Sam's Bush VHF90

Sam popped by with her much beloved, but sadly non-working Bush VHF90 radio...

"It sometimes picks up Radio 2, but nothing else.. Can you take a look?"

Yeah , why not?

It's a dual-band MW and VHF (FM) set, dating from 1956. Now, back then, VHF was in it's infancy. There wasn't any commercial radio in the UK until the 70's, so it was all BBC only. The band extended from 88 - 100 MHz only, not up to the current band edge at 108 MHz.

Removal of the back, and the first thing I notice...













...the mains tap is set to 200-210 Volts .... aghh ! This is never a good sign. The mains voltage in the UK is 240V (listed as 230V since European "harmonisation", but nothing actually changed). As a set's valves aged, unscrupulous repairers (bodgers) would lower the tap setting, giving the warn out valves a bit more voltage in an attempt to eek a little more life out of them, but putting the rest of the set under undue stresses and strains..... It's a practice known as "tapping up the set". Bad news...



Putting the UL84 output valve on test shows the sorry state of things...

Every valve in the set tests bad, and will require replacement.

Thankfully, they're all U pre-fix (designed for 100mA series heaters) valves, and are reasonably inexpensive.




So, I've got a couple of valves in stock, and a couple sourced locally... I can get on with the rest of the chassis whilst the others turn up from the internet.

First off, let's check out the dropper resistor, as it's going to have a hard life, having had the wrong tap selected....

.... hang on a minute... the bodger's been here again! There's a section physically missing! It's the 240-250V section. The 220-230V section is also open circuit... both are replaced.










Whilst most of the wiring is PVC, there's some rubber insulated wire which has perished. It's replaced with PVC....








In a break with usual tradition, the whole chassis recapped wholesale...












After a couple of days, the new valves turned up, and the set was powered up... sure enough BBC Radio Two on 88.6 MHz is all that can be received... and with the tuning dial set to 100 MHz! There's absolutely nothing on Medium wave at all .... not even a crackle...

I start with the lack of medium wave. Much head-scratching, staring at the circuit diagram, drinking of tea, and measuring of components followed.... There's a positive voltage on the grid of the UCH81 mixer-oscillator which shouldn't be there. Tests proved the new valve wasn't the fault, so where was this voltage coming from? I disconnected the wire to the valve pin, and the voltage is on the wire... medium wave starts working (ish) but the voltage should be disconnected by the switch...

Then I found this ... http://www.vintage-radio.com/recent-repairs/bush-vhf90-1.html

The switch has become conductive and is leaking! I cleaned it up.. it didn't help. Thankfully the webpage describes a work-around...










... which is duly implemented, and works well...

Medium wave is restored, but it's really weak.

Re-aligning the set provides great improvements, the second IF amp being way off the mark, as was the front end... Mr Bodger again?

The cathode resistor to the UL84 output pentode was also found to be low in value!


Next to sort out the VHF....

The tuning drive cord had been replaced (bodged) with string at some stage in it's life, it was slipping badly... The pointer had been replaced with a bit of copper wire, something I've done in the past when the original is missing and unobtainable..

The whole drive was slipping badly. There should be a spring in there somewhere, to tension the cord around the drum and pulleys too. The drum is directly connected to the AM tuning capacitor. VHF tuning, is that piece of cord you can see disappearing into the grey VHF front end to the left. It pulls a spring-loaded ferrite core out of an inductor inside the can, thus changing the frequency. It looks like the whole lot had been assembled wrongly.

After more tea, a new drive cord, some more tea, and some considerable head scratching, it all works as it should.

After a quick re-alignment of the VHF stages, it happily tunes from 87.5 -102.5 MHz.


Now Sam was keen to do the cabinet herself... but we had a problem...

I won't let it leave my workshop with a gaping hole in the bottom, as the chassis is connected to the neutral, and there's all sorts of live bits accessible through that hole... Electric shock is not an option.






