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regulator for motor bike single phase

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neilprice

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It's supposed to be simple! big magnets spinning round a fixed coil on one side and on the other a battery and a hole load of bulbs. so i looked on the net to find a circuit to regulate and rectify or rectify and regulate. rectify was easy of cause, ether 1 diode for half wave or a diode bridge for full wave rectification. That just depends whether one side of the coil is hooked up to the mass or not.

now we come to the hard part: regulate. there seem to be two schools: clipper circuits or shunter circuits (if there is a difference?). clipper circuits use power transistors. shunt circuits use scr or triacs. both use zener diodes to detect over voltage.

now for the details:
coil dc resistance 0.247:eek:hm:
coil max power output 135w
open volts at idle 55Vpeak, 12Vrms
open volts at 6000rpm 137Vpeak, 30Vrms
idle with 3:eek:hm: load 39Vpeak, 10Vrms
wave form is a "sawtooth"

now for the circuits:
1st what i call a clipper circuit

**broken link removed**

when i "spice" this one it works well, but i'm told that it gets very hot because it limits 14A with all the volts the magneto can give (135w for 2 transistors)

2nd what i call a shunt circuit

**broken link removed**

but the problem is this is a cut down 3 phase circuit and doesn't work well. only one of the scr shorts and the zener diode doesn't change any thing.

PLEASE can anybody help me to understand.

Neil
 
Find a schematic for an automotive alternator. They use 6 diodes to rectify 3 phase.
 
Car and lorry alternators are very different because they regulate the field winding. Motorbikes have permanent magnet fields.

On the shunt circuit, only one SCR is supposed to short at a time. When AC1 is positive, the right hand upper diode will conduct, as will the lower left hand diode. (I can't read the numbers. Sorry).

When the voltage is too big, gate current is sent to both SCRs, but only the right hand one is forward biased, so only that one turns on. Then the alternator current flows through it rather than through the right hand upper diode.

I did manage to make a motorbike voltage regulator using SCRs instead of the upper diodes. I would short the gate to the cathode when the battery voltage got too big.

I had to do that instead of shunting because the small motorbike had a directly lit headlight, which dimmed badly when the alternator was shunted.
 
i would love to see a diagram of the circuit you made (a diagram is worth a thousand words). I have only modeled the circuits i show in LTspice. I have no idea what they will do in real life. if you have a circuit that really worked ...

i have seen on the net some very crude triac stuff and i am trying to model a circuit. i will post a diagram as soon as it models ok or when i get stuck.
 
Here is the circuit as well as I can remenber it. It is quite a few years since I built it.

I found that the funny voltage spikes on automotive stuff is such that I prefer to use discrete components where possible. The same sort of reasons were behind me adding an opto-isolator when there is no isolation needed. The circuit is practically impossible to destroy by simple things like connecting wires wrong, or surges when the ignition is turned on or off.

I'm not going to work out values, but here is how it works.

The voltage from the generator is rectified by SCR1. Current through R1 will turn on SCR1. D1 will stop the gate voltage going negative on the negative half of the cycle.

When the ignition is on, and the battery voltage exceeds the voltage of ZD1, current (limited by R3) turns on the LED in the opto isolator. The transistor of the opto isolator bypasses the R1 current so that SCR1 never turns on.

R2 stops ZD1 leakage current turning on the opto-isolator.

It is would be perfectly possible to fit several SCRs for 2 or 3 phase generators. I was stuck with a single phase generator because the coil was shared with the headlight bulb, which was directly lit on by AC current.
 

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Diver300,

looks really different to all the designs i have seen up till now. i'll try and model it and let you know how it works.

Neil
 
Diver300 said:
Here is the circuit as well as I can remenber it. It is quite a few years since I built it.

I found that the funny voltage spikes on automotive stuff is such that I prefer to use discrete components where possible. The same sort of reasons were behind me adding an opto-isolator when there is no isolation needed. The circuit is practically impossible to destroy by simple things like connecting wires wrong, or surges when the ignition is turned on or off.

I'm not going to work out values, but here is how it works.

The voltage from the generator is rectified by SCR1. Current through R1 will turn on SCR1. D1 will stop the gate voltage going negative on the negative half of the cycle.

When the ignition is on, and the battery voltage exceeds the voltage of ZD1, current (limited by R3) turns on the LED in the opto isolator. The transistor of the opto isolator bypasses the R1 current so that SCR1 never turns on.

R2 stops ZD1 leakage current turning on the opto-isolator.

It is would be perfectly possible to fit several SCRs for 2 or 3 phase generators. I was stuck with a single phase generator because the coil was shared with the headlight bulb, which was directly lit on by AC current.

is there a way you could do the design for a 3 phase circuit? i'm a bit confused as to how you could do it.
 
"I found that the funny voltage spikes on automotive stuff"

well thats normal. when you switch a magneto it gives huge spikes. this circuit is switching on and off each cycle. thats why the regulators are shunt or clipper and not switch.

as for three phase regulators i found this on the net:
http://www.geocities.com/loudgpz/GPZvRegExciteField.html
i tried to model it in LTspice but it didn't work.

the single phase version is above (didn't model ether)

but programs are not all and if somebody could tell me if it really works it would be cool.
 
neilprice said:
as for three phase regulators i found this on the net:
http://www.geocities.com/loudgpz/GPZvRegExciteField.html
i tried to model it in LTspice but it didn't work.

the single phase version is above (didn't model ether)

but programs are not all and if somebody could tell me if it really works it would be cool.

