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Build this low cost
Dual tracking
±18.5V po-wer supply
Take a squiz at this: a dual tracking
power supply of modest cost giving up to
+ 18.5 volts DC. It has voltage metering,
a LED dropout indicator and short
circuit protection.
By JOHN CLARKE & LEO SIMPSON
Sooner or later, every electronics
enthusiast needs a DC power supply. They used to get by with a
variable supply giving up to 15 volts
or so at around 500 milliamps but
today's circuits using op amps,
memory and logic devices need a lot
more than that. For op amps you
need balanced positive and
negative supplies of ± 15V while
some memory chips such as
EPROMs need ± 5V.
The problem with designing a
power supply for the enthusiast or
technican is that it is easy to get
carried away with fancy features
that are seldom used. The end
4
result is an expensive supply that
no one can afford. So we at SILICON
CHIP have put our heads together on
this project to produce a supply
which has good performance and
features while keeping the cost
within bounds.
What are the big cost items in a
power supply? That was the question we asked ourselves as we set
out to design this supply. The big
cost items are the transformer,
meter, case, filter capacitors and
printed circuit board. We could not
eliminate any of these components
in a self-contained power supply so
we selected them very carefully to
Silicon Chip’s Electronics TestBench
optimise the performance versus
price ratio.
For example, we selected a
transformer with a centre-tapped
30V winding rated at one amp. This
was much cheaper than a centretapped 44V 1.5-amp transformer
that we would have selected as first
choice if price was not so important. But we had to admit that the
times when enthusiasts want high
currents are fairly rare.
By picking the smaller transformer, we greatly cut down the
power dissipation in the circuit and
thereby reduced the heatsinking requirements, the size of the case and
the cost of the filter capacitors and
regulatprs, all for very little reduction in overall utility of the supply.
We also saved money by using a
smaller meter, smaller rectifier
diodes and so on.
The end result is a compact
power supply which will serve the
needs of the vast majority of electronic enthusiasts and technicians.
It will become another in a growing
list of SILICON CHIP test equipment.
D7
1N4002
POWER
D2
LOAD
S2a
0--0+
.
[
2.7k
2200
25VW
+
100
25VW
_
+
D10
1N4002
- 14V
47k
ADJ
1200
LOAD
OUT
S2b
IN
,ru~,
,ru~M
2.2M
LED2
DROPOUT
f
IN
1
OUT
D11
DUAL TRACKING POWER SUPPLY
D41·188
2.7k
08
337
317
o--o-
D12
...
..,.
4x1N4148
Fig.2: the circuit uses a 30V 1A transformer to drive a bridge rectifier and two adjustable 3-terminal regulators. ICl
inverts the control voltage provided by VR1 to drive the LM337. IC2 monitors the output ripple to provide drop-out
indication.
The SILICON CHIP power supply
has tracking positive and negative
DC outputs adjustable from ± 1.2V
to ± 18.5V. Both supply rails are
protected against short circuits and
2.0-r,;,- - . . . . . . . . - - - - , - - - - , . - - - - ,
~
::E
5.
>-
~ 1.01-f'---+---
=
:::,
c.,
-+--+---+-----t
c:,
;
o,._._ _...,__ __.__ __.__ _
0 1.2
Fip, 1
10
~
15
SUPPLY VOLTAGE (VOLTS)
Fig.1: this graph plots the maximum
output current for voltage settings
between ± 1.2V and ± 18V.
20
voltages generated by external
loads.
Maximum load current is 1. 7A
between ± 3V and ± 10V. When
the supply stops regulating, a LED
indicator lights.
You can use the power supply in
the conventional way to provide
balanced positive and negative
rails, or you can take the output
from between the positive and
negative output teminals and
thereby get more than 36 volts DC
output. The circuit is fully floating
(ie, not tied to mains earth) and so
the output can be referenced to
earth via the positive, negative or
0V rail.
What will it do?
Fig.1 shows the maximum output
current available for voltage settings between ± 1. 2 volts and ± 18
volts DC with the positive and
negative rails loaded. Up to 1. 7
amps is available for settings between ± 3 and ± 10V. Above 10V
the available current reduces, to
200 milliamps at ± 18 volts.
Remember that this performance
applies with both the positive and
negative rails loaded, so that by
taking the output between the
positive and negative rails, you get
get up to 1. 7 amps at 20 volts and
up to 200 milliamps at 36 volts.
