Creating High Amps, Low Voltage

In summary: BOOM.In summary, you would need a transformer to create high voltage on low voltages, a battery, or a capicator to discharge the battery quickly.
  • #1
Arctic Fox
176
0
I understand it's possible to create high voltages (low amps) with a Tesla Coil.

How would I go about creating high amps yet on low voltages?

IE: 1000a @ 3-6v
 
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  • #2
Given a Power supply capable of producing 1000A, all you would need is a low resistance capable of carrying 1000A.

E=IR

so 3V and R=.003 ohms should do the trick.

The question of what material to use for the resistance and even better the power supply that will provide that much current remains unanswered.
 
  • #3
I think the original question was what kind of power supply will provide that type of voltage and current. Off the top of my head, I'd say a faraday disk. I believe I have the name correct. A brush on the outside of the disk, a brush on the shaft, a magnet placed next to the disk between the brushes. Often times a liquid metal of some kind is used for brushes.

You may also consider getting a very large battery such as something that would have come out of a semi tractor. Of course the lowest voltage I know of is 6 volts, but it is 2 volts per cell if you want to disect one. If the battery is good for 1000 amps, then each cell is too because they are wired in series. Also, the phone company has used very large batteries in the past. I don't know if they still use them. They had a VERY large plate area and I believe were a lead acid battery so they would be 2 volts per cell. It goes without saying to be careful around lead acid batteries. Not only is there danger of severe burns in the event of a short circuit, there is danger of explosion. I have seen and been around lead acid batteries that explode. It gives you a lot more respect for them after seeing one go up. Sometimes even after a battery explodes and the top is totally removed it will still turn the starter enough to start an engine. Just because the battery has exploded does NOT mean the danger is gone.
 
  • #4
Couldn't you collect bunch of capicators and then discharge then all at once? :P There is your high current!

Anything wrong with using a capicator in this case?
 
  • #5
You're question is about supplying 3000W to 6000W of power, a lot more than you can pull from a regular household outlet or even a couple regular car alternators at full output. So your level of difficulty is increased a little bit, and as you can see from Integral's post even .001 ohms resistance is a large voltage drop as a percentage of total voltage (and a lot of wasted power in terms of efficiency) so you're likely using 0000 gauge wire or something like it to minimize transmission loss.

Batteries would be the easiest, definietly vent them (even the 'sealed' ones) to avoid gas buildup and be ready to have plenty of capacity as the lifetime of the batteries is substantially shortened if you discharge them too far. For a regular 12V battery the CCA (cold-cranking amps) is rated at 7V and near freezing, so by guesstimation the 6V battery should get you in the ballpark.

There are some heavy-duty 6V batteries for marine use that have a rating of 180Ah to 200Ah which is big when you consider a regular car battery is only 50Ah or so! Five of those marine batteries in parallel would get you the 1000A with a nice long useful lifetime close to 20 hours, if that's important.

Cliff
 
  • #6
Ebolamonk3y said:
Couldn't you collect bunch of capicators and then discharge then all at once? :P There is your high current!

Anything wrong with using a capicator in this case?


Hmm, let's see what we'd need for .1 second of discharge.

V(t) = V0 * e^(-t/RC)

C = - t / (R * ln (V(t) / V0))

C = -.1 / (.003 * ln(3/6))

C = 48 Farads

Now a cap that large would need the ESR/ESL factored in as well, and hopefully the electrolyte wouldn't get cooked out from the heat of discharge.

Cliff
 
  • #7
Bottom line here: you'll need to be a little more specific about what you're trying to do.
 
  • #8
I understand it's possible to create high voltages (low amps) with a Tesla Coil.

How would I go about creating high amps yet on low voltages?

IE: 1000a @ 3-6v.
Transformer, of course. Primary coil is some 20-100 turns of heavy wire, heavy core, secondary coil is single or half turn of, umm, just huge brick of metal. Mains line in, huge amps out at low volts.
 
