Can We Harness Lightning to Generate Energy?

In summary, the conversation discusses the difficulty of capturing the energy from a lightning strike due to its short duration and the amount of energy involved. The idea of using a tower with a wind turbine and solenoids to capture the lightning is proposed, but the practicality and challenges of this method are questioned. Factors such as the size and weight of the wire, inductance, and potential heat generation are discussed. Ultimately, it is acknowledged that this may not be a feasible or efficient method for harnessing lightning as an alternative energy source.
  • #1
Leonardo
14
0
two very large solenoids (tons maybe ) Stacked vertically, very large capacity wire coil w/ iron core. upper solenoid attached to guide rails to keep its trajectory vertical.
now introduce current I.E. lightning strike. how can one tell if the upper solenoid will be lifted or how far it would be separated from the lower?
 
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  • #2
The difficulty in mechanical capture of the energy in lightning is that there is a lot of energy in an extremely short amount of time. That's not much time to charge an inductor or accelerate a mass.
 
  • #3
envision a hollow tower w/ a leading edge technology wind turbine @ the top, leaving the tower a lightning rod mast , inside the tower the solenoids, one on guide rails extending to the top of the tower.
the lightning rods insulated ground w/ appropriate gage wire cable runs down the tower and is distributed to the solenoids.
what gage is the cable in order to conduct w/out melt down? what weight is the solenoid & what will limits its travel up the tower other than gravity and friction (the extent of the magnetic field?) ,
how tall is the tower that will contain the solenoid / projectile?
what to do with the stored energy at the top of the tower when the weight is at its apex would be the next matter to consider.

The difficulty in mechanical capture of the energy in lightning is that there is a lot of energy in an extremely short amount of time. That's not much time to charge an inductor or accelerate a mass.

would the size of the wire help here?, or some sort of buffer?
 
  • #4
First off would be how quickly the charge transfer occurs with a lightning bolt. One discharge lasts only 60uSec according to the link below.

http://home.earthlink.net/~jimlux/lfacts.htm

In addition, note the air is heated to 50K F. That's where most of the work is going is into heating the air. Read near the bottom of this link, it references the same book and provides more info on how impractical lightning capture is as a power source.

http://www.uic.edu/labs/lightninginjury/ltnfacts.htm

Cliff
 
  • #5
FROM CLIFF_J
First off would be how quickly the charge transfer occurs with a lightning bolt. One discharge lasts only 60uSec according to the link below.

would rapid charge transfer cause explosive acceleration of the solenoid in our hypothetical tower ?
what happens to all that heat when lightning strikes a lightning rod? If the lightning rod won't melt there shoudn't be a problem w/ the conductor to the
solenoids.

FROM CLIFF_J Read near the bottom of this link, it references the same book and provides more info on how impractical lightning capture is as a power source.

I will look at the library that sounds like a good reference book, meanwhile to make it practical is an interesting puzzle, besides wasn't it fun when you did something they said you couldn't ?

Thanks for the links, very interesting stuff.
The average lightning stroke has a peak electrical current of 30,000 amps. (taken from another link ; The average lightning strike contains 20,000 amps.)

The average flash will light a 100 watt bulb for more than 3 months.

Lightning’s heat exceeds 50,000 degrees F. or three times hotter than the surface of the sun.

Electrical current travels along the outside of a conductor, as in a person struck.
"In reality, lightning often flashes over the outside of a victim, sometimes blowing off the clothes but leaving few external signs of injury and few, if any, burns".



Uman, M "All About Lightning", Dover, 1986.

Rakov, V. A. and Uman, M. A: "Lightning: Physics and Effects." Cambridge University Press, 2001.

Source: USA TODAY research by Chris Cappella
 
  • #6
Your biggest problem is likely the inductance of the wire itself as a straight piece of wire, much less the wire wound in a coil.

Any impedance means the current will be converted into heat. Current squared times impedance tells you the heat generated, and this would be a lot. Might need like MCM500 wire or something...

Its always nice to prove something can be done when everyone says it can't. I was pretty sure I could trisect an angle at one point! :) I think we'd all like for you to prove us wrong and provide a meaningful alternative energy source (any of us that have been to the gas pump lately anyways) but you do have convential wisdom working against you.