Line regulation is within ± 5mV
of a given output voltage setting for
mains input variation between
220V AC and 260VAC. Load regulation at 1.7 amps is within 100mV at
a setting of 9 volts; ie, close to 1 % .
Ripple output (ie, 100Hz hum and
noise superimposed on the DC rails)
is less than lmV peak-to-peak for
load currents up to one amp. These
are excellent figures. Dinkum.
Note that the actual maximum
Silicon Chip’s Electronics TestBench 5
The supply is very easy to wire but you should take extra care with the mains
wiring. Use a cord-grip grommet to secure the mains cord.
available current from the power
supply will depend on the
temperature of the heatsink and the
amount of power being dissipated
in the regulator(s) for a given output
setting.
Circuit details
Fig.2 shows the complete circuit.
As already noted, it is based on a
30V centre-tapped 1A power
transformer, Arlec 6672A or
equivalent. Diodes Dl to D4 are
connected as a bridge rectifier
which, combined with the two
22001,lF filter capacitors, give plus
and minus DC rails of about 21
volts.
These unregulated DC rails are
fed to LM317 and LM337
3-terminal regulators to provide the
adjustable plus and minus supply
outputs respectively. We'll briefly
explain how these regulators work
before going on with the rest of the
circuit description.
· The regulators are designed to
give 1.25V between their output
and adjust terminals. With this in
mind, and the fact that the current
flowing out of their ADJ (stands for
ADJust) terminal is negligible, it is
easy to design a variable regulated
6
Fig.3: operating principle of the
LM317 3-terminal regulator. Rt
and R2 set the output voltage (see
text).
·
supply. The circuit of Fig.3
demonstrates their operating
principle.
Two resistors are used to set the
output voltage in the circuit of
Fig.3. Rl is fixed while R2 is
variable. Since the voltage be~ween
the OUT and ADJ terminals is fixed
at 1.25V, the current through Rl
and R2 is also fixed. This gives a
simple formula for the output
voltage as follows:
Vout = 1.25(1 + R2/R1)
In our circuit Rl is 1200 while R2
is made up of of a 2.7k0 resistor in
parallel with VRl, a 5k0 potentiometer. The maximum effective
value of R2 is thus 1.75k0 and the
theoretical output voltage range is
therefore between 1.25 volts and
19.5 volts. However, the
unregulated DC voltage fed into the
Silicon Chip’s Electronics TestBench
regulators is normally not quite
high enough to enable 19.5 volts
output to be delivered.
That explains the circuit as far
as the positive regulator (LM317) is
concerned but what about the
negative regulator'? It has an operational amplifier connected to its
ADJ terminal instead of a variable
resistor. What giveth'?
The idea of the op amp is to provide a mirror of the voltage at the
ADJ terminal of the positive
regulator. So if the ADJ voltage at
the positive regulator is + 10 volts,
the op amp will produce an output
of - 10 volts by virtue of the fact
that it is connected as a unity gain
inverting amplifier. So ICl ensures
that the negative regulator always
tracks with the positive regulator.
The 1200 resistor between the
ADJ terminal and output of the
LM337 is there for two reasons:
first, to give the required minimum
load for the regulator, and second
to set a load current flow into ICl.
This load current of 10.4 milliamps
impresses a voltage drop of 10.4V
across the lkO resistor at the output of ICl. This allows the op amp
to drive the ADJ terminal of the
LM3 3 7 regulator to - 17. 3 volts in
spite of the fact that the negative
supply rail to ICl is only - 14 volts.
The supply rails for ICl are provided by zener diodes D5 for the
positive line and D6 in series with
LED 1 for the negative line.
Diodes D7, DB, D9 and DlO protect the regulators from reverse
voltages which may be generated
by capacitive or inductive loads
connected across the outputs.
Drop-out indicator
When the regulators are working
as designed, the ripple voltage
superimposed on the DC rails will
be very low. However, if the current drain is higher than the
regulator can supply while still
maintaining about 2 volts between
its input and output terminals, the
ripple voltage will suddenly become
quite high. The output voltage will
fall rapidly if even more current is
called for and the ripple will go
even higher.
