Repair Briefs, an Introduction V1.00

Contents:


1) About the Author

This is the current version of my 'Repair Briefs, an Introduction'

Author: Samuel M. Goldwasser
E-Mail: sam@stdavids.picker.com
Corrections/suggestions: [Feedback Form] [mailto]
Copyright (c) 1995
All Rights Reserved

Reproduction of this document in whole or in part is permitted if both of the following conditions are satisfied:

  1. This notice is included in its entirety at the beginning.
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2) Introduction

This series will present case studies of selected repair problems from my archives. (Archives sounds more impressive than scribbled notes and schematics, doesn't it?). I hope that these summaries will be useful for those of you are interested in tackling your own repairs. These will NOT be of the form: "replace C418 when vertical size is reduced on HyperTech TV chassis HT312". Rather, they will document specific but common problems with TVs, VCRs, CDs, computer peripherals, etc. The symptoms, testing, diagnostic procedure, repair procedure, and comments will be included so that you can learn from my approach (and my screwups). If you want specific solutions to well known or repeat problems with your RCA or Zenith, then the repair professionals who frequent this group will be in a better position to help since they work on many of the same line of equipment on a regular basis. However, if you want to develop a general diagnostic approach, then this series may provide some tips and insight based on theory and experience.

Not all of these will be exciting cast of thousands repairs. Many will be mundain but will address common problems with consumer electronic equipment. There will probably even be some of those 'dogs' that we all hate - the problems that never seem to go away. In any case, these will all be based on my true experiences with minimal embellishment.

3) Some of My Rules of Troubleshooting

Safety First
You should know the hazards associated with the equipment you are troubleshooting. Take all safety precautions. Expect the unexpected. Take your time.

Always think 'what if'.
This applies both to the analytic procedures as well as to precautions with respect to probing the equipment. When probing, insulate all but the last 1/8" of the probe tip to prevent costly shorts. (If I had a nickel for every time I have been screwed not following this advice...)

Learn from your mistakes.
We all make mistakes - some of them can be quite costly. A simple problem can turn into an expensive one due to a slip of the probe or being over eager to try something before thinking it through. While stating that your experience in these endeavors is measured by the number of scars you have may be stretching the point, expect to screwup - we all can point to that disaster due to inexperience or carelessness. Just make it a point not to make the same mistake again.

How you approach matters.
Don't start with the electronic test equipment, start with some analytical thinking. Many problems associated with consumer electronic equipment do not require a schematic (though one may be useful). The majority of problems with VCRs, CD player, tape decks, and answering machines are mechanical and can be dealt with using nothing more than a good set of precision hand tools; some alcohol, degreaser, contact cleaner, light oil and grease; and your powers of observation (and a little experience). Your built in senses and that stuff between your ears represents the most important test equipment you have.

If you get stuck, sleep on it.
Sometimes, just letting the problem bounce around in your head will lead to a different more successful approach or solution. Don't work when you are really tired - it is both dangerous and mostly non-productive (or possibly destructive).

Many problems have simple solutions.
Don't immediately assume that your problem is some combination of esoteric complex convoluted failures. For a TV, it may just be a bad connection or failed diode. For a VCR, it may just be a bad belt or idler tire - or an experiment in rock placement by your 3-year old. For a CD player, a dirty lens or need for lubrication. Try to remember that the problems with the most catastrophic impact on operation - a dead TV or a VCR that eats tapes - usually have the simplest solutions. The kind of problems we would like to avoid at all costs are the ones that are intermittent or difficult to reproduce: subtle color noise, the occasional interference, or the dreaded horizontal output transistor blowing out every 3 months syndrome.

Whenever possible, try to substitute a working unit.
With modular systems like component stereos and computers, narrowing down a problem to a single unit should be the first priority. This is usually safe to do in such cases and will quickly identify which unit needs work. This same principle applies at the electronic or mechanical parts level. Note that there is the possibility of damaging the known good part by putting it into a non-working device or vice versa. This risk is most likely with the power circuitry in amplifiers, TVs and monitors, power supplies, etc. With appropriate precautions (like the series light bulb) the risk can be minimized.

Don't blindly trust your instruments.
If your get readings that don't make sense, you may be using your equipment in a way which is confusing it. DMMs are not good at checking semiconductors in-circuit or the power transistor you are testing may have a built in damper diode and/or base resistor. Your scope may be picking up interference which is swamping the low level signal you are searching for (TVs and Monitors, or low level circuits in VCRs and CD players). Your frequency counter may be double triggering due to noise or imperfect signal shape.

