Here's a link to the instruction manual.
http://www.wass.net/manuals/Melcor%20SC-635.pdf
Note that it says to have the battery in place if you want to run it off the external ac
adaptor.
Sent from my iPhone
On Jul 20, 2018, at 14:06, Brent Hilpert via cctalk <cctalk at
classiccmp.org<mailto:cctalk at classiccmp.org>> wrote:
On 2018-Jul-20, at 10:18 AM, Jules Richardson via cctalk wrote:
Anyone got pinout/spec information for a MOS MCS2529? In particular, I'm curious about
operating voltage. I acquired a Melcor SC-635 calculator yesterday and there seems to be
some uncertainty about the output voltage of its (rechargeable) battery pack; some places
say 2.4V, i.e. the pack is a pair of 1.2V cells, but others say 9V.
2.4V seems a little low to me for typical logic, but on the other hand I've seen a
period ad which says that the external PSU was 9V - and so the rechargeable battery must
have been somewhat less than that.
Rechargeable and 1.2V/cell would correlate to 2 NiCd cells, a not-unusual configuration
for calculators of that period.
Such units would typically use a simple built-in switching power supply to boost the
battery voltage up to levels adequate for the logic and/or display.
In the pic of the PCB board here:
http://www.teclas.org/maquina.php?mm=C125
the chunky box component 'below' the IC is probably a switching PS module.
It was also common to use simple resistive current limiting in the charge circuit for
NiCds.
In consequence, the voltage supplied by the external AC charger may be quite a bit higher
than the battery voltage.
It's possible that's where the 9V external spec comes from, if not just a
mistake.
Sometimes the current limiting R is in the external charger, sometimes it's in the
calculator.
Further, such designs also tended to rely on the battery to provide AC filtering &
voltage regulation (limiting) of the charger V down to the battery V.
If the battery/cells have been removed or are in really bad condition, operating the calc
from the original external charger
can result in too high a voltage being applied to the electronics.
My usual procedure for such calcs is to cut out the NiCd cells (there is ~0 probability
they are any good), noting the polarity.
For testing, clip on a bench supply to substitute for the batteries, set of course to the
appropriate V for the battery ( # of cells * V/cell ).
If the batteries have already been removed and there are no polarity markings, let me know
if you'd like some assistance trying to figure it out.
If you want to power it through the charger jack, then you need to assess whether there is
any internal charging circuitry (rectification, aforementioned current-limiting R, etc.)
sitting between the jack and the cells.