The Sony TC-161SD
09/01/2022
Repair Progress Report
I bought this on ebay for a little less than £25, as 'faulty'.
Here are some pictures after the deck had been cleaned. The blog pages will be modified as the weeks and months go by ...
No backlight for the VU meters - bulbs had failed. |
Immediate Issues & Fixes:
Play turns off after about 1 second.
Reason: The capstan drive to take-up spool transmission and hence torque was lost due to the clutch rubber idler not engaging. Cause? - the mechanism's elbow/knee joint here has seized up!
Freeing the joint with isopropyl alcohol, later a light oil, then back and forth movement returned the mechanism to full operation - no more unwanted Stop!
Playback speed now was slow and inconsistent
Reason: The main square section belt drive had lost its ability to transmit energy efficiently - it was slack. Today I don't have the correct replacement, but I do have a smaller belt ~ 90mm diameter, 1.2mm x 1.2mm cross section. This works quite well, but a longer belt is on order!
Left & Right Pinch Roller Fixes
Both were cleaned - first with isolpropyl alcohol, then 'roughed up' with a fine grit paper, then cleaned again, finally Rubber Renue was applied.
Rolling the pinch roller back and forth along the 400 grit sheet broke-up the surface of the rubber. |
Hidden from view is a spring mechanism that applies a force pushing the assembly up against the locating ring controlled by the grub screw. The nut is gently tighten for a permanent fix. |
Note: Since the height of the leftmost pinch roller and guide are adjustable, it was important to make sure the guide height was in the middle of the incoming tape.
The tape flow into, and out of the tape guide should be as central as possible. Test this by inserting the cassette for both sides A & B. Also - the tape must not 'ride' against the sides of the guide. |
The TC-161SD Play mode now stable. Fast forward and Rewind now functioning well.
Power Supply Servicing
Motor Run Capacitor: I will re-cap the whole power supply board, but for now I will want to replace the Motor Star/Run Capacitor. As can be seen, there are two settings - one for 50Hz, and a higher voltage for 60Hz mains frequency.
Switch Noise Suppressor: Also, I need to replace the ON/OFF switch 'back emf' or 'spark' suppressor. These can catch fire or smoke as I have experienced before.
General Electrolytic Capacitors: I have begun to replace the old electrolytic capacitors on the power supply circuit board. Checking them so far - the old caps seem fine, but I'll replace them anyway!
Remember, caution is everything, as this deck is possibly 48-50 years old!
New Motor Start/Run Capacitor:
Original Motor Run Circuit |
The original Motor Run Capacitor, which was measured at just over 1.2uF. Note: an electrically isolating plastic cap has been removed here. |
New Motor Run 1uF capacitor, with 450v rating in place. |
A new CBB61 Motor Run Capacitor 1uF, with a 450v rating. Note: 50Hz/60Hz switch removed, and the higher voltage setting (cable) for 60Hz operation has been isolated. |
Warning: Replacing the Motor Run Capacitor can be a dangerous procedure to undertake if you are unfamiliar with electrical, or electronic work and diagrams. If you are uncertain, please do seek the advise and skills of a qualified technician or engineer.
VU Meter Lighting
Surface Mount LEDs used to illuminate the VU Meter display |
Cassette Tape Backlight
The old filement lamps for 'tape progress' indication were replaced with LEDs working off a modified circuit.
Motor Speed
As suggested above, the speed was initially slow and very inconsistent. With new belts and a new 1uF motor run capacitor, the speed has stabilised, but is still incorrect.
I have to date tried all three motor pulley diameters - much too slow, too slow, and too fast. The better of the two speeds from the three possible are still 'way off', perhaps as much as 5%, or even slightly more? I haven't measured, don't need to - it's obvious.
Solution: just realised what the problem was - I had put in a belt of approximately the correct diameter, but only 1.2mmx1.2mm cross section. This narrow belt had worked its way into the narrower area of the v-section of the pulley - effectively a narrower working diameter, thus providing a lower gearing ratio!, that meaning - a slower speed.
The middle pulley seems to be the engineered diameter for 50Hz mains frequency. |
I need to find a 100mm ... 110mm diameter belt with at least 1.5mmx1.5mm cross section.
