NE of the most useful pieces of equipment an electronics experi-
menter can possess is a good work-bench power supply. Indeed even for thosewho already have one, a second will oftenprove useful for projects requiring morethan one source of supply or for theoccasional design that requires long-termtesting.
Ideally a workbench supply should have
an output voltage that can be adjusted rightdown to zero as it is occasionally useful tobe able to power a circuit gradually fromthis when fault-finding. There should alsobe a fast and effective current limitingfacility, again adjustable from zero as this
also provides valuable protection whentesting circuits.
If the supply can be set to deliver a con-stant output current instead of a voltage itcan also be used as a charger for the manytypes of re-chargeable battery that areavailable nowadays, both alkaline andsmall sealed lead-acid types. The latter arenormally charged to a constant voltage butuntil this is reached a current limit is oftenrequired to prevent an excessive chargerate.
Preferably the supply should have twometers so that the voltage and current sup-plied to the load can be seen at a glance,and most users would probably prefer ana-
logue meters to the digital type for this.Power supplies meeting these specifica-tions can be expensive, but this project canbe constructed at reasonable cost, especial-ly if some of the parts such as the case andmeters are already to hand, or are pur-chased from inexpensive sources such assurplus stores or amateur radio rallies.
The power supply described here pro-vides an output of up to 20V with currentin two ranges of 100mA or 1A, whichshould be more than sufficient for most of the projects which appear in EPE .
The design of a good power supply is
more complex than might be supposed. It
must provide a constant voltage or current
whilst being able to react rapidly to anychanges in the load it is supplying. Thismeans that the circuit must have a fastresponse and remain stable for a widerange of output loads, voltages andcurrents, so the circuit is inevitably a com-promise between speed and stability.
The design used for this project shouldbe fast enough for most purposes and hasgood output stability.
The method of voltage control used maybe a little difficult to follow so a simplifiedexplanation is in order before a descriptionof the full circuit. Some of the more com-mon methods of controlling voltage areshown in Fig.1.
In Fig.1a the controlling device is a sim-ple transistor. A reference voltage isapplied to the base and this is reproducedat the emitter to supply the load, minusabout half a volt for the base-emitter dropof the transistor. This can suffice for sim-ple designs but suffers from small changes
with variations in load, partly because itdraws a small current from the referencesource, which is usually a variable resistorconnected to a fixed voltage.
Use of a power MOSFET in place of thetransistor would cure this, but these have amuch larger and less predictable gate-source voltage drop.
An op.amp can be used to partly over-come these problems, as shown in Fig.1b,but there are still some disadvantages. Asthe required output voltage rises, the inputvoltage to the transistor must also rise sothere is effectively less control voltageavailable as the output approaches the sup-ply voltage. Also, this simple circuit can-not supply an output voltage greater than
the reference.
Everyday Practical Electronics, January 2002 33
g
d
s
b
c
e
b
c
e
VREF
VREF
VREF
V+
V+
V+
0V
TR1
0V
TR1
TR1
0V
R1
R2
A)
B)
C)
+
IC1
LOAD
LOAD
LOAD
+
IC1
Fig.1.Various methods of voltage control: (a) transistor, (b) op.amp and transistor
A somewhat better solution is shown inFig.1c. A power MOSFET is controlled byan op.amp and a pair of resistors causesthe op.amp to multiply the reference volt-age. But the problem of low drive voltageat high output voltages remains and it isdifficult to sense the output current fromany of these circuits.
An arrangement which overcomes these
difficulties is shown in Fig.2. It uses two
power supplies, a “main” one of about 25Vcapable of supplying up to 1A of currentfor the output, and an auxiliary “split” sup-ply of +12V for the controlling circuit. The“0V” rail of this is the “ground” for thecontrol section. It operates as follows:
A reference voltage is produced usingregulator IC1 and applied to resistor R1.During normal operation op.amp IC2 usesfeedback to maintain equal voltages at itsinputs, so a constant current flows into R1.This current also flows through resistorR2, developing a voltage across it directlyproportional to its value. If a linear vari-able resistor (potentiometer) is used for R2it will provide linear control of the output.