Cliff
 
  • #7
Cliff- Your biggest problem is likely the inductance of the wire itself as a straight piece of wire, much less the wire wound in a coil.

Avoiding the heat problem seems to be a simple problem unless I am missing something ( wouldn't be the first time). The questions I can't answer myself are like these.
will the solenoid accelerate to rapidly (or explode)? How would one arrive @ the optimum weight of the solenoids (goal being to lift the greatest weight possible under control). Any help is appreciated, thanks for your input Cliff.

From; www.lightningrodparts.com/parts1.html
- Standard of the industry for structures less than 75' high.
Catalog Number 1 - 32 strands of 17 gauge bare copper wire in smooth or basket weave configuration. 7/16" diameter, 65,500 circular mil cross section. Weight of copper - 204 lbs. per 1,000' - (Other size cables are available)
 
  • #8
Lets pretend the wire can capture the energy without losses to heating the air to 50,000 F. Inductance is the resistance to change in current. You're asking the wire to flow 10-30kA (very tough job) with a rise time of like 10uSec or 10KHz.

Here's a formula for straight wire inductance, don't know how accurate it is but should be good enough for purposes of example. I'll use the wire you spec'd above.

L=.0002*B(2.303*LOG(4B/d)-.08}

L= inductance in uH
B= length in mm
D= diameter in mm

I get L = .0002*22860*(2.303*log(91440/11.11)-.08) = 41 uH

XL=2*PI(F*inductance) = 2.58 ohms

Add the .02 ohms for the wire resistance, and now we have 2.6 ohms. Since current^2 * impedance tells us power dissapated, we get somewhere between the equivalent of 260MW to 2340MW being dissapated by a copper wire the size of your thumb? Plus, we're talking only 2-3 circular mils per amp, typical conservative range for insulated wire would be 200-300 circular mils per amp to avoid the wire burning up. Obviously this is kinda fun to throw numbers around, but this would never work as you'd need a wire the size of an entire skyscraper to handle such monster numbers, and you're trying to conduct from two poor conductors (dirt and air).

Sorry, your solenoid would hardly even move unless super lightweight and still move mere inches if you could get it to move without the wires vaporizing.

-------------

Lets do the math backwards from the authors conclusions. He said there's enough power leftover for a light bulb to be lit a few months. Let's say a 100W bulb, and use a whole year. You'd need millions of good lightning captures to equal just the a single local peak demand power generator, much less a bigger generator like Hoover or Niagra Falls.

That's not to say that lightning isn't powerful. It is. It just lasts for entirely too short a period of time and expels too much of its energy in heating air to become any kind of meaningful power source.

Cliff
 
  • #10
Not considering problems relating constructing means for storing lightning energy captured on ground ,I must say that only 1 or 2 % of total energy of the lightning could be stored in this way.
Some rough and simple calculations give about 50 - 500 MJ of total energy for a typical lightning discharge.And captured would be only
0.5 -10 MJ.Not very efficient..Great deal of original energy is being lost as heat in lightning channel,dissplacement field currents in cloud and ground,far field EM radiation and so (sound waves of thunder..)
 
  • #11
Although it seems now a stale topic, with somewhat limited usefullness. I would never the less produce a simulator, that leaves an impression. The Answer to me is obvious, The lightning has a nominal pulse duration of 6uS. The corresponding resonant frequency is 1/6 us. You build a parallel tuned circuit, The L is the primary of an open circuited power transformer with the seconadary opened by means of a relay. This primary is shunted by a capacitance that equates 1/6uS=1/Sqrt(L*C). the C will be small, therefor will need to be two widely separated sheets, of very large area to suck up the charge, as the inductance will be an open circuit at the transient, the cap a short.

After the initial unit impulse, the tank circuit "rings", the seconadary connection is the relayedand dumped into a pulse-bumped motor-flywheel that stores the energy. It will be a cool sim, exept the visulization of the bolt is hard to simulate using a spark gap, real lightning changes direction above every 150 meters.
 
