of the unit. It provides the control pulses to open and close the switching elements which deliver power to the output. This section also regulates the output to ensure that the unit is delivering a constant power at either a constant voltage or constant current setting. In the event that this cannot be achieved, then the protection subsystem is employed to limit the power to the output.
To understand how this control is achieved, consider Figure 4-1, the simplified schematic. Power from the output is sampled and attenuated before it is fed back to the Constant Voltage Error Amplifier. Another input to this amplifier is the
Program Voltage which the user sets via the front panel. The difference between these two voltages is amplified and becomes the CV Error Signal. The output of the supply is also sampled by the CC Monitor Amp. This sample voltage is fed into the Constant Current Error Amp. The other input to the Constant Current Error Amp is the program current which the user sets via the front panel. The difference between these two voltages is amplified and becomes the Constant Current
Error Signal. These two signals are connected in a wired-OR configuration and fed into the Constant Voltage Comparator.
The control mechanism which the unit employs to regulate its output comprises the Primary Current Monitor Transformer, the Control Voltage Comparator and the Pulse Width Modulator. The Primary Current Monitor Transformer senses the power transferred by the FETs and generates the Ip Ramp Voltage which continues to build up as the output increases. This
Ramp Voltage and the Control Voltage are used as inputs to the control voltage Comparator. If the Ramp Voltage exceeds the Control Voltage, the output of the comparator goes low and resets the Pulse Width Modulator in the process. If the unit develops power in excess of its requirements, the power LIMIT Comparator effectively monitors this condition and returns a low signal which disables the Pulse Width Modulator and prevents any further power development.
The PULSE WIDTH Modulator (PWM) is the device which the unit employs to constantly alter the duty cycle of the switching waveform produced by the FETs. Once reset, it triggers the off-pulse one-shot which turns off the FETs via the off-pulse driver. The 20KHz entering the PWM holds it reset for 1.5
µ S and on the next clock pulse from the oscillator the output is clocked high. This in turn triggers the on-pulse one-shot which enables the FETs. Other inputs which can disable the PWM are the outputs from the Power Limit Comparator, the Master Enable, the CV and CC loop.
Figure 4-2 shows the timing diagram of the signals which control the FETs. Notice that on the rising edge of the on-pulse, the PWM is activated and remains on until the off pulse is sent. There is a slight delay in the time the off-pulse is sent and the time the FETs are actually turned off. This turn off delay results in greater power being generated than is required as shown by the Ramp Voltage exceeding the Control Voltage. To prevent this situation, there is an Initial Ramp Circuit which increases the Ramp Voltage and enables the voltage to ramp up to the Control Voltage level earlier.
The sampled output voltage is fed back through the Constant Voltage Circuit and the Constant Current Circuit before it becomes the Control Voltage. The CV and CC circuits provide the means for the instrument to deliver power at either constant voltage or constant current.
The CONSTANT VOLTAGE circuit takes its input from two positions on the output voltage rail: the Innerloop Voltage
Sense (IVS), and the outerloop Voltage Sense (OVS) at the + S and - S terminals. The CV Monitor Amplifier attenuates the
OVS in the ratio of 1:40 (6010A); 1:4 (6011A); 1:12 (6012B); 1:100 (6015A), and produces the Voltage Monitor(V-MON) signal. This signal connects through protective circuitry to the rear panel and display circuits on the front panel, and also forms the input to the CV Error Amplifier. The Program Voltage which the user sets at the front panel voltage control is also an input to this amplifier. The output is the error signal which together with the output from the Innerloop Voltage
Sense (IVS) generates the CV Control Voltage.
In addition to the Front Panel settings, the CV Program Voltage can be set from an external voltage applied between rear panel terminals VP and P, or from an external resistor between these same terminals.
48
Figure 4-1. 6010A and 6015A Simplified Schematic
49
50
Figure 4-1. 6011A and 6012B Simplified Schematic
Circuit
Bias Power
Supply (BPS)
Bias Voltage
Detector (BVD)
Timed Delay
Circuit (TDC)
Power Limit
Comparator (PLC)
Control Voltage
Comparator
(CVC)
Constant Voltage
Circuit (CV)
Constant Current
Circuit (CC)
Pulse Width
Modulator (PWM)
Primary Current
Monitor
Transformer
Power
Transformer
Table 4-1. Quick Reference Guide to Major Circuits
Major Function
Provides Bias and
Reference Voltage.
Delays the unit's operation at poweron.
Enables power circuits.
Determines maximum primary current.
Regulates the operation of the
PWM.
Produces CV
Control Voltage.
Produces CC
Control Voltage.
Switches FETs.
Generates I
Voltage.
P
Ramp
Stores and transfers output power.
Dependent Circuits
Input from
Mains
BVS
Output to Operation
Control Circuits Mains voltage at BVS input is converted to lower voltage levels to provide the internal operating voltages
Delay Circuit,
OVP for the various circuits.
Holds all circuits reset until all internal voltages are at acceptable levels.
BVD: DOD PWM; Relay
BVS; Ramp
V
IP RAMP
Control
Port Voltage (V
CP
Outer Voltage
Sense (OVS)
Innerloop Voltage
Sense (IVS) CV
Program Voltage
Outer Current
Sense (OCS). CC
Program Voltage
)
PWM
PWM
CVC,
Display
Circuits
CVC; Display
Circuits
Waits for 3 seconds after power-on and then shuts out inrush current limiting resistor. The circuit is triggered by the
BVD when the + VDC is stable.
Compares V
IP RAMP when V
IP RAMP
> V with V
REF.
REF
and produces a signal to inhibit the PWM
Compares V
IP RAMP produces a signal to inhibit the PWM when V
IP RAMP
> V with V
CP.
CP
and
Monitors OVS s ignals from which
VMON is derived. Combines OVS and
IVS to give CV Control Voltage.
Master Enable;
PLC, CVC
FETs
FETs
CVC; PLC
Monitors OCS signals from which l-MON is derived. Combines OCS and; differentiated IVS to give the CC control voltage.
Switching action achieved at 20KHz rate with on-pulse activated by 20KHz clock and off-pulse by CVC, PLC,
20KHz clock or shutdown circuits.
Senses Ip current build-up while FETs are on.
FETs
A4 Q1,2,3,4
Down
Programmer (DP)
Control gating of current in power, and Sense
Transformers.
Rapidly lowers output voltage.
PWM
CV Circuit, OVP,
DOD
Output Rectifier When FETs are on, the primary
Sensing
Transformer windings of the transformer store energy until the FETs are switched off when the energy is transferred to the secondary for output circuits.
FETs open and close in response to pulses from the PWM. The length of its on/off time depends on the duration of the PWM on or off pulse.
Output Rail Output filter capacitor are rapidly discharged at varying ampere rates depending on output voltage. Circuit activated under condition of ac power loss, shut down or low voltage.
51
Circuit
Drop out Detector
(DOD)
Over Voltage
Protection (OVP)
Circuit
A9 Output board
(6015A)
Table 4-1. Quick Reference Guide to Major Circuits (continued)
Major Function
Shuts down output power when line drops out for more than one cycle.
Limits maximum output voltage.
Protects output capacitors and power mesh from reverse voltage.
Dependent Circuits
Input from
Bias Transformer
Output to
PWM; DP
+ Out Sense
Power Mesh
DP; PWM
Output terminals
Operation
If no ac pulse is detected after 20ms, the circuit inhibits the PWM and triggers the Down Programmer.
Senses Output Voltage and compares with a preset limit set by its reference circuit. It triggers the Down
Programmer in extreme situations.
Diodes provide protection against reverse voltage applied across the output terminals.
Figure 4-2. FET Control Signals Timing Diagram
The CONSTANT CURRENT CIRCUIT also produces a control voltage. The outerloop current sense (OCS) is taken across the current monitoring resistor and the combined signal is amplified by the CC Monitor amplifier to give the outerloop
Current-Sense Voltage, I-MON. This signal is then diverted along two paths: one terminating at the barrier strip while along the other path the signal combines with the differentiated output of the Innerloop Voltage Sense (IVS). The CC error amplifier compares this combined output with the user-set CC Program Voltage to produce the CC Control Voltage.
The Control Voltage used to regulate the unit may be derived from either the CV or CC circuit. These circuits are connected via a wired-OR connection to the CV or CC circuit. If the CV Control Voltage exceeds the CC Control Voltage then diode A2CR24 is reversed biased but diode A2CR11 is forward biased and the CC Circuit provides the controlling signal.
Similarly when CC Control Voltage exceeds CV Control Voltage, the CV circuit provides the regulating control voltage.
52
When the unit is operating in CV mode, the CV Control Voltage varies between - 0.5Vdc and + 0.5Vdc. It is most negative when the load is drawing no power but as power output increases the voltage becomes more positive.
Protection Subsystem
The diverse system configurations and operating environments under which the unit will be required to operate, will certainly require it to be adequately protected if it must function reliably. The protection circuits of the unit offer protection at turn-on and also during operation.
The CURRENT LIMIT RESISTORS is the first protection along the power rail which the unit utilizes. This circuit prevents any surges of AC input to the input filter by limiting the inrush current. After a predetermined elapsed time the resistor is bypassed and the unit is ready to deliver power. The circuit which carries out this function is the TIMED DELAY
CIRCUIT. When both the Dropout Detector and the PCLR are high, this delay circuit is enabled and counting at the clock frequency of 1.25KHz begins. After 3 seconds, DROPOUT goes high and enables the PWM.
Turn-on protection is also offered by the BIAS VOLTAGE DETECTOR (BVD) which prevents spurious operation that may occur at power-on of the unit if circuits attempt to operate before the + 5Vdc bias voltage is at the clock, PWM, and logic circuits. After power-on, as the output of the + 5Vdc bias power supply rises the BVD is turned on inhibiting the
Relay Driver and the On-Pulse Driver and creating the power clear signal PCLR . The latter signal is held low until the unregulated input to the + 5Vdc bias supply is greater than an input voltage sufficient to assure a + 5Vdc output
Certain circuits also give the unit on-going protection during its operation The AC SURGE AND DROPOUT DETECTOR is such a circuit. This circuit protects the unit from damage from AC mains voltage surges. It shuts down the unit when there is either a 40% overvoltage or a 20 ms voltage interruption in the ac mains voltage. The mains detect signal senses the ac mains voltage and pulls the DROPOUT signal low thereby inhibiting the PWM and shutting off the power.
During conditions of overvoltage when a monitored fraction of the output voltage exceeds the limit set by the front panel
OVP Adjust, the OVER VOLTAGE PROTECTION circuit inhibits the PWM and triggers the Down Programmer. This condition persists until the unit is turned off. At power-on, the Bias Voltage Detector resets the OVP.
The DOWN PROGRAMMER is another protection circuit which is activated when any of the following adverse operating conditions occurs: over voltage; over temperature; primary power failure; and programming of a lower output voltage.
Under these conditions, the Down Programmer lowers the output voltage by rapidly discharging the output filter capacitors.
The Down Programmer takes its input from the Master Enable and the CV Error Amplifier. When either of these signals is low, it is activated. The + 8.9Vdc bias supply provide enough energy to the Down Programmer to discharge the output circuit even when primary power is lost.
The TEMPERATURE PROTECTION circuit protects the FETs from excessive temperature gradients. A thermostat mounted on the FET heat sink monitors the temperature build up of the FETs and disables the PWM when the temperature exceeds a predetermined limit.
In addition to an over-temperature protection, there is also an OVERVOLTAGE PROTECTION circuit. When the FETs turn off, the leakage inductance of the power transformer forces current to continue to flow in the primary. Clamp diodes are employed to protect the FETs from excessive reverse voltage by bypassing the FETs and conducting the current to the input filter.
Input Power Subsystem
This subsystem forms the interface between the ac mains supply and the switching elements of the unit. It takes ac power from the mains, converts it to dc and delivers this unregulated dc to the switching elements and internal control circuitry.
Input power takes two distinct pathways to carry out the above function: mains -rectifier/filter--switching elements and mains--bias supply--control circuits.
53
If the first pathway is taken, it is seen that primary power from the ac mains enters the INPUT RECTIFIER via the inrush current limiting resistor. The rectifier converts the ac voltage to dc voltage and passes its output to the input filter. The unit has a feature which allows it to operate either at 110/120 or 220/240Vac mains voltage. The voltage doubling capability as it is called is effected by connecting jumper AlW1 between the rectifier and filter. When the mains voltage is 220/240Vac, the jumper is open permitting the filter to develop a typical bus voltage of about 300Vdc. However, when the mains voltage is 110/1120Vac, the jumper terminals are connected and the rectifier/filter combination now behaves as a voltage doubler enabling a bus voltage of 300Vdc to be developed .
For the second pathway, primary power passes the Mains Voltage Select Switches to the BIAS POWER SUPPLIES which provide the operating voltages for the internal circuits. The Mains Voltage Select Switches connect the primary windings of the Bias-Supplies' transformer for operation at 120, 220, or 240Vdc.
The unit checks that the + 5Vdc bias voltage and the ac mains voltage are within acceptable limits as part of its turn-on sequence.
DC Power Conversion Subsystem
The current available at the input rails after rectification enters the power transformer A1T2 and Primary Current Monitor
Transformer A1T1. This current flow is controlled by the FETs which act as high frequency switches. The FETs driver circuits are under the control of the Pulse Width Modulator where the On/Off pulses originate.
During the on-pulse the FETs are turned on and current enters the primaries of transformers A1T1 and A1T2 as described above. The output rectifiers A5CR4 and A5CR5 (6011A and 6015A) being reversed biased block the flow of current from the secondary of A1T2 to the output. There is therefore a current build up and the secondary windings of A1T2 act as a storage device. Meanwhile the current in the secondary of current transformer A1T1 develops a linearly increasing voltage waveform across resistors A2R116 and A2R117. This waveform is the Ip Ramp Voltage and corresponds to the energy build up in the secondary of the power transformer.
When the FETs are turned off, the collapsing magnetic field reverses the polarity across the power transformer causing the output rectifiers to be forward biased. Current therefore flows from the secondary windings to the output filters.
Output Subsystem
As discussed above, power reaches the output rail when the FETs are turned off and the output diodes are forward biased.
The signal is first passed through the first stage of the output filter network where most of its 20KHz ripple derived from the switching FETs are attenuated. Part of the signal leaving the first stage filter is fed back to the CV and CC Circuits as the Innerloop Voltage Sense and becomes part of the inner control loop. The primary purpose of these feed-back loops is to impart sufficient stability to the power supply and enable it to cope with a variety of loads.
The signal from the first stage filter also becomes the input to the second stage capacitor filter which provides the additional filtering necessary for the unit to meet its specifications. This filter is close to + S and - S output terminals thereby ensuring that the filter is as close to the user's load as possible. The output from the + S and - S terminals is also fed back to the CV and CC Circuits and forms part of the outer feedback loop.
The 6015A units contain an A9 output board that provides protection against excessive reverse voltage applied across the output terminals.
The Front Panel Board
Figure 4-3 is a simplified schematic of the front panel board. The V-MON, I-MON, and OVP signals are passed to the front
54
panel board from the A2 Control Board. The V-MON and I-MON signals are then. amplified by buffer amplifiers before they are directed to their respective digital voltmeters for display. As an intermediate step before display, the V-MON signal passes through a pair of bilateral range switches A3U4A and U4D which determine the resolution of the voltage display. When the voltage to be displayed is below a certain value, the unit selects the low-range bilateral switch A3U4 which enables the voltage to be displayed to an accuracy of two decimal places; however above this critical output voltage value, the high-range switch A3U4D assumes control and the voltage displayed is accurate to one decimal place.
In addition to providing the display voltage, the V-MON and I-MON signals are used to generate the CV and CC control voltages respectively. When the CV control voltage is found to be more negative than the Control Port Voltage, the power supply is operating in the CV Mode and the CV LED lights. Similarly the CC LED lights when the CC Control Voltage is below the Control Port Voltage confirming that the power supply is operating in CC Mode. When both CV and CC Control
Voltages exceed the Control Port Voltage, the power supply becomes unregulated and the unregulated LED lights.
The CV of CC Program voltages are obtained by depressing the "DISPLAY SETTINGS" switch and reading the respective display. By depressing this switch and turning the Voltage or Current control, the technician can set the program voltage or current. If the instrument is operating in CV Mode for example, then the display voltage and the CV Program Voltage are identical but the display current may vary with the CC Program Voltage. This condition is reversed when the unit is under
CC Mode.
The OVP set potentiometer is also located on the front panel. By depressing the “OVP DISPLAY” switch and adjusting the pot with a small flat screw-driver, the OVP limit can be set. When the output voltage exceeds this pre-set limit, the unit is disabled and the OVP LED lights.
55
56
Figure 4-3. Simplified Front Panel Schematic
5
Replaceable Parts
Introduction
This chapter contains information for ordering replacement parts. Table 5-3 lists parts in alpha-numeric order by reference designators and provides the following information: a.
Reference Designators. Refer to Table 5-1.
b.
Agilent model in which the particular part is used.
c.
Agilent Part Number.
d.
Description. Refer to Table 5-2 for abbreviations.
Parts not identified by reference designator are listed at the end of Table 5-3 under Mechanical and/or Miscellaneous.
Table 5-1. Reference Designators
S
T
R
RT
J
K
L
Q
DS
F
FL
G
A
B
C
CR
W
X
Y
TB
TS
U
VR
Assembly
Blower
Capacitor
Diode
Signaling Device (light)
Fuse
Filter
Pulse Generator
Jack
Relay
Inductor
Transistor
Resistor
Thermistor Disc
Switch
Transformer
Terminal Block
Thermal Switch
Integrated Circuit
Voltage Regulator (Zener diode)
Wire (Jumper)
Socket*
Oscillator
* Reference designator following "X" (e.g. XA2) indicates assembly or device mounted in socket.
57
Ordering Information
To order a replacement part, address order or inquiry to your local Agilent Technolgies sales office. Specify the following information for each part: Model, complete serial number, and any option or special modification (J) numbers of the instrument; Agilent part number; circuit reference designator; and description. To order a part not listed in Table 5-3, give a complete description of the part, its function, and its location.
