SERVICEMAN'S LOG
A bounce with a twist
No, that’s not a new section in an Olympic Games
diving competition. Perhaps I should have called
it the bounce that wasn’t. Anyway, we all know
what a bounce means in servicing parlance, and
that’s the theme.
I’ve been talking a lot about bounces
in recent notes - and the trauma and
acrimony they can cause. Well this
story had all the makings of a bounce
situation, except for one factor; the
time between failures. I wonder what
the record is?
Anyway, to start at the beginning.
The set involved was a General GC187,
43cm colour set of around 1984 vintage
and was one of several belonging to a
40 Silicon Chip
local motel. It is a rather elementary
type of set by modern standards,
without any remote control or other
up-market gimmicks encountered in
later models.
The first time I serviced this particular set was back in 1993 and the
complaint at that time was that the
image was very dark. Because all sorts
of funny things - technical things,
that is - go on in motels I find it best
to view such problems in situ. Damaged antenna outlets, faulty antenna
distribution systems, even faulty
power points, are all possibilities in
such installations.
In fact, it didn’t take long to eliminate all these and confirm that yes, the
set was faulty. But in spite of having
serviced most of these sets in the
motel over the years - and some from
other customers - I had never seen this
symptom before. So it was into the van
and back to the workshop.
As a general rule, faults of this
kind suggest a low or missing voltage
around the picture tube and immediate
circuitry.
My first check was to the picture
tube screen (pin 8), which was something over 500V with the screen control as set. I decided that this was a
perfectly reasonable figure. The EHT
voltage is shown as 22kV and this was,
if anything, a fraction high.
At a more basic level I checked the
supply rails. There are four altogether, +175V off pin 9 of the horizontal
output transformer, T602, +127V from
the switchmode supply (test point
TP601) and two low voltage rails, one
at +13.8V and another at +12V. All
checked out as specified.
That routine completed, it was time
to look for something more specific.
And the first thing I checked was the
collector voltages on the red, green and
blue driver transistors, Q201, Q202
and Q203. These are shown as ranging
from +105V to +108V but in fact were
much higher, over +150V.
Which meant, of course, that the
picture tube cathodes were similarly
too high; around 50V more positive
than they should have been. Which
is only another way of saying that the
respective picture tube grids were 50V
more negative than they should have
been. No wonder the picture was dark.
OK, we were on the track. But why?
The fact that this error was occurring
on all three drive transistors suggested
a common cause and the most likely
Fig.1: General GC187. IC301 is at the top, with the sub-brightness and
brightness controls below it, and D360 and resistors R624, R640 below again
and to the left. One of the drive transistors (red) is at lower right.
one would be something associated
with the brightness circuit.
The three drive transistors are
driven from pins 26, 27 and 28 of
IC301, described as the video amp/
PAL processor. And the brightness
circuit connects to pin 4 of this IC and
consists of a sub-brightness control
VR304 (10kΩ) and the main brightness
control, VR709 (5kΩ).
And this leads back to a network, via
a diode, D360, consisting of resistors
R624 (560kΩ) and R640 (120kΩ) in
parallel, connected to the 127V rail.
More importantly, the voltage at pin
4, shown as 8.4V, was down significantly. (I can’t remember by exactly
how much after all this time but it was
significant.)
I tried adjusting the sub-brightness
and brightness controls but this had
only a marginal effect; enough to indicate that they seemed to be working,
within the constraints of the fault.
I checked diode D360, which was
OK, then resistors R624 and R640.
And this looked like the answer because R640 had gone high. I replaced
it and R624 at the same time, just to
be on the safe side. Unfortunately,
it wasn’t the real answer; it helped
but it didn’t cure the fault. In fact,
it made me aware of another fault;
the colour was dropping in and out
intermittently.
I made a few more voltage checks
but could find nothing wrong. It was
time to check the dynamic aspects of
the system; blanking pulses and such
like. My first check was on a horizontal pulse to pin 23 of IC301, via a 1kΩ
resistor, R327. This was shown as a
typical triangular pulse at 3.2Vp-p.
And it was; exactly.
Next, I checked pin 19. This is
shown as a similar pulse at 2.6Vp-p.
Only it wasn’t; this waveform was
missing completely. Well, I was hot
on the trail now, even though it was
a rather longish one; all the way back
to pin 16 of IC401, the horizontal and
vertical oscillator and drive stages.
On the way it goes through a 15mH
choke, L402 and a couple of resistors.
On an impulse, I wiggled the choke.
And bingo! Suddenly everything came
good; full brightness, normal colour
and a first class picture.
I didn’t waste time finding out what
was wrong with the choke; I reefed it
out and fitted a new one. Everything
came good again, I let it run for the
next couple of days, with no sign of
trouble and returned it to the customer.
And that was the end of the story.
Well, for 1993.
But a few weeks ago the motel proprietor was on the phone asking me
to have a look at a set. And what was
September 1996 41
wrong with it? “Aw, the picture’s gone
dark.” And yes, it was the same set,
with the same fault, three years later.