  • #12
Hydrogen production from lightning?
 
  • #13
Nitrides are the main benefit, or at least generated as a by product if lightning, and by the way, most these lighting has provided the nutrition that allow food to be grown and produced. As far as hydrogen is concerned, it is good for blimps. not much else really.
 
  • #14
wwtog said:
Although it seems now a stale topic, with somewhat limited usefullness. I would never the less produce a simulator, that leaves an impression. The Answer to me is obvious, The lightning has a nominal pulse duration of 6uS. The corresponding resonant frequency is 1/6 us. You build a parallel tuned circuit, The L is the primary of an open circuited power transformer with the seconadary opened by means of a relay. This primary is shunted by a capacitance that equates 1/6uS=1/Sqrt(L*C). the C will be small, therefor will need to be two widely separated sheets, of very large area to suck up the charge, as the inductance will be an open circuit at the transient, the cap a short.

After the initial unit impulse, the tank circuit "rings", the seconadary connection is the relayedand dumped into a pulse-bumped motor-flywheel that stores the energy. It will be a cool sim, exept the visulization of the bolt is hard to simulate using a spark gap, real lightning changes direction above every 150 meters.
To me it looks like you r up to think of forcing the lighting channel to alternately "oscillate" instead of monopolary decay.
By provoking the channel to hit larger or smaller inductance tall antenna and capacitor system for instance?That will not work in reality.Due to al least 3 reasons.You might capture small portion (a few % - best case) of the energy and that's it.
cheers.
 
  • #15
I was thinking much simpler, say a simple transient circuit analysis. (1) unit pulse function into a tuned LC tank circuit, and with a delay, after the unit pulse, the power transformer secondary load relay is closed into a load, weakly coupled enough as to not totally kill the Q of the tank circuit, Or large enough to bump start a flywheel. (for a simulator of course, I am not ready to take on the gods with a kite and key, yet.)
 
  • #16
wwtog said:
I was thinking much simpler, say a simple transient circuit analysis. (1) unit pulse function into a tuned LC tank circuit, and with a delay, after the unit pulse, the power transformer secondary load relay is closed into a load..
There are problems I forsee in thinking "simple" in the case you want good representative for interaction between lightning
and LC circuit of any sort.These problems concerns:
a)Distributed geometry of the equivalent circuit representing lightning discharge (lightning channel paths are kilometers long)
b)Impedance variation of the channel during return stroke as well as during whole event.
c)Info good to know before the modelling in advance that there is whole class of rise times and duration times varying from shot to shot."Nominal" times of return stroke (did you reffered to the rise time 6microsec in your post?) are just nominal as word says.I don't know if that is in right ballpark or not but I suspect it isn't a fixed value.

Even if,by some miracle,problem c gets overcome,problems a ,b include complex intraction between the struck object (Physical LC circuit) and the channel resulting in very rich frequency domain spectrum content.Impedance matching between lightning channel and the circuit wouldn' help much in capturing significant part of stroke energy eiher (the outcome is different than in circuit with concentrated and constant parameters).However,it is always better to have characteristic impedance of the circuit small (or around impedance of lightning channel) than higher due to flashower danger in the latter.
One way or another,taking adventure in constructing means for capturing couple of % ( best case scenario) of original lightning stroke energy at one location isn't worth a try.Awerage power during one year will be too small to justify investments in the project.
location
 
  • #17
That would be pulsewidth 6-20 mS, risetime 50nS. Side flash would be an issue. As far as impedance matching the channel, I would not consider this an issue after the conduction path is established, It is not like a transmission line whereas you have forward and reflected waves. (maybe if it is a short circuit, ie Gamma=-1, then you can reflect the lightning stroke back to the cloud, ... not likely).
 
  • #18
You have forward and reflected waves in the return stroke times.In struck object they are severe.In the channel they are attenuated due to significant disipation.
Long lasting currents (miliseconds latter) are in order of only 100-200 amps and can be modeled I think like generated by current source.
Feasibility of the scheme is poor.Relisation is troublesome.Ask for advice HV EE people of this forum.They should know more.
 