Perhaps the easiest way to understand
the action of the circuit is to consider whatwould happen if the voltage at the junctionof R1 and R2 were to rise slightly. The out-put of IC2 would start to rise and thus turnon the MOSFET TR1 a little more. Thiswould cause the 0V rail to rise with respectto the main negative supply rail so thatmore current would flow through R2 tobring the input to IC2 down again, restor-ing the balance.
The 0V rail, of course, is the positiveoutput so the voltage developed across R2is what is delivered to the load. Naturally,as the 0V rail rises with respect to the mainsupply, so do the positive and negative12V rails, so that even when the outputvoltage is close to the maximum of themain supply there will still be a full 12Vavailable for IC2 to use in controlling thegate of power MOSFET TR1.
It is also simple to measure the output
current in this arrangement using thesensing resistor R3, which develops a cur-rent-dependent voltage with respect to the
34 Everyday Practical Electronics, January 2002
control circuit “ground”. The only disad-vantage of this arrangement is that thereturn path for the reference current fromresistor R1 is via the main supply, TR1 andR3, so this current should be kept small toprevent any noticeable effect on the mea-sured output current.
This also applies to the voltmeter whichis connected directly across the output.
The full circuit diagram for the Versatile
Bench Power Supply is shown in Fig.3.The incoming 230V a.c. mains passesthrough a 2-pole isolating switch S1 to thetwo transformers T1 and T2, whilst thetransient suppressor VDR1 removes anybrief high voltage spikes that may occur.
No supply fuses are fitted to the proto-type, a 3A fuse in the mains plug beingconsidered adequate.
Transformer T1 is a 20V 20VA (1A)type and, with bridge rectifier REC1 andreservoir capacitor C2, produces a no-loadvoltage of about 30V. Under full-load con-ditions this drops to about 24V which isstill sufficient to maintain the 20V output.Capacitor C1 and resistor R1 also help toeliminate transient voltage spikes.
Transformer T2 is a smaller 100mAtype with a centre-tapped 9V-0V-9V out-put. Arranged as shown with bridge recti-fier REC2, it develops both positive andnegative supplies of about 12V each. A 5Vreference voltage is generated by IC1, astandard 78L05 regulator.
The earthing arrangements used in this
project are slightly unusual and requiresome explanation. Earthing of a mains-powered project is essential both for safe-ty and because capacitive couplingbetween windings in the transformer cantransfer potentially damaging a.c. voltagesto the output, even though from a veryhigh impedance.
However, the output of a bench powersupply is often required to have d.c. isola-tion from earth so that other earthed equip-ment, such as oscilloscopes, can be safelyconnected to any part of the circuit on test.
Commercially produced bench suppliesoften overcome this problem by using trans-formers with internal foil screens between
the primary and sec-ondary windingswhich are earthed toeliminate the capaci-tive coupling. Theseare not readily avail-able to the home con-
structor, so a differentmethod must be used.Switch S2 allows
the mains earth to beconnected directly toeither the positive ornegative output termi-nal or left “floating”,where capacitivelycoupled a.c. voltage isgrounded throughcapacitors C3, C4 andresistor R2. Althoughnot ideal, this systemworks well in practiceand reduces noise anda.c. voltage at the out-
Printed circuit board, available fromthe EPE PCB Service , code 333; casewith metal front and rear panels or metalcase, 205mm x 140mm x 110mm; plasticfeet (4 off); cable ties (see text); knob (2off); 8-pin d.i.l. socket (3 off); heatsink,100mm x 65mm; fixings; connectingwire; solder, etc.