A small piece of glass-fibre matt is cut...













... and hardened with resin to make it safe.

Sam seems to think she knows where the bit that fell out is, so she can cut this out at a later date and refit.








The guilty parties ...












Here's a quick video description and the thing finally working on AM....

Arduino PPM monitoring and switching.

I got involved with the local hospital radio station back in 2000, as station engineer. Been there ever since.

Now the station's studio used to be in a rather damp basement of a building built in about 1860. The hospital have decided to sell the building, so the station was evicted. They found us some nice new accommodation in a nice new building, and built us a super studio. All we had to do was move the kit and get it back on the air.


 The old studio used an undocumented "TX bay" rack to route the signals from 2 separate control studios and one presenter booth to the broadcast output. One studio would be live, and one for rehearsal/production.

Now we had one studio, so a lot of the switching could be eliminated. We would still need a rehearsal solution though.

This is the old TX bay, now minus it's switching and compressors etc... It was designed and built in the early 80's by person or persons unknown. It had a propensity to blow logic and transistor arrays up with the slightest hint of a rumble of thunder within a 100 mile radius! I shan't really miss it!

So, the desk was moved, and a nice new rack donated to house all the broadcast gear!

After a long day, the thing is back on the air!
















I built up a new headphone distribution amplifier, using 5 Class-D PM8403 amplifiers, wired for mono. A note here, the PAM8403 does not allow you to tie the -ve speaker outputs together for stereo headphone operation! The station is mono anyway, so it doesn't matter!










Completed headphone distribution amplifier.









Looking all quite nice and professional...


 


... but there's no method of switching the studio into rehearsal mode, and the PPM monitoring (allowing the operator to set her or his levels before going live) was lashed up using an old box donated by my good friend Piers at Raycom.

So... we need a small box, that will allow the following...

PPM level display from the monitor output from the mixing desk.
Switching to allow the desk output to be disconnected from the transmitter feed, and switch in the output from the 24 hour play out computer, to allow rehearsal mode.
Drive the "MIC LIVE" red lights.

So... after a bit of head scratching ....

Now the studio uses professional level, balanced audio (mostly). The output from the 24 hour playout system isn't. This is fed into the box, and it's turned into a balanced signal by IC5, and IC6A. There's a bit of amplification there too, to take the level up match the rest of the studio. This signal is fed back out to it's own fader on the desk, to allow for a seamless transition between live and rehearse.
In rehearsal mode, this signal is also fed straight out to the transmitter feed.
The live/ rehearsal switching is carried out by the microcontroller, controlling relay K1
In "live" mode, the signal from the desk is routed straight from the desk to the transmitter feed.

The monitor signal is also sent to the box, and is unbalanced by IC6B, and fed to the analogue input of our microcontroller. R29 and R31 are used to give the signal a 2.5V off-set.

The "mic live" signal (18V active low) is connected from the desk, via an opto-coupler, to the micro, where it's inverted in the code, and used to control the Mic live output FET Q2.

You will notice there are two, quite separate power supplies. One supplies +/-15V for the audio stuff, and the other an unregulated +15V and a regulated 5V for the micro and switching duties. The grounds are only commoned at one location.

There's a couple of LEDs to indicate the rehearsal status, and for peak (overload) warning. A 20x4 LCD provides the same information, as well as Mic live status and the level monitoring...

Now the level display. I wanted something smooth, not just using whole character blocks...
So I've defined a bunch of single pixel wide special characters, which are written to the display on the fly.

I also wanted a slower responding "peak" display. This is implemented in a similar manner.

(When I refer to the Pin's here, it's the physical pin on the ATMEGA328 IC itself, NOT arduino pin numbers.)

The audio is sampled (in the void getSample) from the ADC 0 pin, 48 times. This provides the required 5mS delay to stop the meter flickering around wildly. The maximum value is taken, and centered around 512 (our 2.5V offset) and then converted into a log scale.
The bar graph level is then plotted.