Confirm the problem before diving into the repair.
It is amazing how many complaints turn out to be impossible to reproduce or are simple cockpit error. It also makes sense to identify exactly what is and is not working so that you will know whether some fault that just appeared was actually a preexisting problem or was caused by your poking. Try to get as much information as possible about the problem from the owner. If you are the owner, try to reconstruct the exact sequence of events that led to the failure. For example, did the TV just not work when turned on or were there some preliminary symptoms like a jittery or squished picture prior to total failure? Did the problem come and go before finally staying bad for good?

4) Tools, Test Equipment, and Other Stuff

Invest in good tools.
If you are into garage sales, you can often pick up excellent well maintained tools very inexpensively but be selective - there is a lot of junk out there. In the end, sub-standard tools will slow you down and prove extremely frustrating to use. Keep your tools healthy - learn to use a wet-stone or grinding wheel where appropriate (screwdrivers, drill bits, etc.) and put a light film of oil (e.g., WD40) on steel tools to prevent rust.


4.1) Some basic hand tools

Screwdrivers, common ...
Screwdrivers of all types and sizes including straight, Philips, Torx.

Screwdrivers, Jewelers...
screwdrivers - both straight and Philips.

Small socket drivers.

Allen (Hex) key
Hex key wrenches or hex drivers. Miniature metric sizes for VCRs.

Pliers
Long nose, round nose, curved. Both smooth and serrated types are useful.

Wrenches
Adjustable wrench (small).

Wire Cutters
Diagonal and flush. Linesman pliers.

Wire strippers
fixed and adjustable. Crimp tool.

Alignment tools
(at least a standard RCA type for coils).

Files
Small set of assorted types including flat, round, square, and triangular.

Soldering equipment
A low wattage (25 W) iron for delicate components (e.g., ICs, small parts), a medium wattage (40-50W) iron for heavy duty circuit board work (e.g., power plane connections, transformers), and a 100-140 W soldering gun for chassis connections. Three wire grounded soldering equipment is recommended but I do not consider it essential for this type of repair work. However, a temperature regulated soldering station is a really nice piece of equipment if you can afford it or happen on a really good deal. I consider fine gauge rosin core solder (.030 or less) to be best for most applications (e.g., Ersin Multicore).

Desoldering pump
SoldaPullit or similar 'solder sucker' for removing components easily and usually nondestructively. SolderWick is also handy for cleaning up de-soldered connections. A vacuum rework station is not needed unless you are removing your soldered in 500 pin Intel P6!

(From the Editor - for those in/around the USA only!)

I have found the Radio Shack one-piece desoldering iron to be excellent. It's a 35Watt pen iron with a long tube, a vacuum bulb, and a tip. The tips are replaceable and come in copper or iron-plated designs. The later last a lot longer. I have de-soldered 24 pin EPROMs from 4 layer boards with EXCELLENT results. Of course, practice first on scrap.

Magnetic pickup tool
You can never tell when you will drop something deep inside a VCR. If you keep a strong magnet stuck to your workbench, you can use it to magnetize most steel tools such as screwdrivers. Just keep anything magnetized away from the tape path and magnetic heads.

Hand drill, electric drill, drill press - one or all.
A small bench-top drill press (e.g., 8") is invaluable for many tasks. A good set of high speed bits (not the 1000 bits for $9.95 variety). Also, miniature bits for PCB and small plastic repairs.

4.2) Basic test equipment

Obviously, you can load up on exotic test equipment. What follows are those that are most used.

DMM and/or VOM
I prefer to have both. A good old Simpson 260 is better in many ways than a cheap digital multi-meter. For most measurements, I still use a 25 year old Lafayette (remember them?) VOM. I only go for the DMM when I need to measure really low ohms or where better accuracy is needed (though this can be deceptive - just because a DMM has 3-1/2 digits does not mean it is that accurate - check you manual, it may prove enlightening). The Simpson 260 also has a nice 5000 V AC/DC scale which the others lack.

Scales for transistor, capacitor, frequency counter, etc. are not really essential. A diode test function on a DMM is needed, however, to properly bias semiconductor junctions. Even this is not useful for in-circuit tests or for some power transistors or transistors with built in damper diodes and/or base resistors.

Make sure you have a good well insulated set of test probes. This is for your own safety as you may be measuring relatively high voltages. Periodically inspect for damage and repair or replace as needed.

A high impedance high voltage probe is sometimes useful for TVs and monitors. You can build one of these which will suffice for most consumer electronics work.

