Silicon ChipIn the good ol' days of my childhood - July 1993 SILICON CHIP
  1. Outer Front Cover
  2. Contents
  3. Publisher's Letter: Old textbooks & data books are valuable
  4. Feature: The Keck Optical Telescope Pt.1 by Bob Symes
  5. Order Form
  6. Review: Tektronix TDS 320 100MHz Digital Scope by Leo Simpson
  7. Feature: Programming The Motorola 68HC705C8 by Barry Rozema
  8. Feature: Data: The ISD1016 Voice Recorder IC by Darren Yates
  9. Subscriptions
  10. Project: Build A Single Chip Message Recorder by Darren Yates
  11. Project: Light Beam Relay Extender by Darren Yates
  12. Serviceman's Log: When it looks easy, it often ain't by The TV Serviceman
  13. Project: Build An AM Radio Trainer; Pt.2 by Marque Crozman & Leo Simpson
  14. Project: Windows-Based Digital Logic Analyser; Pt.2 by Jussi Jumppanen
  15. Product Showcase
  16. Project: A Low-Cost Quiz Game Adjudicator by Darren Yates
  17. Feature: Remote Control by Bob Young
  18. Feature: Amateur Radio by Garry Cratt, VK2YBX
  19. Vintage Radio: In the good ol' days of my childhood by John Hill
  20. Back Issues
  21. Notes & Errata: Nicad Cell Discharger, May 1993
  22. Market Centre
  23. Advertising Index
  24. Outer Back Cover: Nilsen Instruments

This is only a preview of the July 1993 issue of Silicon Chip.

You can view 37 of the 96 pages in the full issue, including the advertisments.

For full access, purchase the issue for $10.00 or subscribe for access to the latest issues.

Articles in this series:
  • The Keck Optical Telescope Pt.1 (July 1993)
  • The Keck Optical Telescope Pt.1 (July 1993)
  • The Keck Optical Telescope; Pt.2 (August 1993)
  • The Keck Optical Telescope; Pt.2 (August 1993)
Articles in this series:
  • Programming The Motorola 68HC705C8 (July 1993)
  • Programming The Motorola 68HC705C8 (July 1993)
  • Programming the Motorola 68HC705C8 (October 1993)
  • Programming the Motorola 68HC705C8 (October 1993)
  • Programming The 68HC705C8 Microcontroller (December 1993)
  • Programming The 68HC705C8 Microcontroller (December 1993)
Items relevant to "Build A Single Chip Message Recorder":
  • Single-Chip Message Recorder PCB pattern (PDF download) [01104931] (Free)
Items relevant to "Light Beam Relay Extender":
  • Light Beam Relay Extender PCB pattern (PDF download) [03106931] (Free)
Items relevant to "Build An AM Radio Trainer; Pt.2":
  • AM Radio Trainer PCB Pattern [06107931] (Free)
Articles in this series:
  • Build An AM Radio Trainer; Pt.1 (June 1993)
  • Build An AM Radio Trainer; Pt.1 (June 1993)
  • Build An AM Radio Trainer; Pt.2 (July 1993)
  • Build An AM Radio Trainer; Pt.2 (July 1993)
Articles in this series:
  • Windows-Based Digital Logic Analyser; Pt.1 (June 1993)
  • Some customers can be a real pain (June 1993)
  • Windows-Based Digital Logic Analyser; Pt.1 (June 1993)
  • Some customers can be a real pain (June 1993)
  • Windows-Based Digital Logic Analyser; Pt.2 (July 1993)
  • Windows-Based Digital Logic Analyser; Pt.2 (July 1993)
Items relevant to "A Low-Cost Quiz Game Adjudicator":
  • Low-Cost Quiz Game Adjudicator PCB pattern (PDF download) [08106931] (Free)
Articles in this series:
  • Remote Control (May 1993)
  • Remote Control (May 1993)
  • Remote Control (June 1993)
  • Remote Control (June 1993)
  • Remote Control (July 1993)
  • Remote Control (July 1993)
  • Remote Control (August 1993)
  • Remote Control (August 1993)
Articles in this series:
  • Amateur Radio (November 1987)
  • Amateur Radio (November 1987)
  • Amateur Radio (December 1987)
  • Amateur Radio (December 1987)
  • Amateur Radio (February 1988)
  • Amateur Radio (February 1988)
  • Amateur Radio (March 1988)
  • Amateur Radio (March 1988)
  • Amateur Radio (April 1988)
  • Amateur Radio (April 1988)
  • Amateur Radio (May 1988)
  • Amateur Radio (May 1988)
  • Amateur Radio (June 1988)
  • Amateur Radio (June 1988)
  • Amateur Radio (July 1988)
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  • Amateur Radio (September 1988)
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  • Amateur Radio (October 1988)
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  • Amateur Radio (November 1988)
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  • Amateur Radio (December 1988)
  • Amateur Radio (December 1988)
  • Amateur Radio (January 1989)
  • Amateur Radio (January 1989)
  • Amateur Radio (April 1989)
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  • Amateur Radio (May 1989)