  • #19
TeV, you are Awwwwwssssuuuuummmm Dude. Never considered reflected waves on electrons, traveling in a plasma stream. But actually electromagnetic, effects due to the magnetic field created by such electrons provide the feedback for such phenomem.

Actually, my "simulator", was to be a simple arc gap generator, that would be shadowed onto a larger projection area. To keep the whole thing honorable, the spark, would in fact transfer the charge to a flywheel mechanism. I thought it would be a big hit to the younger, to be able to push a button, produce a magified arc, that would actually be converted to rotational energy, maybe a wheel with a "see-through-glasses" spiral pattern. This simple demonstration is complicated enough, differential equations and all. Now I have to worry about the impedance of the source-arc for not, max, but adequate power transfer to to provide a real effect. Now add rain noise, and "thunder" effect at the pushputton, and you get a real crowd pleaser.

Well, Ma, load up the vortex charging fuel cell in the p-truck, looks at we got to go tornado hunting again. When Ya fish, its best to go for the big ones!
 
  • #20
wwtog said:
To keep the whole thing honorable, the spark, would in fact transfer the charge to a flywheel mechanism... that would actually be converted to rotational energy...
Ok.But,in the case of a natural lightning ,simultaneous transferring of the energy in rotational (or mechanical) is even less promising as concerns efficiency than capturing it in the capacitor.Simple reason is too short time of the event.
My only idea how to think of the problem is something like this:
to use the system of long ( kilometers) transmission lines parallel to the ground plane.The lines should be terminated by HV capacitor banks capable of withstand megavolts.When incident EM wave reach the capacitor bank and charge it to the max potential,very fast HV switching equipment reacts and disconnects capacitor off the line.It is a horrible technical task to achive something like this in practical life.If possible ,definitively very expensive solution.Not worth a try.
 
  • #21
TEV,capturing the energy from lightning doesn't appear complicated following your procedure.Can someone estimate costs for building the facility proposal?
 
  • #22
zhana said:
TEV,capturing the energy from lightning doesn't appear complicated following your procedure.Can someone estimate costs for building the facility proposal?
zhana,"hurry up slowly":-)I think you got a wrong impression.I didn't describe "the procedure";I just gave the superficial hint where and in what form the energy should be trapped in ,and that you need controlable high voltage switching devices for that feat.The system more detaily described:long straight transmission line is made to be hit by lightning at one end.Its' other end is terminated by capacitors put in parallel where connection between adjenced capacitors of the bank is realized by short "transmission lines" of high inductance (the geometry solenoid ala solenoidal coil).In other words,the formed mesh is the chain of "PI" structure.The most important requirement for the mesh is that input impedance be as close as possible to the characteristic impedance of the long line used.In that case very little energy is reflected back to the long line (practically regardless of shortlasting injected lightning wave forms).After the traveling lightning electromagnetic wave fills the mesh enough,multistage controlable switching process begins:First the mesh dissconnection off the long line occurs (prior to the first capacitor in the chain),than the mesh is left alone on its own transients and structure-progressively capacitor by capacitor in the mesh is disconnected in the moment when peaks in voltage.If you are crazy and rich enough you may want to think latter to discharge the capacitors to superconductive coils/loops and save the energy in the magnetic form..
But,I ask what all the effort for?Storing couple of MJ?C'mon!Besides,If possible to build ,the project would be expensive as hell (millions of $$$,that's for sure).

cheers
 
  • #23
Stupid question, does lightning strike the ocean? I know it hits ships in the ocean. It seems that the highly conductive seawater would provide a completely different conduction means compared to static charge build up on solid objects.
 
  • #24
Answer

wwtog said:
does lightning strike the ocean?
This gallery has many photos confirming it does:
http://www.genesisfineart.com.au/lightning_gallery_1/ocean_reef_4.html [Broken]
 
Last edited by a moderator:
  • #25
The static electricity is generated from falling ice crystals generating friction such that the charge is distributed + high level cloud, -mid level to low level cloud ,& + at ground. But my friends here in this forum state that water can not hold a charge. what makes the lightning strike to the neutral water?
 