SeeSHOPTALK page
Approx. Cost Guidance Only £39
excluding meters & case
g
d
s
+25V
+12V
-12V
0V
5V
IN IC1
MAIN
PSU
CONTROLPSU
OUT
COM
REFERENCE
CURRENTMEASURINGCIRCUIT
LOAD
0V
R1
R2
R3
TR15V
SETVOLTS
OUTPUT
+
VOLTMETER
+IC2
Fig.2. Simplified schematic of the voltage control method
at most. For safety, capacitors C3 and C4must be 250V class X2 suppression types.
The voltage controlling part of the cir-
cuit is constructed around op.amp IC2 andoperates as described earlier. The resis-
tance to which the reference voltage isapplied includes the preset VR1 so that themaximum output voltage may be set toexactly 20V.
The input to IC2 has a pair of protectiondiodes, D1 and D2. Capacitor C12 ensuresstability but is small enough to allow a fastresponse to output load changes. PowerMOSFET TR1 handles the full output cur-rent. Output voltage is indicated by meterME1 with VR3 allowing preset adjustmentfor calibration to 20V full-scale.
Load current is sensed by the one ohmresistor R10. At full output this dissipates awatt of heat, so a 7W type is used to dissi-pate this safely. A potential divider acrossR10, consisting of R12 with R13 and R14
in parallel, allows selection of either thefull potential across it or one tenth throughswitch S3, giving the 100mA and 1A cur-rent ranges.
The voltage from S3 is compared byop.amp IC3 with an adjustable voltagederived from the reference by divider net-work VR4, R16 and the current controlVR5. When the S3 voltage exceeds thissecondary reference voltage, the output of IC3 goes low, pulling the gate voltage of TR1 down through diode D3 to limit thecurrent flow through this transistor.
It also turns on transistor TR2, whichilluminates light emitting diode (l.e.d.) D7to indicate that current limiting is taking
place. Preset VR4 allows the current ranges
to be set precisely to 100mA and 1A,whilst VR5 gives control from zero to theselected maximum.
Op.amp IC4 also receives the voltagefrom S3, and converts it into a 1-100 Adrive for the current indication meter ME2.Preset VR6 allows calibration of this meterfor full-scale corresponding to the 100mAand 1A signal inputs. The high value of resistor R21 prevents any possibility of meter damage through overdriving.
Double-pole switch S4 allows the outputto be switched off independently and alsoprovides instant isolation from the circuit
connected to it at any time.
Zener diode D6 protects TR1 from anyhigh voltage pulses arising from the con-nected load. This can happen with sometypes of inductive load and, whilst normal-ly tolerant of brief high currents, semicon-ductors are easily damaged by excessivevoltage.
As this unit is mains powered, its con-
struction should only be carried out bythose who are suitably experienced orsupervised. All mains connectionsshould be fully insulated using heat-
shrink or other suitable materials.
36 Everyday Practical Electronics, January 2002
Internal view of the prototype showing the a.c. supply components.
C1
S1
R1
R
3REC1
230V
0V
0V
0V
20V
+
+
+
R2
9V 9V
T2 C3C4
S2
C2
CONTROL
CIRCUIT
SUPPLY
MAIN
SUPPLY
EARTH
SELECT
ON/OFF
230V
A.C.
MAINS
L EN
S1 AND S2 MOUNTED ON
FRONT PANEL. VIEWED
FROM REAR
ALUMINIUM PANEL
VDR1
POS
NEG
T1
0V9V 9V
230V 0V
P
EARTH FOR FRONT
AND REAR PANELS
Fig.4. Layout and interwiring of power supply components mounted on an aluminium base plate. The plate also acts as the heatsink for the 6A bridge
rectifier REC1. S1 and S2 are mounted on the front panel.
Construction should begin with thetransformers, the rectifier REC1 and earth-ing arrangements. These can be assembledin any manner preferred by the construc-tor. The layout used in the prototype isshown in Fig.4.
These components are attached to a190mm × 100mm metal plate drilled to fitthe threaded mounting pillars provided inthe plastic enclosure. The two transform-ers and rectifier REC1 are bolted in place
so that the plate acts as the heatsink for therectifier.