If the peak level is exceeded, it's updated and plotted too. It decays 0.1dB every loop cycle. It's limited to -54.19 dB to prevent a divide by zero error!

The mic live signal is read in via pin 14 and inverted, and then output on pin 12, which causes the output FET Q2 to switch the LED lamps on.

The Live/Rehearsal switch is read, and used to start a timer, which provides debounce, and plots a bar graph to give the user some feedback that switching is about to occur. The switching is carried out at pin 16, which switches T1, and the relay.

The Mic live lamps themselves, are a 3W LED, and a simple LM317T constant current source set to about 500mA.

 Construction was on three boards, the display has the digital and switching board "piggybacked", the analogue stuff is kept separate, and the two power supplies are on the third board.

All the interconnecting signal and power supply connections are twisted where possible.

Mic-live lamps are simple....












... but effective, and much more energy efficient than the old 60 watt incandescent lamps!











I'm rather pleased with the look of the thing.

It was built up into a second hand case, which I put in the dishwasher and re-painted :)








Here's a quick video of the thing in action!


There, the patients at two hospitals can enjoy some relaxing music and requests once more!

Here's the code:

/* Console controller V1.0 * (c) A.G.Doswell 17th January 2017 License: The MIT License (See full license at the bottom of this file) */ #include <LiquidCrystal.h> LiquidCrystal lcd(12, 11, 5, 4, 3, 2); byte oneBar[8] = { //these define the special characters required 16, 16, 16, 16, 16, 16, 16, 16 }; byte oneBarPlusThree[8] = { 20, 20, 20, 20, 20, 20, 20, 20 }; byte oneBarPlusFour[8] = { 18, 18, 18, 18, 18, 18, 18, 18 }; byte oneBarPlusFive[8] = { 17, 17, 17, 17, 17, 17, 17, 17 }; byte twoBar[8] = { 24, 24, 24, 24, 24, 24, 24, 24 }; byte twoBarPlusFour[8] = { 26, 26, 26, 26, 26, 26, 26, 26 }; byte twoBarPlusFive[8] = { 27, 27, 27, 27, 27, 27, 27, 27 }; byte threeBar[8] = { 28, 28, 28, 28, 28, 28, 28, 28 }; byte threeBarPlusFive[8] = { 29, 29, 29, 29, 29, 29, 29, 29 }; byte fourBar[8] = { 30, 30, 30, 30, 30, 30, 30, 30 }; byte barTwo[8] = { 8, 8, 8, 8, 8, 8, 8, 8 }; byte barThree[8] = { 4, 4, 4, 4, 4, 4, 4, 4 }; byte barFour[8] = { 2, 2, 2, 2, 2, 2, 2, 2 }; byte barFive[8] = { 1, 1, 1, 1, 1, 1, 1, 1 }; float dBLevel; boolean rehearse; float zero = 512; float dBPeak; int count; int barsPlotted; int wholeCharsPlotted; int remainingBarsPlotted; int cursorPos; int peakWholeCharsPlotted; int peakBarsPlotted; int peakRemainingBarsPlotted; int rehPin = 9; int micLiveInputPin = 8; int micLiveOutputPin = 6; int rehRelayPin = 10; int rehLEDPin = 7; int overLEDPin = 13; int rehCounter = 0; boolean rehFlag = false; void setup() { // set up IO's pinMode (rehPin, INPUT); digitalWrite(rehPin, HIGH); pinMode (micLiveInputPin, INPUT); pinMode (micLiveOutputPin, OUTPUT); digitalWrite (micLiveOutputPin, LOW); pinMode (rehRelayPin, OUTPUT); digitalWrite (rehRelayPin, LOW); pinMode (rehLEDPin, OUTPUT); digitalWrite (rehLEDPin, LOW); pinMode (overLEDPin, OUTPUT); digitalWrite (overLEDPin, LOW); // set up LCD lcd.begin (20, 4); lcd.clear (); lcd.print ("Cotswold Hospital"); lcd.setCursor (0, 1); lcd.print ("Radio 'Dolls house'"); lcd.setCursor (0, 2); lcd.print ("(C) 2017 A.G.Doswell"); delay (1000); lcd.createChar (2, barFive); lcd.clear (); lcd.print ("Desk LIVE Mic off"); lcd.setCursor (15, 2); lcd.write (byte(2)); lcd.setCursor (7, 2); lcd.print ("Set PFL>"); } void loop() { getSample(); updateStatus (); barsPlotted = (1.845 * dBLevel) + 100; // convert dB to bars plotted (there are 100 bars on the display) peakBarsPlotted = (1.845 * dBPeak) + 100; // as above but for the peak level wholeCharsPlotted = barsPlotted / 5; peakWholeCharsPlotted = peakBarsPlotted / 5; remainingBarsPlotted = barsPlotted - (wholeCharsPlotted * 5); peakRemainingBarsPlotted = peakBarsPlotted - (peakWholeCharsPlotted * 5); for (cursorPos = 0 ; cursorPos < wholeCharsPlotted; cursorPos++) { //plot whole characters lcd.setCursor (cursorPos, 3); lcd.print (char(255)); } switch (remainingBarsPlotted) { //plot partial charachers, by defining chars on the fly case 4: lcd.createChar(0, fourBar); lcd.setCursor (cursorPos, 3); lcd.write(byte(0)); cursorPos++; break; case 3: lcd.createChar(0, threeBar); lcd.setCursor (cursorPos, 3); lcd.write(byte(0)); cursorPos++; break; case 2: lcd.createChar(0, twoBar); lcd.setCursor (cursorPos, 3); lcd.write(byte(0)); cursorPos++; break; case 1: lcd.createChar(0, oneBar); lcd.setCursor (cursorPos, 3); lcd.write(byte(0)); cursorPos++; break; } for (cursorPos; cursorPos < 20; cursorPos++) { lcd.setCursor (cursorPos, 3); lcd.print(" "); } //plot peak level cursorPos = peakWholeCharsPlotted ; if (peakBarsPlotted != barsPlotted) { if (peakWholeCharsPlotted > wholeCharsPlotted) { lcd.setCursor (peakWholeCharsPlotted, 3); switch (peakRemainingBarsPlotted) { case 4: lcd.createChar(1, barFour); lcd.setCursor (cursorPos, 3); lcd.write(byte(1)); break; case 3: lcd.createChar(1, barThree); lcd.setCursor (cursorPos, 3); lcd.write(byte(1)); break; case 2: lcd.createChar(1, barTwo); lcd.setCursor (cursorPos, 3); lcd.write(byte(1)); break; case 1: lcd.createChar(1, oneBar); lcd.setCursor (cursorPos, 3); lcd.write(byte(1)); break; } } } if (wholeCharsPlotted > 15) { lcd.setCursor (16, 2); lcd.print("OVER"); digitalWrite (13, HIGH); } else { lcd.setCursor (16, 2); lcd.print(" "); digitalWrite (13, LOW); } dBPeak = dBPeak - 0.1; //decay the peak value, but limit it to -54.19 if (dBPeak <= -54.19) { dBPeak = -54.19; } } void getSample () { float maxRaw = 0; float raw; for (int sample = 0; sample < 48; sample++) { //get 48 samples from the A to D, use the biggest. ~5mS delay to the meter raw = analogRead(A0); if (raw > maxRaw) { maxRaw = raw; } } if (maxRaw == 512) { // This fudges the result slightly, so we don't return an inf (divide by zero) maxRaw = 511; } dBLevel = (20 * log10 (abs(maxRaw - zero) / zero)); // convert to dB scale if (dBLevel > dBPeak) { //sets "peak" value dBPeak = dBLevel; } } void updateStatus () { //check all digital inputs and update rehearse staus/ mic live as required int val = digitalRead(micLiveInputPin); digitalWrite (micLiveOutputPin, val); if (val == HIGH) { lcd.setCursor (16, 0); lcd.print ("LIVE"); } else { lcd.setCursor (16, 0); lcd.print ("Off "); } if (digitalRead (rehPin) == LOW) { // Read reh push button. Counter prevents switch bounce, and also gives a press-and-hold function to mode select to prevent accidental switching. rehCounter ++; lcd.setCursor (rehCounter / 5, 1); lcd.print (char(255)); } else { rehCounter=0; } if (rehCounter == 100) { rehFlag = !rehFlag; rehCounter = 0; } if (rehCounter == 0 ) { lcd.setCursor (0, 1); lcd.print (" "); } if (rehFlag == true) { digitalWrite (rehRelayPin, HIGH); digitalWrite (rehLEDPin, HIGH); lcd.setCursor (5, 0); lcd.print ("REH "); } else { digitalWrite (rehRelayPin, LOW); digitalWrite (rehLEDPin, LOW); lcd.setCursor (5, 0); lcd.print ("LIVE"); } } /* Copyright (c) 2016 Andrew Doswell Permission is hereby granted, free of charge, to any person obtaining a copy of this software and associated documentation files (the "Software"), to deal in the Software without restriction, including without limitation the rights to use, copy, modify, merge, publish, distribute, sublicense, and/or sell copies of the Software, and to permit persons to whom the Software is furnished to do so, subject to the following conditions: The above copyright notice and this permiSerialion notice shall be included in all copies or substantial portions of the Software. Any commercial use is prohibited without prior arrangement. THE SOFTWARE IS PROVIDED "AS IS", WITHOUT WARRANTY OF ANY KIND, EXPRESS OR IMPLIED, INCLUDING BUT NOT LIMITED TO THE WARRANTIES OF MERCHANTABILITY, FITNESerial FOR A PARTICULAR PURPOSE AND NONINFRINGEMENT. IN NO EVENT SHALL THE AUTHOR(S) OR COPYRIGHT HOLDER(S) BE LIABLE FOR ANY CLAIM, DAMAGES OR OTHER LIABILITY, WHETHER IN AN ACTION OF CONTRACT, TORT OR OTHERWISE, ARISING FROM, OUT OF OR IN CONNECTION WITH THE SOFTWARE OR THE USE OR OTHER DEALINGS IN THE SOFTWARE. */