Oscilloscope
Dual trace, 10-20 MHz minimum vertical bandwidth, delayed sweep desirable but not essential. A good set of proper 10x/1x probes. High vertical bandwidth is desirable but most consumer electronics work can be done with a 10 MHz scope. If you get into digital debugging, that is another story - 100 MHz and up will be required. If money is no object, get a good digital storage scope. You can even get relatively inexpensive scope cards for PCs, but unless you are into PC controlled instrumentation, a stand-alone scope is much more useful.

I would recommend a good used Tektronix or HP scope over a new scope of almost any other brand. You will usually get more scope for your money and these things last almost forever. My 'good' scope is the militarized version (AN/USM-281A) of the HP180 lab scope. This has a dual channel 50 MHz vertical plug-in and a delayed sweep horizontal plug-in. I have seen these going for under $300 from surplus outfits. For a little more money, you can get a Tek 465 100 MHz scope ($400-700) which will suffice for all but the most demanding (read: RF or high speed digital) repairs.

TV set
(color is desirable) and/or video monitor for testing of video equipment like VCRs, camcorders, laser disc players, etc.

VCR
or other video signal source for testing of video monitors and TVs.

Stereo tuner
or other audio signal source for testing of audio equipment.

Audio signal generator
A function generator (sine, square, triangle) is nice as well. The usual audio generator will output from a few Hz to about 1 MHz.

Audio amp connected to a loudspeaker
The input should be selectable between line level and mic level and be brought out through a shielded cable to a test probe and ground clip. This is useful for tracing an audio circuit to determine where a signal is getting lost.

RF signal generator
For serious debugging of radio and tuner front-ends. These can get quite sophisticated (and expensive) with various modulation/sweep functions. For most work, such extravagance is unnecessary.

LCR meter
A capacitor tester is desirable but I prefer to substitute a known good capacitor rather than trusting a meter which will not test under the same conditions as in-circuit.

Adjustable power supplies
At least one of these should be of the totally indestructible variety - one you can accidentally short out without fear of damage. Mine is a simple 1 amp 0-40 V transformer and rectifier/filter cap affair with a little Variac for adjustment.


4.3) Handy widgets

These are the little gadgets and homemade testers that are useful for many repair situations. Here are just a few of the most basic:

Series light bulb
... for current limiting during the testing of TVs, monitors, switching power supplies, audio power amplifiers, etc. I built a dual outlet box with the outlets wired in series so that a lamp can be plugged into one outlet and the device under test into the other.

Variac
It doesn't need to be large - a 2 A Variac mounted with a switch, outlet and fuse will suffice for most tasks. However, a 5 amp or larger Variac is desirable. If you will be troubleshooting 220 VAC equipment in the US, there are Variacs that will output 0-240 VAC from a 115 VAC line.

(From the Editor)

DANGER!! Variac, an autotransformer, does NOT isolate you in any way from the 120V line! If you NEED isolation, please see next section.

120VAC ------------------    (120VAC output if here)
                         )
                        (
                         )
                        (
                         )
                        (
                         ) <--------------- OUTPUT 1
                        (
                         )
                        (
                         )   (0VAC output if here)
120VAC ------------------+----------------- OUTPUT 2

Isolation transformer
This is very important for safely working on live chassis equipment. You can build one from a pair of similar power transformers back-to-back. I built mine from a couple of old tube type TV power transformers mounted on a board with an outlet box including a fuse. Their high voltage windings were connected together. The unused low voltage windings can be put in series with the primary or output windings to adjust voltage.

(From the Editor)

BTW, in the USA, used 250VA isolation transformer can be had for under $100... Sit down when you price new ones ;-)

Video cassette cheater
This is the shell of a VHS or Beta cassette with all of the innards removed and most of the top and bottom cut out to permit access to the reel spindles and other rotating components of a VCR during operation. You can also purchase these at grossly inflated prices.

Degaussing coil
Make or buy. The internal degaussing coil salvaged from a defunct TV doubled over to half it original diameter to increase its strength in series with a 200 W light bulb for current limiting will work just fine.

Tape head demagnetizer
This could just be a coil wrapped around a common nail with its end protected with tape. Connect to low voltage AC. However, these are so inexpensive that you should just buy one. Caution: do not use on video heads unless specifically designed for them. Some are strong enough to damage the fragile ferrite cores.

Clip leads
Like woodworking clamps, you can never have too many of these.

Patch cords
... for audio, video, and telephone interconnection.

Printer
Centronics printer and serial computer cables.

IR detector
This can be a photodiode/LED circuit or IR sensitive card. Use for testing remote controls, IR LEDs in photo-sensors, and CD laser-diodes.

