-Jan
Can't you measure the dc RESISTANCE ?
Seems like 3.2 or 4 ohm might be a better match.
greg
Presumably it's the cone which has gone? If so the coil should still be ok
so measure the DC resistance. That will be near enough the impedance for a
guide. Early small transformer less (output) small transistor amps
sometimes used 35 ohm speakers, but they got round this when silicon
transistors arrived.
--
Small asylum seeker wanted as mud flap, must be flexible and willing to travel
Dave Plowman da...@davenoise.co.uk London SW
To e-mail, change noise into sound.
DC resistance IS NOT impedance.
To the OP: it may not be totally correct, but 8 ohms is a valid choice.
Unfortunately the cone is fine, but the coil reads several megaohms.
-Jan
The speaker is used as the collector load for am MPSA20 transistor, and supplied
by an 18V source. The only "audio" from the speaker is a square wave from the
clock chip.
I haven't looked up the max collector current for the MPSA20, but you need to
consult the datasheet for that, and calc the impedance for the speaker from
that. I'd suggest something like a 100-ohm speaker for this clock.
--
Dave M
MasonDG44 at comcast dot net (Just substitute the appropriate characters in the
address)
Life is like a roll of toilet paper; the closer it gets to the end, the faster
it goes.
Is it an ordinary electromagnetic speaker? Can't it be some of that piezo
parts? A 17Vpp is pretty high. Too high for a low impedance 2.5" speaker.
Try to connect some audio oscillator to it. If you hear nothing at 1kHz/10V
then the speaker is really gone.
petrus bitbyter
>To clarify the circuit, the postive side of the speaker receives 17 volts
>thru one diode and a resistor and the negative side is connected via
>transistor to ground and the transistor is driven by 4001 IC.
What value resitor?
What's the part number on the speaker?
I just happen to have the manual for a similar Heathkit GC-1005
"Electronic Clock" handy. No specs on the speaker (401-163). The
circuit is similar in that the speaker has one lead going to the
collector of an MPS-A20 and the other to 18.5VAC (not DC) through a
diode and 1200 uf to ground for a DC voltage of 25.7VDC. No resistor
in series.
So, let's do the math. My guess(tm) is that 1 watt will be
sufficiently loud to wake the dead. Yours has about a 15VDC swing.
Assuming a 50% duty cycle and a pure sine wave (yeah sure):
Power = E^2 / R
1 watt = 15^2 / R
R = 225 ohms.
So, it's probably a high impedance speaker of some sorts. I have the
digital clock and an LRC meter and could probably measure the
impedance. If you can't get the info any other way, bug me and I'll
rip it apart.
--
Jeff Liebermann je...@cruzio.com
150 Felker St #D http://www.LearnByDestroying.com
Santa Cruz CA 95060 http://802.11junk.com
Skype: JeffLiebermann AE6KS 831-336-2558
Sound quality certainly hasn't been a high priority on any radio alarm clock
I've ever had so maybe you should concentrate on what *IS* important on a
radio alarm clock - the speaker should be loud enough and the output devices
should not overheat at maximum volume. If an 8 Ohm works - is loud enough
and doesn't overheat anything then fine, otherwise 16 Ohm aren't that hard
to find - 35 Ohm do exist but are harder to find.
A good clue as to whether its a piezo sounder is that some other component
would provide a DC path for the collector of the driver transistor - maybe
an inductor or just a resistor if its a real cheapie.
Isn't it easier just to look at it? A piezo sounder looks nothing like a
moving coil speaker.
--
*Why is it called tourist season if we can't shoot at them?
I assume the OP has it but for others trying to help in the manual the
speaker looks like a normal moving coil speaker
Yes, it is a normal, paper cone speaker.
And to clarify further, this is not a clock/radio.
-Jan
Yes, thanks I am aware of this. I have several Heathkits at home.