However, I must confess to stretching things a bit when I imply that this
was a “bounce” in the normal servicing
sense of the word. The truth is that
I was the only one to appreciate the
situation.
The proprietor had completely forgotten that this was the same set with
the same symptoms of three years
previously. So there was no aggro of
any kind; just a funny feeling on my
part as to what might have been.
Anyway, down to business. I visited
the motel again and yes, at switch-on,
the picture was very dark. Instinctively
I reached for the brightness control and
gave it a tweak. And up came the picture to normal brightness. What was
more, the set seemed to be behaving
perfectly normally. The brightness
control setting was quite reasonable
and the range of control was normal.
So what did this mean? There was
a temptation to assume that it was
simply finger trouble on the part of
the last user but while I hesitated to
accept that, there didn’t seem to be
much point in assuming a fault on
42 Silicon Chip
such rather flimsy evidence. I suggested that I leave it and for them to keep
an eye on it.
A couple of weeks went by and
they were on the phone again; same
problem. I checked it out in situ and
yes, it was faulty. So it was into the van
and back to the shop again. The only
snag was, as soon as I set it up on the
bench, it worked perfectly. In short,
my worst suspicions were confirmed,
it was intermittent.
I set it up in “intermittent corner”;
the corner of the bench which I reserve for such troublesome devices
and let it run all day and every day.
This proved only partially successful.
The fault did occur on several occasions but by the time I attacked it, it
had cured itself.
But I did notice a couple of important points. It had a greater tendency
to fail when first switched on in the
morning and most particularly, when
the weather was damp. If not touched,
it would come good after about an
hour. It was a most frustrating situation; one where one could waste hours
of time speculating on likely causes
and testing these ideas.
In fact I did try a number of ideas.
This model is rather notorious for dry
joints and I went over all the likely
ones and resoldered any which looked
at all doubtful. I replaced any electrolytics which looked at all daggy. I went
over the work I had done previously.
I found nothing positive and in fact,
it achieved nothing; the symptoms
remained exactly as before.
In the meantime, the motel was on
my hammer wanting to know when I
could finish the job and what it was
going to cost. To pacify them, I voiced
the only idea had in mind; a fault in the
horizontal output transformer (T602)
being effected by the damp weather.
I quoted them for a replacement –
should that prove to be the fault – and
of course, it wasn’t cheap. They said
they’d think about it. Which at least
gave me some breathing space.
So I simply let the set run from day
to day, hoping for a more definite indication of the fault. And eventually
it happened. We had a long bout a
very wet weather and I noticed that,
instead of a brief burst of the fault at
switch-on - which I knew would not
stand investigation - it was taking
longer and longer for the fault to clear.
So, finally, after the fault had remained for several hours, I moved
the set out of the corner and tackled
it. Thankfully, the fault held and I
was able to make a quick check of the
four supply rails, screen voltage on
the tube and the EHT. All were spot
on. Which exposed the fallacy on my
faulty transformer theory.
Bypassing some of the steps in my
previous exercise, I went straight to
pin 4 of IC301, fed by the brightness
control circuit. Sure enough, the voltage was way down from the stated
8.2V. And incidentally, the fault now
seemed to have worsened; it was almost impossible to get any image on
the tube.
I backtracked to the sub-brightness
control, then to the brightness control,
still measuring the very low voltage. It
was only when I went the other side of
the brightness control and measured
the voltage applied to it from the 127V
rail and the beam limiter circuit of
pin 7 of T602, that I found a normal
voltage.
So it was being applied to the
brightness pot but was not appearing
on the other side of it. Time to look at
the pot itself. Easier said than done,
because the control panel had to come
out. But sure enough, this was where I
Fig.2: Sharp DV-1600X. IC701 is at top left, FB701 below it off pin 4 and C711 to the left of it. Mains power is
applied to pins 1 and 3 at extreme right.
found it. I had to dismantle the pot to
pinpoint it and found that the voltage
applied to the lug was not present on
the moving arm. And there was no
continuity between these two points.
The reason? The centre lug of the
pot, which ultimately connects to the
moving arm, is riveted in place. And
under and around this rivet, visible
only under the jeweller’s loupe, there
was faint evidence of corrosion.
The result had been an intermittent
break in the lug, under the rivet and
effected by temperature and humidity and progressively getting worse.
I didn’t have an exact replacement
handy and had to put one on order.
In the meantime I patched in a 10kΩ
pot temporarily. Everything came
good immediately. And it stayed that
way. The replacement pot eventually
arrived, I fitted it, put everything back
together and let the set run for a few
more days. It never missed a beat and
was finally returned to the motel.
And that’s my story of a three-year
bounce. As I said earlier, it wasn’t a
real bounce but the point is it could
have been. Had that pot decided to
play up a few weeks after the 1993 episode, producing identical symptoms
and had it involved a less understanding customer, I would have been hard
put to it to convince them it wasn’t the
same fault. In fact, I doubt whether
they would ever have believed me.