Harman Kardon PM660

Hamstall called by. I've got this 'arman Kardon, can you give it the once-over?

Yeah, why not.

It a nice early 80's integrated amplifier. Spec recons on about 80 watts per channel into 8 Ohms. No spec is given for power into 4 ohms. It's a completely discrete design. Not an op-amp in sight.



Nicely laid out...











A good-sized transformer and rectifiers... and plenty of smoothing caps.










10,000 uF , and there's 4 of 'em....













... and that "Sony" on//off switch .... (it all looks a bit Sony to be honest)











Super phono pre-amp, MC and MM....












... fitting with a smattering of ELNA "for audio" capacitors, so you know where your money went....











... and four position, front panel adjustable, capacitance loading for your odd-ball cartridge....


















Underneath reveals, well, not a lot really. 4 pairs of Toshiba 2SB775/2SD845 output transistors. Cleverly mounted through holes in the PCB, straight onto those gargantuan heatsinks....

Speaker wiring takes a bit of a long route home....











... and through some rather flimsy looking speaker select switches. I don't think I'd want to be switching speakers whilst playing....

























Two tape loops, two phono inputs (with short circuit plugs if you're not using one to keep the noise out), an aux and a tuner input....









So ... set the bias up (a blissfully easy procedure, thanks to a great service manual), a clean up of the pots and switches, all the caps look in great condition, and testing the ESR of a good few proves this to be the case.