It is not a question of needing just a clock, but having a working Heathkit
from 1978 ;-)
-Jan
Speaker is a 401-163
Resistor is 150 ohm
-Jan
>Speaker is a 401-163
>Resistor is 150 ohm
>-Jan
Ok the speakers are the same. 225 - 150 = 75 ohms which would be my
guess for the proper speaker impedance. I don't know what value to
suggest based on these calcs. I guess I have to meaure it. That's
going to be rough because the speaker is UNDER the PCB. Give me an
hour or so.
Done. The speaker measures 41.5 ohms DC resistance. I'm too lazy to
measure the inductance, but my guess(tm) is that added inductance will
raise the impedance to somewhere between 50 and 60 ohms. Standard
impedances (from the Digikey search page) are 40, 45, 48, and 60 ohms.
I'm at a loss as to where you would find such a speaker, but at least
you have a better clue as to what to search for. For a temporary
kludge, the impedance of many headsets are in this range. Sony
headsets tend to be about 45 ohms.
Incidentally, I plugged in my GC-1005. It made a loud noise and only
the NE-2 lamp lit. Looks like yet another repair project. Sigh.
Thanks a million, appreciate your effort very much!
-Jan
I actually built this thing circa 1980, and still use it. I recently
found pdf's of a manual and circuit diagram for it at
http://www.pestingers.net/Heathkit_manuals_sequential.htm
A quick look at these pdf's didn't tell me any specs for the speaker,
tho.
--- Joe
>On Thu, 18 Sep 2008 22:15:27 +0300, "Joe"
><natkro...@dnainternet.net> wrote:
>
>>To clarify the circuit, the postive side of the speaker receives 17 volts
>>thru one diode and a resistor and the negative side is connected via
>>transistor to ground and the transistor is driven by 4001 IC.
>
>What value resitor?
>What's the part number on the speaker?
>
>I just happen to have the manual for a similar Heathkit GC-1005
>"Electronic Clock" handy. No specs on the speaker (401-163). The
>circuit is similar in that the speaker has one lead going to the
>collector of an MPS-A20 and the other to 18.5VAC (not DC) through a
>diode and 1200 uf to ground for a DC voltage of 25.7VDC. No resistor
>in series.
>
>So, let's do the math. My guess(tm) is that 1 watt will be
>sufficiently loud to wake the dead. Yours has about a 15VDC swing.
>Assuming a 50% duty cycle and a pure sine wave (yeah sure):
> Power = E^2 / R
> 1 watt = 15^2 / R
> R = 225 ohms.
>So, it's probably a high impedance speaker of some sorts. I have the
>digital clock and an LRC meter and could probably measure the
>impedance. If you can't get the info any other way, bug me and I'll
>rip it apart.
The GC-1107 supplies the speaker via a rectified 13VAC source and 150
ohm 1/2W resistor. That's a DC supply of 18V.
I believe maximum power will be transferred to the speaker if it has a
resistance equivalent to that of the series resistor, ie 150 ohm. In
this case, when the transistor is turned on, the current will be
18/300 = 60mA. Assuming a square wave signal with a duty cycle of 50%,
the power dissipated in the speaker will then be 9V x 60mA x 0.5 =
270mW.
Therefore I'm guessing that the speaker has an impedance/resistance of
at least 150 ohms and a power rating of at least 0.5W. If the
speaker's impedance were any less, then the dissipation in the
resistor would increase.
If we accept that the speaker should dissipate less than 270mW in both
clock circuits, then in in the GC-1005 case we have ...
Power(max) = 0.27 = 25 x 25 x 0.5 / R(min)
So R(min) = 1157 ohms
- Franc Zabkar
--
Please remove one 'i' from my address when replying by email.
Rip the cone apart and see if you can find a reading. The wire usually breaks
away from the coil.
greg
And sounds nothing like a moving coil speaker. I say,
throw a resistor across it and measure the AC signal voltage to
get something we can compute with.
greg
Try resoldering the flexible wires at the terminal strip. I have
seen a few new speakers that size with bad joints. It is a Litz type of
wire, and hard to tin if it isn't really clean. Also, I have seen pocket
joints where the terminal was hot enough for the solder to wet, but the
wire is barely touching the other side.