New Belts Arrived: So now I have a selection of square section belts - 1.2mmx1.2mm, 1.4mmx1.4mm, ~1.9mmx1.9mm, 2mmx2mm, and 2.5mmx2.5mm. Presently, I am unable to get hold of 1.5mm, 1.6mm, or 1.7mm belts.
Below is a set of results showing the playback of a 3150Hz tone, reference ABEX tape, and the various square belt cross sectional measurements -
1.4mmx1.4mmx102mm: 3050Hz (-3.17% error)
1.9mmx1.9mmx105mm: 3280Hz (+4.13% error)
2.0mmx2.0mmx110mm: 3275Hz* (+3.97% error)
2.0mmx2.0mmx110mm: 3295Hz * (+4.60% error)
The latter two belts were supposidely identical!?
The original square belt which is now slack, measures ~1.7mm x 1.7mm x 113mm and returned a test frequency of 3120 .. 3150Hz.
Since the belt had worked itself into a 'slack' state, steady playback was difficult to obtain, but we can see that speed accuarcy with this belt looked promising.
I still need to source a 1.6mm/1.7mm square section belt of around 100mm .. 110mm.
01/02/2022: New 1.6mm x 1.6mm, and 1.7mm x 1.7mm belts ordered - these should improve speed accuracy over the 1.4mm x 1.4mm belts? However, I'm not expecting a miracle, if I can get the TC-161SD to play within ±2% I'll be happy. Athough I would prefer the deck to run a little too fast, rather than too slow.
Blogger article is likely to be amended in the coming weeks and months. 02/02/2022
15/02/2022: New belts 1.7mm x 1.7mm x 101mm arrived.
The updated belt size vs capstan speed is now ...
1.4mm x 1.4mm x 102mm: 3050Hz (-3.17% error)
1.7mm x 1.7mm x 101mm: 3155Hz (~+0.16% error)
1.9mm x 1.9mm x 105mm: 3280Hz (+4.13% error)
2.0mm x 2.0mm x 110mm: 3275Hz* (+3.97% error)
Please note: a meter calibration resolution error of less than 10Hz (~0.3%) should to be taken into account for all measurements above.
The new belt has given a surprising and very satisfying result!
Wow & Flutter?
Yes, there is audiable wow and flutter - higher than the quoted specifications.
So what are the potential sources of this unwanted wow and flutter?
Sources of Wow & Flutter
1) Belt too tight?
At 101mm, it may be a little too tight? Perhaps a diameter of 105mm-110mm would improve matters? At this moment, I cannot not source a 1.7mm x 1.7mm x 105mm..110mm (diameter) belt.
2) Traction between pinch roller and capstan?
Now improved, both pinch roller mechanisms removed and cleaned, especially the bearings. Earlier I discovered some unwanted friction on the leftmost pinch roller.
Pinch rollers cleaned, and treated with Rubber Renue.
* Despite the work done, it is still possible that I need new pinch rollers?!
3) Slippy Capstans?
Thoroughly cleaned. Make certain no oil is creeping up the capstan shaft.
4) Motor and Flywheel Pulleys?
Thoroughly cleaned.
5) Transmission line?
The belt is 'in line' between motor pulley and flywheel.
6) Vertical Flywheel 'Play' or Movement?
The flywheels are not experiencing any unwanted friction.
7) Excessive and/or constant friction in overall transmission chain?
8) Inconsistent elasticity along different parts of the belt?
{Hooke's Law: Deformation of a material is proportional to the force applied, within the elastic limits of the said material. I sense that some belts offer inconsistent deformation along their lengths!? A source for additional wow and flutter???}
17/02/2022: New belt 1.6mm x 1.6mm x 110mm fitted.
Just arrived today, this is the final belt I'll purchase for this machine.
Big thanks to Donberg Electronics for selling so many belt variations.
Speed result: 3135Hz! and of course less overall belt tension, I'm very tempted to suggest that this is better than the 1.7mm x 1.7mm x 101mm I put on earlier!?