Flyback tester
I use a 12 V chopper with a 10 turn coil to excite the flyback under test. This will identify most primary and secondary short type faults under near-operating conditions.

Insulating sheets
For separating circuit boards when removed from the chassis. These can be cardboard, fiberglass, plastic, etc.

Insulating sticks
For prodding to locate intermittents.

Small parts tray and container
I always use a film canister or pill bottle for storing the screws, washers, and springs removed during disassembly. An ice-cube tray or egg carton makes a handy parts bin for temporary storage of small parts while you are working.

4.4) Basic Ancillary Equipment

Various common items are useful for testing of the following consumer electronics and computers. These will normally be used before and during use of any actual test equipment. (Some of these were already listed under the heading of 'test equipment').

TVs
VHF and UHF antennas and/or VCR or other video source with both RF and baseband (RCA plugs) outputs.

VCRs
A small TV (preferably color but a monochrome TV will suffice for many tests) and/or NTSC/PAL video monitor, antenna, known good video tapes at both SP and SLP speeds. Also, a couple of blank cassettes for record tests.

Camcorders
Same as VCRs but in addition, a test chart, tripod, and lamps for indoor testing.

CD and Laser-disc Players
A garbage CD and test CD (or Laser-discs). A garbage disc is one you do not care about if it gets scratched. A test disc does not need to be an official (and expensive) test disc - any known good disc will do for most tests. The garbage CD can even be an outdated CD-ROM - an audio CD player will usually read the directory of a CD-ROM just like an audio CD. An audio amplifier with speakers or headphones will be needed for the audio tests, or headphones if the unit has a headphone jack. A TV or video monitor will be needed for Laser-disc video tests.

Audio Equipment
A set of known working stereo components consisting of at least a tuner, amplifier, and speakers. Headphones are also useful. For most purposes, an inexpensive setup is preferred since there is no telling what kind of abuse it may need to endure during troubleshooting. I suppose that a turntable may even be needed occasionally. A couple of pre-recorded audio cassettes are handy when testing tape decks. One of these should have a tone of known frequency recorded on an accurately calibrated deck for setting tape speed. Also, a couple of blank cassettes for record tests.

Microwave Ovens
A cup of water for a load. A thermometer for power tests. Neon or incandescent bulbs with their leads shorted together can serve as microwave detectors inside the oven (though these may not always survive for very long).

PCs and components
A working basic PC is useful to serve as a testbed for trying suspect components. I use an old 286 main-board with just enough to boot from an old hard drive. A set of known working basic PC peripheral boards is useful - SVGA, IDE and MFM HD and FD controller, I/O ports, sound card and speakers, 5-1/4" and 3-1/2" floppy drives, etc. A spare power supply - even one that is not an exact mechanical match - is also handy for testing. An old laptop (commonly used as a door stop) is useful for testing printers on location.

Computer Monitors
A test PC is useful as a video source. Of course, it will need to support whatever scan rates and video types the monitor is designed to accept. Programs are available to display purity, convergence, focus, color, and other test patterns.

Telephones, answering machines, faxes
A phone line simulator is useful for initial tests. A pair of normal phone lines will work but of course you will need to provide jacks where you are working and access (which may be difficult with teens in the house).

4.5) Chemicals


(From the Editor)

You can also see the article Chemicals used in Electronics/Repair Info (http://www.paranoia.com/~filipg/HTML/FAQ/BODY/F_Chemistry.html) for some more information... especially on contact enhancers and WD-40

4.6) Adhesives


4.7) Parts

I was going to attempt to make a basic list of recommended parts but this quickly got out of hand. The list below is just a start.

The idea is to have enough parts available so that you do not need to raid the local electronics store every time you want to try something. A good source for many of the basic parts is dead equipment - their organs can live on at your workbench.


5) Sources of Information

5.1) Manufacturer's service literature

Service manuals are available for a great deal of consumer electronics. Once you have exhausted the obvious possibilities or mechanical problems, the cost may be well worth it. Depending on the type of equipment, these can range in price from $10-50 or more. Some are more useful than others. However, not all include the schematics so if you are hoping to repair an electronic problem try to check before buying.

5.2) SAM's Photofacts

These have been published for over 45 years (I don't know for how long) and are generally the best most consistent source of service info for TVs, radios, some VCRs and other consumer electronics. There are some Computerfacts but the number of these is very limited. The VCRfacts are also somewhat limited and the newer ones tend to have strictly mechanical information.

SAM's are often available (for photocopy costs) from you local large public library which may subscribe to the complete series. If not, a large electronic distributor can order the selected folder for you.