--
http://improve-usenet.org/index.html
aioe.org, Goggle Groups, and Web TV users must request to be white
listed, or I will not see your messages.
If you have broadband, your ISP may have a NNTP news server included in
your account: http://www.usenettools.net/ISP.htm
There are two kinds of people on this earth:
The crazy, and the insane.
The first sign of insanity is denying that you're crazy.
I like your calcs better than mine. That suggests that Heathkit would
have used something like a high impedance earphone "speaker" in the
design. That's possible and probably would work quite well.
However, I tore apart a similar Heathkit clock, with the identical p/n
speaker, and measured 41.5 ohms DC resistance. Adding the inductance,
that I didn't bother measuring, will produce about 50 to 60 ohms
impedance. Obviously, this is not the optimum power transfer design,
but that's what Heathkit apparently used. The important thing is that
a common 4, 8, or 16 ohm speaker will NOT work.
In this situation I'd probably nick a replacement speaker from an old pocket
radio along with the O/P transformer, in which case the resistor could
probably be omitted without overstressing the driver transistor or supply..
Actually, radios of that vintage are probably worth a bit, but many people
will have such transformers in the junk box, Maplin among others still stock
the Eagle Electronics LT700 transformer that would do the job.
I remember ordering some 100 ohm paper cone speakers from Mouser many years ago
for my Johnson walki-talkies. I know they still have some 100 ohm speakers.
greg
The highest I've seen were 150 Ohm as used in the Philips EE kits, they were
driven class A by a single transistor - an AC128 in the EE20, the EE1003
used a BC148 - those horrible "lockfit" transistors which were quite large
for only 220mW, one of the two BC148s in the kit had a pressed steel 'heat
fin' that didn't fit at all snugly to the transistor and stayed pretty much
cold as the transistor got hotter and hotter.
Neither of the clock circuits makes any sense to me.
Your clock has a 25VDC supply which, at a 50% duty cycle, would cause
a 41.5 ohm speaker to dissipate 7.5W.
In the OP's clock circuit, a 41.5 ohm speaker would cause the 150 ohm
1/2W resistor to dissipate ...
(18/191.5 x 0.5) x (18 x 150/191.5) = 0.66W
I can only assume that the speaker's impedance at the operating
frequency of the alarm is *much* higher than one would expect. For
example, at 1kHz an impedance of 100 ohms would require an inductance
of 16mH. I measured the inductance of an 8 ohm 1W 3" speaker on my
DMM's 2mH scale as 0.08mH and about 0.5mH on the 2mH and 20mH scales.
I could hear a high pitched tone on the 2mH range (1kHz ?) and a low
pitch on the 20mH range (100Hz ?).
This site appears to be dedicated to saving and restoring old Heathkit
clocks:
http://www.decodesystems.com/heathkit-clocks.html
Here is some info on the MK5017 clock chip that was used in the
GC-1005:
http://www.decodesystems.com/mk5017.html
The MK5017's Tone output is shown driving a 2N3904 transistor
connected to a 17VDC supply through a transformer-coupled 8 ohm
speaker:
http://www.decodesystems.com/mk5017-2.gif
The transformer is spec'ed as "2K/8R".
I'm really clutching at straws now, but is it possible that the
Heathkit speaker has a built-in 2K/8R transformer ??? Does it have the
usual permanent magnet? Would it make sense to have a stationery 2K
winding and an 8R moving coil on a soft iron former ???
Finding a way to reduce the duty cycle might be a means to get away with a
more commonly available lower impedance speaker.
>Finding a way to reduce the duty cycle might be a means to get away with a
>more commonly available lower impedance speaker.