That is for an alternator with a field winding. That is what is on larger motorbikes, cars and lorries.

All the alternators in this thread are permanent magnet ones where the field can be varied.

I don't suppose that LTspice can model the generator with a field winding. The induced voltage in the 3-phase windings depends on the value of the current in the field winding, and that is vital to the voltage regulation.
 
hi Nigel,

My XT 500 has crappy lights too. The headlight runs strait off the magneto. In fact it has a high power and a low power wires coming from the same coil. all that hooked up to the ground of the bike. the regulator is hooked up to the lights wire (high p) when the lights are on or onto the charge wire (low p) lights off. I want to take the ground off the coil (for full wave rectification) and change from 6v to 12v (thats why i need a good regulator) and last of all replace the battery by a big capacitor.

All that said, did you get your dt to shine brightly?

Neil

PS was it you who already treated a motorbike regulator that blew up a bunch of 2N3055?
 
tom_eaton said:
is there a way you could do the design for a 3 phase circuit? i'm a bit confused as to how you could do it.

Here is an untested version for a 3 phase circuit. I have shown the opto-isolators separated on the diagram to make it easier to read.

IC1 is a TL431 or equivalent. The battery voltage is smoothed by R4 and C1. The voltage is divided by R5 and R6. When the divided voltage is above 1.25, IC1 turns on and turns on the opto isolators.

When the opto isolators are on they stop the SCRs from turning on by bypassing the gate current.

However, the circuits shown elsewhere in this thread would seem to be more suitable for 3-phase generators. The internal inductance of generators is so large that they can be considered constant-current supplies, so no damage is done by shorting them. The only reason that I built a circuit like this was that shorting the generator effectively shorted the directly lit headlight, run straight from the generator, not from the battery. Any motorbike with a 3-phase alternator won't have a directly lit headlight.

If anyone is thinking of increasing the voltage on a small motorbike with a directly lit headlight, it is worth remembering that the current, not voltage is set by the coil design. If you chose a headlight of a higher voltage, but the same current, the generator should light it OK.

I had a 1984 Honda CG125, which had a dreadful electrical system. Honda should be ashamed of what they made. It had magneto ignition, a directly lit headlight and no voltage regulator. The battery only powered the brake light, indicators and neutral light, and the battery was in effect used as a shunt regulator.

I fitted electronic ignition, and used the magneto coil as an additonal generator coil. That gave me enough power to run the side and tail lights from tha battery. I fitted the regulator that I showed the circuit for. I changed the battery to 12V.

On the headlight, it used to be a 25W 6V bulb, with a 5W 6V tail light. The total was 30W at 6V which is 5A. I changed it to a 60W 12V headlight which was also 5A and was lit very well from the existing generator. It was rather dim at tickover, where the low voltage became more important than the constant current at high revs.
 

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neilprice said:
hi Nigel,

My XT 500 has crappy lights too. The headlight runs strait off the magneto. In fact it has a high power and a low power wires coming from the same coil. all that hooked up to the ground of the bike. the regulator is hooked up to the lights wire (high p) when the lights are on or onto the charge wire (low p) lights off. I want to take the ground off the coil (for full wave rectification) and change from 6v to 12v (thats why i need a good regulator) and last of all replace the battery by a big capacitor.

All that said, did you get your dt to shine brightly?

No, I didn't see any way of doing it - and I don't see how you can convert the 6V alternator to 12V very well?.

I gave it a LOT of thought back when I had the bike, as far as I can see the only solution is to rewind the alternator for the higher voltage, and (hopefully) lose the self regulating feature of the coils.

The DT400 had a half wave rectifer feeding directly from the low power coil to the battery, no regulator. The headlight bulb connected directly to the high power coil (fed off AC) - at low revs the lights were pathetic, but once you got a few revs on weren't too bad, and didn't increase further with extra revs (self limiting alternator coil).

PS was it you who already treated a motorbike regulator that blew up a bunch of 2N3055?

I was offering suggestions, based on the old Triumph design which used a large zener on a heatsink between the front fork legs.
 
PS on one of the yamaha xt500 sites people have done the change to 12 v (there are plenty of volts) but you need to unsolder the ground (and resolder a wire)for full wave rectification.

if the regulator is hooked up to the low current wire that regulates the high current as well (they are on the same coil)
 

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You could try to use those modern PWM controlled Solar charge regulators. They are very efficient andle currents up to 30A. Just use a bridge rectifies and capacitor to filter the input.
 
Helder Ferreira said:
You could try to use those modern PWM controlled Solar charge regulators. They are very efficient andle currents up to 30A. Just use a bridge rectifies and capacitor to filter the input.

Do you have any plans or circuits? could they handle 130v?
 
Remember, 130V is "no-load" voltage. Try to connect 100W lamp and you never reach 130V. The regulators are no so expensive. You can google for switchmode regulators. These are good and efficient too. I have some circuits for these but only up to 3A.
 
Nigel Goodwin said:
I gave it a LOT of thought back when I had the bike, as far as I can see the only solution is to rewind the alternator for the higher voltage, and (hopefully) lose the self regulating feature of the coils.

I realise that it is all a bit acedemic, as you don't have the bike, but winding the alternator for a higher voltage would have been counterproductive.

Twice the turns would mean twice the voltage, but 4 times the inductance, so half the current, and exactly the same amount of power......

I found that just changing to a higher voltage bulb of the same current worked well, although the dimming at tickover was worse. The self regulating feature of the coils kept the current the same as before at high revs.
 
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