Maker Pro
Maker Pro

High Voltage low current power supply

D

D from BC

I would like to use a 9 volt battery to create a high voltage source. It's
been awhile since I've messed with electronic componets. But it seems like
I
need something like a 555 timer to create a series of d.c. voltage pulses so
I
can then use a transformer to step up the voltage from say 9 volts to 900
volts.

Is the 555 timer the way to go? or is there a better device to turn the dc
into
a pulsating dc to step up with a transformer?

Thanks in advance.
Robert

There are smps IC's that have more features than the 555.
D from BC
 
R

Robert Miller

I would like to use a 9 volt battery to create a high voltage source. It's
been awhile since I've messed with electronic componets. But it seems like
I
need something like a 555 timer to create a series of d.c. voltage pulses so
I
can then use a transformer to step up the voltage from say 9 volts to 900
volts.

Is the 555 timer the way to go? or is there a better device to turn the dc
into
a pulsating dc to step up with a transformer?

Thanks in advance.
Robert
 
W

Winfield

D said:
Robert Miller asked,



There are smps IC's that have more features than the 555.

Indeed. The venerable Motorola (now ON Semi) mc34063A
can be called the 555 of the switcher world. Their app
note an920 teaches how to use it and has a high-voltage
circuit. The mc34063AP1 (miniDIP package) is $1.11 at
DigiKey in singles, soic reels are as low as 30 cents.
 
M

MooseFET

Indeed. The venerable Motorola (now ON Semi) mc34063A
can be called the 555 of the switcher world. Their app
note an920 teaches how to use it and has a high-voltage
circuit. The mc34063AP1 (miniDIP package) is $1.11 at
DigiKey in singles, soic reels are as low as 30 cents.


If you are going to 900V at low currents in one jump, a resonant
circuit may be better. The stray capacitance of the secondary of the
transformer is going to reflect back into the primary and cause losses
in a normal square wave switcher.

You can go up to a lower voltage with the transformers and then
voltage multiply in the output rectifier to avoid the issue.

I once make a 1000V 1mA power supply that ran at 1MHz. I just used a
transistor oscillator to do the power switching and an op-amp to
modulate the oscillators duty cycle. It worked quite well but I had
to place the op-amp on a different bench because no op-amp would work
near the transformer. The efficiency was about 50%. I figured that
the losses were %10 as heat generation and %40 as radiated RF.
 
T

Tom Bruhns

If you are going to 900V at low currents in one jump, a resonant
circuit may be better. The stray capacitance of the secondary of the
transformer is going to reflect back into the primary and cause losses
in a normal square wave switcher.

You can go up to a lower voltage with the transformers and then
voltage multiply in the output rectifier to avoid the issue.

I once make a 1000V 1mA power supply that ran at 1MHz. I just used a
transistor oscillator to do the power switching and an op-amp to
modulate the oscillators duty cycle. It worked quite well but I had
to place the op-amp on a different bench because no op-amp would work
near the transformer. The efficiency was about 50%. I figured that
the losses were %10 as heat generation and %40 as radiated RF.

Unless you built it as a HUGE circuit, it's extremely unlikely that
40% was radiated as RF. A square loop about a foot on a side of 18AWG
(1mm) copper wire has about 100,000 times more dissipative resistance
than radiation resistance. ;-) Similarly short electrical dipoles
wouldn't fare much differently.

The electric or magnetic fields may have been locally relatively
strong, but the likelihood that you actually put out much 1MHz
electromagnetic radiation is very small.

Cheers,
Tom
 
M

MooseFET

Unless you built it as a HUGE circuit, it's extremely unlikely that
40% was radiated as RF. A square loop about a foot on a side of 18AWG
(1mm) copper wire has about 100,000 times more dissipative resistance
than radiation resistance. ;-) Similarly short electrical dipoles
wouldn't fare much differently.

The electric or magnetic fields may have been locally relatively
strong, but the likelihood that you actually put out much 1MHz
electromagnetic radiation is very small.


You assumed a loop. Try it as a a pair of plates with 1000VAC on
them.
 
S

Spurious Response

OK. Even less EM radiation.


1MHz is a silly speed to operate a power supply at. A 60kHz switcher
is all this application needs.
 
T

Tom Bruhns

I would like to use a 9 volt battery to create a high voltage source. It's
been awhile since I've messed with electronic componets. But it seems like
I
need something like a 555 timer to create a series of d.c. voltage pulses so
I
can then use a transformer to step up the voltage from say 9 volts to 900
volts.

Is the 555 timer the way to go? or is there a better device to turn the dc
into
a pulsating dc to step up with a transformer?

