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VINTAGE RADIO By RODNEY CHAMPNESS, VK3UG The AWA 719C Console; Pt.2 Last month, we took a look at the impressive AWA 719C console radio and described a typical restoration. In Pt.2 this month, we detail the alignment of this complex receiver. All the normal restoration jobs had been completed on this particular set. I’d cleaned the chassis, replaced suspect paper capacitors, tested various other components, replaced perished wiring and had the cabinet restored to its former glory. There was really only one major job left to do – the alignment of the RF, aerial, oscillator and IF circuits. Now as anyone who has ever attempted to align one of these sets knows, it isn’t a 10-minute job as it is for most superhet broadcast receivers. The average superhet set has four IF adjust­ments and four adjustments for the aerial and oscillator cir­cuits, so the job is straightforward. By contrast, the AWA “7-banders” have four IF transformer adjustments plus 19 other adjustments (and some of these are compromises) for the front end of the set. What’s more, some of these adjustments have to be repeated as they tend to interact with each other. In addition, a stable RF signal generator that is well calibrated and capable of operation up to at least 23MHz is required. Apart from the alignment taking more time, there are a few rather nasty problems that crop up during the procedure. First, the dial isn’t attached to the chassis, so how do you align the front end without a dial-scale? If you have the correct alignment data for the particular model set, it is relatively easy to do. The dial drum has a semi-circular scale around one side and there is a pointer that is alongside the scale, as can be seen in one of the photos. It’s then a matter of looking up the “alignment table”. For example, in one of the alignment tables, the listing for 600kHz is 19° on the drum, while for 1500kHz it is 168°. However, as I found out, models that are claimed to be the same electrically, such as the 617T that I have and the 719C that I have been restoring, may not be identical. My set tunes from 540-1500kHz on the BC (broadcast) band, while the 719C tunes from 540-1600kHz. This means that the alignment data for my set and the 719C will be different even though the published data says they are electrically identical! Why won’t it track? This photograph shows the two brackets (coloured with a black felt-tipped pen) that were made to hold the dial in place during alignment. 78  Silicon Chip Normally, you would expect to tune the oscillator slug at the low frequency end of each band and the trimmer at the high frequency end of each band. However, while the alignment freq­ uen­cies are known, the angular position of the dial drum that corre­sponds to the alignment frequencies is often unknown. Initially, I went ahead and used the AWA listings but found that the coil cores and trimmers on the 719C receiver had to be altered considerably to get the set operating as per the align­ment table. This seemed a bit strange, so I held the dial mechan­ism in approximately its correct position and attached the point­er to the dial cord. The alignment points were nowhere near where they should have been. It was then that I realised that the www.siliconchip.com.au 719C covers from 540-1600kHz instead of 540-1500kHz as for my 617T, as noted above. And that explained why I couldn’t get it to track correctly. The 719C I was restoring is obviously a later set due to the extended broadcast band calibrations, therefore the degree settings would be different on the dial drum. But what settings should I use? This was getting messy. A tuning aid So how I could align this set without the relevant set of alignment instructions? After some thinking, I came up with the idea of mounting the dial scale onto the receiver chassis by some means. I had some scrap 24-gauge galvanised flashing (plumbers or hardware stores often have it available) and decided that I could make some simple brackets for the job. It really is a pity the chassis design wasn’t similar to the 805G and other radiogram models, where the dial scale was firmly attached to the chassis assembly – alignment would have been so much easier. The brackets that I made can be clearly seen in one of the photos (they’ve been coloured black using a felt-tipped