Table 5-2. Description Abbreviations
IC
INP
LED
MET
MOS
OP AMP
OPTO
OVP
PCB
PORC
POS
PRIOR
ROM
RAM
RECT
REGIS
ADDR
ASSY
AWG
BUFF
CER
COMP
CONV
DECODER/DEMULTI
ELECT
EPROM
FET
FF
FXD
RES
TBAX
TRIG
UNI
VAR
VLTG REG
WW
Addressable
Assembly
American Wire Gauge
Buffer
Ceramic
Carbon Film Composition
Converter
Decoder/Demultiplexer
Electrolytic
Erasable Programmable Read-Only Memory
Field Effect Transistor
Flip-Flop
Fixed
Integrated Circuit
Input
Light Emitting Diode
Metalized
Metal-Oxide Silicon
Operational Amplifier
Optical
Over Voltage Protection
Printed Circuit Board
Porcelain
Positive
Priority
Read-Only Memory
Random Access Memory
Rectifier
Register
Resistor
Tube Axial
Triggered
Universal
Variable
Voltage Regulator
Wire Wound
58
C13,14
C15,16
C15,16
C13-16
C17,18
C17,18
C17,18
*C19
*C19,20
*C19
*C19
Ref. Desig.
A1
A1
A1
B1
C1,2, 4-*6,8
C9
C10
C11,12
C11,12
C11,12
C13,14
C13,14
*C20-23
*C20,22
*C22
*C23
C24
*C24
*C25
*C25
*C25
*C25,26
C26
*C26
C27
C28
C28
C28
C29
C29
C30
C30,31
C30
C32
C33
Agilent Model
6010A, 6011A
6012B
6015A
All
All
All
All
6010A
6011A
6012B, 6015A
6010A
6012B
6015A
6010A, 6012B
6015A
6011A
6010A, 6012B
6011A
6015A
6010A
6011A
6012B
6015A
6010A, 6015A
6012B
6011A
6011A
6010A, 6015A
6012B
6010A
6012B
6015A
6011A
6010A, 6015A
6012B
6011A, 6012B, 6015A
6010A, 6012B
6011A
6015A
6010A, 6012B, 6015A
6011A
6010A
6011A
6012B, 6015A
6011A
6011A
Table 5-3. Replaceable Parts List
Agilent Part Number
06030-61032
06032-61032
06030-61033
See Chassis Electrical
0180-4528
0160-5932
0180-3699
0160-6392
0160-5895
0160-5933
0180-3702
0180-3492
0180-4204
0180-3693
0180-3587
0180-3425
0180-0291
0180-3693
0180-4129
0160-0260
0160-0291
0160-5286
0160-0904
0160-6392
0160-7732
0160-5377
0160-7732
NOT USED
0160-4281
0160-0269
0160-5286
0160-0904
0160-5377
NOT USED
0160-4281
0160-6805
See Chassis Electrical
0160-7732
NOT USED
0160-4323
0160-4281
See Chassis Electrical
NOT USED
0160-4962
0160-4323
0160-4962
Description
MAIN BOARD ASSEMBLY
MAIN BOARD ASSEMBLY
MAIN BOARD ASSEMBLY fxd poly 1.0
µ F 20% fxd met .047
µ F 20% 250V fxd poly 1.0
µ F 20% fxd elect 1800 µ F 200V fxd poly 0.47
µ F 250V fxd elect 470 µ F 20% 35V fxd poly .047
µ F 20V fxd poly .047
µ F fxd elect .022
µ F 10% fxd elect 1600 µ F 125V-10% +50% fxd elect 2600 µ F 75V fxd elect 900 µ F 350V fxd elect 1000 µ F 20% fxd elect 1000 µ F 20% fxd elect 5500 µ F 40V fxd elect 1 µ F 35V fxd elect 1000 µ F 50V fxd elect 1 µ F 35V fxd cer .047
µ F 20% fxd cer 1 µ F 35V fxd cer .47
µ F 20% fxd ww 0.05
µ F 1KV fxd poly .047
µ F 20% fxd poly .47
µ F fxd poly, 2.2
µ F 10% 63V fxd poly, .47
µ F fxd met 2200pf 20% fxd cer .047
µ F 20% fxd cer .47
µ F 20% fxd ww 0.05
µ F 1KV fxd cer 2.2
µ F 10% 63V fxd met 2200pf 20% fxd met 0.01
µ F 400V fxd poly, .47
µ F fxd met .047
µ F 20% 250VAC fxd met 2200PF 20%
* Part of output filter (6010A, 5060-3520; 6011A, 5060-3525; 6012B, 5060-3523; 6015A, 5060-3521) which is mounted on the output bus bars.
59
60
Table 5-3. Replaceable Parts List (continued)
Agilent Model
All
All
All
All
All
6010A 6012B, 6015A
All
All
All
All
All
All fxd met 0.01
µ
Description
F 400V power rect. 400V power rect. 400V 1A diode-switching 80V 200ma
Power rect. 400V
Power rect. 400V
LED visible fuse 1A 250V fuse .125A 125V
Relay
Snubber wire ferrite core, (ref. L1)
Magnetic core jumper for L2
Output Choke
Output Choke ferrite core, (ref. L1)
Output Choke
Ind fxd 18 µ H 5A
Magnetic core jumper for L2
MOSFET N-Chan
Trans FET N-Ch 600V 3.2A
FET N-Chan fxd ww 10K 1% 5W fxd comp 619 1% 1/8W fxd comp 6.8 5% 1/2W fxd comp 36.5K 1% 1/8W fxd ww 20 10% 20W fxd ww 6 10% 20W current sensing resistor current sensing resistor fxd film 2.2 5% 1/4W fxd film 26.1 5% 1/4W
Current Sensing Resistor solid tinned copper wire fxd ww 2K 5% 5W fxd comp 10M 5% 1/2W fxd film 750 1% 1/8W fxd film 121 l% 1/8W fxd film 1 5% 1/4W fxd comp 200 5% 1/2W
J1
J2
J3,4
J5
J6
U3
U3
U4
U5
U6
VR1
R36,37
R36,37
R38,39
R40
R41
R43,44
R45
S3
T1
T2
T2
R46
R47,48
R49
S1
S2
T2
T3
U1
Ref. Desig.
R29,30
R29,30
R31
R32
R31,32
R33
R33
R34
R35
All
All
All
All
All
6010A
6015A
6010A, 6015A
6010A, 6015A
All
All
All
0811-1909
0811-1913
0757-0467
NOT USED
0764-0041
0698-0085
0698-8827
All
All
All
All
All
6015A
All
All
6010A, 6012B, 6015A
6011A
0757-0419
0698-3622
0757-0401
3101-2046
3101-1914
6010A, 6012B, 6015A See Chassis Electrical
All
6010A
6012B
9100-4350
06030-80090
06032-80090
9100-4827
9100-4864
1906-0218 or
1906-0389
1826-0393
6015A
6010A, 6015A
All
All
Table 5-3. Replaceable Parts List (continued)
Agilent Model
6010A
6015A
6010A
6010A
6015A
6010A
6015A
6010A, 6015A
6010A, 6015A
Agilent Part Number
0811-1887
0811-3557
0757-0367
0686-7535
0698-8959
0757-0451
0757-0471
0757-0438
0698-8827
1906-0006
1826-0643
1990-1074
1902-0955
Description fxd ww .05 5% 10W fxd ww 0.5ohms 5% 10W fxd film 100K 1% 1/2W fxd comp 75K 5% 1/2W fxd film 619K 1% fxd film 24.3K 1% 1/8W fxd film 182K 1% fxd film 5.11K 1% 1/8W fxd film 1M 1% 1/8W fxd ww 500 5% l0W fxd ww 1.5K l0W fxd film 121K 1% 1/8W fxd ww 30 5% 2W fxd film 2.61K 1% 1/8W fxd film 1M 1% 1/8W fxd film 681 1% 1/8W fxd film 120 5% 2W fxd film 100 1% 1/8W switch, DPDT slide switch, 2-DPDT slide current transformer power transformer power transformer power transformer bias transformer diode bridge
IC, volt-reg 1.2/37V
U3 is included with heatsink assembly 5060-
2942, see A1 Mechanical diode bridge 400V
IC, switched-mode ckt opto-isolator diode zener 7.5V 5%
6010A, 6012B, 6015A
6011A
6015A
All
All
All
All
All
A1 MECHANICAL
1205-0282
5060-2942
1205-0562
21l0-0269
0403-0086
06032-60010
0340-1095
2190-0586
NOT USED
1251-5384
NOT USED
5060-2877
5060-2878 heatsink (ref. U3) heatsink assembly (includes U3) heatsink (ref. U1) fuse clip (ref. F1) bumper foot (ref. R9,10) output bus bar insulator for buss bar lockwasher (ref. U1)
Post-Type Connector,3pin ribbon cable(2inch)(ref.W8) ribbon cable(4inch)(ref.W7)
61
Ref. Desig.
J7,8
J9,10,
L,N,P
J11-14
XA4,5
C29
C30
C31
C32
C32
C33
C33
C33
C33
C34
C34
C35
C36
C20
C21,22
C23
C24
C24
C25
C25
C26
C27
C27
C28
C28
C17
C17
C18
C19
C19
C20
A2
A2
A2
A2
C1-4
C5
C6-7
C8
C9
C10
C11
C12
C13-16
All
All
All
All
Table 5-3. Replaceable Parts List (continued)
Agilent Model
All
All
All
All
All
All
6010A
6011A
6012B
6015A
All
All
All
6010A, 6012B, 6015A
6011A
All
6010A, 6011A, 6012B
6015A
6010A, 6012B, 6015A
6011A
All
All
6010A, 6012B, 6015A
6011A
6010A, 6012B, 6015A
6011A
All
6010A, 6012B, 6015A
6011A
6010A, 6012B, 6015A
6011A
All
All
All
6010A, 6012B, 6015A
6011A
6010A
6011A
6012B
6015A
6010A, 6012B, 6015A
6011A
All
All
Agilent Part Number
1251-0600
1251-5613
1251-0600
1252-1052
0160-5534
0160-5422
NOT USED
0160-0162
0160-0161
0160-4812
NOT USED
0160-4807
0160-5892
0160-5534
0160-4834
0160-4833
0160-5422
0160-4807
0160-5422
0160-5644
0160-4832
0160-4822
NOT USED
0160-4831
0160-4824
NOT USED
0160-4832
0160-5422
0160-4812
06030-60022
06011-60022
06032-60022
06030-60028
0160-5422
0160-4801
0160-5422
0160-5892
0160-5422
0160-4807
0160-5892
0160-4830
0160-5422
0160-4833
0160-4832
0160-5892
0160-5469
0160-5534
0160-5892 connector, single contact connector, single contact connector, single contact connector 64pin fxd cer .01
µ
Description
F 10% 100V fxd cer .047uf 20% 50V fxd cer 220pf 5% 100V
Control Board Assembly
Control Board Assembly
Control Board Assembly
Control Board Assembly fxd cer .047
µ F 20% 50V fxd cer 100pf 5% 100V fxd cer .047
µ F 205 50V fxd poly .22
µ F 10% fxd cer .047 20% 50V fxd cer 33pf 5% 100V fxd poly .22
µ F 10% fxd cer 2200pf 10% 100V fxd cer .047
µ F 20% 50V fxd cer .022
µ F 10% 100V fxd cer .01
µ F 10% 100V fxd poly .22
µ F l0% fxd met 1 µ F 10% 50V fxd met .1
µ F 10% 63V fxd poly 22 µ F 10% fxd poly 0.1
µ F 10% 63V fxd cer .047
µ F 20% 50V fxd poly .022
µ F 10% 200V fxd poly .01
µ F 10% 200V fxd cer 220pf 5% 100V fxd cer 33pf 5% 100V fxd poly .22
µ F 10% fxd poly 0.1
µ F 10% 63V fxd cer .047
µ F 10% 100V fxd cer .022
µ F 10% 100V fxd cer .047
µ F 20S 50V fxd cer 33pf 5% l00V fxd cer .047
µ F 20% 50V fxd cer .033
µ F 10% 50V fxd cer .01
µ F 10% 100V fxd cer 1000pf 5% 100V fxd cer 4700pf 10% 100V fxd cer 680pf
62
C50
C51
C52
C53
C54
C54
C55
C56,57
C58
C59
C60
C61
C62
C63
C64
C64
C65
C66
C67
C68
C69,70
C71
C72
C79
C80
C81
C82
C83
C84
C85
C73
C74,75
C76
C77
C78
Ref. Desig.
C37
C37
C38-40
C41
C42
C43
C44
C45
C46
C46
C47
C48,49
C50
Table 5-3. Replaceable Parts List (continued)
All
All
All
All
All
All
All
All
All
All
All
All
Agilent Model
6010A, 6011A, 6015A
6012B
All
All
All
All
All
All
6010A, 6011A, 6012B
6015A
All
All
6010A, 6011A, 6012B
6015A
All
All
All
6010A, 6011A, 6012B
6015A
All
All
All
All
All
All
All
All
6010A, 6011A, 6012B
6015A
All
All
All
All
All
All
All
Agilent Part Number
NOT USED
0160-4830
0160-5422
0160-4831
0160-4812
0160-4831
0160-5422
0160-4812
0160-5166
0160-4832
0160-5422
0160-4835
0180-0291
0180-4129
0180-1731
0180-0230
0180-1731
0180-0291
0180-4129
0180-0230
0160-5422
0160-4801
0160-4835
0160-5422
0160-4812
0160-4835
0180-1980
0180-0116
0180-4132
0160-5422
0160-4801
0160-5422
0160-4822
0160-5422
0180-0376
0180-2624
0180-3407
0160-5098
0160-4835
0160-4833
0160-4832
0160-4830
0160-4813
0160-5422
0160-4812
0160-5422
0160-4812
0160-4832
Description fxd cer 2200pf 10% 100V fxd cer .047
µ F 20% 50V fxd cer 4700pf 10% l00V fxd cer 220pf 5% 100V fxd cer 4700pf 10% 100V fxd cer .047
µ F 20% 50V fxd cer 220pf 5% 100V fxd cer .015
µ F 20% 100V fxd cer .01
µ F 20% 100V fxd cer .047
µ F 20% 50V fxd cer .1
µ F 10% 50V fxd elect 1 µ F 10% 35V fxd elect 1 µ F 10% 35V fxd cer 4.7
µ F l00V fxd elect 1 µ F 20% 50V fxd cer 4.7
µ F 100V fxd elect 1 µ F 10% 35V fxd elect 1 µ F 10% 35V fxd elect 1 µ F 20% 50V fxd cer .047
µ F 20% 50V fxd cer l00pf 5% l00V fxd cer .1
µ F 10% 50V fxd cer .047
µ F 20% 50V fxd cer 220pf 5% l00V fxd cer .1
µ F 10% 50V fxd elect 1 µ F 5% 35V fxd elect 6.8
µ F l0% 35V fxd elect 6.8
µ F l0% 35V fxd cer .047
µ F 20% 50V fxd cer 100pf 5% l00V fxd cer .047
µ F 20% 50V fxd cer 1000pf 5% 100V fxd cer .047
µ F 20% 50V fxd elect .47
µ F 10% 35V fxd elect 2000 µ F 10V fxd elect 2200 µ F 35V fxd cer .22
µ F 10% 50V fxd cer .1
µ F 10% 50V fxd cer .022
µ F 10S 100V fxd cer .01
µ F 10% 100V fxd cer 2200pf 10% 100V fxd cer 180pf 52 l00V fxd cer .047
µ F 203 50V fxd cer 220pf 5% l00V fxd cer .047
µ F 20% 50V fxd cer 220pf 5% l00V fxd cer .01
µ F l0% l00V
63
R16
R17
R18
R18
R19
R20
R20
R21
R21
R21
R21
R9
R10
R11,12
R13
R11-13
R13
R14,15
R5
R6
R6
R6
R6
R7
R8
R9
Q9
Q10
Q11
R1,2
R3
R4
Ref. Desig.
CR1-6
CR7,8
CR9,10
CR11
CR12
CR13,14
CR15,16
CR17,18
CR19
CR20-31
CR32
L1
Q1-3
Q4-6
Q7
Q8
Q9
Q9
Agilent Model
All
All
All
All
All
All
All
All
All
All
All
All
All
All
All
All
6010A, 6012B
6011A
6015A
All
All
All
All
All
All
6010A
6011A
6012B
6015A
All
All
6010A, 6011A, 6012B
6015A
All
6010A, 6012B, 6015A
6010A, 6015A
6011A
6012B
All
All
All
6010A, 6011A, 6015A
6012B
All
6010A, 6015A
6011A, 6012B
6010A, 6015A
6011A
6012B
6015A
Table 5-3. Replaceable Parts List (continued)
Agilent Part Number
1901-0033
1901-0050
1901-0033
1901-0050
1901-0033
1901-0050
1901-0033
1901-0050
1901-0033
1901-0050
1901-0992
06023-80090
1854-0823
1855-0413
1854-0823
1853-0012
1854-0635
5060-2944
1853-0036
1858-0023
0686-5125
0683-5125
0757-0483
0683-2015
0698-6615
0699-1011
0698-7631
0757-0424
0683-5125
2100-3353
2100-3352
2100-3351
0698-3433
0757-0465
0698-3430
NOT USED
0757-0379
0686-5125
0683-2015
0698-7082
0683-1025
0683-1024
0757-0442
0686-5135
0686-1025
2100-3274
2100-3350
2100-3273
2100-3274
Description gen prp 180V 200ma switching 80V 200ma gen prp 180V 200ma switching 80V 200ma gen prp 180V 200ma switching a0V 200ma gen prp 180V 200ma switching 80V 200ma gen prp 180V 200ma switching 80V 200ma schottky 40V 3A choke
NPN Si
J-FET P-chan Si
NPN Si
PNP Si
NPN Si
NPN Si (included with heatsink 5060-2944, see A2 Mechanical)
NPN S/HS Assy
PNP Si transistor array fxd comp 5.1K 5% 1/2W fxd film 5.1K 5% 1/4W fxd film 562K 1% 1/8W fxd film 200 5% 1/4W fxd film 3.75K .1% fxd film 3.32K .1% 1/8W fxd film 2.87K .1% fxd film 1.1K
fxd film 5.1K 5% 1/4W trimmer 20K 10% trimmer 1K 10% trimmer 500 ohms fxd film 28.7 1% 1/8W fxd film 100K 1% 1/8W fxd film 21.5 1% 1/8W fxd film 12.1 1% 1/8W fxd comp 5.1K 1/2W fxd film 200 5% 1/4W fxd film 100K 1% 1/8W fxd film 1K 5% 1/4W fxd film 1K 5% 1/4W fxd film 10K 1% 1/8W fxd comp 51K 5% 1/2W fxd comp 1K 5% 1/2W trimmer 10K 10% trimmer 200 10% trimmer 2K 10% trimmer 10K 10%
64
Table 5-3. Replaceable Parts List (continued)
R43
R43
R43
R44
R45
R46
R46
*R40
R41
R41
R41
R40,41
R42
R42
R42
R47
R48
R47,48
R49
R49
R49
**R49
R31
R31
R32
R33
R34
R34
R35
R35
R35
R36
R37,38
R37
R38
R39
R40
R40
Ref. Desig.