Thanks in advance.
Robert

A little more to the point than the other replies I've seen here, you
likely will want to make a flyback-type supply, using stored magnetic
energy to generate a primary-side pulse that's a lot larger than 9
volts. Then the transformer turns ratio won't have to be astronomical
to get your 900 volts. You can make a blocking oscillator with one
transistor and a transformer, and not worry about using an IC at all,
though the regulation may not be what you want.

Note that Harbor Freight sells an "electronic fly swatter," sometimes
on sale for next to nothing, that generates a high voltage from a
couple of D cells. In fact, I see it listed for $1.99 right now...
It could be a way to get started cheap, with a circuit that works.
Can't swear to the voltage though.

Cheers,
Tom
 
T

Tom Bruhns

A little more to the point than the other replies I've seen here, you
likely will want to make a flyback-type supply, using stored magnetic
energy to generate a primary-side pulse that's a lot larger than 9
volts. Then the transformer turns ratio won't have to be astronomical
to get your 900 volts. You can make a blocking oscillator with one
transistor and a transformer, and not worry about using an IC at all,
though the regulation may not be what you want.

Note that Harbor Freight sells an "electronic fly swatter," sometimes
on sale for next to nothing, that generates a high voltage from a
couple of D cells. In fact, I see it listed for $1.99 right now...
It could be a way to get started cheap, with a circuit that works.
Can't swear to the voltage though.

Cheers,
Tom

OK, I measured the voltage: 4.0kV, with two reasonably fresh alkaline
D cells. The circuit is apparently a blocking oscillator using a
transformer and a single transistor, into a voltage multiplier.
There's an 0.033uF cap at the output. "Don't touch the net while the
red light is on" is an apt warning. The output cap is stressed rather
far beyond its rated voltage...

You'd probably come pretty close to the desired 900V just directly off
the transformer with a single half-wave rectifier. The transformer is
roughly a cube half an inch on a side.

Cheers,
Tom
 
M

MooseFET

OK. Even less EM radiation.


Are you sure about that. It seems to me that 1KV AC on a pair of
plates would radiate more than 1mA in a loop.
 
M

MooseFET

1MHz is a silly speed to operate a power supply at. A 60kHz switcher
is all this application needs.

I attempted the opration at 1MHz to make the switcher be above the
bandwidth of another part of the system. I ended up lower and well
shielded.
 
T

Tom Bruhns

Are you sure about that. It seems to me that 1KV AC on a pair of
plates would radiate more than 1mA in a loop.

What's the current through the capacitance of the plates? In other
words, what's the capacitance between the plates? How large are the
plates, and what's their separation? Anything else in the
configuration I should consider? As Win suggested in his posting,
it's still extremely unlikely that at 1MHz with an apparatus contained
within, say, a cube a foot on a side (or two feet, or three feet) that
you'll get anything like four times the radiation as you do I^2*R
dissipation, short of using superconductors.

Cheers,
Tom
 
a car coil can give you 100mw of power from 12v at 30kv unloaded that is simple enough or get an LM555 and use a mulipler to get to whaever you want in voltage.
 
D

Don Lancaster

Tom said:
Unless you built it as a HUGE circuit, it's extremely unlikely that
40% was radiated as RF. A square loop about a foot on a side of 18AWG
(1mm) copper wire has about 100,000 times more dissipative resistance
than radiation resistance. ;-) Similarly short electrical dipoles
wouldn't fare much differently.

The electric or magnetic fields may have been locally relatively
strong, but the likelihood that you actually put out much 1MHz
electromagnetic radiation is very small.

Cheers,
Tom
A voltage tripler is often a good solution to high voltage low currents
with extreme stepup ratios.



--
Many thanks,

Don Lancaster voice phone: (928)428-4073
Synergetics 3860 West First Street Box 809 Thatcher, AZ 85552
rss: http://www.tinaja.com/whtnu.xml email: [email protected]

Please visit my GURU's LAIR web site at http://www.tinaja.com
 
M

MooseFET

What's the current through the capacitance of the plates? In other
words, what's the capacitance between the plates? How large are the
plates, and what's their separation? Anything else in the
configuration I should consider? As Win suggested in his posting,
it's still extremely unlikely that at 1MHz with an apparatus contained
within, say, a cube a foot on a side (or two feet, or three feet) that
you'll get anything like four times the radiation as you do I^2*R
dissipation, short of using superconductors.

What started out as a not completely serious comment has gone way past
where it should have, but to continue down this silly path:


The transformer was a toroid about 1 inch in diameter. The core was
plastic. ie: This really was an air core transformer, but it was
formed to limit the magnetic field it created. The turns ratio was
IIRC 11:1 the winding was done with a wire rope and then connected in
series. So the whole thing bulked up to maybe 1.25 inches in
diameter.

The secondary side rectifier was a fast high voltage diode on about 1
inch leads. The primary switch was a highish voltage NPN in a TO-202
package. 1W went in, 0.5W came out and nothing seemed to get hot.
 
Top