  • #9
A Faraday Disk looks like something I'd be interested in - if it actually works.

Battries would be my second option.

To me, capacitors are like little explosives. I don't like snap, crackle or pop. :)

A transformer would've been my first guess, but I don't want to have to be connected to mains.

What I'm wanting to do is create a huge electromagnetic field - like a degausser coil, but using pulsed DC. My thinking is the eM field comes from amps, not voltage. Is this correct?
 
  • #10
If you don't like snap crackle and pop, then I don't know if this is something you should pursue.
 
  • #11
BTW I was mistaken above, your batteries would last about 20 minutes not hours. So 300lbs of batteries costing $1200 or more last 20 minutes.

Mains power isn't big enough for your original spec unless you're going 240V for your mains.

You're talking a big field like an MRI uses right? Some of those things had like 20KW amps in them made by Crown (the pro-audio guys) and that's going to need 480V 3-phase power.

There's going to be big caps somewhere, likely inside the amplifier you find to drive your coil.

Cliff
 
  • #12
To create a huge electromagnetic field you do not need huge amps, you need number of turns in the electromagnet coil. Wire resistence is then just a thing of efficiency, ie losses. Voltage is needed to just overcome the losses. If you get your wires to supercnduction, no voltage is needed.

Tokamak magnetic coils come to mind.

Re crackle and pops, eletric welding uses like 200 amps. If you want to go past 1000A, you don't mean to say that this is some easy stuff?
 
  • #13
So... if I have two coils of the exact same size, yet one uses 0AWG cable and the other uses 12AWG wire... the magnetic fields should be the same for both if the power supplied, as well as the number/size of turns, is the same?

Somehow that doesn't seem right. I have the idea that one needs to squeeze more power through a wire in order to get a higher magnetic field. This is false?
 
  • #14
You need current to produce magnetic field. Smaller wire will have higher resistence, so to get same amount of current you'd need more voltage. When you get to same current through both, same magnetic field will be made.

In regards to power, its a measure of work done over time. Magnetic field byitself is not any work done, only heat dissipation in the wire resistence is. Thus smaller wire will dissipate more heat - more losses.

Power to the magnetic field will become an issue when the field interacts to make some real work.

I guess you can think of magnetic field as of transmission line of power grid. You don't want to get much power AT the wires, you want to get as much as possible _through_ it with minimal losses. Ideal wire is that with zero resistence, needing zero volts to transfer infinite amps with no losses, an so is magnetic coil too.
 
  • #16
drag said:
Praise the Lord and Alleluya - you are delivered :biggrin: !
Try this:
http://www.lambda-emi.com/product_html/esspower.htm
Gee... There is no price listed on that page... Anybody care to guess what that beauty might run? $10k? These guys are accustomed to dealing with industry, not a home hobbyist, they expect to get paid. Maybe even $20k, more would not surprise me, less would.
 
  • #17
Details my friend, small details... :biggrin:
 
  • #18
Actually, come to think of it, I suppose that if you hook
that thing with a very low resistance circuit it could just
short circuit, so eventually you'll just get a part of those
phousands of amps. But, maybe I'm wrong and it won't
short circuit, don'no... :confused:
 
  • #20
wimms said:
To create a huge electromagnetic field you do not need huge amps, you need number of turns in the electromagnet coil. Wire resistence is then just a thing of efficiency, ie losses. Voltage is needed to just overcome the losses.
I second this motion. Strong electromagnetic fields are created most easily by adding many turns of wire to your electromagnet just making sure you have enough voltage to get through the resistance.

"The simplest electromagnet is a wire through which a current is flowing. If the wire is now wound into a coil or solenoid, the strength of the magnetic field is increased to a very large degree. This increased strength is due to the fact that the field around each turn of the coil adds its effect to the fields of all the other turns, just as would occur if a number of permanent magnets were tied together. The resultant magnetic field is the sum total of all the individual fields."

