ANTIQUE RADIO REPAIR : a short course INTRODUCTION: It really doesn't require a great deal of test equipment or technical savvy to restore an antique radio to top notch condition. You should however have some knowledge of the fundamentals of electronics (how tubes work to amplify a signal, the differences between a TRF receiver and a superhet, how diodes rectify, how power supplies work, etc, etc...) in order to fully utilize the following material. If you need assistance in getting a better grasp of the these fundamentals, your library may have a few books on the subject. Now as far as test equipment is concerned, you should have three items: a good 20,000 (or greater) ohms/volt VOM, a signal tracer with a demodulator probe, and a schematic diagram of the radio receiver you are working on. The VOM can be purchased from Radio Shack, the signal tracer can be purchased in kit form from Heath Company. By the way, the manual that comes with the signal tracer will give basic troubleshooting procedures. One other item will be helpful at times, and this is an RF signal generator which is also available from the Heath Company in kit form, but you can buy this later after you become more proficient at troubleshooting. Most experts also mandate using an isolation transformer for safety, but later I will suggest an alternative. The first step in troubleshooting a dead (no sound from speaker) radio is to see if the tubes light up. As you can see from an (older) textbook, radio's with a power transformer have their filaments wired in parallel and are supplied with AC voltage from a winding on the power transformer. Therefore suppose the radio you are working on is dead, has a power transformer and one of the tubes is not lit. You will probably find the tube not lit to have an open filament, which can be verified by removing the tube from the socket and measuring its filament resistance with the lowest range of your ohmmeter. If you don't get a reading, the filament is open and you have found the trouble. Now suppose that all tubes were not lit. In this case the problem is caused by either a faulty AC line plug, an open line cord, a defective fuse in the primary of the power transformer (if one exists), a defective on/off switch, or a bad winding on the power transformer. By the way, power transformers rarely go bad. ALWAYS BE ON THE LOOKOUT FOR BAD SOLDER JOINTS !!!!!!!! Now lets suppose the radio you are working on is dead (no sound from the speaker), and has no power transformer. Your textbook will show that radio's without a power transformer wire the filaments in series with the on/off switch, line cord and line plug. As you can see, an open in any one of the above will cause the filaments not to be lit. Again, you can use your ohmmeter, but an open tube filament is probably the cause of failure. What do you do if you find a bad RESISTIVE LINE CORD? Replace it with a regular line cord, but install a resistor in series with the tube filaments. How do you calculate the resistor value? First look up the filament voltage for each tube in a tube manual. The resistor is equal to 120 minus the sum of the filament voltages, divided by the filament current (of one tube only) in amperes. Now wasn't that easy! Its wattage is equal to 120 minus the sum of the filament voltages, times itself, and divided by the resistance value you just calculated. FOLLOW YOUR WIRING DIAGRAM!!!!!! Lets talk about another easily corrected problem. When you turn the tuning knob, the frequency pointer remains stationary. At this point, you must remove the chassis from the cabinet by removing the screws from the bottom and back of the cabinet. It will also be necessary to pull off the front knobs. Be very careful, I can't give explicit directions as each model is different. As you can see, a drive mechanism moves the frequency pointer as the tuning knob is turned. But look....the dial cord which goes from pulley to pulley