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  • Amateur Radio (November 1989)
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  • Amateur Radio (December 1989)
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  • Amateur Radio (February 1990)
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  • Amateur Radio (March 1990)
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  • Amateur Radio (April 1990)
  • Amateur Radio (April 1990)
  • Amateur Radio (May 1990)
  • Amateur Radio (May 1990)
  • Amateur Radio (June 1990)
  • Amateur Radio (June 1990)
  • Amateur Radio (July 1990)
  • Amateur Radio (July 1990)
  • The "Tube" vs. The Microchip (August 1990)
  • The "Tube" vs. The Microchip (August 1990)
  • Amateur Radio (September 1990)
  • Amateur Radio (September 1990)
  • Amateur Radio (October 1990)
  • Amateur Radio (October 1990)
  • Amateur Radio (November 1990)
  • Amateur Radio (November 1990)
  • Amateur Radio (December 1990)
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  • Amateur Radio (January 1991)
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  • Amateur Radio (January 1992)
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  • Amateur Radio (July 1992)
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  • Amateur Radio (January 1993)
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  • Amateur Radio (December 1993)
  • Amateur Radio (December 1993)
  • Amateur Radio (February 1994)
  • Amateur Radio (February 1994)
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  • Amateur Radio (May 1994)
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  • Amateur Radio (September 1994)
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  • Amateur Radio (December 1994)
  • Amateur Radio (December 1994)
  • Amateur Radio (January 1995)
  • Amateur Radio (January 1995)
  • CB Radio Can Now Transmit Data (March 2001)
  • CB Radio Can Now Transmit Data (March 2001)
  • What's On Offer In "Walkie Talkies" (March 2001)
  • What's On Offer In "Walkie Talkies" (March 2001)
  • Stressless Wireless (October 2004)
  • Stressless Wireless (October 2004)
  • WiNRADiO: Marrying A Radio Receiver To A PC (January 2007)
  • WiNRADiO: Marrying A Radio Receiver To A PC (January 2007)
  • “Degen” Synthesised HF Communications Receiver (January 2007)
  • “Degen” Synthesised HF Communications Receiver (January 2007)
  • PICAXE-08M 433MHz Data Transceiver (October 2008)
  • PICAXE-08M 433MHz Data Transceiver (October 2008)
  • Half-Duplex With HopeRF’s HM-TR UHF Transceivers (April 2009)
  • Half-Duplex With HopeRF’s HM-TR UHF Transceivers (April 2009)
  • Dorji 433MHz Wireless Data Modules (January 2012)
  • Dorji 433MHz Wireless Data Modules (January 2012)
VINTAGE RADIO By JOHN HILL In the good ol’ days of my childhood Because radio receivers were expensive in the 1920s, many people built their own sets and even made the batteries to run them. In those days, it was a case of improvise or go with­out. We even built our own batteries. My interest in vintage radio started only eight years ago and I have learnt quite a lot in that time and enjoy my hobby immensely. However, it is not all new to me for there was a time in my childhood when I built crystal sets and often listened to these simple receivers until my callused ears could not tolerate the pressure of the headphones any longer. I guess my early interest in radio rubbed off from my father. Dad was into radio in the early 1920s when about the only thing one could expect to hear was an occasional Morse signal from a distant transmitter. In those very early days of radio, there were not many stations on the air to listen to and those that were had quite limited transmission times. My father was but a humble gardener in the 1920s and his wages were such that there was nothing left over from household expenses to spend on radios in any shape or form. Therefore, poor old Dad had to make his own equipment and, what’s more, it worked. Unfortunately, my father’s homemade radio gear has now gone. It didn’t seem important at the time so it all went to the tip when he died For the best part of the author’s life, this old radio cabinet has served to remind him of many exciting childhood activities. It sits on top of a post in the front yard and was where the billy was left for the milkman. 