R22
R23
R24
R25
R26
R27
R28
R29
R30
Agilent Model
All
All
All
All
All
All
All
All
All
6010A, 6011A, 6012B
6015A
All
All
6010A, 6012B, 6015A
6011A
6010A, 6015A
6011A
6012B
All
6010A, 6011A, 6015A
6012B
6012B
All
6010A
6011A
6015A
6010A
6011A
6015A
6012B
6010A, 6015A
6011A
6012B
6010A, 6015A
6011A
6012B
All
All
6010A, 6012B, 6015A
6011A
6010A, 6012B, 6015A
6010A, 6012B, 6015A
6011A
6010A
6011A
6012B
6015A
Agilent Part Number
2100-3353
2100-3273
2100-3350
2100-3273
2100-3274
0157-0470
0757-0464
0698-4509
0757-0280
0698-3260
0757-0471
0698-8827
0698-3449
0757-0458
0757-0442
0683-l055
0683-3355
0683-l555
0698-3455
0698-4536
0698-4536
0698-3455
0683-4725
0699-1210
NOT USED
0699-1744
0699-0118
0699-3104
0699-1210
0699-1742
0699-0059
0699-0642
0699-1743
0699-0118
0699-1211
0757-0199
0698-8816
0683-1255
0698-4359
0757-0470
0757-0458
0757-0458
0699-1745
0698-7496
5060-3404
Description trimmer 20K 10% trimmer 2K 10% trimmer 200 10% trimmer 2K 10% trimmer 10K 10% fxd film 162K 1% 1/8W fxd film 90.9K 1% 1/8W fxd film 80.6K 1% 1/8W fxd film 1K 1% 1/8W fxd film 464K 1% 1/8W fxd film 182K 1% fxd film 1M 1% 1/8W fxd film 28.7K 1% 1/8W fxd film 51.1K 1% 1/8W fxd film 10K 1% 1/8W fxd film 1M 5% 1/4W fxd film 3.3M 5% 1/4W fxd film 1.5M 5% 1/4W fxd film 261K 1% 1/8W fxd film 340K 1% 1/8W fxd film 340K 1% 1/8W fxd film 261K 1% 1/8W fxd film 4.7K 5% 1/4W fxd film 80K .1% .1W
111.1K and 2M in parallel fxd film 280K 1% .1W
fxd film 20K .1% .1W
fxd film 250K 0.1% fxd film 80K .1% .1W
fxd film 70K .1% .1W
fxd film 5K .1% .1W
fxd film 10K .1% .1W
fxd film 345K .1% .1W
fxd film 20K .1% .1W
fxd film 95K .1% .1W
fxd film 21.5K 1% 1/8W fxd film 2.15 1% 1/8W fxd film 1.2M 5% 1/4W fxd film 402K 1% 1/8W fxd film 162K 1% 1/8W fxd film 51.1K 1% fxd film 51.1K 1% fxd film 560K .1% 1/4W jumper (see W1-3) fxd film 20K .1% 1/4W
2M(two 1M in series)
*R40 is comprised of two 1% fixed film resistors, 11.1K (0698-6979) and 2M (0683-2055), assembled in parallel.
** R49 is comprised of two 1M 1% fixed film resistors (0698-6369) assembled in series.
65
R64
R65
R65
R66
R67
R67
R67
R59,60
R61
R61
R61
R61
R62
R63
R64
R68
R69
R70
R71
R72
R73
R73
R73
R74
R75
R76
R53
R54
R55
R55
R55
R56
R56
R57
R57
R58
R58
R58
R58
R59,60
R59,60
R59,60
Ref. Desig.
R50
R50
R51
R51
R52
R52
R52
R53
R53
Table 5-3. Replaceable Parts List (continued)
Agilent Model
6010A, 6015A
6011A, 6012B
6010A, 6012B, 6015A
6011A
6010A, 6015A
6011A
6012B
6010A, 6015A
6011A
6012B
All
6010A, 6015A
6011A
6012B
6010A, 6012B, 6015A
6011A
6010A, 6011A, 6012B
6015A
6010A
6011A
6012B
6015A
6010A
6011A
6012B
6015A
6010A
6011A
6012B
6015A
All
All
6010A, 6012B, 6015A
6011A
6010A, 6011A, 6015A
6012B
All
6010A, 6015A
6011A
6012B
All
All
All
All
All
6010A, 6015A
6011A
6012B
All
All
All
Agilent Part Number
0686-5135
0686-1025
0698-3433
0699-1742
0699-0059
0699-0642
0757-0451
0757-0462
0757-0458
0698-3450
0757-0451
0757-0462
0757-0458
0757-0199
0698-3155
0757-0124
0757-0344
0757-0449
0698-3572
0699-1630
0698-4486
0698-0442
0757-0438
0698-7668
0757-0344
0757-0449
0698-3572
0699-1630
0757-0124
0683-l015
0757-0124
0757-0270
NOT USED
0757-0473
0683-4725
NOT USED
0757-0459
0757-0123
0757-0270
0683-1015
0757-0449
0698-0085
0757-0452
0757-0289
0757-0442
0757-0461
0757-0460
0698-8827
0757-0438 fxd film 56.2K 1% 1/8W fxd film 34.8K 1% 1/8W fxd film 249K 1% 1/8W fxd film 100 5% 1/4W fxd film 20K 1% 1/8W fxd film 2.61K 1% 1/8W fxd film 27.4K 1% 1/8W fxd film 13.3K 1% 1/8W fxd film 10K 1% 1/8W fxd film 68.1K 1% 1/8W fxd film 61.9K 1% 1/8W fxd film 1M 1% 1/8W fxd film 5.11K 1% 1/8W
Description fxd film 51K 5% 1/2W fxd film 1K 5% 1/2W jumper (see W1-3) fxd film 28.7 1% 1/8W fxd film 70K .1% .1W
fxd film 5K .1% .1W
fxd film 10K .1% .1W
fxd film 24.3K 1% 1/8W fxd film 75K 1% 1/8W fxd film 51.1K 1% 1/8W fxd film 42.2K 1% 1/8W fxd film 24.3K 1% 1/8W fxd film 75K 1% 1/8W fxd film 51.1K 1% 1/8W fxd film 21.5K 1% 1/8W jumper (see W1-3) fxd film 4.64K 1% 1/8W fxd film 39.2K 1% 1/8W fxd film 1M 1% 1/8W fxd film 20K 1% 1/8W fxd film 60.4K 1% 1/8W fxd film 4M fxd film 24.9K 1% 1/8W fxd film 10K 1% 1/8W fxd film 5.11K 1% 1/8W fxd film 39.91K 1% fxd film 1M 1% 1/4W fxd film 20K 1% 1/4W fxd film 60.4K 1% 1/8W fxd film 4M fxd film 39.2K 1% 1/8W fxd film 100 5% 1/4W fxd film 39.2K 1% 1/8W fxd film 249K 1% 1/8W fxd film 221K 1% 1/8W fxd film 4.7K 5% 1/4w
66
Table 5-3. Replaceable Parts List (continued)
Ref. Desig.
R77
R78
R79,80
R81
R81
R82
R83
R84
R85
R86
R87
R87
R87
R88
R88
R88
*R88
R89-91
R92
R92
R92
R93
R94,95
R96
R97
R98
R99
R100
R101
R102
R103
R104,105
R106
R106
R107
R108
R109
R110
R111
R112
R113
R114
R115
R116,117
R118
R119
R120
R121
R122
All
All
All
All
All
All
All
All
All
All
All
All
All
All
All
All
All
All
All
All
All
All
All
All
All
All
Agilent Model
6010A, 6012B, 6015A
6011A
All
All
All
All
All
6010A, 6012B
6011A
6015A
6010A
6011A
6012B
6015A
6010A, 6015A
6011A
6012B
All
All
All
All
6010A, 6015A
6010A, 6011A, 6012B
Agilent Part Number
0683-4715
0698-6322
0683-2035
0757-0419
0698-3444
0683-4715
0698-6322
0698-6320
0698-6983
0757-0465
0698-7933
0698-6322
0699-2850
0699-1745
0698-8695
0698-6979
5060-3405
0683-2225
0898-4480
0757-0457
0757-0464
0683-3325
0683-2225
0757-0481
0757-0290
0757-0444
0698-4416
0757-0404
0698-4608
0698-4447
0698-4416
0683-4725
0757-0404
0683-2715
0683-1815
0683-2715
0683-1815
0683-5105
0683-2035
0757-0199
0757-0283
0683-2225
0757-0280
0757-0346
0698-3498
0757-0438
0683-4725
0683-2025
0683-1025
Description fxd film 470 5% 1/4W fxd film 4K 1% 1/8W fxd film 20K 5% 1/4W fxd film 681 1% 1/8W fxd film 316 1% 1/8W fxd film 470 5% 1/4W fxd film 4K 1% 1/8W fxd film 5K .1% 1/8W fxd film 20.4K .1% 1/8W fxd film 100K 1% 1/8W fxd film 3.83K .1% 1/8W fxd film 4K 1% 1/8W fxd film 10.01K 0.1% 25PM fxd film 500 .1% 1/8W fxd film 36K .1% 1/8W fxd film 111.1K .1% 1/8W
2.5M (two 1.25M in series) fxd film 2.2K 55 1/4W fxd film 15.8K 1% 1/8W fxd film 47.5K 1% 1/8W fxd film 90.9K 1% 1/8W fxd film 3.3K 5% 1/4W fxd film 2.2K 5% 1/4W fxd film 475K 1% 1/8W fxd film 6.19K 1% 1/8W fxd film 12.1K 1% 1/8W fxd film 169 1% 1/8W fxd film 130 1% 1/8W fxd film 806 1% 1/4W fxd film 280 1% 1/8W fxd film 169 1% 1/8W fxd film 4.7K 5% 1/8W fxd film 130 5% 1/8W fxd film 270 5% 1/4W fxd film 180 5% 1/4W fxd film 270 5% 1/4W fxd film 180 5% 1/4W fxd film 51 5% 1/4W fxd film 20K 5% 1/4W fxd film 21.5K 1% 1/8W fxd film 2K 1% 1/8W fxd film 2.2K 5% 1/4W fxd film 1K 1% 1/8W fxd film 10 1% 1/8W fxd film 8.66K 1% 1/8W fxd film 5.11K 1% 1/8W fxd film 4.7K 5% 1/4W fxd film 2K 5% 1/4W fxd film 1K 5% 1/4W
R123
R124
All
All
0683-4715
0757-0442 fxd film 470 5% 1/4W fxd film 10K 1% 1/8W
* R88 is comprised of two 1.25M 0.1% fixed film resistors (0698-6950) assembled in series.
67
R150
R150
R151
R152
R153
R154
R155
R156
R157
R158
R159,160
R161
R162
R163
R164
R165
R166,167
R168
R169
R170
R171
R172
R173
R174
R175
R176
R141
R142
R143
R144
R145
R146
R147
R148
R149
R134
R135
R136
R137
R138
R139
R140
Ref. Desig.
R125
R126
R127
R128
R129
R130
R131
R132
R133
Agilent Model
All
All
All
All
All
6010A, 6015A
All
All
All
All
All
All
All
All
All
All
All
All
All
All
All
All
All
All
All
All
All
All
All
All
All
All
All
All
All
All
All
All
All
All
All
All
All
All
All
All
All
All
6010A, 6015A
6011A, 6012B
All
Table 5-3. Replaceable Parts List (continued)
0754-0404
0683-2715
0683-4725
0757-0442
0757-0443
0757-0451
0757-0444
0683-4725
0683-1005
0686-2005
0686-6215
0757-0283
0757-0442
0757-0283
0757-0434
0683-1035
0686-1315
0683-1515
0757-0124
0698-3136
0757-0280
0811-3174
0683-2225
0683-3625
0683-1525
0683-2225
Agilent Part Number
0757-0465
0757-0442
0698-8827
0698-3136
0698-4121
NOT USED
0757-0449
1810-0205
0683-5625
0683-1025
0683-1855
0757-0420
0698-4435
0757-0199
0683-4725
0683-2025
0683-5135
0683-6835
0683-4725
0757-0415
0683-1005
0683-1035
0683-5115
0757-0422
0683-2025
Description fxd film 100K 1% 1/8W fxd film 10K 1% 1/8W fxd film 1M 1% 1/8W fxd film 17.8k 1% 1/8W fxd film 11.3K 1% 1/8W fxd film 20K 1% 1/8W resistor network fxd film 5.6K 5% 1/4W fxd film 1K 5% 1/4W fxd film 1.8M 5% 1/4W fxd film 750 1% 1/4W fxd film 2.49K 1% 1/8W fxd film 21.5K 1% 1/8W fxd film 4.7K 5% 1/4W fxd film 2K 5% 1/4W fxd film 51K 5% 1/4W fxd film 68K 5% 1/4W fxd film 4.7K 52 1/4W fxd film 475 1% 1/8W fxd film 10 52 1/4W fxd film 10K 52 1/4W fxd film 510 5% 1/4W fxd film 909 1% 1/8W fxd film 2K 5% 1/4W fxd film 130 5% 1/4W fxd film 270 5% 1/4W fxd film 4.7K 5% 1/4W fxd film 10K 1% 1/8W fxd film 11K 1% 1/8W fxd film 24.3K 1% 1/8W fxd film 12.1K 1% 1/8W fxd film 4.7K 5% 1/4W fxd film l0 52 1/4W fxd comp 20 5% 1/2W fxd comp 620 5% 1/2W fxd film 2K 1% 1/8W fxd film l0K 1% 1/8W fxd film 2K 1% 1/8W fxd film 3.65K 1% 1/8W fxd film 10K 5% 1/4W fxd comp 130 5% 1/2W fxd comp 150 5% 1/4W fxd film 39.2K 1% 1/8W fxd film 17.8K 1% 1/8W fxd film 1K 1% 1/8W fxd WW .07 5% 5W fxd film 2.2K 5% 1/4W fxd film 3.6K 5% 1/4W fxd film 1.5K 55 1/4W fxd film 2.2K 5% 1/4W
68
U12
U13
U14
U14
U15
U16
U17
U18
U19
U20
U21
U22
U23
VR1
VR2
VR3,4
VR5
VR6
W1-3
(R51,VR6)
W1-3 (R49,
R51, VR6)
Y1
Y1
U7
U8
U9
U10
U11
U11
Ref. Desig.
R177
R178,179
R180
R181
R182
S1
U1-3
U4,5
U6
U11
U12
U12
6015A
6010A, 6012B
6011A
Table 5-3. Replaceable Parts List (continued)
Agilent Model
All
All
All
All
All
All
All
All
All
All
All
All
All
6010A, 6012B
6011A
Agilent Part Number
0683-0335
0683-4725
0683-l045
0683-3335
0698-8827
3101-2097
1826-0493
1826-0161
1826-0346
1826-0544
1826-0138
1820-0935
1826-0065
1826-0393
5060-2942
1826-0527 fxd film 3.3 5% 1/4W
IC op-amp
IC op-amp
IC op-amp
Description fxd film 4.7K 5% 1/4W fxd film 100K 5% 1/4W fxd film 33K 5% 1/4W fxd film 1M 1% 1/8W switch (6) 1A
IC voltage regulator
IC voltage reg. Dual trkg.
IC counter CMOS
IC comparator
IC voltage regulator
IC voltage regulator (incorporated into heatsink assy 5060-2942, see A2
Mechanical)
IC volt reg/HS assy
IC voltage regulator
IC voltage regulator (incorporated into heatsink assy 5060-2943, see A2
Mechanical)
IC volt reg/HS assy
IC buffer TTL LS
6015A
All
6010A, 6015A
6011A, 6012B
All
All
All
All
All
All
All
All
All
All
All
All
All
All
6010A, 6012B, 6015A
6011A
5060-2943
1820-1287
NOT USED
Correct Designation is
Q11
1820-1272
1820-1437
1826-0138
1820-1205
1820-1112
1820-2096
1826-0544
1826-0428
1826-0065
1902-3110
1902-0777
1902-0018
1902-0575
7175-0057
7175-0057
IC buffer TTL LS
IC multivibrator TTL LS
IC comparator
IC gate TTL LS
IC flip flop -type
IC counter TTL LS
IC voltage reg
IC voltage regulator
IC comparator zener 5.9V 2% zener 6.2V
zener 6.8V
zener 6.5V 2S jumper (see W1-3) jumper jumper
6010A, 6011A, 6015A
6012B, 6015A
6010A, 6012B, 6015A
6011A
6011A
6011A
0960-0586
1960-0586
A2 MECHANICAL
1205-0282
5060-2942
5060-2943
5060-2944 resonator- cer resonator- cer heat sink (Q9,U11,U12) heatsink assy (includes U11) heatsink assy (includes U12) heatsink assy (includes Q9)
69
A3
A3
A3
A3
C1
C2
C3
J1,2
J3
J4
J5,6
J15
TB1
TB2
C4-6
C7
C8
C9
C10
C11
C12
C13
C14
C15
C16
C17-19
CR1,2
CR3-5
DS1-8
DS9,10
DS9,10
DS11-13
DS11-13
R1-17
R18
R19-37
R38
R39
R40-44
R45
R46-54
R55
R56
R56
R56
R57
Ref. Desig.