The large electrolytic capacitor C2 isfastened with a cable tie passed throughholes to each side of it. The three 470nFcapacitors, C1, C3 and C4 are glued inplace. It is essential that you ensure that good adhesion occurs. Preferably also usecable ties for these components as well to prevent them from contacting mains con-nections should they become detached.
Note the arrangement of the earthwiring, which uses one of the main trans-former mounting bolts as a “common”point for all earth connections. Any other metal parts of the case used, such as front
and rear panels, must also be connected tothis point.This part of the circuit can now be fitted
into the case and tested. When connectedup and powered, the output of the “main”supply should be about 30V d.c. acrosscapacitor C2 and 9V-0V-9V a.c. should beavailable from the 100mA transformer.These supplies will be needed for testingthe remainder of the circuit.
The front panel should be drilled as
shown in Fig.5 and assembled next. Theearthing selector switch S2 should be fittedand tested with a continuity testing meter.Mains switch S1 can also be connected up.
The mains input is taken to the upper two
Everyday Practical Electronics, January 2002 37
Completed power supply with the top-half of the plastic case removed to reveal the circuit board and power MOSFET TR1 bolted to the metal rear panel.
198mm
104mm
14mm 14mm
65mm 65mm
27mm
31mm
33mm
18mm 23mm
77mm
27mm
27mm
30mm
108mm
D7
M2 M1
S1
S2
VR5 VR2
S4
S3
OUTPUT+
30mm
19mm
Fig.5. Front panel drilling details and dimensions. The general layout of compo- nents and front panel lettering are shown in the photograph below.
connections on this. Transient suppressorVDR1 is fitted directly to the lower twoconnections on the output side.
The rear metal panel of the case has fourmounting bolts for the printed circuit board(p.c.b.) which can be used as a template tomark out for drilling. It also has an externalheatsink to aid dissipation of heat fromTR1, which is secured to the inside with aninsulating mounting washer and a boltpassing right through the heatsink. Fournuts are used as spacers for the p.c.b. when
it is fitted.
Most of the rest of the circuit is con-
structed on the p.c.b. whose details are
38 Everyday Practical Electronics, January 2002
CURRENT
VOLTS
333
REC2
IC1
C6
C10
C8
C11
C7
C5
C9
D2D1
R8
R7
IC2
R4
R5
R6
VR1 VR4R16
D4D5
C15
D3
IC3 R18
R17
R19
TR2
IC4
VR6 VR3
R21
C16
R11
C13
R10
R12
R13
R14
R9
C14 D6
R20
R15
IN
COM
OUT
++
+
+
+
e
b
c
a
a
a
a
a
a
k
k
k
k
k
k
C12
FLAT ME1
ME2
+
+
+
+
FROM MAIN
SUPPLY 25V+
g sd
TR1
a k
SETCURRENT
METER
SETVOLT
METER
SETMAX
CURRENT
SETMAX
VOLTS
1A
100mA
9V
9V
0VFROM 9V-0V-9VTRANSFORMER
OUTPUT ON/OFF
MAIN SUPPLY VE
VR2 VR5
D7
CURRENTLIMIT
SETOUTPUTVOLTAGE
SETOUTPUT
CURRENT
OUTPUT S4
OUTPUT
S3
SK1 SK2
5in (127mm)
26in(67mm)
CURRENTRANGE
INSULATINGKIT WASHER
Fig.6. Topside printed circuit board component layout, interwiring to front and rear panel mounted components and full-size underside copper foil master. Note the MOSFET (TR1) bolted to the rear panel using an insu- lating kit, in the photograph above.
shown in Fig.6. This board is availablefrom the EPE PCB Service, code 333.
After ensuring that the board will fit onthe mounting bolts, the pins for externalconnections can be fitted, there are 23 of these, and then the links, of which there areseven. Next fit the 0·6W resistors, diodes,dual-in-line (d.i.l.) i.c. sockets, the smallceramic capacitors, presets VR1, VR3,VR4 and VR6 , transistor TR2, regulatorIC1, rectifier REC2, the four remainingelectrolytic capacitors and 7W resistor
R10, preferably in this order for ease of assembly.Fully check your assembly for correct-
ness of the soldering, componentpositioning and polarity. The board is thenready for testing.
