HB9ON

G8MNY  > TECH     23.01.21 07:49z 137 Lines 7366 Bytes #999 (0) @ WW
BID : 20910_GB7CIP
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Subj: 0-35V 0-5A Lab PSU CS FL-305
Path: HB9ON<IW2OHX<UA6ADV<VE2PKT<K5DAT<KE0GB<K3CHB<PE1RRR<GB7CIP
Sent: 210123/0741Z @:GB7CIP.#32.GBR.EURO #:20910 [Caterham Surrey GBR]
From: G8MNY@GB7CIP.#32.GBR.EURO
To  : TECH@WW

By G8MNY                               (Corrections Nov 19)
(8 Bit ASCII graphics use code page 437 or 850, Terminal Font)
Here is a very unusual circuit principles, of this Italian 0-35V 0-5A PSU. It
uses a transformer variac secondary to make an efficient linear regulated PSU,
together with variable current limiting & dissipation power fold back.

ÚÄÄÄÄÄÄÄÄÄÄÄÄÄÄÄÄÄÄÄÄÄÄÄÄÄÄÄÄÄÄÄÄÄÄÄÄÄÄÄÄÄÄÄÄ¿
³ÚÄÄÄÄÄÄÄ¿ ÚÄÄÄÄÄÄÄ¿  ( )       FL-305       ³
³³ \ V   ³ø³ \ A   ³ Fine V      ___         ³  It was all blown up &
³³  \    ³ ³  \    ³           .-   -.       ³  modified into a simple
³ÃÄÄÄÄÄÄÄ´ ÃÄÄÄÄÄÄÄ´          / Course\      ³  raw PSU. So I did a lot
³ÀÄÄÄÄÄÄÄÙøÀÄÄÄÄÄÄÄÙ          \   V   /      ³  of reverse engineering,
³     overload        ( )      '-___-'       ³  to find out it how it
³ on        trip sw    A                     ³  originally worked, before
³  !        ÚÄÄÄÄ¿            +  -  e  +  -  ³  attempting the restoration.
³  ø ø      ÀÄÄÄÄÙonø        (o)(o)(o)(o)(o) ³
ÀÄÄÄÄÄÄÄÄÄÄÄÄÄÄÄÄÄÄÄÄÄÄÄÄÄÄÄÄÄÄÄÄÄÄÄÄÄÄÄÄÄÄÄÄÙ

SCHEME                       15A Power NPN                          15A
LÄÄo-oÄ¿    6-42V AC          Darlington__          Amp             Trip
   2A  )||(<ÄÄÄÄÄÄÄ¿   ÚÄÄÂÄÄÄÄÄÄ´~~~\_/e ÃÄRshuntÄMeterÄÂÄÄÄÄÂÄÄÄÄÂÄÄ\ÄÄ +ve
Mains _)||( \     ~³15A³+ ³8-60V ³    ³   ³              ³ Control ³
       )||( Var   Bridge  ³      ³  Drive ÃÄÄÄÄImonÄÄÄÄÄÄ´ PSU 0V! ³    0-35V
   ON  )||(  R    ~³   ³- ³      ³        ³Out           ³       Volt
N___ \_)||(________³   ³ ===16mF ³+In  Out³            Vmon      Meter  0-5A
        || ___         ³  ³ 65V  ÀDrop MonÙ              ³         ³
   300W ||(30V Control ÀÄÄÁÄÄÄÄÄÄÄÄÄÄÄÄÄÄÄÄÄÄÄÄÄÄÄÄÄÄÄÄÄÄÁÄÄÄÄÄÄÄÄÄÁÄÄ\ÄÄ -ve
EÄÂÄÄe    ÀÄÄÄ +/-12V PSU
 ///

The coarse Voltage Variac control has stops on it to give between 6V - 42V AC,
& a 50K Var R to control the course regulated Volts. Unusually a separate 30V
winding is used to make a floating +/-12V @ 40mA zener PSU on the +ve O/P rail,
for 5 Op amps, 6 transistors & 3 LEDs of the complex control circuit.

The 1st Op amp with input protection diodes & 1K Rs, monitors the output Volts,
compares PSU -ve through VarR & Fine VarR to +ve from 5K preset & 5K6 using +6V
zener reference. And with 2 transistors it shunts away the 3mA drive to the
darlington, & lights up the green OK LED.

                                  +12VÄÄÄÂÄÄÄ2k7ÄÄÂÄ470Ä>Darlington Base 0-3mA
      Voltage Comparitor        ÚÄÄÄÄÄÄÄÄ)ÄÄÄÄÄÄÄÄ´               (Or a Mosfet)
                     ³\         ³        ³        ³           /³
+6V       0VÄ1KÄÂÄÄÂÄ´+\      ³/e       1K2       e\³        /+Ã
 ³   preset    /_\\~/³1 >Ä´<ÃÄ´PNP    ÚÄÄÁÄÄ¿    PNPÃÄÂÄ´>ÃÄ< 2³ Current Limit
 À5k6ÄÄ5KÄÄÂÄ1KÄÁÄÄÁÄ´-/      ³\     OK  OVERLOAD  /³ ³      \-Ã Comparitor
          2K         ³/         ³    LED   LED    ³   ³       \³
       Fine VarR               10K    ³     ³    10K  ³
           ³                    ³   ³/       \³   ³   ³       /³
          50K                   ÃÄÄÄ´NPN   NPNÃÄÄÄ´   ³      /+Ã
      Course VarR               ³   ³\e     e/³   ³   ÀÄ´>ÃÄ< 5³ Power Foldback
           ³                   10K    ³     ³    10K         \-Ã Comparitor
          -Ve             -12VÄÄÁÄÄÄÄÄÁÄÄÄÄÄÁÄÄÄÄÄÙ           \³

A 2nd Op amp monitors the output current & compares it to the current set pot &
-6V ref zener. Overloads, limit the drive current & with 2 more transistors, by
again shunting away the 3mA darlington drive, & lighting the red OVERLOAD LED,
instead of the green OK LED.