To recap -
1.4mmx1.4mmx102mm: 3050Hz (-3.17% error)
1.6mm x 1.6mm x 110mm: 3135Hz (-0.48% error)
1.7mmx1.7mmx101mm: 3155Hz (+0.16% error)
1.9mmx1.9mmx105mm: 3280Hz (+4.13% error)
2.0mmx2.0mmx110mm: 3275Hz* (+3.97% error)
Less than 10Hz (~0.33%) meter calibration error
has not been added/subtracted into the above figures.
Broken Grub Screw for Pinch Roller Assembly
Unfortunately the right sided pinch roller assembly's fixing screw ('grub screw') broke very easily. I had to drill the spacer/collar out and eventually replace (for now) with a series of nylon washers, with the 3mm (threaded) securing nut to set the height for the roller. I used clear nail varnish as a bonding agent so the nut will remain fixed in position.
Any unwanted movement will be detected when the two blue marks are out of line.
Wow & Flutter Issues Resolved? (13/02/2022)
Have I finally solved the problem of excessive W&F? Well, not quite - I initially thought so.
The leading pinch roller seemed to be too high. Small but visible imperfections in the machining of the capstan's top end appeared to be transmitting some 'wobble' to the smooth running of the pinch roller>
However, I can still hear W&F, but more like a flutter especially in classical music, in particular pianos and slow moving strings etc.
Perhaps I ought to think about replacing the pinch roller?, I've done everything I can think of.
23/03/2022: New Pinch Rollers Fitted
The old pinch roller pins were 2mm in diameter but with a narrower section at one end. To remove them I had to partially, and carefully drill-out the 'rivetted' side of the pin. This also meant I had to later ream the existing hole to about 2mm in diameter - this was a delicate process.
The new 11mm x 8mm x 2mm-centred pinch rollers fitted perfectly, and are held in place using steel rivets with a 12mm length. Gravity and friction will hold the rivets in place.
With new pinch rollers fitted, the record head had to be physically re-calibrated for stroke, tilt, track height, and azimuth.
New pinch rollers, and steel rivets. |
Removing the record head assembly proved difficult because of the 50 year old adhesive which had set quite hard. It was difficult to establish azimuth control which is why I removed as much of the old adhesive. I will later remove it all with pure acetone, but for now it works!
Capstan Re-Sanding (Do not do this!!!)
Some weeks ago I very foolishly applied 800 grit sanding paper for a handful of seconds to the capstans in a desperate attempt to kill the wow/flutter - big mistake!!! In doing so the capstan-to-tape slippage on the supply side became a little irratic - occasionally I would experience the tape lifting slightly up over the erase head. A another bigger problem soon became evident - the take up capstan and the pinch roller worked together in such a way that the tape began to ride up a little perhaps 1mm-1.5mm!
This completely upset the balance of the transport, the results were as follows - tape wouldn't erase properly in the right channel, head alignment had to be re-configured, and of course the tape ran above its normal line of travel. What a mess!
Solution? - carefully cut and shaped, then applied 3000 emery paper until I was happy with the 'finish' to both capstans. I did consider obtaining finer paper, but it wasn't required.
(June 2022: Finer 5000 and 7000 grit paper was used to polish the capstans. All good now.)
After resetting the pinch rollers, erase head, and the record head - all was good again. Consistent high stability restored, even on C120 tapes!
Change in Tape Speed?
Back to this topic again!
I suppose I can expect a small change in tape speed now that the capstans have been 'sanded' a little.
1.4mmx1.4mmx102mm: 3050Hz (-3.17% error)
1.6mm x 1.6mm x 110mm: 3135Hz (-0.48% error)
1.6mm x 1.6mm x110mm: 3125Hz ( -0.80% error)
1.7mmx1.7mmx101mm: 3155Hz (+0.16% error)
1.9mmx1.9mmx105mm: 3280Hz (+4.13% error)
2.0mmx2.0mmx110mm: 3275Hz* (+3.97% error)
and random speed variations which cannot be
accounted for, except perhaps a small change
in (UK) 50Hz mains frequency.
Not sure why WFGUI varies on its W&F measurements? Although on examining 3000Hz sinewave playback traces on the oscilloscope, there appears to be transient breaks in the waves, and so may be misinterpreted by WFGUI?
(11/04/2022)
- Flat belts probably yield lower wow & flutter figures?
