Troubleshooting; Introduction; Electrostatic Protection - Agilent Technologies 6622A Service Manual

Most of the maintenance procedures given in this
section are performed with power applied 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).
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INTRODUCTION

This section provides
information for the power supply. The troubleshooting
technique is to first isolate the problem to an assembly and
then follow the troubleshooting procedure provided for the
faulty assembly. The assembly (GPIB board or output
board) troubleshooting procedures will isolate the problem
to the defective component or circuit on the board.
Before attempting to troubleshoot the supply, ensure that
the fault is with the supply itself and not with an associated
circuit, load, or power line. The verification tests described
in Section III enable 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
Section II of this manual as well as the Operating Manual
(Agilent Part No. 9557-6377 ) be reviewed before attempting
to troubleshoot the unit.
If a component is found to be defective, replace it and re-
conduct the performance tests given in Section III of this
manual. When the GPIB board or the EEPROM (U221) IC on
the GPIB board is replaced, each output present in the
supply must first be recalibrated as described in Appendix
A of the operating Manual. If an Output board is replaced,
the associated output channel must be recalibrated. If a
component in the output circuits or readback circuits on an
output board is replaced, the output must be calibrated
before you can reconduct the performance tests.
Section V in this manual lists all of the replaceable parts for
the power supply.
4-2

ELECTROSTATIC PROTECTION

This instrument uses components which can be
damaged by static charge. Most semiconductors can
suffer serious performance degradation as a result of

TROUBLESHOOTING

troubleshooting and repair
Section IV
static charge, 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 or components.
b. Always store 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 shunt charges too quickly. The work surfaces
should have distributed resistance between 10
ohms per square.
d. Ground all conductive equipment or devices that may
come in contact with static-sensitive devices or
assemblies.
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 wrist size) 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 synthetic (e.g. 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.
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and 10
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