The aim of using separate op.amps for
the various functions is partly to make test-ing and trouble shooting easier, so hopeful-ly this will be the case.
The first test is to connect the 9V-0V-9Vtransformer as shown in Fig.6. Using 0V (thecentre-tap connection) as a reference, the cir-cuit should be powered up and the presenceof +12V and –12V checked at pins 7 and 4
respectively of the three d.i.l. sockets.The presence of +5V from regulator IC1
can also be checked at its output pin. Next,the MOSFET TR1 and VR2, the Voltagecontrol, should be connected, along withthe two leads from the main power supply,from REC1 and C2. IC2 should now beinserted into its socket.
Whilst monitoring the output with avoltmeter, the circuit should be poweredup, and it should now be possible to varythe output from zero to around 20V withVoltage control VR2. If so, VR2 can beturned right up and the voltage set to exact-ly 20V with preset VR1. If the voltmeterME1 is now connected this can be adjustedfor an indication of 20V (full scale) withpreset VR3.
Next the current range switch S3 should
be connected and set to 100mA,and the cur-rent control VR5 should be connected. Thecurrent control op.amp IC3 should be insert-ed into its socket, and a meter set to read acurrent of about 100mA connected in serieswith a 100 ohm resistor across the output.The circuit should again be powered and thevoltage control turned right up.
Potentiometer VR5 should now control thecurrent, from zero to around 100mA. Preset
VR4 can be adjusted for a maximum outputof exactly 100mA. The 1A range shouldautomatically be correct following this.
The l.e.d. D7 can be connected, thisshould light whenever current limiting isactive.
Finally, the current meter ME2 shouldbe connected, op.amp IC4 inserted, andpreset VR6 set for full scale at 100mA. Asbefore, the 1A range should now automati-cally be correct following this adjustment.
Once these tests are concluded, the
board can be attached to the rear panel tocomplete the assembly. It might be worth-while re-checking the adjustments, the pre-sets have been arranged for easy accesswith the case top half removed to make thissimple.
The unit will normally be used to supplya constant voltage to circuits on test, but itmay also be operated continuously in con-stant current mode which is very useful forcharging NiCad batteries of various types.
Although the heat-sinking will be ade-quate for most purposes, the fact should beborne in mind that it could dissipate over20W and therefore get rather hot. The sup- ply of low voltages at high currents for long periods is not recommended .However, most loads of the kind that arelikely to be found in the average workshopshould present no problems.
If in doubt, just place a hand on theheatsink now and again to check tempera-ture. The prototype has been used continu-
ally for weeks on end to power circuitsused with electric clocks, and is also thefavourite for programming PICs in theworkshop, leaving another supply free foroperating the PlC-driven circuitry.
It should be noted that the current limit
takes a finite time to operate so there aresome applications where external limitingis needed. The output of IC3 has to comeout of saturation and slew through abouteight volts before limiting begins, and thiswill take a microsecond or two!
The limit protects the supply itself against short circuits, and in almost everypractical fault situation it is fast enoughto prevent damage to faulty circuits ontest as these are rarely total short circuitsanyway.
However, it should be remembered thatthe MOSFET output device can handlevery high currents and has a large capacitorbehind it so, for the brief time it takes forthe limit to operate, many amperes can bedelivered into a short! An obvious exampleis the testing of l.e.d.s.
The limit should never be relied upon onits own for this, a suitable series resistorshould always be used.
Everyday Practical Electronics, January 2002 39
Rear of the completed power supply unit showing the finned heatsink bolted to the rear panel to aid dissipation of heat from the power MOSFET.
Everyday Practical Electronics is published on the second Thursday of each month and distributed S.O.R. by COMAG
Make sure of your copy of EPE each month – cut out or photostat this form, fill it in and hand it to your newsagent.