pen). At the lefthand end, one bracket is attached (using a nut and bolt) to a vertical piece of metal that supports a dial scale pulley. The other end of this bracket then goes to an existing bracket at the bottom of the dial-scale. At the other end, the second homemade bracket goes between another existing dial-scale bracket and a plate which carries the dial-drive mechanism. It was necessary to drill a small hole near the front bottom of this plate to accept a nut and bolt to secure the second bracket in place. Provided you get the brackets right, the dial drive will work quite well. Remember however, that this is a rather flimsy ar­rangement, so take care to ensure that no stress is applied to the assembly. It should be perfectly adequate while the alignment procedure is carried out, however. Tuning the IF stage With the gang closed, the pointer is attached so that it is just below 540kHz (Kc/s) on the dial. This done, the IF trans­formers are tackled first. With the set turned off, attach a digital multimeter (DMM) (set to the 20V DC www.siliconchip.com.au The dial drum has a semi-circular scale (marked in degrees) around one side and this is used in conjunction with the “alignment table” (see Table 1) when making alignment adjustments. The holes adjacent to the two arrows at bottom, left of the chassis allow access to the 9MHz aerial and RF trimmers. range) between the AGC/AVC line and chassis using clip leads. An ideal spot is across C37, with the negative lead going to the unearthed side of the capacitor. With the set turned on, the DMM should read about -3V, which is the standing bias on the front-end valves. Next, attach the signal generator to the aerial terminal of the receiver, set it to 455kHz with (tone) modulation and in­crease the power until the tone is heard from the speaker. You may have to tune around 455kHz on the signal generator to get a response, although I usually find that most sets are close enough to 455kHz in their alignment to make this step unnecessary. Now increase the output on 455kHz (if you can hear it on that frequency) until the DMM shows an increased reading. (It is possible to “walk” the IF frequency up or down to 455kHz if it is way off frequency; eg, if there is a problem with the IF stage due to someone’s fiddling or if there is a fault). That done, adjust the tuning slugs (using a small plastic screwdriver) in the top and bottom of each IF transformer for April 2002  79 9MHz (20) 17.8MHz (11) 9MHz (19) 17.8MHz (10) 11.8MHz (16) 1450kHz (8) 11.8MHz (15) 1450kHz (7) 17.8MHz (9) 600kHz (5) 15.2MHz (13) 11.8MHz 9.5MHz (14) (17) 1.5MHz (6) 4MHz (21) 1.6MHz (22) 3.7MHz (23) 9MHz (18) 21.0MHz (12) This under-chassis view shows the locations of the aerial and RF coil trimmers (white & light green type respectively), the oscillator cores (yellow type) and the trimmers (red type). The numbers in the brackets refer to the corresponding adjustment number in the alignment table. a maximum reading on the meter. All being well with the IF transformers, a peak will be found within a turn or two either side of the initial settings. The screws can then be locked in position with a dab of plastic cement or nail polish. RF, aerial & oscillator circuits Now we come to the “fun” part – the alignment of the front-end of the set. Table 1 (at the end of this article) is an extract from a set of alignment 80  Silicon Chip instructions for the 611-T and a few other sets. This table can be used to tune the RF, aerial and oscilla­tor sections of the set. However, although I used this information to tune my 617-T, some of the component numbers for the 611-T are different. The procedure is as follows. Using the 611-T alignment table, switch the set to the broadcast band and turn the dial drum until 19° appears under the small pointer. This is the 600kHz mark and the dial pointer should also be aligned to the 600kHz mark on the dial scale. Note that I have used “kHz” and “MHz” abbreviations in this article, whereas the dial and tuning instructions show “Kc/s” and “Mc/s”. It is now possible to either use the alignment table or do it directly from the dial-scale that has been temporarily at­tached to the chassis via the brackets described earlier. There is no problem in aligning the set using the bracket method. However, if you use the alignment table and the calibration table for the 