Table 5-3. Replaceable Parts List (continued)
All
All
All
All
All
All
All
All
All
All
All
All
All
All
All
All
All
6010A, 6015A
6011A, 6012B
6010A, 6015A
6011A, 6012B
All
6010A
6011A
6012B, 6015A
All
All
All
All
All
All
All
Agilent Model
All
All
All
All
All
All
All
All
All
6010A
6011A
6012B
6015A
All
All
All
Agilent Part Number
1200-0485
1200-0181
1251-8417
1251-7743
1251-8676
1251-5240
1251-0600
0360-2195
0360-2192
06010-60020
06011-60020
06012-60036
06010-60023
0160-5893
0160-0168
0160-4835
0160-5422
NOT USED
0160-5893
0160-0168
0160-4835
0160-5422
NOT USED
0160-4835
0160-5422
0160-4831
0160-4807
0160-5422
1901-0050
1901-0033
1990-0985
1990-0995
1990-0521
1990-0895
1990-0524
0683-2015
0698-3456
0683-2015
0683-1045
NOT USED
0683-2015
0698-3456
0683-2015
0683-1045
0698-8871
0698-6348
0698-6362
NOT USED fxd film 200 5% 1/4W fxd film 287K 1% 1/8W fxd film 200 5% 1/4W fxd film 100K 5% 1/4W fxd film 953 1% 1/8W fxd film 3K 1% 1/8W fxd film 1K .1% 1/8W
IC socket (S1) insulator, (Q8) connector 16-pin connector 26-pin
Description connector 5-pin connector 20-pin connector 1-pin barrier block 6-pos.
barrier block 2-pos.
Front Panel Board
Front Panel Board
Front Panel Board
Front Panel Board fxd plyprpln .047
µ F 10% 100V fxd poly 0.1
µ F 10% 200V fxd cer 0.1
µ F 10% 50V fxd cer .047
µ F 20% 50V fxd plyprpln .047
µ F 10% 100V fxd poly 0.1
µ F 10% l00V fxd cer 0.1
µ F 10% 50V fxd cer .047
µ F 20% 50V fxd cer 0.1
µ F l0% 50V fxd cer .047
µ F 20% 50V fxd cer 4700pf l0% l00V fxd cer 33pf 5% l00V fxd cer .047
µ F 20% 50V photoswitch IF=350ma VAX=15V diode gen prp 180V 200ma display kit led green IF=30ma BVR=5V led green IF=30ma BVR=5V led yellow IF=20ma BVR=5V led yellow IF=20ma BVR=5V fxd film 200 5% 1/4W fxd film 287K 1% 1/8W fxd film 200 5% 1/4W fxd film 100K 5% 1/4W
70
R83
R83
R84
R84
R84
R84
R85
R77
R77
R78
R79
R80
R81
R82
R83
R86
R87
R88
R89
R90
R91
R92
R93
R94
R95
R96
R70
R70
R71
R71
R72
R73
R74
R75
R76
R67
R67
R67
R68
R68
R69
R70
Ref. Desig.
R58
R58
R58
R59
R60-62
R63
R64
R65,66
R65,66
Table 5-3. Replaceable Parts List (continued)
Agilent Model
6010A
6011A
6012B, 6015A
All
All
All
All
6010A, 6011A, 6012B
6015A
6010A, 6011A
6012B
6015A
6010A, 6011A, 6015A
6012B
6010A, 6011A, 6015A
6010A, 6011A
All
All
All
All
6012B
6015A
6010A, 6011A, 6015A
6012B
All
All
All
All
All
All
All
All
All
All
All
All
6010A, 6011A, 6012B
6015A
All
All
All
All
All
6010A
6011A, 6012B
6015A
6010A
6011A
6012B
6015A
All
0698-3159
NOT USED
0757-0458
0683-1025
0683-5135
0683-3025
0683-1025
0698-6363
0698-6343
0698-6322
0698-6563
0698-6363
0698-8861
0699-1211
0757-0438
0683-5135
0757-0199
0683-3925
0698-5808
0686-6815
0757-0452
NOT USED
0683-2025
0757-0280
0683-l035
0683-5125
Agilent Part Number
0698-0533
0698-6392
0699-1212
0683-6215
0683-2015
0683-5125
0683-1025
0683-5615
0683-3201
0757-0449
0757-0453
0757-5615
0698-3201
0757-0449
0757-0442
0698-7353
0698-4493
0698-6671
0757-0280
0698-3476
0698-6362
0757-0452
NOT USED
0683-5135
0757-0441
Description fxd film 4.64K 0.1% 1/8W fxd film 22K 0.1% 1/8W fxd film 19K 0.1% 1/8W fxd film 620 52 1/4W fxd film 200 5% 1/4W fxd film 5.1K 5% 1/4W fxd film 1K 5% 1/4W fxd film 560 5% 1/4W fxd film 560 5% 1/4W fxd film 20K 1% 1/8W fxd film 30.1K 1% 1/8W fxd film 20K 1% 1/8W fxd film 80K 1% 1/8W fxd film 20K 1% 1/8W fxd film 10K 1% 1/8W fxd film 19K 1% 1/8W fxd film 34K 1% 1/8W fxd film 7K 0.25% 1/8W fxd film 1K 1% 1/8W fxd film 6K 1% 1/8W fxd film 1K 0.1% 1/8W fxd film 27.4K 1% 1/8W fxd film 51K 5% 1/4W fxd film 8.25K 1% 1/8W fxd film 26.lK 1% 1/8W fxd film 51.1K 1% 1/8W fxd film 1K 5% 1/4W fxd film 51K 5% 1/4W fxd film 3K 5% 1/4W fxd film 1K 5% 1/4W fxd film 9K 0.1% 1/8W fxd film 9K 0.1% 1/8W fxd film 4K 0.1% fxd film 40K 0.1% 1/8W fxd film 40K 0.1% 1/8W fxd film 6.66K 0.1% 1/8W fxd film 95K 0.1% fxd film 5.11K 1% 1/8W fxd film 51K 5% 1/4W fxd film 21.5K 1% 1/8W fxd film 3.9K 5% 1/4W fxd film 4K 1% 1/8W fxd comp 680 5% 1/2W fxd film 27.4K 1% 1/8W fxd film 2K 5% 1/4W fxd film 1K 1% 1/8W fxd film 10K 5% 1/4W fxd film 5.1K 5% 1/4W
71
U8
VR1
VR2
W1
W2,4
W2,3
W3,5-7
W5
W6,7
W8
W8
Ref. Desig.
R97
R98
R98
R99,100
S1,2
U1,2
U3
U4
U5
U6
U7
J3
All
All
All
All
All
All
All
Agilent Model
All
6010A, 6012B, 6015A
6011A
All
All
All
All
All
All
6011A, 6012B
6010A, 6015A
6011A, 6012B
6011A, 6012B
6010A
6015A
Table 5-3. Replaceable Parts List (continued)
Agilent Part Number
2100-1775
0698-4457
0757-0415
See Chassis Electrical
5060-9436
1826-0876
1820-1144
1826-0502
1826-0138
1826-0493
1826-0346
1826-0502
1902-3092
1902-0064
8159-0005
7175-0057
7175-0057
NOT USED
NOT USED
7175-0057
7175-0057
NOT USED
Description var. ww. trimmer 5K 5% fxd film 576 ohms 1% 1/8W fxd film 475 1% 1/8W switch, rockerarm
IC Converter A/D CMOS
IC NOR Gate TTL LS Quad
Analog Switch, 4SPST, 14pin dip
IC Comparator, quad, 14pin dip
IC Op Amp, Low-Bias-Hi-Impd.
IC Op Amp, gen. purpose
Analog Switch, 4SPST, 14pin dip diode, zener, 4.99V 2% diode, zener, 7.5V 5% res. 0 ohms jumper, solid tinned copper jumper, solid tinned copper jumper, solid tinned copper jumper, solid tinned copper
All
6010A, 6015A
6011A, 6012B
A3 MECHANICAL
1251-5055
5041-0309
4040-2121
Connector Post Type key cap (ref. S1,S2)
Plastic-misc (ref. DS9-13)
A4
C1
C2
C3
C4
C5,6
C7
C7
C8
All
All
All
All
All
All
6010A, 6011A, 6012B
6015A
All
06011-60023
0160-4569
0160-5981
0160-4569
0160-5981
0160-4835
0180-0116
0180-4132
0130-0228
**CR1
CR1
CR2,3
**CR4
CR6-11
F1,2
L1-4
Q1-4
6010A, 6011A, 6012B
6015A
All
All
All
All
All
All
1901-1418
5060-9667
1901-1087
1901-1418
1901-0050
2110-0671
9100-1610
1855-0473
Q5,6
R1-4
R5-8
All
All
All
1854-0585
0811-1065
0698-3609
** If either diode needs replacement, replace both diodes.
FET Board fxd poly .01uf 10S% 800Vdc fxd poly .047
µ
F 10% 630Vdc fxd poly .01
µ
F 10% 800Vdc fxd poly .047
µ
F 10% 630Vdc fxd cer .1
µ
F 10% 50V fxd elect 6.8
µ
F 10% 35V fxd elect 6.8
µ
F 10% 35V fxd elect 22
µ
F 10% 15V diode rect. /HA assy diode rect. /HA assy pwr rect. 600V diode rect. /HA assy diode-switching 80V 200ma fuse .125A 125V coil 150
µ
H 20%
MOS FET N chan.
NPN Si fxd ww 0.2 5% 1/2W fxd met 22 5% 1/2W
72
P1
C2
C2
C3
C3
C4
C4
A5
A5
A5
A5
C1
C1
C2
C2
C4,5
C5
C5
C6
C7
CR1
CR1
CR2
R26
R27
R28
R29-33
R34
TS1
T1
T2
U1-3
VR1,2
Ref. Desig.
R9-11
R12
R13-16
R17-19
R20
R21
R22
R23,24
R25
All
All
All
All
All
All
All
All
All
All
All
All
All
All
All
All
All
All
All
Agilent Model
Table 5-3. Replaceable Parts List (continued)
Agilent Part Number
0698-5139
0757-0466
0698-3609
0698-5139
0757-0379
0683-1505
0683-1815
0686-2005
0757-0466
0683-1815
0757-0379
0683-1505
0683-0475
0683-0275
3103-0081
06011-80091
06011-80095
1820-l050
1902-0779
Description fxd comp 3.9 5% 5W fxd film 110K 1% 1/8W fxd met 22 5% 2W fxd comp 3.9 5% .5W
fxd film 12.l 1% 1/8W fxd film 15 5% 1/4W fxd film 180 5% 1/4W fxd comp 20 5% 1/2W fxd film 1l0K 1% 1/8W fxd film 180 5% 1/4W fxd film 12.1 1% 1/8W fxd film 5% 1/4W fxd film 4.7 5% 1/4W fxd film 2.7 5% 1/4W switch-therm +202F
Transformer
Transformer
DRVR TTL NOR DUAL zener 11.8V 5%
6010A, 6012B
All
All
All
All
All
6010A
6011A
6012B
6015A
6010A, 6012B, 6015A
6011A
6010A
6011A
6012B
6015A
6010A, 6012B, 6015A
6011A
6010A, 6012B
6015A
6011A
6010A
6015A
6010A
6015A
6010A, 6012B, 6015A
6011A
6010A, 6012B, 6015A
A4 MECHANICAL
1205-0398
1252-0093
06032-20001
06032-20002
0380-1524
1252-1053
06030-60024
06011-60024
06032-60029
06030-60029
0180-3167
0160-4832
0160-5464
0160-5422
0160-4569
0160-7222
0160-5422
0180-3167
0160-4832
0160-4835
0160-6077
0160-5464
0160-7222 see chassis electrical
0160-5166
1901-0050
5080-2068
1901-0731 heatsink (ref. CR1,4) socket pin (ref. Q1-4) heatsink (ref. Q1,Q2) heatsink (ref. Q3,Q4) standoff (8mm) connector 64-pin
Diode Board
Diode Board
Diode Board
Diode Board fxd elect 1000 µ F 20% 25V fxd cer .01
µ F 10% 100V fxd poly .01
µ F 5% 1.5KVdc
fxd cer .047
µ F 20% 50Vdc fxd poly .01
µ F 10% 800Vdc fxd poly .0022
µ F 1600Vdc fxd cer .047
µ F 20% 50Vdc fxd cer 1000 µ F 25Vdc fxd cer .01
µ F 10% 100Vdc fxd cer .01
µ F fxd poly pr 0.015
µ F 200V fxd poly .01
µ F 5% 1.5KVdc
fxd poly .0022
µ F 1600Vdc fxd cer 0.015
µ F 100V diode-switching 80V 200ma rectifier matched pair (with CR5) pwr rectifier 400V 1A
73
R5
R6
R6
R7
R7
R7
R8
R8
R9
R9
R9
R9
R10
R10
R10,11
R11
R11
R2
R3
R3
R3
R4
R4
R4
R5
Q2
R1
R1
R2
L3
Q1
Q1
Q1
Q2
F1
F1
L1,2
L1,2
L1,2
L1
Ref. Desig.
CR3
CR2,3
CR4,5
CR4,5
CR4
CR4
CR5
CR6
F1
6010A, 6015A
6010A, 6015A
6011A
6012B
6011A
6012B
6010A, 6012B, 6015A
6011A
6011A
6010A, 6012B, 6015A
6010A, 6012B
6011A
6015A
6010A, 6012B
6011A
6015A
6010A, 6012B, 6015A
6011A
6010A, 6012B, 6015A
6011A
6010A, 6015A
6011A
6012B
6010A, 6012B, 6015A
6011A
6010A
6011A
6012B
6015A
6010A, 6015A
6012B
6011A
6010A, 6015A
6012B
Table 5-3. Replaceable Parts List (continued)
Agilent Model
6010A, 6012B, 6015A
6011A
6010A
6015A
6011A
6012B
6011A
6010A, 6015A
6010A
6011A
6012B
6010A
6011A
6015A
6012B
Agilent Part Number
1901-0050
1901-0050
1901-1542
1901-1388
1901-0731
1901-1182
5080-2068
1902-3203
NOT USED
0698-3151
0757-0459
0683-1025
0757-0459
0698-3202
0757-0317
0698-3202
0757-0317
0698-4196
0683-l045
0698-4211
0683-2735
0757-0465
0683-1025
0698-7332
0757-0447
0698-8144
0757-0428
0757-0480
0683-2055
0698-3512
0698-4196
0698-3601
NOT USED
0686-1005
2110-0699
2110-0546
9170-1334
9170-1272
5080-2132
06012-80003
9170-0707
9170-0894
1855-0767
1854-0264
1855-0549
1855-0549
1854-1070
0683-1855
0811-3460
0686-1005
Description diode-switching 80V 200ma diode-switching 80V 200ma pwr rectifier 400V 50A diode pwr rectifier pqr rectifier 400V 1A pqr rectifier 300V 50A rectifier matched pair (with CR1) diode 14.7V 5% 400mW fxd comp 10 5% 1/2W fuse 5A 125V (axial) fuse 5A 125V (axial) ferrite core for L1,2 core-magnetic ferrite inductor snubber wire ferrite core for L1 core-shield bead (ref. Q1)
MOS FET N chan
NPN Si
MOS FET N chan
FET N-CHAN
NPN Si fxd film 1.8M 5% 1/4W fxd ww 0.05 5% 5W fxd comp 10 5% 1/2W fxd film 2.87K 1% 1/8W fxd film 56.2K 1% 1/8W fxd film 1K 5% 1/8W fxd film 56.2K 1% 1/8W fxd film 1.74K 1% 1/8W fxd film 1.33K 1% 1/8W fxd film 1.74K 1% 1/8W fxd film 1.33K 1% 1/8W fxd film 1.07K 1% 1/8W fxd film 100K 5% 1/4W fxd film 158K 1% 1/8W fxd film 5% 1/4W fxd film 100K 1% 1/8W fxd film 1K 5% 1/8W fxd film 1M 1% 1/8W fxd film 16.2K 1% 1/8W fxd film 787K 1% 1/8W fxd film 1.62K 1% 1/8W fxd film 432K 1% 1/8W fxd film 2M 5% fxd film 1.13K 1% 1/8W fxd film 1.07K 1% 1/8W fxd film 10 5% 2W
74
A6
C101
C101
C102
C102
C103
C103
R19
R20
TS1
TS1
U1
VR1
VR1
R15
R15
R16
R17
R18
R19
R19
Ref. Desig.