86  Silicon Chip and although it may sound unkind, the tip was the right place for most of it. However, with my rekindled inter­est in radio today, some of Dad’s home-made equipment would now be nice to have, if only for sentimental reasons. I am convinced that few people today have the capacity to improvise as did those of yesteryear. Some of the projects my father tackled were incredible for a guy who left school at 13. That’s another interesting thing about my father: he caddied at the local golf course for a year while his mother thought he was still going to school. God help me if I had tried that trick when I was 13. Crystal set One of Dad’s first radio projects was his crystal set. Now making a crystal set may not seem a very daunting task today but when my father made his, he had to make everything including the tuning capacitor and the crystal detector. The only item he purchased was a set of headphones, which gave excellent service for many years. In fact, I was still using them in the postwar years. I remember the tuning capacitor quite well for it was used in some of my creations. I also remember that it was a bit stiff to turn and the old Emmco dial slipped when the shaft became tight at one end of the travel. I also recall that it should have had a few more plates in it, for it lacked sufficient capacitance to cover the full width of the broadcast band. The crystal detector was made up from miscellaneous bits and pieces mount­ed on a small sheet of ebonite. However, the basic requirements were there. The crystal cup had three setscrews to retain the piece of crystal and the arm that held the cat’s whisker was This Leclanche cell is similar to those used for the front gate bell. During the 1930s, the wet Leclanche cell was used almost exclusively for powering door bells. pivoted so as to give movement across the face of the crystal. Home-made batteries But those early achievements fade into insignificance when one thinks of Dad’s home-made “B” batteries. When I graduated from crystal sets to a 1-valve receiver, I was able to obtain a discarded B battery from the local tip. This battery kept me listening for a month or so but there soon came a time when it was no longer serviceable. Once again, good old Dad solved the problem by making a rechargeable 20-volt B battery. Now this was no ordinary battery – in fact, few would recognise it as such. It consisted of a wooden baseboard with 10 shallow holes bored into it. Placed into the holes were 10 small pill bottles – Doctor Morse’s Pink Pills for Pale People if I remember cor­rectly. These formed the cells of the battery and were three parts filled with dilute sulphuric acid. Strips of sheet lead were used for the plates. These were shaped like an inverted “U” and arranged in the bottles so that the ends of each strip occupied two adjoining bottles. In other words, it was a very simple lead acid accumulator. When placed on the battery charger (which used a home-made transformer and metal oxide rectifier), the lead plates changed colour almost immediately. The positive plates turned to a cho­colate brown, while the negative plates went a light grey. Howev­er, because the battery charger could only produce about 12 volts, the battery had to be charged in two halves. This 20-volt B supply kept the little 1-valver working quite happily, but after a couple of days it went strangely quiet. Reason – a flat B battery. Further testing indicated that the battery had almost no capacity. It could reach full charge in a matter of minutes and would discharge almost as rapidly. In fact, it could supply only about one milliamp of current for approximately 10 hours. But although that miserable battery often went flat in the middle of an interesting program, it got me out of a tight spot at the time. Making a rechargeable battery was nothing new to my father because he had made one once before. It lived under the house in a wooden crate and had been a source of mystery to me for many years. Apparently it was used way back in the days when part of Bendigo had a DC power supply (most likely from the tramway depot) and the battery was recharged by plugging it into the DC mains. During recharging, a globe was connected in series with the battery to provide the correct charge rate. When my 1-valver subsequently grew into a 2-valver, the pill-bottle B battery was grossly inadequate; in fact, it was never even considered. It was time to crawl under the house and drag out Dad’s old battery to see if it could be recommissioned. Refurbishing an old relic Once again, the old disused battery was a marvel. It