One advantage of the SAM's info is that it is compiled in a very consistent format so that once you are familiar with one model TV, it is easy to transfer that knowledge to any other. They provide waveforms at key locations and DC voltage measurements almost everywhere. Additional info such as coil resistance is often provided as well. The manufacturer's service manuals are generally not nearly as complete.

(BTW, I have no connection with SAM's.)

5.3) Inside cover of the equipment

TVs often have some kind of circuit diagram pasted inside the back cover. In the old days, this was a complete schematic. Now, if one exists at all, it just shows part numbers and location for key components - still very useful. Some TVs - as late as 10 years ago, maybe even now - included a complete schematic with the product information and owner's manual. I have a 1984 Mitsubishi which has this. It is, however, the exception rather than the rule anymore.

Microwave ovens almost always have a schematic diagram of the microwave power generation circuitry pasted inside the sheet-metal cover. This will always include the high voltage transformer, interlocks, rectifier, capacitor, and magnetron. Since most microwave oven problems are in these areas, this is all you are likely to need. The controller, especially electronic units, is often omitted or only covered superficially.

5.4) Parts information

I have found the most useful single source for information on semiconductors to be the ECG Semiconductors Master Replacement Guide, about $6 from your local Philips distributor. STK, NTE, and others have similar manuals. The ECG manual will enable you to lookup US, foreign, and manufacturer 'house' numbers and identify device type, pinout, and other information. Note that I am not necessarily recommending using ECG (or other generic) replacements if the original replacements are (1) readily available and (2) reasonably priced. However, the cross reference can save countless hours searching through databooks or contacting the manufacturers. Even if you have a wall of databooks, this source is invaluable. A couple of caveats: (1) ECG crosses have been known to be incorrect - the specifications of the ECG replacement part were inferior to the original. (2) Don't assume that the specifications provided for the ECG part are identical to the original - they may be better in some ways. Thus, using the ECG to determine the specifications of the parts in your junk bin can be risky.

5.5) On-line Repair Notes and Guides

(From the Editor)

Check the Appliance/Electronics Repair Notes & Guides (http://www.paranoia.com/~filipg/HTML/FAQ/BODY/Repair.html) that I keep on-line. A number of them have been written by the author of this article, Samuel M. Goldwasser!

5.6) Last Resort

Finally, as with medical problems, an accurate diagnosis can only be made with good complete information. Use your senses to their fullest. If you decide to post to sci.electronics.repair or take the unit into a shop to be repaired - the more complete your description of the problem the easier (and cheaper) it will be to locate the problem. Include functional behavior or lack thereof, mechanical and electronic sounds it makes, anything that is related at all to the operation of the device in question. Sometimes seemingly unrelated factors can be important. For example, the fact that your officemate rearranged their desk and you monitor's image is now shaking. Don't omit anything - even what you feel is inconsequential - leave that judgment to the repair person. Also, what may have changed in your setup, did you move the equipment recently or add a component? What about your cable connections? Did you rearrange the furniture? When was the last time you know it worked properly? What were you trying to do at the time of the failure? To paraphrase a famous quote: 'The only stupid or useless information is that which is not provided'. However, unless you really are sure of what you are talking about, don't try to tell the repair person what you think the problem is likely to be. Don't bombard them with buzzwords - any competent tech will see right through that. You can be sure that if you mention that you suspect the expensive flyback is toast, it will be diagnosed as bad. Let them do their job. Listen carefully to their diagnosis. You should be able to tell if it makes sense.

Posting to sci.electronics.repair is a bit different - speculation is safer. There is enough cross-checking such that any gross errors in analysis will be uncovered. There is also generally no profit motive. If your speculation is totally bogus, you will find out quickly enough, turn various shades of red - and learn from the responses.

6) Safe Troubleshooting

These guidelines are to protect you from potentially deadly electrical shock hazards as well as the equipment from accidental damage when working on line powered equipment including: TVs, monitors, and microwave ovens. With low powered devices such as VCRs and CD players, you are much more likely to do damage to the equipment than yourself.

Note that the danger to you is not only in your body providing a conducting path, particularly through your heart. Any involuntary muscle contractions caused by a shock, while perhaps harmless in themselves, may cause collateral damage - there are many sharp edges inside this type of equipment as well as other electrically live parts you may contact accidentally.

The purpose of this set of guidelines is not to frighten you but rather to make you aware of the appropriate precautions. Repair of TVs, monitors, microwave ovens, and other consumer and industrial equipment can be both rewarding and economical. Just be sure that it is also safe!


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