When this condition is beginning
to occur you may have no idea that
it is happening. You need a visible
PARTS LIST
1 plastic instrument case, 205
x 159 x 68mm
1 PCB, code SC041-188, 112
x 92mm
1 . Scotchcal front panel, 1 90 x
60mm
1 meter scale display, 52 x
• 43mm
1 6672 30V, 1 A transformer
1 single-pole pushbutton mains
switch
1 DPDT mini toggle . switch
4 banana panel terminals (blue,
white, red and green)
1 5k0 potentiometer
1 knob
1 mains cord and plug
1 cord clamp grommet
2 solder lugs
1 aluminium panel, 196 x
64mm x 1.5mm
2 T0-220 insulating kits (mica
washer and bush)
1 MU45 panel meter, 0-1mA
movement
Semiconductors
1 LM31 7T positive adjustable
3-terminal regulator
1 LM337T negative adjustable
3-terminal regulator
1 TL071, LF351 FETinputop
amp
1 741 op amp
9 1N4002 or equivalent 1A
diodes
6 1N914, 1N4148 small signal
diodes
1 12V 1W zener
1 15V 1W zener
2 5mm red LEDs
Capacitors
2 2200µF 25VW PC
electrolytic
2 1 OOµF 25VW PC electrolytic
4 1µF 25VW PC electrolytic
1 0.1 µF metallised polyester
Resistors (5%, 0.25W)
1 x 2.2MO, 2 x 47k0, 1 x.39k0,
1
X
X 22k0, 3 X 2 .7k0, 3 X 1k0, 1
2200, 1 X 1800, 2 X 1200
Miscellaneous
Solder, hookup wire, insulating
sleeving, screws, nuts, selftapping screws etc.
Putting it together
Close-up view showing how the 3-terminal regulators are mounted (see also
Fig.5). Use your multimeter to check that the metal tabs are isolated from
chassis.
indicator. Hence, we have designed
a drop-out indicator using IC2.
ICZ is connected as an inverting
amplifier with a gain of about 800.
It monitors both the positive and
negative regulators via 2.7k0
resistors and a O.lµF capacitor.
Diodes Dl 1 and Dl 2 limit any noise
or ripple signal level to a maximum
of ± 0.7V.
The amplified ripple at the output
of IC2 is fed to a full wave rectifier
consisting of D13 to D16 via a lkO
limiting resistor, to feed a light
emitting diode, LED 2. The LED
begins to glow when the ripple at
one of the regulator outputs
becomes greater than about 4mV
peak-to-peak. At about 19mV p-p
ripple the LED is fully alight.
A lmA meter monitors the output
voltage via the lkO and 39kn
resistors. This gives it a full-scale
reading of 20 volts.
The supply is housed in a standard plastic instrument case
measuring 205 x 159 x 68mm
(Altronics Cat. No. H-0480 or
equivalent). All the circuit with the
exception of LEDs, switches and the
pot, is accommodated on a printed
circuit board measuring 112 x
92mm (coded SC041-188). Both
3-terminal regulators are bolted to
the rear metal panel of the case for
hea tsinking.
You can start assembly by checking the copper pattern of the board
for any breaks or shorts in the
tracks. Compare it with the pattern
published in this article.
With that done, you can install
all the small parts on the printed
board. These include the resistors,
diodes, links, small capacitors and
the two op amps. Make sure that
the ICs and diodes are correctly
oriented before soldering them into
place. Note that the two ICs face in
the same direction. Use the wiring
diagram of Fig. 4 to check each
stage of assembly.
Next, install the two 2500µF
capacitors and the two 3-terminal
regulators. The regulators should
be mounted so that their bodies are
about 10mm clear of the board, to
allow them to be easily bolted to the
back panel of the case.
We recommend the use of PC
pins for all external wiring from the
Silicon Chip’s Electronics TestBench 7
POWER TRANSFORMER
9
CLAMP
GROMMET
L......<=,.-=,._,,.._~~Lo_v~-------:----;<at> Sl
\
,o~LED1
MAINS CORD
Fig.4: follow this wiring diagram carefully and your supply should work first time. Use medium-duty 24 x 0.2mm
cable for connections between the PCB and transformer, and to the output terminals and Load switch (see text).
board. They simplify connecting it
up and give easy test points when
checking voltages.
The completed printed board is
supported on four of the integral
plastic standoffs on the base of the
case and secured with self-tapping
screws. The transformer must be
mounted directly onto the base of
the case. To do this, two of the standoffs will have to be removed or
drilled out and holes drilled for
3mm roundhead or countersunk
screws. Use lockwashers under the
two nuts.