was capable of supplying B voltages to the largest of battery receiv­ers and was an impressive sight. My father’s perseverance never failed to amaze me. His B battery was entirely home-made, including the glass containers which housed each cell. These were made from small flat sided medicine bottles. The tops of the bottles had been cut off using the hot wire and quench method of glass cutting. It must have taken quite some time just to collect all the bottles and cut them to size! COMPONENTS Are you sick of being told that the components you are always looking for are either not available or discontinued??? Call us now. We specialise in discontinued electronic components (03) 742 7330 We can help with 90% of any component on today’s market. WOMBAT COMMUN CATIONS SUPPLIERS & IMPORTERS OF ELECTRONIC COMPONENTS 83 RAILWAY AVENUE WERRIBEE, VIC 3030. PHONE: (03) 742 7330 FAX: (03) 741 6834 KITS & PCBs 2.5 Watt 88-108MHz FM Transmitter Kit $49 This is the highest powered transmitter kit available. With line of sight, distances of up to 100 miles can be achieved. Requires high-level input from tape or CD player. Runs from 12-28 volt supply. Coming soon XTAL controlled PLL stereo version. Note: It is illegal to use this transmitter without a licence. MAX I/O board for PCs 7 Relays, ADC, DAC, 8 TTL inputs, Relay/ motor driver demonstration & sample software, manual. Kit form $169. B&T $269. PCB/Disc/manual $39. DIGI-125 Amplifier Kits One of the nicest amplifier kits to build for the experienced or beginner, fits into the palm of your hand. Dual PCB $9. 50W kit $14. 125W kit $19. Now available 200 watt kit $29, instructions inc. AEM 35 watt single chip amp 35 watts RMS from a TO220 chip on a 1" x 1" PCB. Easy to build, 70 watts in bridge. Kit $15. P.C.Computers 36 Regent St, Kensington. S.A. Phone (08) 332 6513 July 1993  87 VINTAGE RADIO – In the days of my childhood The plates were also time consuming to make – no lead strips in this battery. Each plate had been hand-cast in a special mould which shaped the plate with an open grid structure similar to that of a car battery plate. The respective lead compounds (red lead oxide for the positive plates and yellow lead oxide for the negative) were then hand-hammered into the plates. The plates were installed two to a cell with a separator in between and held in place at the top with bees wax. The wax seal had a vent hole which also served as a top-up hole for distilled water or for checking the electrolyte with a hydrometer. All things considered, a “helluva” lot of effort had gone into the making 88  Silicon Chip of this battery. However, the question at the time was could it be re­commissioned to work my little 2-valve receiver? Unfortunately, a quarter of a century spent in limbo under the house hadn’t done the old battery much good. The electrolyte had not been drained before storage and the plates had sulphurat­ ed and were all white and horrible looking. What’s more, many of the plates were starting to fall apart. But it was not all bad news. After dismantling the whole battery, there seemed to be enough good plates to make up a reasonable size unit. And when the sulph­ ur­­a t­e d plates were scrubb­ ed up with a wire brush, the prospect of a “new” battery actually looked quite promising. To cut a long story short, there were enough service­a ble plates to make up a 40 volt B battery, with the leftover-plates being used to build a rechargeable A battery. Battery charger As previously mentioned, my father’s battery charger could only charge at 12 volts, which made recharging a 40-volt battery a bit awkward. But good old Dad soon solved that problem. A special switch was made consisting of a rotating drum with numerous brass contacts on it. The battery was wired to this switch in four 10-volt banks and the switch connected these banks either in series or parallel. This ingenious switch took the best part of a weekend to make and install. The rechargeable batteries were a complete success and were used for several years. The B battery was put on charge every three months, while the A battery required attention at about 3-weekly intervals. Leclanche battery There were other special batteries used at home back in those distant days of my childhood. One of them was a wet cell Leclanche battery and it too lived under the house in a wooden box. This 3-cell battery powered the front gate bell and what a set up that was. On the front gate was a home-made gate