R12
R12,13
R13
R14
R14
R14
R14
R15-18
R15-18
Table 5-3. Replaceable Parts List (continued)
Agilent Model
6010A, 6015A
6011A
6010A, 6012B, 6015A
6010A
6011A
6012B
6015A
6010A
6015A
6011A
6012B
6011A
6011A
6011A
6010A
6011A
6015A
6010A, 6015A
6010A, 6011A, 6015A
6012B
All
6010A
6011A, 6012B, 6015A
Agilent Part Number
0757-0447
0698-3609
0683-1005
0811-1746
0757-0459
0811-3290
0811-0923
0811-3729
0811-3842
0683-1855
0811-1068
0698-7332
0698-3151
0683-1005
0689-8144
0811-1903
0683-2055
0811-3731
3103-0082
3103-0081
1826-0346
1902-0515
1902-0575
Description fxd film 16.2K 1% 1/8W fxd met 22 5% 2W fxd film 10 5% 1/4W fxd ww .36 5% 2W fxd film 56.2K 1% 1/8W fxd ww .1 5% 2W fxd ww 0.91ohms 2W fxd ww 250 5% 10W fxd ww 600 ohms 10W fxd film 1.8M 5% 1/4W fxd ww 50 5% 10W fxd film 1M 1% 1/8W fxd film 2.87K 1% 1/8W fxd film 10 10% 1/4W fxd film 787K 1% 1/8W fxd ww 100 5% 10W fxd film 2M 5% fxd ww 1.2 5% 2W switch-thermal 200 degree/C switch-thermal 202 degree/C
IC OP-Amp zener 6.5V 2% zener 6.5V 2%
P1
6010A, 6015A
6010A, 6012B
6012B
6011A
6011A
6011A
6012B
6012B
6010A, 6015A
6010A, 6015A
6010A, 6015A
All
6010A, 6015A
6010A, 6015A
6011A
6011A
6015A
All
6010A, 6011A, 6012B
6015A
6010A, 6011A, 6012B
6015A
6010A, 6011A, 6012B
6015A
A5 MECHANICAL
5020-2878
1205-0398
1252-0093
1205-0520
06011-20001
1205-0398
06032-00018
06032-00017
1251-7600
5020-2877
5020-2878
1251-1053
0340-1123
5080-2065
06011-00001
8150-4777
2190-0100
5060-3522
0160-4355
0160-4048
0160-4281
0160-4439
0160-4355
0160-4048 heatsink (ref. Q1) heatsink (ref. Q1) socket pin (ref. Q2) heatsink (ref. Q1) heatsink (ref. diodes) heatsink (ref. Q2) outer heatsink heatsink bracket connector sgl. Cont. skt.
front heatsink (ref. CR5) rear heatsink (ref. CR4) connector 64-pin
Insulator (ref. L1,2)
Jumper (ref. L1,2) bracket (ref. diode heatsink) wire snubber (ref. T1, L1, L2) lockwasher (CR4 to HS)
AC Input Filter fxd met .01
µ F 10% 250Vac fxd ppr-met .022
µ F 250V fxd met 2200pf 20% 250Vac fxd ppr-met .0047
µ F 250V fxd met .01
µ F 10% 250Vac fxd ppr-met .022
µ F 250V
75
Ref. Desig.
C104
C105
C106,107
C106,107
C108,109
L101
R101
W101-103
TB110
A9
C1,2
C3
CR1
CR2,3
R1-4
W1
W7
W8
6015A
6015A
6015A
6015A
6015A
6015A
6015A
All
6011A
6011A
6015
All
Table 5-3. Replaceable Parts List (continued)
All
All
All
All
Agilent Model
6010A, 6011A, 6012B
All
6010A, 6011A, 6012B
6015A
Agilent Part Number
0160-4281
0160-4962
0160-4183
0160-4439
0160-4962
66000-80004
0686-3945
1251-5613
A6 MECHANICAL
0360-2217
Description fxd met 2200pf 20% 250Vac fxd poly 1 µ F 20% 250Vac fxd met 1000pf 20% 250Vac fxd ppr-met .0047
µ F 250V fxd poly 1 µ F 20% 250V choke, input fxd comp 390K 5% .5W
connector, single
Barrier Block 3-pos
All
All
All
All
6010A
6011A
6012B
6015A
All
All
6012B, 6015A
All
All
All
All
All
All
6010A, 6011A, 6012B
All
All
All
All
All
0180-4231
0160-2569
1901-0325
1901-0759
0764-0027
A9 MECHANICAL
06030-0005
CABLING
06011-60001
5060-2864
CHASSIS
MECHANICAL
5021-8403
5041-8802
5001-0539
06032-00015
06010-00009
06011-00009
06012-00018
06015-00001
0370-1091
5041-0309
5041-2089
4040-1954
06032-00025
06032-00024
06032-00011
06032-00012
0380-1362
06023-00026
1510-0044
0400-0086
0380-1692
5001-6739
5001-6738
OUTPUT BOARD fxd elect 750 µ F 350V fxd cer 0.02
µ F 2KV diode 700V 35A diode 600V PRV 3A fxd met 75K 5% 2W heatsink (ref. CR1) ribbon cable (A2 to A3) see A1 Main Board see A1 Main Board cable assy (ref. fan) front frame casting top trim strip side trim strip front sub-panel lettered front panel lettered front panel lettered front panel lettered front panel knobs plain key cap (ref. Front) lettered key cap display window
Chassis
Internal cover (under top cover, lettered) air baffle (ref. fan, attached to rear panel, sheet metal)
DC output mounting plate standoff (12mm) cover plate (ref. rear panel) binding post, single,(ref. rear panel ground) insulated bushing (ref. rear panel AC Input
Board) standoff (l09.4mm) top cover bottom cover
76
B1
B1
C6
Ref. Desig.
Agilent Model
All
6010A, 6015A
6011A, 6012B
6010A, 6015A
All
All
All
All
6010A, 6015A
6015A
6015A
6015A
6015A
6015A
6015A
6015A
6015A
6010A, 6011A, 6015A
6015A
6015A
6015A
6015A
6015A
6015A
6015A
6015A
10,11,15
10,11,15
10,11,15
15
15
Table 5-3. Replaceable Parts List (continued)
Agilent Part Number
5040-1626
5040-1627
5060-3237
5040-1625
5062-3703
5041-8819
5041-8820
5041-8801
06032-000l0
2190-0587
3050-0894
0535-0077
0515-0155
0515-0064
0515-0156
0515-0210
0515-0211
0515-0413
0515-0414
0515-0610
0515-0642
0515-0751
0515-0896
0515-0968
0515-1132
0515-0031
0515-0964
2190-0586
3050-0893
06671-40002
06671-40003
DC output cover (ref. Barrier Block.) line cord)
Description
AC output cover (ref. AC line cord)
AC output cover with strain relief (ref. AC strain relief (power cord) strap handle handle retainer (front) handle retainer (back)
Foot bus bar-output lockwashers flatwashers hex nuts screw mach M5x0.8 (ref. bus bar) screw mach M3x0.5 (ref. fan) screw mach M4x0.7 (ref. ac input cover) screw mach M4x0.7 (ref. baffle, top cover, diode board to main board, frame casting to frame) screw mach M3x0.5 (ref. rear plate, output bus assy) screw mach M3x0.7 (ref. main board to chassis, ac input board, front panel) screw mach M4x0.7 (ref. line choke, bus bar cover) screw mach M5x0.8 (ref. bus bar to main board) screw mach (ref. bus bar ) screw mach M4x0.7 (ref. pwr xmfr, relay, ac input board ) screw mach M4x0.7 (ref. inside top cover ) screw mach (ref. output bus assy)) screw mach M5x0.8 (ref. strap handle)) nut hex w/lkwr (ref. fan front panel to subpanel) screw (ref. bias transformer A1T3) lock washer (ref. bias transformer A1T3) flat washer (ref. bias transformer A1T3) clamp (ref. bias transformer A1T3) bracket (ref. bias transformer A1T3)
6010A, 6012B, 6015A
6011A
6010A
CHASSIS
ELECTRICAL
3160-0097
3160-0381
0160-2569
Fan
Fan fxd cer 0.02
µ F 20% 2KVdc
77
Ref. Desig.
C28
C28
C28
C30
C30
C31
C34
CB1
L4
R20-23
R99,100
S3
Table 5-3. Replaceable Parts List (continued)
Agilent Model
6010A
6012B
6015A
6010A
6011A
6011A
6010A
All
All
6015A
All
All
Agilent Part Number
0180-3703
0180-3491
NOT USED
0160-4962
0160-0381
0180-3491
0160-6805
3105-0126
5080-2307
0699-0208
2100-4060
3101-0402
Description fxd elect 1500 µ F 250V fxd elect 2600 µ F 75V fxd poly 1.0
µ F 20% fxd poly .01
µ F 10% 400V fxd elect 10,000 µ F 40V fxd poly .01
µ F 10% 400V
Circuit Breaker 4A 65Vdc choke (input line) fxd comp 1 5% 1/4W
5K pot. (ref. Frt. Panel) switch DPST (on/off)
78
6
Component Location and Circuit Diagrams
1.
2.
3.
5.
6.
This chapter contains component location diagrams, schematics, and other drawings useful for maintenance of the power supply. Included in this section are: a.
Component location illustrations (Figures 6-1 through 6-6), showing the physical location and reference designators of almost all electrical parts. Components located on the A6 AC Input Board and on the output filter board mounted on the output bus bars are easily identified by reference designators silkscreened on the boards.
b.
Notes (Table 6-1) that apply to all schematic diagrams.
c.
Schematic diagrams (Figures 6-7 through 6-9).
AC line voltage is present on the A1 Main Board Assembly whenever the power cord is connected to an ac power source.
4.
7.
Table 6-1. Schematic Diagram Notes
.
denotes front-panel marking.
denotes rear-panel marking.
Complete reference designator consists of component reference designator prefixed with assembly number
(e.g.: A2R14).
Resistor values are in ohms. Unless otherwise noted, resistors are either 1/4W, 5% or 1/8W, 1%. Parts list provides power rating and tolerance for all resistors.
Unless otherwise noted, capacitor values are in microfarads.
Square p.c. pads indicate one of the following: a. Pin 1 of an integrated circuit.
b. The cathode of a diode or emitter of a transistor.
c. The positive end of a polarized capacitor.
In schematic symbols drawn to show right-to-left signal flow, blocks of information are still read left to right. For example:
indicates shift away from control block (normally down and to right). indicates shift toward control block
(normally up and to left).
79
8.
Table 6-1. Schematic Diagram Notes (continued) indicates multiple paths represented by only one line. Reference designators with pin numbers indicate destination, or signal names identify individual paths. Numbers indicate number of paths represented by the line.
9.
For single in-line resistor packages, pin 1 is marked with a dot. For dual in-line integrated circuit packages, pin 1 is either marked with a dot, or pin 1 is to the left (as viewed from top) of indication at end of integrated circuit package. e.g.:
Pin locations for other semi-conductors are shown below:
80
Figure 6-1. Top View, Top Covers Removed
81
82
Figure 6-2. Main Board (A1) and Filter Board (A6) Component Location
Figure 6-3. Control Board (A2) Component Location
83
84
Figure 6-4. Front Panel Board (A3) Component Location
Figure 6-5. FET Board (A4) Component Location
85
86
Figure 6-6. Diode Board (A5) Component Location
87
88
89
90
A
System Option 002 (6010A, 6011A, 6012B)
General Information
This option facilitates the operation of the power supply in an automated system. Four major circuit blocks provide:
1 ) remote analog programming of the supply's output by three different control methods; 2) signals indicating the power supply modes and conditions; 3) two different digital methods of remote control; and 4) the outputs of three bias supplies for use with external circuitry.
The power supply equipped with this option can be operated from either a 6940B Multiprogrammer equipped with a
69520A power supply programming card or a 6942A Multiprogrammer equipped with a 69709A power supply programming card.
Remote Programming . Through this interface both the output voltage and current can be remote programmed by either an external voltage source, resistance, or a current sink.
Status Indicators . Six optically isolated lines provide open-collector digital outputs which indicate the following states: constant voltage mode, constant current mode, output unregulated, ac dropout, overvoltage, and overtemperature.
Remote Control.
Two optically isolated methods of remote control are available. 0ne method requires a negative going edge, which sets a latch on the 002 card to inhibit the power supply. The latch and OVP are reset by a negative-going pulse on another input line. The second method of remote control requires a low logic level to inhibit the power supply for the duration of the low level.
Bias Supplies.
The outputs of three bias supplies are also available at the option connector. These outputs are +
15V, -15V, and +5V.
Monitoring.
The 002 Option Board provides two monitoring outputs (I.MON. and V.MON) available at the option connector. They both vary from 0 to 5V corresponding to a 0 to full scale output.
Other modes of operation, such as multiple supply system control, are described in detail in later paragraphs. Modes such as Auto series, Auto Parallel, and Auto tracking operation are described in the Operating Manual.
Specifications
Table A-1 provides specifications for the Option 002. This table is referred to periodically throughout the text of this
Appendix.
Option 002 Hardware
The Option 002 hardware consists of a single printed circuit board installed at the right side (facing the front panel) of the chassis. Two cables connect the option board to the A2 control board at A2J1 and A2J2. Connections between the option board and external circuits are made via the 37-pin connector mounted on the option board and available at the rear of the power supply. A mating connector is also included for the user's convenience.
91
Table A-1. Specifications, Option 002
Remote Programming
Resistance Programming: 0 to 4 k ohm provides 0 to maximum rated voltage or current output.
Accuracy: @25 ° C ± 5 ° C
CV:
CC: 1.0% ± 170mA (6010A)
0.5% ± 35mV (6011A)
1.0% ± 800mA (6011A) *
0.5% ± 70mV (6012B)
1.0% ± 500mA (6012B)
Voltage Programming: 0 to 5V provides 0 to maximum rated voltage or current output.
Accuracy: @25 ° C ± 5 ° C
CV: 0.3% ±
CC: 0.36%
235mV (6010A)
± 170mA (6010A)
0.25% ± 35mV (6011A)
0.4% ± 800mA (6011A) *
0.3% ± 70mV (6012B)
0.36% ± 500mA (6012B)
Current Programming: 0 to 2mA current sink provides 0 to maximum rated voltage or current output.
Accuracy: @25 ° C ± 5 ° C
CV: 0.43%
CC: 0.50%
±
±
235mV (6010A)
170mA (6010A)
* After 5 minute warm-up.a
Input Compliance Voltage: ± 1V
0.25% ± 2mV (6011A)
0.30% ± 35mV (6011A) *
0.43%
0.50%
±
±
71mV (6012B)
500mA (6012B)
Current Programming Enable:
Relays K2 (CV) and K1 (CC) are biased from the Control Isolator Bias input (see Remote Shutdown and OVP Clear)
Relay Bias Voltage: +4V minimum + 7V maximum
Relay Resistance: 500 Ω ± 10%
Note
For Control Isolator Bias voltages greater than 7V, a series resistor must be used to maintain the relay bias voltage within specified limits.
Enabling either relay is accomplished by bringing CV or CC enable line to Control Isolator Bias common via a suitable driver; maximum driver off-state leakage =0.5mA.
Output Voltage and Current Monitor: 0 to 5V output indicates 0 to maximum rated output voltage or current.
Accuracy: @25 ° C ± 5 ° C
CV: 0.3% + 60mV (6010A)
CC: 0.36% + 10mA (6010A)
0.3% ± 15mV (6011A, 6012B)
0.36% ± 20mA (6011A, 6012B)
Output Impedance: 10.2 k ohm ± 5%
Temperature Coefficient:
CV: 12.5 ppm/
CC: 47 ppm/ °
° C +2.4mV/
C + 0.54mA/ °
° C (6010A)
C (6010A)
Status Indicators:
Status Isolator Bias input (referred to Status Isolator Common)
12.5 ppm/ ° C +810 µ V/ ° C (6011A, 6012B)
47 ppm/ ° C + 1.6mA/ ° C (6011A, 6012B)
92
Table A-1. Specifications, Option 002 (continued)
Voltage Range:
Current Drain:
+4.75V to 16V
20mA maximum
Status Indicator output:
Open collector output:
Maximum Output Voltage (logic high) : + 16V
Logic Low output: + 0.4V maximum at 8mA
Remote Control (Trip, Reset, Inhibit) Control Isolator Bias Input.
Voltage Range: +4.75V to 16V
Remote Control Inputs ( Remote Trip , Remote Reset ) Remote Inhibit
On State (logic low):
Minimum forward current required (I f maximum.
): 1.6mA Isolator forward voltage (V f
) at 1.6 mA (I f
): 1.4V typical, 1.75
For Control Isolator Bias voltage greater than ± 5V, an optional resistor (Ropt) may be added to reduce drive current .
Off state ( logic high) maximum leakage current: 100 µ A.
REMOTE TRIP and REMOTE RESET Timing
Pulse duration (TL): 15 µ S minimum
Reset time (TH): 125 µ s minimum
Set-up time (Ts): 25 µ s minimum
OVP clear delay: 1 sec ± 30% Bias Supplies DC output Ratings:
Power-on Preset
Output Ratings: open collector output (referred to power supply common).
Maximum output voltage (logic high):
Logic low output:
+ 16V
+0.4V maximum at 8mA
93
Pulse Timing
Table A-1. Specifications, Option 002 (continued)
Low Bias or AC DROPOUT will go false after 5V supply stabilizes.
Bias Supplies
DC Output Ratings: (25 °C ± 5)
No Load to Full Load 104V to 127V line.
+ 5 V ± 3% at 100mA
+15 V ± 3% at 75mA
-15V ± 4% at75mA
Short Circuit Output Current:
+ 15V
-15V
±
103mA ± 6%
103mA ± 6%
PARD (Typical):
+ 5V
+ 15V
-15V
25mV pk-pk
Same
Same
1.5mV Rms
Same
Same
Isolation:
Status Indicator lines and Remote Control lines may be floated a maximum of 240Vdc (6010A, 250Vdc, 6011A, 6012B) from ground from the power supply or from each other. These lines may not be connected to any primary circuits.
Jumpers Designation
W1--jumpered: OV indication @ A7J3-17 is active (lo) if OVP; Remote Trip or Remote Inhibit is active.
W1--open: OV indication is active (lo) if OVP or Remote Trip is active.
Normal operation as shipped:
OVP Programmable (6011A)
W3 and W4 jumpered W2 and W5 open.
A7J3-25/CV: W2 jumpered; W3 open or
AJ3-24/CC: W5 jumpered; W4 open
S1A,B in open position.
94
Installation
When installing the board, perform the following steps: a.
Remove the top and inner cover of the power supply as discussed in Section 3 under Repair and Replacement.
b.
Remove the plate next to the barrier strip on the rear panel of the supply by unscrewing the 2 M3 screws.
c.