The tuner indicator lamp is open-circuit...

Diminutive little lamp, so we'll replace it with a warm-white wide-angle LED...










The holder had to be drilled out slightly to enable the slightly fatter legs of the LED to pass through, and a 10K currently limiting resistor is fitted, to run the LED at a low ~1mA.









Not a bad colour match....

It plays effortlessly. I've no idea on it's output power as it easily over-ranges my audio wattmeter at 50 watts, with no sign of distress.

The phono stage is a delight. Nice and quiet.

Tone controls have a lot more range than is probably required...

There... another repair done...

Linn Axis (of evil) repair

Belated happy new year readers!

Been a really busy January, and I've not had much time in the workshop. I've completely moved a radio station for a charity, and it's been stressful! (more on that in a forthcoming post)

Anyway, Jon rang. A fine cycling chap from Bristol. Got an Linn Axis that won't run....

Can you take a look?

Yeah, why not...

It duly arrives sans platter and stylus.

I plug it in , and sure enough the motor just stutters... which is pretty usual for one of these.

The motor drive board will be faulty. Now there's much BS on the interwebs that these boards aren't repairable as "the programmable parts are no longer available" .... which is rubbish, as there aren't any.... someone's probably just trying to flog you an upgrade ... and Linn ownership is all about upgrades , right?

It's just a bunch of logic, and some op-amps...

This board is quite an early one, as it's got a ribbon cable to the speed/on/off switch which is soldered straight into the board...


So. Remove the sub platter and belt. Clean up the inevitable oil spill from the bearing. Now move the turntable to the edge of the bench, and remove the three large suspension screws holding the top plate to the rubber suspension mounts. If you're doing this with the arm attached, remove the cable strain relief first. Lift up the front edge of the top plate a bit and have a peep underneath. If your switch is attached by a coloured ribbon cable, then you'll need to pop the switch out, and slide it back inside. If it's a copper coloured flexi, (like Jon's below) just disconnect it from the motor drive board. Lift the top plate clear and put it out of reach of the cat.


Now remove the 6 small screws indicated by the red arrows, and the mains lead from the terminal block on the bottom right.

With a bit of jiggling, you should now be able to extract the board. You may need to squash one of the suspension mounts a bit to extract it.






Now change every last damn electrolytic on the board, even the high voltage ones.

Here's the shopping list:
2 x 33uF 350V axial
2 x 47uF 250V axial
2x 220uF 16V axial
7x 22uF 50V radial.





Now a word of warning.... this board is "live" when it's connected. So use an isolation transformer when doing any fault finding on it. With a bit of luck, you should now have a running board.. however, I have seen turntables with D2 & D3 open circuit, BR1 short circuit. A real head scratcher was one which intermittently blew fuses, which was one of the BUX85F output transistors!

Now if you switch the motor on without a platter and belt on, it will spin up, and then stall a few seconds later. This is usual. Once the platter is on, it should work fine.

.... of course Jon's wasn't going to be so easy, and also needed an LM324 quad op-amp replaced to finally restore operation....

I've seen forum posts saying just change the small caps....... change 'em all. These had been in there since 1989 and were shot away!











Once it's all happy, put the top plate back on, do up the suspension screws (not too tight) and replace the strain-relief on the tone arm wires and check the speed (you really need the top platter on when doing this)

Speed is adjusted using an INSULATED screw driver through two holes on the underside. They have bungs in them, you'll need to just pop those out, and replace them once happy.


Now Jon ... where's your stylus?

UPDATE March 2019! ...

Colin's just popped round with another Axis with a common problem after recapping .... motor spins backwards or not at all or just sits there vibrating. Usual causes are the two HEF4013 flip-flops hanging a line up. Change 'em both. They're just by the switch cable, and are U1 and U2.

Other frequent flyers are the two watty 15K resistors, R2 & R3. With these faulty, there won't be 35V across C5.

Have fun all!