closer and combined switch. This switch closed its contacts when the gate was opened about six inches (sorry, but we didn’t have millimetres back then). The switch was connected to the battery by underground cables which were laid before the front lawn was planted more than 60 years ago. The cable then ran from the battery to an electric bell in the kitchen. When the gate was opened, the bell gave a short ring and then another short ring when it closed. This switching arrange­ ment prevented the bell from ringing continuously if someone held the gate open for a prolonged period. For reasons unknown, the bell was later changed to a buzzer. The bell always gave a warning when someone came through the front gate and by looking into the strategically placed mirror outside the dining room window, the “intruder” could be observed walking down the garden path. Now I ask you – who needs expensive modern electronic surveillance equipment? Just consider the small cost and effectiveness of this old style system. I’m sure that my father was never involved in any underhand activities but he sure had a suspicious nature, particularly where strangers were concerned. Actually, the gate bell did detect the presence of a few undesirables. In those days, stealing milk money was commonplace and several would-be milk money snatchers were met halfway across the front lawn. As Dad was a fairly good boxer in his day, the trespasser usually got a straight right to the jaw if he didn’t beat a hasty retreat. This gate bell early warning system also had its prob­lems, such as on those occasions when Dad had forgotten that I had gone out to a picture show. We had several confrontations in the middle of the front lawn at midnight! The problem was solved by developing a special gate opening technique. If the gate was zapped open quickly and then zapped closed again, the old bell didn’t have time to get into the swing of things and I was able to sneak in (or out) at any hour –undetected. A horsey story Still another battery was used at home for a while and this one was installed in the workshed. At the time, my older brother was interested in electroplating and he required a DC supply for his experiments, hence the need for still another battery. In this case, it was a 3-cell potassium bi-chromate battery. This battery was bought in kit form from Selbys and when assembled used large glass jars to hold the potassium bi-chromate and sulphuric acid electrolyte. When not in use, the plates (zinc and carbon) had to be lifted out of the solution to protect the zinc plates. As I recall, the electroplating experiments were far from successful. However, it was not the fault of the battery. Elec­troplating is a specialised process which requires special tech­ niques. Unfortunately, these were never learnt. The bi-chromate battery did find another use, however. Its 6-volt output was used to drive an old T-model Ford ignition coil (the trembler type). The most spectacular experiment with this equipment by far involved the electrification of the back fence. Our neighbour at the back had a horse which kept scratching itself on the fence and, in the process, had just about flattened the rickety structure. The fence was re-erected and steel wire was woven throughout the weather-beaten palings to help hold things together. The final touch to the fence repair was to connect the old Ford coil to the wire reinforcement (with an earth return) and wait for the horse to come back for another scratch. The electric fence equipment was installed in the shed, complete with a peep hole drilled in the rear wall for observa­tion purposes. The primary of the Ford coil was wired to the battery via a Morse key switch. Eventually the horse returned for a rub up along the fence and Dad gave him a quick zap. Neddy must have backed away at the crucial moment and only got a bit of tickle. But the second time around he had his nose on the wire when the switch was closed. He never went near that fence again. Part of the potassium bi-chromate battery still survives. One and a half zinc plates still remain and I solder odd pieces of these plates to my car radiator cap as sacrificial anodes. The zinc protects the aluminium cylinder head and other alloy compon­ents. The only other thing that remains to remind me of all this childhood excitement is an old 1920s battery radio cabinet. It stands on a wooden post beside the garden path where it has stood for the last 40 years or