Insert the already prepared 002 board in the slot closest to the right side (looking from the front panel) of the supply.
d.
Use the two M3 screws to connect the rear end of the 002 board to the rear panel of the supply.
e.
Attach ribbon cables from the A2 Control Board A2J 1 to A7J1 and A2J2 to A7J2.
f.
Replace the inner and outer cover of the supply.
g.
Remove 550V label from rear of unit.
Connector Assembly Procedure
The following instructions describe assembly of the mating connector provided to interface the user's system with the option connector, J3. Figure A-1 identifies the parts of the mating connector.
Proceed as follows:
Note:
It may be desirable to set up a test interface before final assembly of the mating connector to allow checkout of the system. A mating connector with pins accessible for temporary wiring is available from Agilent Technologies, Agilent part number 1251-4464. If the cable assembly presents RFI or
ESD problems, a shielded cable assembly accessory Agilent part number 5060-2890 can be ordered.
a.
If a multi-wire cable is being used as opposed to individual wires), remove approximately 1 1/2 inches of cable insulation from the end. Be careful not to cut the insulation on the individual wires.
b.
Strip 3/16 inch of insulation from the end of each wire to be used.
c.
Insert each wire into a contact pin (1) and crimp firmly.
d.
Insert each pin into a proper hole in connector-pin house (2) from rear. Pins will lock into housing when fully inserted.
Note
Once the pins are locked into the connector-pin housing, they are extremely difficult to remove.
Therefore, be certain pin is in proper hole before inserting fully.
e.
Screw a slotted setscrew (3) partially into a square nut (4) and place in position in connector shield assembly
(6).
f.
Place strain relief (5) in position in connector shield assembly (6), just under set screw (3). Be certain that strain relief is oriented as shown in Figure A-1.
g.
Place connector pin housing (2) in shield assembly (6) and route cable through cable entrance.
h.
Fold connector assembly (6) and secure with three screws.
i.
Strain relief set screw (3) can now be adjusted from top of connector to clamp firmly on cable.
j.
Clip fasteners (7) onto ends of connector pin housing (2).
k.
Connector can now be plugged onto option connector J3 and secured with two screws (8) into the threaded stand-offs on either side of J3.
95
Figure A-1. Mating Connector Assembly
Operation
The following paragraphs provide the operating instructions necessary to interface a 002-equipped power supply into an automated system. A brief description of some circuits is also provided. The unit is shipped for front panel operation with mode switch settings as follows:
B1
0
B2
1
B3
1
B4
0
B5
1
B6
1
Before beginning, switch the power supply's rear panel MODE switches B1 through B6 to their correct positions for the programming source being used, (see Table A-2).
Next switch A1 and A2 also on the rear panel, to the correct program source function, see Figure A-2. All connections are made at the 37-pin rear panel connector J3, and can be wired directly into the mating connector supplied for this purpose.
96
Figure A-2. 002 Option Rear Panel Connector J3 and Switches A1 and A2.
Local/Remote Programming
When switching to local/ control, remember to set Front Panel Voltage and Current Control to safe levels.
Local Programming (Figure A-3).
The supply can be switched back and forth between remote and local programming while initially checking out a remote programming circuit. For proper operation of local programming, the user must supply the bias voltage (CONTROL ISOLATOR BIAS). The Control Isolator Bias voltage can range from +4.75V to + 16V depending upon the user's interface circuits. Refer to Specifications
Table A-1. For local programming, take the Control Isolator Bias common and connect it to both of the LOC/REM terminals, and position mode switch as indicated in Operation.
Although CONTROL ISOLATOR BIAS can be + 4.75V to + 16V, a supply voltage of more than 7V may damage the relays. Therefore, if CONTROL ISOLATOR BIAS exceeds 7V it is necessary to use a resistor in series with each of the LOC/REM terminals. Figure A-4 provides a graph from which the proper series resistance value can be determined. Note that the tolerances of both the Control Isolator Bias and the resistor must be taken into account. The actual Control
Bias used in Figure A-4 is obtained after subtracting any driver gate voltage drop.
97
Figure A-3. Accessing Local Programming while in Remote Programming Mode
If solid state circuitry is used, connect the Control Isolator Bias to a driver capable of sinking 10mA of current, then connect the driver's output to both of the LOC/REM terminals. Refer to Figure A-3. Either method will enable relays K1 (CV) and K2 (CC) to switch regulation to the front panel VOLTAGE and CURRENT controls. For
Control Isolator Bias voltages greater than 7V, a resistor (Ropt) must be used in series with the Control Isolator Bias common or the Driver's output. Figure A-4 provides a graph for determining the proper series resistance value depending on the Control Isolator Bias voltage being used.
The supply can be returned to the remote programming mode by switching off the Control Isolator Bias common or by increasing the Driver's output signal to within 1V of the Control Isolator Bias voltage. If remote programming is solely desired, leave the LOC/REM terminals open and make the proper connections to the RESISTOR/VOLTAGE
PROG. or CURRENT PROG. terminals (see Figures A-5, A-6, A-7).
Table A-2. Mode Switch settings for enabling different Programming Sources
Switch Pole Settings
Program Source Mode
B1 B2 B3 B4 B5 B6
Resistance
Voltage or
Current
0
0
0
1
1
0
0
0
0
1
1
0
98
Figure A-4. Calculating Value of Series Dropping Resistor
Remote Resistance Programming
Check switches A1 and A2 on the rear panel, they must be in their correct positions for CV and CC resistance/voltage programming (see Figure A-2). A resistance variable from 0 to 4K ohms can be used to program the output voltage or current from 0 to full scale. To program the output voltage, connect the variable resistance between J3-25 (CV RES/VOLT PROG.) and J3-22 (E COM.). To program the output current, connect the variable resistance from J3-24 (CC RES/VOLT PROG.) to J3-22 (E COM.).
If the programming lines become open circuited during resistance programming (user’s system becomes disconnected from J3), the power supply's output will tend to rise above rating. The supply will not be damaged if this occurs, but the user's load may be damaged. To protect the load, be sure that the overvoltage trip point is properly adjusted. The unit includes clamp circuits to prevent it from supplying more than about 120% of rated output voltage or current when the remote programming voltage is greater than 5Vdc or remote programming resistance is greater than 4K ohm. Do not intentionally operate the unit above 100% rated output. Limit your programming voltage to 5Vdc and programming resistance to 4K ohm to assure reliable operation.
Remote Voltage Programming (Figure A-6).
Check switches Al and A2 on the rear panel, they must be in the correct positions for CV and CC resistance/ voltage programming (see Figure A-2). A voltage source variable from
0 to 5 volts, can be used to program the output voltage or current from 0 to full scale. The load on the programming source is less than 1mA. To program voltage, the voltage source should be connected from J3-25 (CV RES & VOLT
PROG) to J3-22 (E COM). To program current, the voltage source should be connected from J3-24 (CC RES &
VOLT PROG) to J3-22 (E. COMMON). If the programming lines become open circuited (user's system becomes disconnected from J3) during voltage programming, the Programming Protection circuit will reduce the power supply output to zero.
99
Figure A-5. Remote Resistance Programming
100
Figure A-6. Voltage Programming of Output Voltage and Current
Current Programming (Figure A-7).
Check switches A1 and A2 on the rear panel, they must be in the correct positions for CV and CC current programming (see Figure A-2). A current sink variable from 0 to 2mA, can be used to program the output voltage or current from 0 to full scale (see Figure A-7). The following paragraph provides a brief circuit description, refer to schematic diagram.
Figure A-7. Current Programming of Output Voltage and Current
To program voltage, the current sink can be connected from J3-21 (CV CURRENT PROG) to J3-20 ( -15V). To program current, the current sink can be connected from J3-2 (CC CURRENT PROG) to J3-20 ( -15V). Current sinks can either be connected to the power supply ( -15 V) or to an external negative supply that is referenced to the
L. COMMON of the power supply.
The 0 to 2mA current sink will cause the output signal of op-amps U17 and U18 to vary proportionally from 0 to 5 volts. These signals are then coupled through relays K1 and K2 and then on to the A2 Board's CV and CC circuits which, in-turn, will program the supply's output from 0 to full scale. If the programming lines become open circuited
(user's system becomes disconnected from J3) during current programming, the Programming Protection circuit will bring the power supply output to zero.
Remote Monitoring
The 002 Option board provides a protected 0 to 5V output corresponding to a full scale voltage output. The voltage monitor output is available between pins J3-5 (V. Monitor) and J3-1 (D COMMON).
Observe the caution described in Local Programming (Figure A-3) paragraph, page 96.
101
Output impedance is l0K ohm: the monitoring device input impedance should be at least 1M ohm to limit error to
1% + basic accuracy; 10M ohm to limit error to 0.1% + basic accuracy.
The I. MON signal from the mainframe is also brought out through the 002 Option board. A 0 to full scale currentmonitor output is available between pins J3-3 (I. MON) and J3-1 (D COMMON). Output impedance is l0K ohms: the monitoring device input impedance should be at least 1M ohm to limit error to 1% + basic accuracy.
In some applications it may be desirable to install a noise-suppression capacitor on these monitor outputs to lessen the effects of noise induced in the monitor leads. The capacitors should be ceramic or tantalum type, from 0.1 to
1 µ F. The capacitor is installed directly across the monitor device input terminals .
Status Indicators
Six optically isolated lines provide open collector digital outputs which indicate certain modes and conditions of power supply operation. For proper supply operation of the opto-isolators, the user must supply the bias voltage,
(ISOLATOR BIAS). This voltage can be from +4.75 V to + 16V depending upon the user's interface circuits, refer to the specifications Table A-1. Connect the bias voltage ( + ) between J3-37, (ISOLATOR BIAS) and J3-34
(ISOLATOR COMMON). The status indicator outputs are open collector (referenced to ISOLATOR common); therefore, it is necessary to connect a pull-up resistor from each output to ISOLATOR BIAS. When choosing the resistor value observe the current sink capabilities of these lines as described in the Specifications Table A-1.
Because of the relatively slow rise and fall times of opto-isolators, Schmitt-triggered devices should be used to interface these output lines to logic circuits.
The following signals are in active low-form: a.
CV MODE , J3-36, indicates that the power supply is in constant voltage operation.
b.
CC MODE , J3-35, indicates that the power supply is in constant current operation.
c.
OUTPUT UNREGULATE D , J3-18, indicates that the power supply is in neither constant voltage nor constant current operation and cannot be guaranteed to meet specifications.
d.
e.
trip point set at the front panel; or, a system-initiated shutdown as described in multiple supply system shutdown section, page 103.
OVERTEMPER ATURE , J3-16, indicates power supply shutdown due to an excessive temperature rise on the
FET or output diode heatsink.
The Low Bias AC DROPOUT signal, J3-19, is in active high form. This signal indicates: loss of primary power, momentary AC dropout. or "brownout'' conditions where the AC line voltage drops below approximately 70% nominal.
Remote Control
For operation of the opto-isolators. the user must supply the bias voltage (CONTROL ISOLATOR BIAS). This voltage can be from + 4.75V to + 16V depending on the requirements of the driving circuits. The type of driving logic and bias voltage will determine the amplitude of the high and low logic levels, refer to the Specification Table
A-1 under Remote Control.
Connect the bias voltage ( + ) to J3-10 CONTROL ISOLATOR BIAS, and reference the input signals to this bias supply's negative terminal.
Two optically isolated methods of remote control are available. They are described in the following paragraphs.
102
Remote Trip.
A negative-going edge applied to terminal J3-30 ( REMOTE TRIP ) will shut down the power supply, reducing the output voltage to near zero. For minimum pulse duration and timing considerations with respect to REMOTE RESET , see Table A-1. The following paragraph provides a brief circuit description (see schematic diagram and Figure A-8).
A negative going edge at REMOTE TRIP coupled through opto-isolator (U9) causes one-shot U13B to set the
TRIP/RESET latch (U5A) low. This sets terminal J1-13 ( INHIBIT ) low, thus inhibiting the Pulse Width Modulator of the power supply. It also lights the unregulated indicator on the front panel and generates an unregulated signal from the opto-isolator U3.
The low signal generated by the Trip/Reset Latch is also coupled through opto-isolator U2 and appears at J3-17 as an
Remote Reset.
A negative-going edge applied to terminal J3-29 ( REMOTE RESET ) will return the supply to its initial state following a system-initiated shutdown or an OVP shutdown caused by a temporary over voltage condition. For minimum pulse duration and timing considerations with respect to REMOTE TRIP see Table A-1 under Remote Control. The following paragraphs provide a brief description of this circuit (see schematic diagram and Figure A-8).
A negative-going pulse applied to terminal J3-29 ( REMOTE RESET ) is coupled through opto-isolator U10.
One-Shot U13A then triggers and resets the TRIP/RESET latch output high. This sets terminal J1-13 ( INHIBIT ) high, thus enabling the power supply's Pulse Width Modulator.
The REMOTE RESET signal will also reset the power supply OVP circuit in the event that an overvoltage condition has shut down the supply. When a REMOTE RESET signal is present, ONE SHOT U13A goes low, this will produce an OV CLEAR pulse at terminal J1-12. The OV CLEAR pulse will cause the output of A2U2 to go low thus, resetting the OV FLIP FLOP. When this occurs the output of A2U24D goes high and simultaneously causes the front panel OV LED to turn off and the OV signal (J1-6) to go high. The
U4B also goes high and enables the PWM of the power supply .
Note
By observing the a reset pulse to REMOTE RESET , the user can determine the cause of shutdown. If the output returns and shutdown. If the output takes about one second to return, this indicates that the output voltage had exceeded the OVP trip point. If the OVP circuit trips continually, check the load and/or the trip point setting.
Alternate Method of Remote Control.
The REMOTE INHIBIT input, J3-31, provides an alternate method of remote shutdown. By maintaining a low logic level at this input, the supply's output will be inhibited until
REMOTE INHIBIT is returned to its initial high state. The following paragraph provides a brief description of this circuit (see schematic diagram and Figure A-8).
A low logic level applied to terminal J3-31 ( REMOTE INHIBIT ) is coupled through opto-isolator U8 and causes
U4B to inhibit the power supply's (PWM) Pulse Width Modulator. If jumper W1 is used (see Figure A-8) while a
REMOTE INHIBIT signal is applied, an
103
Figure A-8. Remote Control
Power-On Preset
This open collector output line J3-6, provides a logic low pulse ( Power On Preset ) to the user that can be used to initialize or delay a system's operation until + 5 V Reg. supply has stabilized. The pulse is generated after primary power is turned on and also after resumption of power following momentary ac dropout or conditions in which line voltage drops below approximately 70% of the nominal. See Table A-l for specifications.
Power On Preset signal
(
The Power On Preset circuit also ensures that terminal J3-17 ( supply is turned on. This protects against unwanted Multiple Supply System Shutdowns when using J3-17
The following paragraphs provide a brief description of the power-on preset circuit, refer to schematic diagram
(Section 6).
Circuits on the Power Supply's A2 Control Board produce a power-clear signal, ( PCLR ), when the supply is turned on. These circuits hold PCLR low until the unregulated input to the A2 Board's + 5Vdc bias supply is greater than about 11Vdc, an input voltage sufficient to assure + 5Vdc bias output.
This PCLR signal is coupled through terminal J1-15 to the 002 Option board's power-on preset circuit. When the power-on preset circuit receives the PCLR signal, transistors U14A and U14C turn off.
Turning U14A off causes a DROPOUT signal to appear at terminal J3-19 ( DROPOUT ). Turning U14C off causes
U14B and U14D to turn on. When U14B is on, it holds output J3-17 ( high will prevents any unwanted Multiple Supply Shutdown's from occurring when the supply is wired for such an application. When U10D is on, it causes J3-6 ( a customer's system operation.
Power On Preset ) to be low thus, if used, can initialize or delay
104
AC Dropout Buffer Circuit
This circuit couples, inverts and isolates the DROPOUT signal (received from the A2 Control Board) of status output terminal J3-19 ( DROPOUT ). The dropout signal indicates loss of primary power, momentary AC dropout, or "brownout" conditions where the AC line voltage drops below approximately 70% normal. The following paragraph provides a brief description of the AC Dropout Buffer circuit. Refer to the Schematic Diagram
The AC Dropout Buffer Circuit receives a DROPOUT signal from the A2 Control Board. This causes the bias voltage supplied to the Dropout Buffer U14A to be pulled down through diode CR4 thus, turning U14A off. This in turn will cause opto-isolator U3 to turn off. Since external pull up resistors are used, terminal J3-19 (DROPOUT) will go high and remain high until the dropout signal from the A2 Control Board is removed.
Multiple Supply System Shutdown
When using more than one 002 Option equipped power supply in a system, it may be desirable to implement a system shutdown. In this configuration, an OVP trip or remote shutdown of a single unit will cause all of the supplies to shut down.
Figure A-9. System Shutdown using Controller Power Supply
Figure A-9 shows one method of system shutdown. The advantages of this method are that one common is used for all status and control lines (useful for controller-operated systems), and the capability of system reset. As shown in
Figure A-9, one supply's in a continuous chain.
REMOTE TRIP line, and so on
Note
+5V REG/POWER SUPPLY common from Supply 1 can be used instead of the bias voltage from the controller. However, because of current limits of the + 5V REG, no more than four units can be connected together in this configuration. To prevent ground loops, do not parallel connect + 5V
REG from more than one supply.
The note on page 101 tells how to determine if a shutdown was initiated through the remote trip line or by a supply's
OVP. This allows the controller to determine which supply initiated the shutdown. Following a multiple supply shutdown, each unit can be reset individually or all the REMOTE RESET lines can be tied together for a system reset.
105
If it is necessary to have all the supplies come up simultaneously after a system shutdown, follow this procedure: a.
First bring the REMOTE INHIBIT line low.
b.
Provide a negative-going pulse to the REMOTE RESET .
c.
After at least one second, return REMOTE INHIBIT to a high level.