Note that the mains earth wire is
terminated to a solder lug on the
rear metal panel of the case and
thence to a solder lug secured by
one of the transformer mounting
screws. The earth wire also goes to
8
the green GND terminal on the front
panel.
When the printed board has been
installed, slide the metal rear panel
into the case and mark the mounINSULATING
BUSH
\
~
Deburr de burrs
HEATSINK
(REAR OF CASE)
NUT
/
T0220
DEVICE
Fig.5: mounting details for the
two 3-terminal regulators.
Silicon Chip’s Electronics TestBench
ting hole positions for the two
regulators. The mounting holes
should be drilled for 2.5mm screws.
Fig.5 shows the mounting details
for the two regulators. Note that a
mica washer and insulating bush
must be used to isolate each device
from the metal panel.
Before securing the regulators,
make sure that the mounting holes
are free of burrs. Lightly smear
heatsink compound on the regulator
heatsink surfaces and the mating
areas on the metal panel. Then
screw the two regulators to the
panel as shown in Fig.5.
You should then switch your
multimeter to a low Ohms range
and use it to check that the metal
tabs of regulators are both isolated
from the metal panel.
You can then work on the front
panel. Kitset buyers can expect
that they will be supplied with a
screen-printed precut panel but if
you're working from scratch you
will probably have to make or purchase a Scotchcal panel. The artwork can be used as a drilling
template for the front panel. The
meter is supplied with its own
template for the four mounting
screws and 46mm diameter cutout.
This latter hole can be made by
drilling a series of small holes just
inside the circumference of the
marked circle and then filing the
resulting cutout to a smooth circle.
Having drilled all the holes, you
can affix the artwork to the front
panel. The material covering the
holes is then removed using a
Stanley utility knife.
Now the front panel hardware
can be mounted. In complete kits, a
new scale should be supplied for
the meter. This is easily fitted. Just
unclip the meter bezel, undo two
screws, remove the old panel and
replace it with the new and then
reassemble. Alternatively, you can
remove the existing scale, erase the
numbering and re-do it with
Letraset.
Complete the wiring by following
What's a dual
supply?
"Wotsa dual tracking power
supply anyhow and why would I
want one?" we hear you ask, in
your ardent quest for knowledge.
The word dual refers to the fact
that this power supply has two
supply rails, one positive and the
other negative. The word tracking refers to the fact that when
you adjust the positive supply,
the negative supply automatically
follows so that it has the same absolute value. So if you set the
positive output to plus 1 0 volts
DC, the negative rail will be very
close to minus 10 volts.
That's what you'd expect, isn't
it?
Fig.4. Connecting wires to the
potentiometer, the two LEDs and
the meter can be light-duty hook-up
wire but the remaining wiring
should use heavier wire, such as 24
x 0.2mm insulated cable.
The 3-core mains cable should
have its outer insulation layer
removed for a length of about 10cm
so that the active lead can reach
the mains switch on the front panel.
The mains cord can then be
secured to the rear panel using a
cord-grip grommet.
The neutral lead is terminated
directly at the transformer, as is
the other lead from the mains
switch. Both the mains termination
on the transformer and the mains
switch itself should be sleeved with
plastic tubing to avoid the possibility of accidental shock.
When all the wiring is complete
you should check your work
carefully against Fig.4 and Fig.2
(the circuit diagram). With that
done, you can apply power and
check the voltages. The
unregulated voltages to the input of
the two regulators should be about
± 21 volts, while supplies to the two
op amps should be + 15V at pin 7
and - 14V at pin 4.
Now check that the positive and
negative supply rails can be varied
over the range from below 1.5V to
above 18V and that the two supplies track each other within
± lOOmV.
The dropout indicator can be
checked for correct operation by
connecting a 220 resistor across
either the positive or negative supply. Now, when the output voltage is
wound up above 15 volts, the LED
should light.
All that remains is to secure the
lid of the case and your power supit
ply is ready for work.
""'"f'<>
_, _
1.
CLASS-2.5
MU -45
•
Fig.7: this full-size artwork should
be used to replace the existing
meter scale. The old artwork is
removed by unclipping the meter
bezel and undoing two small
screws.
Fig.6 (left): this full-size
reproduction of the PC pattern can
be copied and used to etch your
own PC board.
Silicon Chip’s Electronics TestBench 9
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