so. However, the reason for the old cabinet’s strange and elevated position is no longer apparent. It was where the billy was left out for the milkman who once called in the early hours of the morning. Remember the days of free home deliveries? No doubt, lack of funds was one of the reasons my father made so many of the things he couldn’t afford to buy. He grew up in difficult times and worked hard all of his life. Nevertheless, he still found time and a little money to follow his hobbies and special interests. Radio and electronics have developed to such a degree today that everything has become too “high-tech” for the average person to handle. Whereas my father and those like him used to build their own equipment, the situation now is entirely different. In my opinion, all the fun has gone out of electronics and the hobby­ist has been reduced to assembling kits if he is inclined to do so. That’s one of the reasons I like vintage radio restoration for it is still a hands-on, do-it-yourself activity that appeals to me in particular. The almost total lack of vintage components encourages one to improvise and scrounge. Such a pastime can be a lot of fun. My current interest in old radios helps to remind me of a time when the style of life and the activities people pursued were a good deal different from the lifestyles of today. I am also glad that I spent my childhood during those times and if I had to choose again, I’m sure I would follow the SC same path. Send Postage Stamp For List Of Other Items Including Valves L.E. CHAPMAN TAPE DECK OR RADIO POWER LEADS Plugs and Sockets $1.50 Test prods and leads $1.50 TOUCH MICRO SWITCHES as used on TV sets. 4 for $1 TRANSISTOR EAR PIECES plug & lead 4 for $2 PUSH BUTTON SWITCHES 4 pos 50c SPEAKER TRANSFORMERS 7000 to 15/Ohm 5W $10 7000 to 3.5Ohm 15W $10 5000 to 3.5Ohm $10 SPEAKERS 5 x 7 $5    6 x 4 $4 5" 8 Watt $5 SLIDE POTS 1/2 Meg dual 1 Meg Dual 1 Meg Dual 1k Dual 25k Dual 5k Single 250k Single 10k Single $1 $2 $2 $1 $2 50c 50c 50c SPECIAL 12 Mixed Switches INLINE FUSE HOLDERS 4 FOR $1 SHIELDED LEADS 7ft 3.5 to 3.5 $1 3.5 to 6.5 $1 6.5 to 7ft 75c Inline Baynet Plugs & Sockets 4 for $1 SHIELDED CABLE 10m $2 TAG STRIPS 10 for $2 mixed TWO WAY SPEAKER CROSSOVER NETWORK $2 50c 50c $1 ea 50c 10 for $1 $1 ea 3 for $1 3 for $1 $1 ea 5 for $1 3 for $1 4 for $1 10 for $1 5 for $1 4 for $1 IC SOCKETS 16 pin * 24 pin * 28 pin Four for $1 PLUGS & SOCKETS R.C.A. plugs and sockets 50c pair 2.5mm sockets 4 for $1 3.5mm sockets 4 for $1 6.5mm sockets 4 for $1 Thermistors 4 for $1 Speaker plugs and sockets 4 pin 50c pair 2 pin 50c pair POTS 1/2Meg $1.50 Dual 2 Meg Ganged Lin $2.00 1/2 Meg Switch $2.00 Dual 1 Meg Ganged Lin $2.00 1 Meg $1.50 1 Meg Dual Ganged Log $2.00 1 Meg Switch $2.00 10k Ganged Log $1.00 25k Dual Ganged $2.50 50 Ohm Single 50c ELECTROS 20UF 450V 2000UF 25V SPECIAL PICK UP ARM Includes cartridge and stylus. Plays mono or stereo $15 5 MIXED ROTARY SWITCHES 5 for $2.50 Special TUNING CAPACITOR 2 gang covers all Aust. AM bands. $10. P&P $1.80 for one or two. CAPACITORS 6N8 150V 1000uF 16V 1000uF 50V 0.0039uF 1500V 0.0068 250V 47uF 63V 47uF 160V 470uF 16V 47uF 200V 0.1uF 250V 680uF 40V 0.027 250V 10uF 25V 22uF 160V 0.039uF 400V SPECIAL Dual VU Meters $4. P&P $1.80 for one or two $1.50 $1 $4.50 200 MIXED SCREWS self-tappers, bolts, nuts etc. 200 for $2 CAR RADIO SUPPRESSORS 4 for $2 OXTAL VALVE SOCKETS $1 each Stick Rectifiers TV20SC $2 Transistors AD61-62 pair $3 AD 149 $2 each Chrome 1/4" push on knobs RRP 1.20 EA 10 for $1 Mixed capacitors fresh stock 100 for $2 Mixed resistors all handy values 100 for $2 Slide pot knobs 10 for $1 1F 455kHz for valve radios $2 ea Telsco Microphone Ceramic $2 pp $1 SPECIAL: CELLULAR HORN TWEETER Mounting specification 12.5cm x 7.1cm. Frequency range 2000-20,000Hz. Sensitivity 105dB. Maximum power 30 Watts. Impedance 8 ohms. $12. TV CRYSTALS 4.43619kHz 03061 NDK; 8.867238kHz 03122.937 $2 each. VALVES 6K7 $10 6U7 $10 6V4 $7 6BL8 $7 6SA7 $10 12AX7 $10 6BQ5 $10 6AV6 $10 6SN7 $10 EF50 $7 6K8 $12 1S5 $7 6BM8 $10 5AS4 $10 IT4 $7 6AM8 $10 6SL7 $10 205A $10 12AT7 $10 6J5 $10 6AS6 $10 6AN8 $10 6005 $10 12DL8 $10 6136 $10 12BL6 $10 6X4 $10 6SL7 $10 12X4 $10 6BE6 $12 6V4 $8 6M5 $12 EM84 $12 IR5 $10 6LEA8 $10 6N8 $12 6BV7 $10 6EM7 $10 6AU6 $10 12AU7 $10 6LM6 $10 EF86 $10 6X9 $10 6BAL6 $10 152 $5 6AQ5 $10 122 Pitt Road, North Curl Curl, NSW 2099 Phone (02) 905 1848 Send Postage Stamp For List Of Other Items Including Valves July 1993  89