is broken! Replace that cord with a new dial cord, but work on the radio with the tuning capacitor in the closed position. This will prevent damaging the capacitor and will insure that the frequency pointer will point to 550 KC on the dial when the tuning capacitor is closed, which is the way it's supposed to be. But before you replace the chassis and speaker, it would be a good idea to see if the radio plays. READ AND HEED THE NEXT SENTENCE!!! Whenever working on a transformerless radio, you must insert the line plug in the wall socket so that no AC voltage can be measured on your VOM between the metal chassis and a good ground. If you don't get 0 volts AC, reverse the line plug. This procedure is done with the ON/OFF switch "on", and must be done each time you work on AC/DC radios, so that you don't receive a jolt each time you touch the chassis! ........REMEMBER, A SHOCK CAN BE LETHAL !!!!! As you know from your studies, the power supply supplies the needed DC voltages to the tubes, without which the radio will not play. Even a low supply voltage may causes problems. The power supply output (or B+) can become deficient in (3) ways. Either it's missing, is low in value, or has an excess AC ripple content. Missing B+ is caused by either a defective rectifier tube or an open filter resister or choke coil. Tube failure can be verified by substitution with a good tube, and the open filter can be verified with your ohmmeter. A low B+ can also be caused by a bad rectifier tube. Excess AC ripple manifests itself as HUM in the speaker, and is caused by a defective electrolytic capacitor in the filter network. The electrolytic capacitor is the big CAN you see on top of the chassis. If you cannot find a CAN type replacement, install a terminal strip on the underside of the chassis and relocate the wiring from the bad capacitor to the strip adding new tubular (with identical ratings) electrolytic capacitors. For esthetic reasons leave the defective CAN on the chassis. Now let's review the signal tracer. It's nothing more than a high gain amplifier with a demodulator probe. As you probably know, the electronic circuitry between the antenna and speaker of an AM radio amplify and modify the received transmitted signal. Each stage has an input and an output, and we use the tracer to methodically trace the development of the signal through the defective radio. For example, suppose we have on the bench a radio with no output from the speaker even with the volume control fully clockwise. We also observe that all filaments are lit. Now lets use the signal tracer to find the defective circuitry! The first thing we must do is set the frequency pointer of the defective radio to a known local station. We can double check the pointer accuracy by touching the CONTROL GRID of the RF AMPLIFIER tube with the demodulator probe. WE NOW HEAR THE LOCAL RADIO STATION from the signal tracer speaker! Next we touch the PLATE of the RF AMPLIFIER tube, the grid and plate of the CONVERTER tube, and the control grid and plate of both IF AMPLIFIER tubes. At each location we hear the local station, so we shift the probe to the control grid of the FIRST AUDIO AMPLIFIER tube. Again we hear the signal, but when we touch the plate we hear nothing. We have found the defective stage! The next thing we do is substitute another good tube for the AUDIO AMPLIFIER tube, but this doesn't help, so we get out our trusty old VOM and start taking DC voltage readings. We check the plate and find o volts DC. The diagram says it should be 65V, so we turn off power, unplug the line cord, and start taking resistance readings of the plate circuitry. WE FOUND IT! The load resister is open, it should read 7500 ohms. With an open load resister, the plate receives no voltage, so the tube stopped amplifying. We replace it and the radio plays....end of story. Restoring an old radio also means returning the cabinet to its original condition. Tuning