611-T, it may be correct for the model that you are aligning, or it may not be – as was the case with the 719C. The alignment table is used for each band but the dial calibrations and not the degree settings must be used to align the circuits correctly. I feel much more confident this way. The location of each of the adjustments is not shown on any literature that I’ve been able to access, so diagrams 2 and 3 have been drawn to show where each of the 19 adjustments are located. This has made it much easier for me to do this job and should help you too. Note that the oscillator adjustments are all made from above the chassis, while the RF and aerial trimmers are under the chassis, as can be seen in the photograph at left. Note also that the 9MHz aerial and RF trim­ mers are accessed through the end of the chassis, as shown by the arrows in the photograph of the dial scale. The broadcast band is aligned as per steps 5, 6, 7 & 8 of the alignment table. I connect the receiver to a “typical” anten­ na, then clamp the output lead from the signal generator over the insulation on the antenna lead. That way, the generator has little effect on the tuning of the aerial coils, although the generator does have to be wound up further to get a reasonable level into the receiver to actuate the AGC. In practice, the generator is set to each of the frequen­cies shown in the alignment data in turn. Note that it’s neces­sary to repeat the adjustments again for maximum reading on the DMM. In fact, you may need to repeat the procedure several times before you are happy that there is no interaction between the individual adjustments. After the broadcast band been completed, the 17.7-22.3MHz band can be www.siliconchip.com.au aligned. This involves setting the dial to 17.8MHz (or 18°) and doing adjustments 9, 10 & 11. You then set the dial to 21MHz and do adjustment 12. On the 15.0-19.0MHz band there is only one adjustment and that is the oscillator at 15.2MHz (adjustment 13). On the 11.7-15.0MHz band, all the circuits are adjusted at 11.8MHz. The adjustment numbers are 14, 15 & 16. Moving now to the 9.4-12.0MHz band, again there is only one adjustment and that is the oscillator on 9.5MHz (adjustment 17). On the 3.6-9.7MHz band, the dial is set to 9MHz and you do the adjustments 18, 19 & 20. The dial is then set to 4MHz for adjustment 21. Personally, I would do 21 first (which is conven­tional wisdom), then 18 and then go between these two until I was satisfied that the oscillator was tracking correctly before doing adjustments 19 and 20. We are now nearly at the end of the alignment procedure. On the 1.5-4MHz band there are two adjustments, both involving the oscillator. Adjust the oscillator core at 1.6 MHz (adjustment 22) and then the trimmer (adjustment 23) at 3.7MHz. Re-check Photo Gallery after adjusting both that the first one is still correct and if not, readjust it. The other adjustment will quite likely be out again but not as much as before. Going between the two adjustments will quite quickly get the oscillator circuit tracking fairly accurately across the band. This technique applies to any of the bands where the oscillator is adjusted at both the low and high ends of the band. Finally, recheck the broadcast band alignment if the 21MHz oscillator trimmer has had to be altered. Note that the informa­tion on the 611-T indicates that the trimmer is C9 but in the 617T and 719C it is C12. The compromises AIRZONE MODEL 300: manufactur­ed by Airzone (Sydney) in 1934, the Model 300 features a classic wooden “Cathedral” style cabinet. The circuit is a 4-valve superhet with the following valve types: 57 autodyne mixer, 58 IF amplifier, 59 anode bend detector/ audio output and an 80 rectifier. Normally, the front end of a set with seven bands and an RF stage will have six adjustments per band, making a total of 42 adjustments. However, there are only 19 adjustments in these particular sets. There are several reasons for this. First, there are no aerial or RF stage adjustments at the low-frequency end of each band. This means that if the coils are not exactly matched, the performance at the low-frequency WHEN QUALITY COUNTS. . . . valve equipment manufacturers and repairers choose only the best... 