AFAICS, at 25VDC a 40 ohm speaker would draw 600mA when the transistor
switches on, regardless of duty cycle, assuming the transistor has a
high enough gain at whatever base drive the IC provides. An MPS-A20
transistor is only rated for 100mA.
As the speech coil is an inductor it will exhibit a linear rising current
waveform from the initial application of voltage, obviously that will be
shorter for a lower impedance/inductance speech coil so the pulse width must
be made shorter to ensure it terminates before the inductor saturates.
>
>"Franc Zabkar" <fza...@iinternode.on.net> wrote in message
>news:e3add4tqmv9e8h771...@4ax.com...
>> On Sun, 21 Sep 2008 15:54:26 +0100, "ian field"
>> <gangprob...@ntlworld.com> put finger to keyboard and composed:
>>
>>>Finding a way to reduce the duty cycle might be a means to get away with a
>>>more commonly available lower impedance speaker.
>>
>> AFAICS, at 25VDC a 40 ohm speaker would draw 600mA when the transistor
>> switches on, regardless of duty cycle, assuming the transistor has a
>> high enough gain at whatever base drive the IC provides. An MPS-A20
>> transistor is only rated for 100mA.
>
>As the speech coil is an inductor it will exhibit a linear rising current
>waveform from the initial application of voltage, obviously that will be
>shorter for a lower impedance/inductance speech coil so the pulse width must
>be made shorter to ensure it terminates before the inductor saturates.
If my inductance measurements make any sense, then the time constant
of the speaker would be L/R = 0.5mH/40R = 12us, or 80uH/40R = 2us.
That's a very short pulse.
>
>"Franc Zabkar" <fza...@iinternode.on.net> wrote in message
>news:e3add4tqmv9e8h771...@4ax.com...
>> On Sun, 21 Sep 2008 15:54:26 +0100, "ian field"
>> <gangprob...@ntlworld.com> put finger to keyboard and composed:
>>
>>>Finding a way to reduce the duty cycle might be a means to get away with a
>>>more commonly available lower impedance speaker.
>>
>> AFAICS, at 25VDC a 40 ohm speaker would draw 600mA when the transistor
>> switches on, regardless of duty cycle, assuming the transistor has a
>> high enough gain at whatever base drive the IC provides. An MPS-A20
>> transistor is only rated for 100mA.
>
>As the speech coil is an inductor it will exhibit a linear rising current
>waveform from the initial application of voltage, obviously that will be
>shorter for a lower impedance/inductance speech coil so the pulse width must
>be made shorter to ensure it terminates before the inductor saturates.
I used Bob Parker's ESR meter to measure various 8 ohm speakers. AIUI,
the meter delivers 8us pulses to the device being tested.
FWIW, here are my results:
10W/8R - 35 ohms
2W/8R - 22 ohms
0.5W/8R - 15 ohms
20W/8R/20kHz tweeter - 18 ohms
> I actually built this thing circa 1980, and still use it. I recently
> found pdf's of a manual and circuit diagram for it at
>
> http://www.pestingers.net/Heathkit_manuals_sequential.htm
>
> A quick look at these pdf's didn't tell me any specs for the speaker,
> tho.
Joe-
Back in the 70s I built a kit clock using parts and instructions from
Radio Shack. The specified 8 Ohm speaker was driven through a 100 Ohm
series resistor. I found a small 100 Ohm speaker, and figured I might
get more power transfer if it matched the resistor. The result was
definitely louder than the original 8 Ohm speaker.
I didn't try it without the 100 Ohm series resistor, which would be
similar to your configuration. Suppose your square wave was 10 V RMS.
As an approximation, that would produce one watt into a 100 Ohm speaker,
which is probably louder than your neighbors would like!
I still have the old clock and have enhanced it over the years. It now
has a 9 volt battery backup with its 60 Hz signal coming from an
oscillator that divides down a color burst crystal tuned to 3.579540
MHz. The frequency may drift a bit, but it doesn't stop when the power
fails.
Fred