knobs and dial plate should also look original. You can find needed parts by advertising in ANTIQUE RADIO CLASSIFIED, or by writing to its advertisers. All this may sound like hard work, but the rewards make it all worthwhile. SERVICING TIPS 1. When working on live circuitry, do so with extreme care. A shock probably will not be fatal, but your response from it may cause you to jerk and cause some other problem such as knocking over and damaging the radio your working on, or upsetting the soldering iron. 2. Keep your soldering iron in an approved holder when HOT. 3. A 100 watt iron or gun is adequate for servicing antique radios. Get one with a small sharp tip. RADIO SHACK can supply the necessary hand tools. 4. Become proficient at soldering before working on a radio, as poor soldering techniques may introduce more defects in the radio your working on. 5. Don't change parts on a whim. Do so only after careful investigation. Unnecessary probing and movement of parts may introduce additional defects. 6. Train yourself to see trouble. Always be on the lookout for bad solder joints and overheated parts. They may be the cause of trouble. 7. Before turning the radio "on", make sure the correct tube type is in the correct tube socket. It's also a good idea to check the tubes on a tube tester before appling AC. 8. KEEP A FIRE EXTINGUISHER IN YOUR WORK AREA ! The following is a list of some of the more popular tubes used in antique radios. REMEMBER ... WHEN REMOVING A TUBE FROM ITS SOCKET, DO SO VERY CARE- FULLY as the tube probably has lost rigidity due to aging ! TUBE FILAMENT ------------PIN NUMBER------------- TYPE FUNCTION volts amps FIL-CT K P G1 G2 G3 G4 G5 G6 01A Amplifier 5.0 .25 1-4 2 3 2A3 Power Amplifier 2.5 2.50 1-4 2 3 2A5 Power Amplifier 2.5 1.75 1-6 5 2 4 3 5 2A7 Converter 2.5 .80 1-7 6 2 5 4 3 C 3 2B7 Amplifier 2.5 .80 1-7 6 2 C 3 6 Detector 4,5 5U4 Rectifier 5.0 3.00 2-8 4,6 5V4 Rectifier 5.0 2.00 2-8 8 4,6 5Y3 Rectifier 5.0 2.00 2-8 4,6 5Z3 Rectifier 5.0 3.00 1-4 2,3 6A7/6A7S Converter 6.3 .30 1-7 6 2 5 4 3 C 3 6A8 Converter 6.3 .30 2-7 8 3 5 6 4 C 4 6B7 Amplifier 6.3 .30 1-7 6 2 C 3 6 Detector 4,5 6C5 Amplifier 6.3 .30 2-7 8 3 5 6C6 Amplifier 6.3 .30 1-6 5 2 C 3 4 6C7 Amplifier 6.3 .30 1-7 6 2 C Detector 4,5 6D6 Amplifier 6.3 .30 1-6 5 2 C 3 4 6F6 Power Amplifier 6.3 .70 2-7 8 3 5 4 8 6F7/6F7S Amplifier 6.3 .30 1-7 6 2 C 3 6 Amplifier 4 5 6G6 Power Amplifier 6.3 .15 2-7 8 3 5 4 8 6H6 Rectifier 6.3 .30 2-7 8 5 Rectifier 4 3 6J5 Amplifier 6.3 .30 2-7 8 3 5 6K6 Power Amplifier 6.3 .40 2-7 8 3 5 4 8 6K7 Amplifier 6.3 .30 2-7 8 3 C 4 5 6K8 Mixer 6.3 .30 2-7 8 3 5 4 C 4 Oscillator 6 5 6Q7 Amplifier 6.3 .30 2-7 8 3 C Detector 4,5 6SA7 Converter 6.3 .30 2-7 6 3 5 4 8 4 6 6SC7 Amplifier 6.3 .30 7-8 6 5 4 Amplifier 2 3 6SK7 Amplifier 6.3 .30 2-7 5 8 4 6 3 6SQ7 Amplifier 6.3 .30 7-8 3 6 2 Detector 4,5 6U5/6G5 Indicator 6.3 .30 1-6 5 2 3 (target=pin 4) 6U6 Power Amplifier 6.3 .75 2-7 8 3 5 4 8 6U7 Amplifier 6.3 .30 2-7 8 3 C 4 5 6V6 Power Amplifier 6.3 .45 2-7 8 3 5 4 8 6V7 Amplifier 6.3 .30 2-7 8 3 C Detector 4,5 6W5 Rectifier 6.3 .90 2-7 8 3,5 6W6 Power Amplifier 6.3 1.25 2-7 8 3 5 4 8 6X5 Rectifier 6.3 .60 2-7 8 3,5 6ZY5 Rectifier 6.3 .30 2-7 8 3,5 7A4 Amplifier 6.3 .30 1-8 7 2 6 7A5 Power Amplifier 6.3 .75 1-8 7 2 6 3 7 7A6 Rectifier 6.3 .15 1-8 2 3 Rectifier 7 6 7A7 Amplifier 6.3 .30 1-8 7 2 6 3 4 7A8 Converter 6.3 .15 1-8 7 2 4 3 5 6 5 7 7B4 Amplifier 6.3 .30 1-8 7 2 6 7B5 Power Amplifier 6.3 .40 1-8 7 2 6 3 7 7C5 Power Amplifier 6.3 .45 1-8 7 2 6 3 7 7C6 Amplifier 6.3 .15 1-8 7 2 3 Detector 5,6 7E6 Amplifier 6.3 .30 1-8 7 2 3 Detector 5,6 TUBE FILAMENT ------------PIN NUMBER------------- TYPE FUNCTION volts amps FIL-CT K P G1 G2 G3 G4 G5 G6 7F7 Amplifier 6.3 .30 1-8 2 3 4 Amplifier 7 6 5 7G7/1232 Amplifier 6.3 .45 1-8 7 2 6 3 4 7H7 Amplifier 6.3 .30 1-8 7 2 6 3 4 7L7 Amplifier 6.3 .30 1-8 7 2 6 3 4 7N7 Amplifier 6.3 .60 1-8 2 3 4 Amplifier 7 6 5 7Q7 Converter 6.3 .30 