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Peak 2 6J8G Cap* 455kHz Broadcast 0 2nd IF Trans. Core L35 Max. Peak 3 6J8G Cap* 455kHz Broadcast 0 1st IF Trans. Core L34 Max. Peak 4 6J8G Cap* 455kHz Broadcast 0 1st IF Trans. Core L33 Max. Peak 5 Aerial 600kHz Broadcast 19 Oscill ator** Core L31 Cal ibration 6 Aerial 1500kHz Broadcast 16 8 Oscill ator C 11 Cal ibration 7 Aerial 1450kHz Broadcast 15 8 Radio Freq. C27 Max. Peak 8 Aerial 1450kHz Broadcast 15 8 Aerial C7 Max. Peak 9 Aerial 17.8MHz 22.3-17.7MHz 18 Oscill ator Core L19 Cal ibration 10 Aerial 17.8MHz 22.3-17.7MHz 18 Radio Freq.** C24 Max. Peak 11 Aeri al 17.8MHz 22.3-17.7MHz 18 Aeri al C4 Max. Peak 12 Aerial 21.0MHz 22.3-17.7MHz 149 Oscill ator C9 Cal ibration 13 Aerial 15.2MHz 19.0-15.0MHz 27 Oscill ator Core L21 Cal ibration 14 Aerial 11.8MHz 15.0-11.7MHz 25 Oscill ator Core L23 Cal ibration 15 Aerial 11.8MHz 15.0-11.7MHz 25 Radio Freq.** C25 Max. Peak 16 Aerial 11.8MHz 15.0-11.7MHz 25 Aerial C5 Max. Peak Recheck 1, 2, 3 & 4 Recheck 5, 6, 7 & 8 17 Aerial 9.5MHz 12.0-9.4MHz 24 Oscill ator Core L25 Cal ibration 18 Aerial 9.0MHz 9.7-3.6MHz 15 6 Oscill ator C13 Cal ibration 19 Aerial 9.0MHz 9.7-3.6MHz 15 6 Radio Freq.** C26 Max. Peak 20 Aerial 9.0MHz 9.7-3.6MHz 15 6 Aerial C6 Max. Peak 21 Aerial 4.0MHz 9.7-3.6MHz 19 Oscill ator Core L27 Cal ibration Recheck 18, 19, 20 & 21 22 Aerial 1.6MHz 4.0-1.5MHz 15 Oscill ator Core L29 Cal ibration 23 Aerial 3.7MHz 4.0-1.5MHz 15 3 Oscill ator C14 Cal ibration Recheck 22 & 23 Finall y, recheck broadcast band. This is necessary onl y wthe setting of C9 has been al tered. * Rock the tuning control back and forth through the signal. ** Wi th grid clip connected. A .001uF capacitor should be connected in seri es wi th the "high" si de of the test instrument. The column headed "Calibration Scale Setting" refers to the 180 degree scale on the ganged tuning capacitor dri ve drum. In taking readings on this scale, read from the right-hand edge of the pointer; ie, the edge nearest the rear of the chassis. Check the setting of the drum before taking readings. The zero mark should be opposi te the pointer wi th the tuning capaci tor ful ly closed. end of the band can be inferior to that obtained at the high-frequency end. Second, on some bands, there are only adjustments for the oscillator at both ends of the band; eg, the 1.54.0MHz band which has no RF or aerial coil adjustments at all. This can be quite a compromise if the coils aren’t accurately matched. In fact, I found that if I wanted good performance at the high end of the band in the 719C, I had to compromise with the oscillator frequency. For this 82  Silicon Chip particular receiver, I found that in order to get good RF sensitivity, I had to adjust the oscilla­tor so that the receiver was actually on 3.65MHz when the dial said it was 3.7MHz. Third, on the 9.4-12.0MHz and 15.0-19.0MHz bands, there is only one adjustment and that is for the oscillator at the low-frequency end. Hopefully the set will track correctly across each of these bands but that’s really a faint hope I’m afraid. The value of C15 is quite critical and by altering GENERAL ELECTRIC MODEL 110: this receiver was made by AWA (Sydney) in 1932 and has the distinction of being the first to be housed in an Australian-made Bakelite cabinet. The same chassis was also marketed under the AWA brand as the Model C87. The circuit is a 4-valve TRF with the following valves: 35 RF amplifier, 24 detector, 47 output and an 80 rectifier. it, it is possible to correct the tracking to some degree. C1 and C22 could also be played with to improve the track­ing of the RF and aerial circuits on shortwave as well. However, it is not an easy task and unless you are a bit of a masochist, it is left well alone. Summary These sets overcome the deficiencies in their tuned cir­cuits by sheer brute force but are not as sensitive as some sets. In addition, the tuning mechanism is free-running and tuning shortwave stations is a dream compared to the “hair’s-breadth” tuning on a conventional dual-wave set. And although the tuning accuracy isn’t as good as it should be, it is better than on most receivers. Most listeners rarely knew the frequencies of the shortwave stations they wanted to listen to anyway. Finally, they are an impressive receiver to look at and well worth a place in your vintage radio collection. If you’ve always wanted to align your AWA 7-bander, this article should be SC all the incentive you need. www.siliconchip.com.au