Figure A-10. System Shutdown Using Bias Supply Output
Figure A-10 shows a second method of system shutdown. This method is appropriate in systems which are not controller-operated and in which more than four supplies must be shutdown simultaneously. Because each supply derives its CONTROL ISOLATOR BIAS from the previous supply's + 5V REG, there is no limit to the number of supplies that can be shutdown. Each supply must be reset individually.
Using either method of system shutdown, PCLR inhibits the shutting down succeeding supplies upon initial sum-on. After the supplies have stabilized, PCLR returns to a high state.
Bias Supplies
The outputs of three current-limited bias supplies are available for user-supplied circuitry. These are + 15V @
75mA at J3-4, -15V @ 75mA at J3-20, and +5 V @ 100mA at J3-23; all with respect to J3-7, L Common.
It may be desirable to install noise-suppression capacitors on the bias supply outputs near the load circuits. The capacitors should be ceramic or tantalum type, approximately 0.1
µ F to 10 µ F.
Maintenance
The following paragraphs provide procedures and setups to aid in checking and troubleshooting the 002 Option
Board. This information, used in conjunction with the schematic drawing and the Operation section of this
Appendix, will help in the isolation and repair of faulty circuits.
When testing the option, use of the test connector on page 95 will allow easier access to the J3 contacts.
106
Troubleshooting
Before attempting to troubleshoot the 002 Option Board, ensure that the fault is with the option itself and not with the main power supply. This can be accomplished by removing the top cover, inside cover and disconnecting the two ribbon cables from the A2 Control board and checking the operation of the main supply. Otherwise troubleshoot the option board as described in the following paragraphs.
Removal of the Option Board.
To facilitate troubleshooting the 002 Option the board can be removed from the power supply and electrically connected via the ribbon cables from Service Kit's 06033-60005 or 5060-2665. To remove the circuit board proceed as follows: a.
Turn off power supply and disconnect line cord.
b.
Disconnect option I/O cable from J3 on rear panel and remove the two screws that secure option board to rear panel.
c.
Disconnect the ribbon cables from the A2 Control board.
d.
Remove option board by lifting the board by the front edge and sliding the board toward the front of the power supply.
e.
Reconnect the option board to the A2 Control board using the extended ribbon cables from the Service Kit, and pace the option board on an insulated surface next to the power supply.
f.
Be careful that the option board lies securely on insulating material and does not touch any part of the main power supply.
Isolating Faulty Circuit.
If it is apparent which function is not operating properly, proceed to the appropriate paragraph. If the problem involves more than one function, check the bias voltages from connectors J1 and J2 and the ± 11.8V on the option board.
Troubleshooting Resistance and Voltage Programming
a.
Confirm that the problem is on the option board by disconnecting the ribbon cables from the A2 Control Board and attempting to program the supply via the rear panel terminal strip.
b.
Check ± 15V and ± 11.8V supplies.
c.
Check for a problem in the programming protection circuit. This circuit should draw about 2 µ A from the programming lines.
d.
Check that W3 and W4 are installed and S1 is in proper position .
Troubleshooting Current Programming
a.
Check ± 15V and ± 11.8V supplies.
b.
Proceed to test set-up shown in Figure A-11 and/or A-12.
c.
Put S1 in V, R position and see if varying the 0-20V voltage source produces a 0-5 volt DC level across R44 or
R39. If not, check op-amps and associated circuitry.
107
d.
Put S1 in I position and see if varying voltage source from 0 to 20 volts produces a 0-5VDC level at W3 or W4.
If not check relay and programming protection circuit.
Figure A-11. Troubleshooting Current Programming of CV Mode
Figure A-12. Troubleshooting Current Programming of CC Mode
Troubleshooting Status Indicators.
The test set-up shown in Figure A-13 can be used to check each of the six status indicators. This set-up will temporarily defeat the isolation of the status lines. Before attempting to troubleshoot a status indicator, check for + 5V Bias for proper operation of the opto-couplers.
108
Figure A-13. Troubleshooting Status Indicators
To check CV Mode proceed as follows: a.
Using test set-up, Figure A-13, connect to end of 2K Ω resistor to J3-36.
b.
Turn on power supply.
c.
Using "Display Setting'' set voltage and current or power supply for 1 volt and 1 amp.
d.
DVM should read between 0 to 0.4 volts.
e.
Turn off power supply and short to output terminals.
f.
Turn on power supply.
g.
DVM should read approximately 5Vdc.
To check CC Mode proceed as follows: a.
Using test set-up, Figure A-13, connect top end of 2K Ω resistor to J3-35.
b.
Turn on power supply.
c.
Using "Display Settings'' set voltage for 1 volt and current for 1 Amp.
d.
DVM should read = 5Vdc.
e.
Turn off power supply and short the output terminals.
f.
Turn on power supply.
g.
DVM should read between 0 to 0.4Vdc.
To check a.
Using test set-up, Figure A-13, connect top end of 2K Ω resistor to J3-17.
b.
Turn "OVP Adjust" fully clockwise and voltage control fully counter clockwise.
c.
Open power supply output terminals and turn on power.
d.
DVM should read approximately 5Vdc.
e.
Press 'Display Settings" and increase voltage control for 15Vdc output.
f.
Turn OVP Adjust'' counterclockwise until supply goes into overvoltage.
g.
DVM should read between 0 and 0.4Vdc.
h.
Turn "OVP Adjust" fully clockwise and turn off input power for 5 seconds.
i.
Turn on input power and DVM should read approximately 5Vdc.
To check OUTPUT UNREGULAT ED proceed as follows: a.
Using test set-up, Figure A-13, connect to end of 2K Ω to J3-18.
109
b.
Connect output terminals of power supply to an electronic load capable of exceed the power supplies output power rating by 50%.
c.
Turn on power supply.
d.
DVM should read approximately 5Vdc.
e.
Set voltage and current controls of power supply to maximum.
f.
Decrease resistance of electronic load until "UNREGULATED" LED on front panel lights.
a.
DVM should now read between 0 to 0.4Vdc.
To check LOW BIAS or AC Dropout proceed as follows: a.
Using test set-up, Figure A-13, connect top end of 2K Ω resistor to J3-19.
b.
Substitute an oscilloscope in place of DVM. Set vertical deflection for 1 volt/div on the DC input.
c.
Turn power on and observe oscilloscope trace. Voltage should increase to 5V at power-on and drop to between
0 to 0.4Vac approximately 3 sec.
d.
Turn power off. Voltage should go to about 5Vdc before decaying back to 0V.
Note
In this test, the Low BIAS or AC Dropout signal decays to 0V only because of loss of power to the +
5V REG Bias Supply used in the test set-up. If in doubt, use an external + 5V supply for this test.
To check OVERTEMPER ATURE proceed as follows: a.
Turn off power supply and disconnect line cord.
b.
Wait at least two minutes for input capacitors to discharge .
c.
Remove top cover and inside cover.
d.
Using test set-up, Figure A-13, connect top end of 2K Ω resistor to J3-16.
e.
Turn on power supply.
f.
DVM should read approximately 5Vdc.
g.
Turn off power and wait two minutes.
h.
Remove the A4 FET Assembly from the unit.
i.
Turn on power supply. DVM should read between 0 to 0.4Vdc.
Note
The FET heatsinks are connected to the primary circuit and hazardous voltage (up to between 300 to
400V) exists between the heatsinks and the heatsink and the chassis. These potentials remain for up to
2 minutes if the power supply is turned off. Do not touch the heatsinks or any components on the heatsink assemblies while the power supply is turned on or for at least two minutes after primary power is removed. Do not place any of the heatsink assemblies on extender boards.
Troubleshooting Remote Shutdown.
The following procedures check the Remote Shutdown features of 002
Option. Troubleshooting can be accomplished by using a logic probe and referring to the schematic and the circuit description on page 104. Before attempting to troubleshoot the Remote Shutdown section of the option, check for +
5Vdc internal bias. This voltage must be present for proper operation of these circuits
To check the REMOTE TRIP and REMOTE RESET proceed as follows: a.
Connect +5V (J3-23) to Control Isolator bias (J3-l0).
b.
Turn unit on and short REMOTE TRIP (J3-30) to + 5V common (J3-7) momentarily. Output should go into unregulated condition with output off.
c.
Short REMOTE RESET (J3-29) to + 5V common (J3-7) momentarily and OUTPUT should return to its initial state.
To check REMOTE INHIBIT proceed as follows: a.
Table A-3. Replacement Connect +5V (J3-23) to control isolator bias (J3-10).
b.
Turn unit on and short REMOTE unregulated output off condition.
INHIBIT (J3-31 ) to + 5V common (J3-7). Output should go to an c.
Remove short between initial state.
REMOTE INHIBIT (J3-31 ) and + 5V common (J3-7) and output should return to its
110
MODEL NO,
All
All
All
All
All
All
All
All
All
All
All
All
All
All
All
All
6010
All
All
All
All
All
All
All
All
All
All
All
All
All
All
All
All
6011A, 6012B
All
All
All
All
All
All
All
All
All
All
All
All
All
All
All
REF. DESIG.
A7
C1,2
C3
C4
C5
C6
C7
C8,9
C10
C11
C12,13
C14
C15
C16
C17,18
C19
C20-22
R6
R7
R8,9
R10
R11
R12
R13
R14
CR26-29
CR30
K1,2
L1-3
Q1,2
R1-3
R4
R5
C20-22
CR1-4
CR5-10
CR11-14
CR15
CR16,17
CR18,19
CR20
CR21,22
CR23
CR24,25
R15,16
R17
R18
R19
R20,21
PART NO.
5060-2854
0180-0230
0180-2825
0160-4835
0160-4554
0160-4835
0160-4554
0180-0230
0180-2825
0160-4801
0160-5422
0160-4801
0160-5422
0160-5422
0180-0230
0180-2825
0160-0128
0160-0122
1901-0050
1901-0327
1901-0033
1901-0327
0683-3035
0683-6225
0683-2035
0683-1035
0683-5125
0757-0984
0683-1615
0683-4715
0683-1235
0686-1525
0683-1535
0683-4715
0683-1235
1901-0050
1901-0033
1901-0050
1901-0033
1901-0050
1901-0033
1901-0327
0490-1418
9170-1223
1854-0823
0683-2015
0683-3925
0683-2035
Table A-3. Replacement Parts
DESCRIPTION
Opt. 002 Interface Board fxd elect. 1 µ F 20% 50V fxd elect. 22 µ F 50V fxd cer. 0.1
µ F 10% 50V fxd cer. 0.0
µ F 20% 50V fxd cer. 0.1
µ F l0% 50V fxd cer. 0.0
µ F 20% 50V fxd elect. 1 µ F 20% 50V fxd elect. 22 µ F 50V fxd cer. 100pf 5% l00V fxd cer. 0.047
µ F 20% 50V fxd cer. 100pfF 5% l00V fxd cer. 0.047
µ F 20% 50V fxd cer. 0.047
µ F 20% 50V fxd elect. 1 µ F 20% 50V fxd elect. 22 µ F 50V fxd cer. 2.2
µ F 20% 50V fxd cer. 2.2
µ F 20% 50V switching 80V 200ma pwr. rect. 300V 40A gen. prp. 180V 200ma zener 9.09V 10% PD=1.5W
NOT USED switching 80V 200ma gen. prp. 180V 200ma switching 80V 200ma gen. prp. 180V 200ma switching 80V 200ma gen. prp. 180V 200ma zener 9.09V 10% PD=1.5W
relay 250ma 28V,5V –coil 3VA core shielding bead
NPN SI PD=300mW FT=200MHZ fxd. film 200 5% 1/4W fxd. film 3.9K 5% 1/4W fxd. film 20K 5% 1/4W fxd. film 30K 5% 1/4W fxd. film 6.2K 5% 1/4W fxd. film 20K 5% 1/4W fxd. film 10K 5% 1/4W fxd. film 5.1K 5% 1/4W fxd. film 10 1% 1/2W fxd. film 160 5% 1/4W fxd. film 410 5% 1/4W fxd. film 12K 5% 1/4W fxd. film 1.5K 5% 1/4W fxd. film 15K 5% 1/4W fxd. film 470 5% 1/4W fxd. film 12K 5% 1/4W
111
MODEL NO,
All
All
All
All
All
All
All
All
All
All
All
All
All
All
All
All
All
All
All
All
All
All
All
All
All
All
All
All
All
All
All
All
All
All
All
All
6010A, 6011A
6012B
6010A, 6011A
6012B
All
All
All
All
All
6010A, 6011A
6012B
6010A, 6011A
6012B
All
REF. DESIG.
R39
R40
R41
R42
R43
R44
R45
R46
R47
R48
R49
R50,51
R52,53
R54
R55
R56
R57
R32
R33
R34
R35
R36
R37
R38
R22
R23
R24
R25,26
R27
R28
R29,30
R31
S1
U1-3
U4
U5
U6
U6
U7
U7
U8-10
U11
U12
U13
U14
U15
U15
U16
U16
U17,18
Table A-3. Replacement Parts
PART NO.
0698-6631
0683-4715
0813-0001
0683-4715
0683-l035
0698-6631
0683-4715
0813-0001
0683-1525
0683-3325
0683-2225
0683-3355
0683-1055
0757-0441
0757-0986
0757-0269
0698-3226
0686-1525
0683-1535
0683-4715
0683-1235
0686-1525
0683-1535
0698-4479
0686-5125
0683-5125
0686-5125
0683-5125
0757-0986
0757-0269
0683-4715
0683-1035
3101-2715
1990-0732
1820-1197
1820-1202
5060-2942
1826-0393
5060-2945
1826-0551
1990-0494
1820-1491
1820-1416
1820-l437
1858-0023
5060-2943
1826-0527
5060-2950
1826-0277
1826-0493
DESCRIPTION fxd. film 1.5K 5% 1/4W fxd. film 15K 5% 1/4W fxd. film 470 5% 1/4W fxd. film 12K 5% 1/4W fxd. film 1.5K 5% 1/4W fxd. film 15K 5% 1/4W fxd. film 14K 1% 1/8W fxd. comp. 5.lK 5% 1/2W fxd. film 5.1K 5% 1/4W fxd. comp. 5.1K 5% 1/4W fxd. film 5.1K 5% 1/4W fxd. film 12.1K 1% 1/2W fxd. film 270 1% 1/8W fxd. film 470 5% 1/4W fxd. film 10K 5% 1/4W fxd. film 2.5K .1% 1/8W fxd. film 470 5% 1/4W fxd. ww. 1K 5% 3W fxd. film 470 5% 1/4W fxd. film 10K 5% 1/4W fxd. film 2.5K .1% 1/8W fxd. film 470 5% 1/4W fxd. ww. 1K 5% 3W fxd. film 1.5K 5% 1/4W fxd. film 3.3K 5% 1/4W fxd. film 2.2K 5% 1/4W fxd. film 3.3M 5% 1/4W fxd. film 1M 5% 1/4W fxd. film 8.25K 1% 1/8W fxd. film 12.lK 1% 1/2W fxd. film 270 1% 1/8W fxd film 6.49K 1% 1/8W
Switch-Slide 2-lA .1A 50V
Opto-Isolator IF=20mA max.
IC NAND gate TTL LS quad
IC NAND gate TTL LS
IC Voltage Reg. heatsink assy.
IC Voltage Reg.
IC Voltage Reg. heat sink assy.
IC Voltage Reg.
Opto-Isolator IF=20mA max.
IC Buffer TTL LS, hex
IC Schmitt-Trig. TTL LS, hex
IC Multi. Vib. TTL LS
Trans. Array 16-pin
IC Voltage Reg. heatsink assy.
IC Voltage Reg.
IC Voltage Reg. heatsink assy.
IC Voltage Reg.
IC Op Amp Low-bias-High-Impd.
112
VR11
VR12
VR13
VR14
VR15
VR16
VR17
Z1
REF. DESIG.
U19
U19
U20
U20
VR1-8
VR9
VR10
MODEL NO,
6010A, 6011A
6012B
6010A, 6011A
6012B
All
All
All
All
All
All
All
All
All
All
All
A7J3
W1
W2
W3,4
W5,6
All
All
6010A
All
All
All
All
All
All
PART NO.
5060-2942
1826-0393
5060-2946
1826-0607
1902-0556
1902-3185
1902-0556
1902-3256
1902-0779
1902-3180
1902-3110
1902-0575
1902-0556
1902-3256
1810-0276
Table A-3. Replacement Parts
DESCRIPTION
IC Voltage Reg. heatsink assy.
IC Voltage Reg.
IC Voltage Reg. heatsink assy.
IC Voltage Reg.
zener 20V 5% PD=1W IR=5 µ A zener 12.4V 5% PD=.4W
zener 20V 5% PD=1W IR=5 µ A zener 23.7V 5% PD=.4W
zener 11.8V 5% PD=.4W
zener 11.8V 2% PD=.4W
zener 5.9V 2% PD=.4W
zener 6.5V 2% PD=.4W
zener 20V 5% PD=.4W IR=5 µ A zener 23.7V 5% PD=.4W
network res. 1.5K x 9
Mechanical
06023-00025
1251-6075
1205-0282
1258-0189
NOT USED
7175-0057
8120-4356
1251-8417
0360-1300 plate (ref. A7J3) connector 37-pin heatsink (ref. U6, 7, 15, 16, 19, 20) jumper jumper, solid tinned copper ribbon cable, 16 cond.
post type header (ref. J1, J2) solder pin
113
Logic Symbols and Definitions
OLD SYMBOL NEW SYMBOL NOTES
Output requires external components to achieve logic state.
A positive-going transition at A or a negative-going transition at B triggers the one-shot. External timing components connect to non-logic inputs.
Output changes state rapidly regardless of input rate of change.
114
SCHEMATIC DIAGRAM NOTES
1.
ALL RESISTORS ARE IN OHMS, ± 5%, 1/4W, UNLESS OTHERWISE INDICATED.
2.
ALL CAPACITORS ARE IN MICROFARADS, UNLESS OTHERWISE INDICATED.
3.
WHITE SILKSCREENED DOTS ON P. C. BOARDS INDICATE ONE OF THE FOLLOWING.