- Flat belt thicknesses are often much less than a square section thickness - allowing us to predict tape speed? Observe above variabilities in tape speed with square section thicknesses, and ±5% excessive speed errors are easily obtained.
Finding a suitable belt has been difficult - the optimum belt square section here being about 1.6mmx1.6mm. If I had the choice, I would like to fit a slightly larger diameter belt of between 112mm and 116mm. This would also lower wow & flutter figures, as tests have revealed.
I have one such belt on order - a 1.7mm x 1.7mm x 116mm. Let's see if this works any better!? I don't mind a cassette deck running a little fast, if this meant that wow and flutter figures are lower than 0.2% wrms, I'll be satisfied.
(4th June 2022)
A new '4mm x 12mm x 4mm' sealed bearing has been fitted. On the motor shaft there are brass/carbon spacers. Surprisingly, replacing the brass-carbon-brass shim washers the other way around on the rotor shaft resulted in 'noisey' motor action, not sure why!? Sounded similar to two sheets of paper rubbing gently together. All is fine now, except for wow and flutter figures still appear to be too high; 0.12% .. 0.18% DIN? according to WFGUI.EXE. It seems that the belt's W/F figures do improve with use, but this 161SD is quoted to have a W/F of about 0.1% DIN?
Lower: Four pole-pair field windings in the Stator. Top: Rotor with brass/carbon spacers Right: New sealed bearings. Right: Motor End-cap and adjustable nylon(?) cap. |
New Belts Arrived: (08/07/2022)
Unfortunately the 116mm was too long, although the belt did run the deck okay, and wow and flutter was indeed lower. However, a 116mm diameter belt is too big for this early model of the TC-161SD - I would not recommend purchasing one.
The optimum square belt diameter for an early production run of the Sony TC-161SD would be between 110mm to 114mm x 1.6 mm x 1.6mm.
Without going into the details too much, an auto-stop failure began to emerge during the end-of-tape state during Play. After analysing the System Control Circuit, I took the precaution of replacing all the remaining electrolytic capacitors that I hadn't replaced, and the C945 (2SC633A according to the SM) transistors that were already in circuit. The signal diodes were also replaced with 1N4148 types.
This slide switch is a 4-pole, double throw mechanism, commonly termed '4PDT'.
This 4PDT slide switch is a 'make before break' switch. |
The internal contacts and the spring contacts were 'cleaned' with fine emery paper and later switch cleaner. The switch was then re-positioned into this PCB and re-soldered.
The dark patch is a coating of clear nail varnish. |
I've decided to order some TE Connectivity PCB Slide Switches: Four Pole Double Throw (4PDT). We shall see if they prove to be a success!?
Standard Deviation: 1.25Hz
Mean Wow/Flutter: 0.15% DIN
Standard Deviation: 0.0183%
I'm tempted to experiment and put in a larger cross-sectional belt, just to see how this affects wow and flutter figures.
21/01/2022 Wow and Flutter Update:
This can be reduced further if I allow the Sony TC-161SD to be running for 15 minutes or more. A figure of 0.134% DIN was recorded from a sample of 200 readings from WFGUI.EXE. Draw your own conclusions why this is; my immediate thoughts were temperature rise, humidity variations, which all affect uniformity in belt elasticity?
Update: 06/04/2024
Firstly, apologies to readers of this article. I have deleted most of what originally followed after this sentence. The reason was simple - I'm still casually working on this TC-161SD deck, and finding various factors that lead to changes in wow and flutter. One such factor which was not immediately obvious is now partially explained.
One Definite Source of Wow & Flutter: (06/04/2024)
On inspection of the FF/RW idler and associated mechanisms, I did notice that spinning (by hand) the axis of the idler gear was easy when in an 'upside down' position (as shown below), but then it gained friction when inverted!? And of course when the 161SD is playing normally, this friction is going to become potentially troublesome for the motor - effectively adding an additional and intermittent load?
The whole FF/RW mechanism was disassembled, thoroughly cleaned, and lubricated, and what followed was a distinct improvement in the consistency of wow and flutter. Rather than being highly variable between tests.
Until I have narrowed down all the factors that lead to excessive wow and flutter, I shall not be making any more contributions to this article.
06/04/2024.