A 3rd Op amp monitors the voltage drop across the darlington pass transistor.
And converts this into current to feed the emitters of a "dual transistor long
tailed pair" mixer, with a sample of PSU O/P current into one of the bases.

      Darlington        ÚÄÄÄÂÄÄÄ+12V     Power Dissapated       ³\
     Volts Monitor     10K 10K                   ³\       0VÄ1KÄ´+\
         ÚÄÄÄ68KÄÄ¿     ÃÄÄÄ)ÄÄÄÄÄÄÄÄÄÄÄÄÄÄÄÄÂÄÄÄ´+\            ³5 >Ä Power 
         ³³\      ³     ³   ³                ³   ³4 >ÄÂÄ680ÄÄÂÄÄ´-/  Foldback
+OutÄ680KÁ´+\     ³     ³   ÃÄÄÄÄÄÄÄÄÄÄÄÄÄÄÄÄ)ÄÂÄ´-/  ³     3K3 ³/  Comparitor
          ³3 >Â6K8´   ³/ V&I \³   ÚÄ1K5Ä+Out ³ ³ ³/   ³      ³
+InÄÄ680K´-/ ³   ³ ÚÄ´ Mixer ÃÄ>Ipot        ³ ÀÄÄÄ10KÙ     5K
         ³³/  ³   ³ ³ ³\e   e/³  100        10K           preset  Set Max Power
         ÀÄ68KÙ   ÀÄ)ÄÄÄÁÄÄÄÙ     ³          ³               ³    Dissipated
                    ÀÄÄÄÄÄÄÄÄÄÄÄÄÄÁÄÄÄÄÄÄÄÄÄÄÁ<+ve & 0V    -6V

The resultant balanced mix product, feeds the 4th Op amp, to give an accurate
signal proportional to the power being dissipated. And that then feeds the 5th
Op amp & also uses the -6V to set the Max Power Dissipated, & also light the
OVERLOAD LED.

CALIBRATION
A high power DC load is needed, I used a large tapped WW resistor 2+2+4ê 1kW.
Set the start position of the Variac VarR, & then the 4 presets are used to
determine, 1 Max overhead voltage, 2 Max Current range, 3 Current foldback
sample Ipot, & 4 Max foldback power. When correctly set the head voltage is
always just enough for a cool regulator at all output voltages & currents!

DOUBLE CURRENT MODIFICATION
As the PSU has a huge mains transformer & a roomy chassis, I decided to see if
it could be made to do 10A! (350W Regulated DC O/P!)

1/ Transfer the 2 heatsink reverse voltage protection tab diodes to the PCB,
   as they don't need heatsinking.

ÚÁÁÁÁÁÁÁÁÁÁÁÁÁÁÂÄÄÄÄÄÂÄÄÄÂÄÄÄ¿
³³    pcb     ³³  C  ³potÃÄBr´³ 2/ Re-use the 2 spare heatsink holes for 2
³~~~~~~~~~~~~~~ÀÂÄÄÄÂÙ~T~     ³    more NPN insulated Darlington 15A
³ _  _  _  _  Rs ÚÄÄÄÄÄÁÄÄÄÄÄ¿³    transistors, pointing away from each other,
³(_)(_)(_)(_)  Ý ³  VARIAC   ³³    to spread the heat.
³      Cs      Ý ³TRANSFORMER³³    File rear case hole to give clearance, &
³ ÚÁÄÁ¿   ÚÁÄÁ¿Ý ³___________³³    wire them up in parallel to PCB, with a 3A
ÀÂÁÄÄÄÁÂÄÂÁÄÄÄÁÂÂÂÄÄÄÂÄÁÄÂÄÄÄÄÙ    fuse in each emitter, as current share Rs.
  ~~~~~   ~~~~~ ÀÙ   ÀÄÄÄÙ
3/ Remount 16mF C & bridge, from PCB metal panel, on to the rear case either
   side of the VarR, making sure the pillar mounted PCB will fit back OK.
4/ Remove the PCB metal panel, & add more main 65V smoothing (I used 4x 5mF) in
   the new space, to maintain low DC ripple @ 10A before regulation.
5/ Shunt 5A meter with resistance wire to now read 10A FSD, & re-label 2x/10A.
6/ Shunt the large current sampling 0.1R with resistance wire to bring it down
   to < 0.06R, & mount it with the left over pillars behind Amp meter mounting
   screw.

Then do the calibrations again with current limit set to @ 10A max, & the fold
back current to 1.5A when set @ 35V. It is all just doo able, right on the
limit of the PSU & still not running too hot.

CONCLUSION
This is now quite useful bench test PSU, able to test low current circuits
with the new current limit from "10mA to 10A" @ voltages from "75mV to 35V".
Used for testing prototypes, zapping & charging batteries, run modest power
rigs (30W) etc.

Be aware not to over voltage kit, as it is a Lab PSU not just a Rig one!

If it is often to be used at this "higher power limit", a 60øC thermal trip
glued on the transformer might be a good safety feature to add!


See also tech buls "Lab PSU", "Simple 20A PS", "High AMP Crowbar Protected PSU"

Why Don't U send an interesting bul?

73 De John, G8MNY @ GB7CIP



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