-Basic Electrical and Electronic Principles

Maurice Grayle Suffern

McGraw-Hill 1949 3rd edition: 1962

He goes on to cite the following four factors that contribute to the strength of any electromagnet:

"1. The number of turns forming the solenoid.
2.The strength of the current flowing through the solenoid.
3.The material of which the core is made.
4.The size of the core."

Whatever kind of iron based core you use will have a somewhat different ability to be magnetized, depending on what elements have been added to the iron and in what proportions. In general, though, the larger the core the stronger the possible field.

All forms, however have a saturation point beyond which it is no longer possible to increase the strength of the magnetic field by adding more turns.

Putting mega-current through a coil of few turns is not a good solution because of the heating. The best solution is to put a reasonable current through many, many turns of wire with a good sized core.
 
  • #21
Greetings !

If what you need is a strong magnetic field use a
ferromagnetic core in your coil, iron, mumetal if you
can afford it, and so on for a strong induction field.
Also, you can concentrate the flux by shaping
one end so that it would have a cross-section
area a few times smaller than the core inside the
coil, or make a loop with an air gap and smaller
cross-sections, thus increasing the field even further.

Live long and prosper.
 
  • #22
Arctic Fox said:
How would I go about creating high amps yet on low voltages?

IE: 1000a @ 3-6v
many ways to do that.here's another one.simple transformer action ala in arcwelders.typical arcwelder machines produce output of something like 500 A @ 10 V.
or if you want DC :strong car batteries can release immense currents at low voltages ( not recommend:the danger of damaging the device and experiment in general is real)
 
  • #23
drag said:
Praise the Lord and Alleluya - you are delivered :biggrin: !
Try this:
http://www.lambda-emi.com/product_html/esspower.htm

Oooh, that looks nice.
A.F.:

Thank you for your interest in Lambda Americas power supplies. Here is
the information you requested:

1) ESS 10-1400-2-D is $ 8,556.00 FOB Neptune, NJ;
{ESS SERIES POWER SUPPLY, 0-10VDC, 0-1400 AMPS, AC INPUT 208VAC THREE PHASE, DIGITAL METERS.}

1) Options available are "RSTL" Digital Interface IEEE488/RS 232
$600.00 additional. Also available are "LB" $25.00 additional.
And the price is right, too. :)


I am wanting to create the magnetic field using only a large coil of wire - like a degausser - with no iron core. Inside the coil there will be aluminum, fiberglass, ceramic and such, but nothing 'magnetic'. My idea is that the coil will make a donut- or torus-shaped field; is this correct? The current will also have to be DC as to show a North/South direction.
 
Last edited:

1. What is the concept behind creating high amps and low voltage?

The concept behind creating high amps and low voltage is to have a large amount of electrical current flowing through a circuit, while keeping the voltage at a lower level. This allows for efficient and safe use of electricity, as high voltage can be dangerous and cause electrical shocks.

2. How is the relationship between amps and voltage in this scenario?

In this scenario, the relationship between amps and voltage is inversely proportional. This means that as the amps increase, the voltage decreases, and vice versa. This is due to the fact that high amps require a larger current flow, which results in a decrease in voltage.

3. What are the benefits of creating high amps and low voltage?

Some benefits of creating high amps and low voltage include decreased risk of electrical shock, increased efficiency in electrical systems, and reduced costs for power transmission and distribution. It also allows for the use of smaller and more affordable electrical components.

4. How can one create high amps and low voltage in a circuit?

To create high amps and low voltage, one can use a transformer to step down the voltage while stepping up the current. This can also be achieved by using resistors to limit the voltage and increase the current.

5. Are there any limitations to creating high amps and low voltage?

Yes, there are limitations to creating high amps and low voltage. One limitation is that as the amps increase, the resistance in the circuit also increases, which can lead to power loss and excess heat. Additionally, not all electrical devices can function properly with low voltage, so it is important to consider the specific needs of the circuit when creating high amps and low voltage.

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