Advertising Index
Altronics.................................27-30
Blackmagic Design....................... 7
Dave Thompson........................ 103
DigiKey Electronics....................... 3
Emona Instruments.................. IBC
Jaycar............................. IFC, 51-54
Keith Rippon Kit Assembly....... 103
LD Electronics........................... 103
LEDsales................................... 103
Microchip Technology.............OBC
Mouser Electronics....................... 4
OurPCB Australia.......................... 5
PCBWay......................................... 9
PMD Way................................... 103
Radio Valves - Dieter Dauner.... 103
Silicon Chip Back Issues........... 25
Silicon Chip Binders.................. 79
Silicon Chip Pico BackPack...... 78
Silicon Chip Shop........ 71, 94, 100
Silicon Chip Subscriptions........ 31
The Loudspeaker Kit.com............ 8
Used Gear - Jim Rowe.............. 103
Wagner Electronics..................... 93
Notes and Errata
Maxwell’s Equations, November
2024: on p91, Gauss’ full name is
incorrectly given as Henrich Gauss
instead of Carl Friedrich Gauss.
Watering System Controller,
August 2023: a bug in the WiFi
stack used in the original WebMite
firmware can cause spurious
reboots of the Controller. We
recommend you update to the
latest firmware version (released
January 2025) which fixes this
problem.
Next Issue: the March 2024 issue
is due on sale in newsagents by
Thursday, February 27th. Expect
postal delivery of subscription
copies in Australia between February
26th and March 14th.
104
Silicon Chip
controllers for the larger motor,
although that would be more expensive than modifying a capacitor start
motor (which might not work anyway).
Any thoughts? (J. C., Auckland, New
Zealand)
● Andrew Levido responds: You
have a couple of good options. It seems
like you have pretty good understanding of motors and understand the risks
in the following advice.
You probably can use an unmodified capacitor start motor with a VSD
as long as you ramp up past the centrifugal switch opening speed and
remain above the closing speed thereafter. I believe there is a fair bit of
hysteresis built into the centrifugal
switch to prevent it from chattering.
You would have to measure the two
speeds (closed and open) for each
motor; I suspect they are pretty variable between models.
Alternatively, you could switch
the start winding and capacitor out
externally with a suitable switch or
contactor once the motor has started.
A manual switch or a simple timer
would probably be enough to control
it. Then you could reduce the speed
as far as you like without any risk of
burning out the start winding (but you
would still need to monitor it to make
sure it doesn’t stall).
The downside I see here is reduced
torque at low speeds. I have no idea
how much of a problem this would
be for a lathe. Still, I suspect once the
work is spinning, the torque required
to keep it going is much lower than that
required to get it up to speed. However,
the speed regulation may be poor at
low speed – I honestly don’t know. I
think you would have to try it and see.
I don’t suggest you switch the motor
between mains power and the speed
controller, as the instantaneous current
demand at switch-over could trip the
over-current protection. It’d be better
to let the motor be spun up gradually
by the speed controller with the start
winding in-circuit, then switch it out.
Also see the letter in the Mailbag
section last month from Ian Thompson (p6, January 2025), who has an
alternative method for controlling the
speed of induction motors with centrifugal switches.
Eliminating hum in 12V
20W Stereo Amplifier
I got around to building the Compact
Australia's electronics magazine
12V 20W Stereo Amplifier kit (May
2010; siliconchip.au/Article/152) from
the Altronics K5136 kit. Overall, I’m
surprised how good the sound is, and
it can drive the two Klipsch speakers
I have quite well.
The only thing I’m not sure about is
that it seems to have a bit of a ‘hum’ at
the loudspeakers when switched on,
even with the volume low, if there is
no input signal. Where does the hum
come from and can I eliminate it? I
used heavy duty shielding on input
cables.
I attached the wire across the three
potentiometers, they are grounded
together and it’s in a metal box. The
potentiometers and wire are grounded
to the negative 12V DC input as per the
instructions. I notice that when I put
my finger on the volume potentiometer, the hum almost goes away. Could
it be some sorting of grounding problem? (E. M., Hawthorn, Vic)
● If the design had an inherent
hum problem, it would have shown
up in the performance measurements/graphs published in the article as a poor signal-to-noise ratio or
high distortion. So we’re pretty sure
it isn’t a circuit problem. Also, it’s
DC-powered, so there’s no reason for
mains hum to be present unless the
DC supply is poorly regulated.
Based on your description, it sounds
like it may be being picked up by the
potentiometer bodies or the case.
First, did you scrape off the passivation from the pot bodies before soldering the wire to them? Please be careful doing this as the dust can be toxic
(eg, do that outside and make sure
it doesn’t blow towards you). If you
didn’t, it’s possible there is no electrical connection to the grounding wire.
If the bodies are definitely grounded,
it’s likely the hum is coming into circuit ground from the power supply.
Do you have a different power supply
you can try? Do you have an Earthed
metal object (like a desktop computer
case) that you can connect to circuit
ground via a clip lead, to see whether
Earthing it helps?
We also suggest checking if the hum
is present without any input signal
connected, to verify that it isn’t being
injected via the signal ground connection from the signal source.
Note: E. M. replied to say that Earthing the negative output terminal of the
switch-mode power supply eliminated
the hum.
SC
siliconchip.com.au