1-8 7 2 4 3 6 3 5 7R7 Amplifier 6.3 .30 1-8 7 2 6 5 7 Detector 3,4 7S7 Mixer 6.3 .30 1-8 7 2 6 5 4 5 7 Oscillator 3 4 7V7 Amplifier 6.3 .45 1-8 7 2 6 3 4 7Y4 Rectifier 6.3 .50 1-8 7 3,6 12SA7 Converter 12.6 .15 2-7 6 3 5 4 8 4 1 12SK7 Amplifier 12.6 .15 2-7 5 8 4 6 3 12SQ7 Amplifier 12.6 .15 7-8 3 6 2 Detector 4,5 15 RF Amplifier 2.0 .22 1-5 4 2 C 3 4 19 Power Amplifier 2.0 .26 1-6 2 3 Power Amplifier 5 4 24A/24S RF Amp-Detector 2.5 1.75 1-5 4 2 C 3 25A6 Power Amplifier 25.0 .30 2-7 8 3 5 4 8 25L6 Power Amplifier 25.0 .30 2-7 8 3 5 4 8 25Z5 Rectifier 25.0 .30 1-6 4 5 Rectifier 3 2 26 Amplifier 1.5 1.05 1-4 2 3 27/27S Det-Amplifier 2.5 1.75 1-5 4 2 3 30 Det-Amplifier 2.0 .06 1-4 2 3 33 Power Amplifier 2.0 .26 1-5 2 3 4 5 35/35S Amplifier 2.5 1.75 1-5 4 2 C 3 35L6 Power Amplifier 35.0 .15 2-7 8 3 5 4 8 35Z5 Rectifier 35.0 .15 2-7 3 8 5 36 RF Amp-Detector 6.3 .30 1-5 4 2 C 3 39/44 AF-RF Amplifier 6.3 .30 1-5 4 2 C 3 4 41 Power Amplifier 6.3 .41 1-6 5 2 4 3 5 42 Power Amplifier 6.3 .65 1-6 5 2 4 3 5 43 Power Amplifier 25.0 .30 1-6 5 2 4 3 5 45 Power Amplifier 2.5 1.50 1-4 2 3 46 Power Amplifier 2.5 1.75 1-5 2 3 4 47 Power Amplifier 2.5 1.75 1-5 2 3 4 50C6 Power Amplifier 50.0 .15 2-7 8 3 5 4 8 50L6 Power Amplifier 50.0 .15 2-7 8 3 5 4 8 55 Amplifier 2.5 1.00 1-6 5 2 C Detector 3,4 56/56S Det-Amplifier 2.5 1.00 1-5 4 2 3 57/57S Det-Amplifier 2.5 1.00 1-6 5 2 C 3 4 58/58S Amplifier 2.5 1.00 1-6 5 2 C 3 4 71A Power Amplifier 5.0 .25 1-4 2 3 75 Amplifier 6.3 .30 1-6 5 2 C Detector 3,4 76 Det-Amplifier 6.3 .30 1-5 4 2 3 78 Amplifier 6.3 .30 1-6 5 2 C 3 4 80 Rectifier 5.0 2.00 1-4 2,3 83 Rectifier 5.0 3.00 1-4 2,3 85 Amplifier 6.3 .30 1-6 5 2 C Detector 3,4 V99 Det-Amplifier 3.3 .063 2-4 3 1 X99 Det-Amplifier 3.3 .063 1-4 2 3 FIL = filament, CT = center tap, K = cathode, P = plate, G# = grid #, C = cap RMA COLOR CODE FOR POWER TRANSFORMERS 1. Primary leads-black. If tapped: common-black; tap-black & yellow striped; finish-black & red striped. 2. High-voltage plate winding-red. Center tap-red & yellow striped. 3. Rectifier filament winding-yellow. Center tap-yellow & blue striped. 4. Filament winding #1-green. Center tap-green & yellow striped. 5. Filament winding #2-brown. Center tap-brown & yellow striped. 6. Filament winding #3-gray. Center tap-gray & yellow striped. RMA COLOR CODE FOR AUDIO-FREQUENCY TRANSFORMERS Blue-Plate lead of the primary. Red-B+ lead. Green & Black-for center-tapped push-pull operation. Green-Grid lead to secondary. Black-Grid return (this applies whether the secondary is plain or center- tapped). RMA COLOR CODE FOR INTERMEDIATE-FREQUENCY TRANSFORMERS Blue-Plate (primary) lead. NOTE: Aging my cause a color change to occur. Red-B+ (primary) lead. Also, a different color code may have Green-Grid (secondary) lead. been used by the builder. Black-Grid or AVC (secondary) lead. RMA COLOR CODE FOR SPEAKER FIELD COILS Black & red striped-start NOTE: The center-tap (if any) will be Yellow & red striped-finish gray & red striped. VACUUM TUBE NUMBERING SYSTEM All vacuum tube pins are numbered according to one easily remembered rule. WHEN VIEWING A TUBE SOCKET FROM THE CHASSIS UNDERSIDE, PINS ARE NUMBERED IN THE CLOCKWISE DIRECTION STARTING FROM THE KEY. VACUUM TUBE SUBTITUTION Many of the vacuum tubes used in antique radios can be replaced with another tube type (such as a 5Z3 for a type 80) without any rewiring, but a sub- stitution manual must be consulted first. Your public library or antique radio supplier will certainly have them. If you expect to do much serviceing, you should purchase your own copy! .............................................................................. Copyright 1989 by L. Lovell SHAREWARE IS NOT FREEWARE This program is distributed under the SHAREWARE concept. If you enjoyed using my program, will you please send a $5.00 registration fee to : Larry Lovell 2732 King St. Endwell, NY 13760 Your financial assistance will be greatly appreciated !!!!