A.
PIN 1 OF AN I. C. (EXCEPT FOR U18 SEE NOTE 4 ).
B.
POSITIVE END OF A POLARIZED CAPACITOR.
C.
CATHODE OF A DIODE OR THE EMITTER OF A TRANSISTOR.
4.
PIN LOCATIONS FOR SEMICONDUCTORS ARE SHOWN BELOW:
5.
ON VOLTAGE REGULATOR DEVICES:
REF SUPPLY BIAS FOR REGULATORS INTERNAL REFERENCE.
REF = OUTPUT FROM REGULATORS INTERNAL REFERENCE.
BOOST OUTPUT = CONTROL FOR EXTERNAL PASS TRANSISTOR.
CS = CURRENT SENSE.
CL = CURRENT LIMIT.
INV = INVERTING INPUT TO REGULATORS ERROR AMPLIFIER.
NI = NON-INVERTING INPUT TO REGULATORS ERROR AMPLIFIER.
COMP = FREQUENCY COMPENSATION.
115
Schematic Notes
1.
W1 in normally open position.
2.
W3 & W4 jumpered.
3.
Relays K1, K2 normally closed.
4.
S1A and S1B are located at the rear panel.
116
Figure A-15. Option 002 Board, Component Location
Figure A-16. Option 002 Board, Schematic Diagram
117
B
Backdating
Manual backdating describes changes that must be made to this manual for power supplies whose serial numbers are lower than those listed in the title page to this manual.
Look in the following table and locate your Agilent Model. Then look at each serial number listed for this group. If the serial number of your power supply is prior to any of the serial number(s) listed, perform the change indicated in the Change column. Note that several changes can apply to your supply. You may also be instructed to update your power supply if certain components are being replaced during repair.
Model 6010A
Serial Numbers
PREFIX NUMBER
US3711 0101-0170
3711A
3544A
3420A
01800-01929
01605-01799
01400-01604
3306A
3214A
3211A
3140A
3105A
3038A
2846A
2824A
2718A
2707A
2536A
01240-01399
01170-01239
01150-01169
01060-01149
00960-01059
00900-00959
00545-00899
00465-00544
00285-00464
00245-00268
00101-00244
Change
1
1
1,2
1-3
1-4
1-5
1-6
1-6
1-7
1-8
1-9
1-10
1-11
1-12
1-13
Model 6011A
Serial Numbers
PREFIX NUMBER
US3546 0101-0155
3546A
3419A
3313A
01838-01962
01588-01837
01518-01587
3303A
3212A
3142A
3139A
3102A
3037A
2850A
2719A
2709A
01498-01517
01398-01497
01348-01397
01338-01347
01278-01337
01218-01277
00856-01217
00466-00855
00436-00465
2614A
2603A
2520A
2438A
2423A
00296-00435
00286-00295
00211-00285
00161-00210
00101-00160
Change
1
1
1,2
1-3
1-4
1-5
1-5
1-6
1-7
1-8
1-9
1-10
1-11
1-12
1-13
1-14
1-15
1-16
119
Model 6012B
2703A
2616A
2614A
2606A
2524A
2519A
2517A
2439A
2428A
Serial Numbers
PREFIX NUMBER
US3543 0101-0335
3543A
3415A
3319A
3303A
04801-05360
04311-04800
04091-04310
04061-04090
3232A
3212A
3139A
3104A
3037A
2846A
2723A
2709A
03981-04060
03481-03980
03661-03840
03411-03660
03271-03410
02711-03270
01911-02710
01891-01910
01771-01890
01151-01770
01131-01150
01011-01130
00586-01010
00511-00585
00436-00510
00211-00435
00101-00210
Change
1-5
1-6
1-6
1-7
1-8
1-9
1-10
1-11
1
1
1,2
1-3
1-4
1-12
1-13
1-14
1-15
1-16
1-17
1-18
1-19
1-20
Model 6015A
Serial Numbers
PREFIX NUMBER
US3705 0101-0145
3705A
3543A
3424A
3402A
00444-00518
00344-00443
00244-00343
00229-00243
3310A
3310A
3243A
3215A
3142A
3103A
3044A
00219-00228
00179-00218
00174-00178
00144-00173
00124-00143
00109-00123
00101-00108
Change
1-4
1-5
1-6
1-7
1-8
1-9
1-10
1
1
1,2
1-3
1-4
CHANGE 1
All In the parts list for the A1 Main Board Assembly change R45 to 82.5K, 1% 1/8W, p/n 0757-0463.
CHANGE 2
6010A, 6015A In the parts list for the A5 Diode Board Assembly change CR4, 5 to p/n 1901-1182. Change Q1 to p/n 1855-0486. Under A5 Mechanical change the heatsink for Q1 to p/n 1205-0398, change heatsink for CR4 to p/n 06030-00004, change heatsink for CR5 to p/n 06030-00003.
6011A, 6012B In the parts list for the A4 FET Board Assembly change CR1, CR4 to p/n 1901-1137.
CHANGE 3
6010A, 6015A In the parts list for the A4 FET Board Assembly change CR1and CR4 to p/n 1901-1137.
6011A, 6012B In the parts list for the A1 Main Board Assembly change K1 to p/n 0490-1457 and K2 to p/n
0490-1341. Change R47 and R48 to 150 5% 1W, p/n 0761-0035.
CHANGE 4
6010A, 6015A In the parts list for the A1 Main Board Assembly change K1 to p/n 0490-1457 and K2 to p/n
0490-1341. Change R47 and R48 to 150 5% 1W, p/n 0761-0035.
6011A, 6012B In the parts list for the A1 Main Board Assembly make the following changes:
Add:
C3, C7 1400 µ F, p/n 0180-3460
120
R6, 1.3K, p/n 0811-1803
U2, U4, Rectifier, p/n 1906-0006
Delete:
C27, C34, 0.01
µ F 400V, p/n 0160-6805
CR6-CR13, power rectifier 400V, p/n 1901-0731
R24, 200 5% 1/2W, p/n 0686-2015
R43, R44, 2.61K 1% 1/8W, p/n 0698-0085
R45, 82.5K 1% 1/8W, p/n 0757-0463
R46, 681 1% 1/8W, p/n 0757-0419
R47, R48 150 5% 1W, p/n 0761-0035
R49, 100 1% 1/8W, p/n 1902-0955
Q2, FET N-channel, p/n 1855-0665
VR1, diode zener 7.5V 5%, p/n 1902-0955
U6, opto-isolator, p/n 1990-1074
Change:
A1 board to p/n 06011-60021
C1, C2, C4-C6, C8 to p/n 0180-3460
C10 to p/n 0180-0426
DS1 to p/n 1990-0325
K1 to p/n 0490-1457
K2 to p/n 0490-1341
R5 to p/n 0686-3015
R7 to p/n 0686-1005
R8 to p/n 0686-3335
R41 to p/n 0811-1869
CR1 to p/n 1901-0028
Under AC Input Filter, change to p/n 06011-60025. Subtract 100 from all of the reference designators. C101 thus becomes C1. Also delete W101-W103, p/n 1251-5613.
Under Chassis Electrical change L4 to p/n.06011-80093. Also add C27 0.01
µ F 10% 400W, p/n
0160-0381and R24 200 5% 1/2W, p/n 0686-2015.
CHANGE 5
6010A In the parts list for the A1 Main Board Assembly make the following changes:
Add:
C3, C7 1400 µ F, p/n 0180-3460
R6, 1.3K, p/n 0811-1803
U2, U4, Rectifier, p/n 1906-0006
Delete:
C27, C34, 0.01
µ F 400V, p/n 0160-6805
CR6-CR13, power rectifier 400V, p/n 1901-0731
R24, 200 5% 1/2W, p/n 0686-2015
R43, R44, 2.61K 1% 1/8W, p/n 0698-0085
R45, 82.5K 1% 1/8W, p/n 0757-0463
R46, 681 1% 1/8W, p/n 0757-0419
R47, R48 150 5% 1W, p/n 0761-0035
R49, 100 1% 1/8W, p/n 1902-0955
Q2, FET N-channel, p/n 1855-0665
VR1, diode zener 7.5V 5%, p/n 1902-0955
U6, opto-isolator, p/n 1990-1074
Change:
A1 board to p/n 06030-60021
121
6011A
6012B
6015A
C1, C2, C4-C6, C8 to p/n 0180-3460
C10 to p/n 0180-0426
DS1 to p/n 1990-0325
K1 to p/n 0490-1457
K2 to p/n 0490-1341
R5 to p/n 0686-3015
R7 to p/n 0686-1005
R8 to p/n 0686-3335
R41 to p/n 0811-1869
CR1 to p/n 1901-0028
Under AC Input Filter, change p/n to 06011-60025 Subtract 100 from all of the reference designators. C101 thus becomes C1. Also delete W101-W103, p/n 1251-5613.
Under Chassis Electrical change L4 to p/n 06011-80093. Also add C27 0.01
µ F 10% 400W, p/n
0160-0381 and R24 200 5% 1/2W, p/n 0686-2015.
In the parts list for the A1 Main Board Assembly make the following changes:
Change C23, C28 to 0.047
µ F, p/n 0160-5895
Add C21,C24, 0.047
µ F, p/n 0160-5895
Add R21, R22, 1 5% 1/4W, p/n 0699-0208
In the parts list for the A1 Main Board Assembly make the following changes:
Change C20, C22 to 0.047
µ F, p/n 0160-5895
Add C21,C23, 0.047
µ F, p/n 0160-5895
Add R20, R23, 1 5% 1/4W, p/n 0699-0208
In the parts list for the A2 Control Board Assembly change R40 to 95K 1% p/n 0699-1211 and
1.21M 1% p/n 0699-0088 assembled in parallel. Change R41 to 200K 0.1%, p/n 0699-6376.
CHANGE 6
6010A In the Diode board A5 parts list and schematic diagram delete L3.
6011A, 6012B In the parts list for the A1 Main Board Assembly change U1 to p/n 1906-0218.
6015A In the parts list for the A1 Main Board Assembly make the following changes:
Add:
C3, C7 1400 µ F, p/n 0180-3460
R6, 1.3K, p/n 0811-1803
U2, U4, Rectifier, p/n 1906-0006
Delete:
C27, C34, 0.01
µ F 400V, p/n 0160-6805
CR6-CR13, power rectifier 400V, p/n 1901-0731
R24, 200 5% 1/2W, p/n 0686-2015
R43, R44, 2.61K 1% 1/8W, p/n 0698-0085
R45, 82.5K 1% 1/8W, p/n 0757-0463
R46, 681 1% 1/8W, p/n 0757-0419
R47, R48 150 5% 1W, p/n 0761-0035
R49, 100 1% 1/8W, p/n 1902-0955
Q2, FET N-channel, p/n 1855-0665
VR1, diode zener 7.5V 5%, p/n 1902-0955
U6, opto-isolator, p/n 1990-1074
Change:
A1 board to p/n 06030-60021
122
C1, C2, C4-C6, C8 to p/n 0180-3460
C10 to p/n 0180-0426
DS1 to p/n 1990-0325
K1 to p/n 0490-1457
K2 to p/n 0490-1341
R5 to p/n 0686-3015
R7 to p/n 0686-1005
R8 to p/n 0686-3335
R41 to p/n 0811-1869
CR1 to p/n 1901-0028
Under AC Input Filter, change to p/n 06011-60028. Subtract 100 from all of the reference designators. C101 thus becomes C1. Also delete W101-W103, p/n 1251-5613.
Under Chassis Electrical change L4 to p/n 06011-80093. Also add C27 0.01
µ F 10% 400W, p/n
0160-0381 and R24 200 5% 1/2W, p/n 0686-2015.
CHANGE 7
6010A In the parts list for the A1 Main Board Assembly change U1 to p/n 1906-0218. In the parts list for the A5 Diode Board, change L1 to p/n 06011-80094.
6011A, 6012B In the parts list for the A5 Diode Board, change L1 to p/n 06011-80094.
6015A In the parts list for the A1 Main Board Assembly change C11, C12 to p/n 0160-6392. Change
R12, R13 to 2.2 5% 1/4W p/n 0699-0188.
CHANGE 8
6010A, 6012B In the parts list for the A1 Main Board Assembly change T3 to p/n 5080-1982. Delete the following mechanical attaching parts:
Screw, p/n 0515-0964 lock washer p/n 2190-0586 flat washer, p/n 3050-0893
6011A In the parts list for the A1 Main Board Assembly delete T3 and the following mechanical attaching parts:
Screw, p/n 0515-0964 lock washer p/n 2190-0586 flat washer, p/n 3050-0893
6015A In the parts list for the A5 Diode Board, delete L3.
CHANGE 9
6010A, 6011A,
6012B
In the parts list for the Mechanical Chassis change the following parts:
From: To:
Internal cover 06032-00024 06032-00005
Chassis
Cover-top
06032-00025 06032-00016
5001-6739 06032-00020
Cover-bottom
Cover-plate
5001-6738 06032-00019
06023-00026 06023-00010
123
6015A
In the option 002 replaceable parts list change cover plate from p/n 06023-00025 to p/n 06023-
00013. Add cover-plate p/n 06023-00010.
In the parts list for the A1 Main Board Assembly change U1 to p/n 1906-0218. In the parts list for the A5 Diode Board, change L1 to p/n 06011-80094.
CHANGE 10
6010A, 6011A,
6012B
6015A
In the parts list for the Mechanical Chassis change the following parts:
From:
Top cover 06032-00020
To:
06032-00002
Bottom cover 06032-00019 06032-00003
Top trim
Side trim
Front frame
5041-8802
5001-0539
5021-8403
5040-7202
5001-0439
5021-5803
Feet
Strap handle
5041-8801
5062-3703
Handle ret. back 5041-8820
Handle ret. front 5041-8819
5040-7201
5060-8903
5041-6820
5041-6819
Lettered panel 06010-00009 06010-00008
In the parts list for the A1 Main Board Assembly delete T3 and the following mechanical attaching parts:
Screw, p/n 0515-0964 lock washer p/n 2190-0586 flat washer, p/n 3050-0893 clamp, p/n 06671-400002 bracket, p/n 06671-400003
CHANGE 11
6010A
6011A
6012B
In the Diode board A5 parts list and schematic diagram delete CR6.
In the Diode board A5 parts list and schematic diagram change R17 from 2.87K 1%, p/n 0698-
3151 to 4.87K 1%, p/n 0698-4444.
In the Diode board A5 parts list and schematic diagram change R2 from 2.87K 1%, p/n 0698-
3151 to 4.87K 1%, p/n 0698-4444.
CHANGE 12
6010A
6011A
6012B
In the Diode board A5 parts list and schematic diagram change R2 from 2.87K 1% p/n 0698-
3151 to 4.87K 1%, p/n 0698-4444.
In the option 002 (Appendix A) parts list and schematic diagram delete R57 and solder pin p/n
0360-1300.
In the Diode board A5 parts list and schematic diagram change CR4 to p/n 1901-0887. Delete heatsink (ref. Q2) p/n 06032-0018, heatsink bracket 06032-00017 and replace with inner heatsink
(ref. Q2) p/n 06032-00006 and outer heatsink (ref. Q2) p/n 06032-00018.
124
CHANGE 13
6010A
6011A
6012B
In the option 002 (Appendix A) parts list and schematic diagram delete R57 and solder pin p/n
0360-1300.
In the parts list for the A1 Main Board Assembly change C17, C18 to 1000 µ F 50V, p/n 0180-
3019. Change C10 to 22 µ F 250V, p/n 0180-0426.
In the option 002 (Appendix A) parts list and schematic diagram delete R57 and solder pin p/n
0360-1300.
CHANGE 14
6011A
6012B
In the parts list for the A2 Control Board Assembly add R130, 1M 1% 1/8W, p/n 0698-8827.
Delete C85. In the Chassis, Mechanical, delete AC output cover with strain relief, p/n 5060-
3237. Add AC output cover, p/n 5040-1627, and strain relief, p/n 5040-1625. In the parts list for the A1 Main Board Assembly delete C33 and R25.
In the parts list for the A1 Main Board Assembly change C17, C18 to 1000 µ F 50V, p/n 0180-
3019. Change C10 to 22 µ F 250V, p/n 0180-0426.
CHANGE 15
6011A
6012B
In the parts list for the A5 Diode Board Assembly change CR1 and CR5 to 1901-1127. In the parts list for the A1 Main Board Assembly change XA4, XA5 to 1251-7891. Under A4 and A5
Mechanical parts list change P1 to 1251-8696. In the parts list for A6 AC Input Filter delete capacitor C9. In the parts list for CHASSIS MECHANICAL, change front frame casting to p/n
5021-8803; chassis to p/n 06032-00001; front sub-panel to p/n 06032-00009; and handle retainer
(front) to 5040-7219.
In the parts list for the A1 Main Board Assembly delete C30 and R25.
CHANGE 16
6011A
6012B
In the parts list for the A3 Front Panel Board delete DS1-8 and replace with the following:
DS1 1990-0681
DS2-4 1990-0540
DS5 1990-0681
DS6-8 1990-0540
In the parts list for the A2 Control Board Assembly add R130, 1M 1% 1/8W, p/n 0698-8827.
Delete C85.
CHANGE 17
6012B In the parts list for the A1 Main Board Assembly change XA4, XA5 to 1251-7891. Under A4 and A5 Mechanical parts list change P1 to 1251-8696.
125
CHANGE 18
6012B In the parts list for A6 AC Input Filter delete capacitor C9.
CHANGE 19
6012B In the parts list for CHASSIS MECHANICAL, change front frame casting to p/n 021-8803; chassis to p/n 06032-00001; front sub-panel to p/n 06032-00009; handle retainer (front) to 5040-
7219 and handle retainer to p/n 5040-7220.
CHANGE 20
6012B In the parts list for the A3 Front Panel Board delete DS1-8 and replace with the following:
DS1 1990-0681
DS2-4 1990-0540
DS5 1990-0681
DS6-8 1990-0540
126
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