So it was a near miss. Well, we must
be thankful for small mercies.
For a complete change of scene,
I have a letter from a Mr. B. L. of
Gwynneville, NSW, relating some of
his DIY experiences involving faults
in his own TV set. This how he tells it.
“Daaada!” cried my two year old son
- one second he was watching Sesame
Street and the next, no more Big Bird.
This was the result of a failure in our
Sharp DC-1600X TV set; a complete
blackout.
I have to own up to not being a
real serviceman, at least not by trade.
However, having graduated last year
with a B.E. (Comp.) I felt that, as an
engineer, I would have to at least have
a look to see if I could do it myself.
(Do I hear you groan, “No, not another
meddler!”?)
Well, after opening the case I discovered the chasm between the basic
principles of television transmission
and the implementation of those principles. I knew roughly how an image
was received, processed and displayed
on a CRT but I had no idea where to
start looking for faults amongst the
myriad of components before me.
I decided to invest in a service manual and despite this model’s manual
being out of print (it’s about 13 years
old), I quickly located one care of
High Country Service Data in Cooma
NSW. The DV-1600X has a number of
service bulletins, mostly relating to
the power supply.
I checked these items and found a
number of apparent faults. R635 (39Ω)
in the return path of the horizontal
deflection coil measured open circuit.
This would explain the symptoms - no
sound, no picture. R616 (1.5MΩ) in
the protection circuit was also open
circuit, which apparently causes
shutdown after a period of operation.
The power supply IC701’s heatsink
appeared to be poorly connected to
the copper pattern. I replaced the self
tapping screw with a small machine
screw, star washer and nut. The horizontal output transistor was similarly
modified. I was surprised to find that it
was mounted with self tapping screws,
soldered to the board and served as
a link between tracks. To quote the
manual, “Power goes from one track
through the metal case of the line
output transistor to the next track.”
Any bad connections here would
spell doom.
While I was dabbling with these
modifications, I noticed a number of
browned-out resistors in the power
supply. These were summarily replaced. At this point I wondered how
the set ever worked. I fired the set up
and found all voltages within specs.
and the set operated fine. I was very
pleased that I was able to solve this
problem without too much drama.
My bubble burst about two weeks
later. Again it was a complete failure of
sound and picture. This time I started
out by measuring line voltages and
found nothing; not a skerrick of life.
I focused on the power supply and
September 1996 43
Serviceman’s Log – continued
quickly came to the conclusion that
IC701 was not operating.
Initially, I wondered about the likelihood of a faulty IC but remembered
how all too often in my university lab
experiments, I mistook my own faulty
design, wiring, or measurements for a
faulty IC. Then I measured 20V or so at
pin 4 of IC701, relative to the negative
terminal of the filter capacitor, C711
(10µF, 100V).
Well, pin 4 is supposed to connect
to this same point, via a device named
FB701. Its schematic symbol looks
somewhat like a fuse. I had never come
across the “FB” monicker before, so
I pulled the device out of circuit to
examine it more closely.
Here was my suspect; I had measured an intermittent 20V across it in
circuit, yet a short circuit when free of
the printed board. I had a chat with a
friendly tech in town, who informed
me that it was a ferrite bead used for
RF suppression. (Of course, FB.) He
suggested replacing it with a link.
That was done and all is well some
four weeks later - touch wood! I really
don’t know if this was the original
problem. I wonder if this multiple
failure issue crops up often in the
serviceman’s world.
Well, thanks B.L. for a very interesting story. I particularly liked your
comment about the chasm between
basic principles and their implementation. Very true B.L. - very true.
Also note your comment about the
body of the horizontal output transistor forming an electrical path and
which, as you suggest, is vital. On
the other hand, the mounting of the
IC701 heatsink would seem to be less
important. As far as I am aware, this
is a purely mechanical arrangement
which does not involve any electrical
circuitry.
Regarding the FB701, I am a little
concerned at your colleague’s idea of
simply eliminating it. It is not clear
what form of RF suppression it was
supposed to perform or how important
this is. However, since the manufacturers chose to fit it - and manufacturers
seldom waste money on something
which is not necessary - there must
have been a reason. It might be advisable to fit a replacement, even at
this stage.
On a more general note, I would
comment that the two main filter capacitors, C711 and C715, are notorious
for failure; they dry out due to the heat
from IC701. High temperature types
are recommended as replacements.
And that power supply board is notorious for dry joints.
B.L. also raises the matter of connecting mains powered test equipment, such as a CRO, to live, or semilive chassis receivers, such as this one.
Unfortunately, this subject is a very
complex one, too complex to discuss
here. Broadly speaking, each situation
has to be assessed individually, using
the skill and experience of the technician involved.
However, a popular approach is to
use a one-to-one 240V isolating transformer, with the secondary floating.
The “earthy” arrangement may then
be configured in any way required.
So, thanks again B.L. for an interesting story – one which has provided an
opportunity to discuss a particular set
and some of its problems and which
may benefit other readers.
SC
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