  • #26
And the photo's did give the impression that the lightning struck the water, but yet, this was not at all conclusive that the lightning actually did strike the water, or maybe something else that was in or near the water, maybe a whale, dolphin, flying fish, or shark fin.
 
  • #27
I walk on a carpet and get a sharp shock from the door knob. Where is the conservation of energy, did it all the stored up charge (energy) get balanced by the "shock". Is it possible to get shocked twice by the same charge?, ie. the carpet friction charge potential is equalized into the door knob. I mean while quickly run outside and touch the car, further depleting the rest of my stored charge, Now can I go back the the door knob and get shocked back by the new electron imbalance between me and my door knob electron storage device?
 
  • #28
Electricity collection

So I understand that it is complicated to collect the electricity because of the short time span and the inability to store this large amount of electricity. However, can the heat generated from this electricity be used and transferred into power?
 
  • #29
Inquiring Mind said:
So I understand that it is complicated to collect the electricity because of the short time span and the inability to store this large amount of electricity. However, can the heat generated from this electricity be used and transferred into power?
I pressume it can (to a certain and small extent),but without meaning of any facility of such kind for practical purposes in everyday life.
This is explained by the other posters ^^).
BTW,how is the total energy of a typical cloud-ground lightning estimated/calculated?Can it be somehow measured?
 
  • #30
zhana said:
BTW,how is the total energy of a typical cloud-ground lightning estimated/calculated?Can it be somehow measured?
I would think you can measure it via sensors on a lightning rod.
 
  • #31
russ_watters said:
I would think you can measure it via sensors on a lightning rod.
Hmm,I doubt that.Now I'm thinking and I recon you can measure current , total charge transfer,or even to extrapolate the energy dissipated locally -in the place that particular lightning strikes.
But total energy that lightning discharge release I think you cannot.
 
  • #32
I've been contemplating this for a while - and I think trying to use modern technology for something so natural isn't the answer - of course we like to think in terms of wires and circuits. But that comes later - the harnessing of this power should be basic at first - raw almost.

I've been working on this... figuring things out - Think about it like this

In the old days we used crystal set radios - they used galena or cadmium sulfide, a semi conductive material inside a copper cup - much like a battery eh?

So yeah - these things weren't powered electrically.

They pulled in the energy of sound waves - radio signals! They actually worked!
Sooo...

what I'm thinking is ditch the circuitry to refine the power until after it's stored.
Look to perhaps allowing something to attract the energy first (Lightning rod)
Then it travels the rod to something else - much like this galena mineral...
perhaps rose quartz? I'm still thinking - will prolly build a model and test some of these ideas out to see what happens.

I'm thinking - if I build a large enough grid - with some of these crystal cells to house the power - and a switch that would allow me to switch from conventional power to stored power - this could be something revolutionary.

at least for times of crisis - or even just to lower your electrical bill every year :p

Come on, all the psychics have been using this crystal energy for decades - why not really use them for energy?

Is it because we don't have the technology to tap into the crystals?

That's simple - it's called light, concentrated laser light maybe.

Sure - use some minimal conventional/generator powered laser light :)

So you have some high tech phototronic device that pulls the energy from the crystal much like a laser - and changes it into a charge that could actually be stored in a power cell of some type.

Of course this will need more brainstorming and I'm not an authority - but I have seen this in my head too many times to keep me from thinking it's not possible.
 
  • #33
A capacitor is more natural for catching the charge than an inductor.

Pretend you had a 10 KiloFarad capacitor that could survive being hit. If it
got hit by a 10 KiloAmp bolt that lasted one second, it would be charged
to one volt on it's terminals, since Q = CV.

The energy in such a capacitor would only be 1/2 C V*V = 5K Joules.

This shows that the enormous power in a bolt is the product of that
large current and the high voltage that it falls through which is millions
of volts.

"OK", you say. "I'll charge a 1 Farad capacitor instead. That will leave
me with a lot of Volts." In this case, the cap will get up to 10 KV.
Now the energy is 1/2 * 1 * 10K*10K = 50 MegaJoules. This is more like
it.


The rest is a matter of simple engineering to make a capacitor that will
not be destroyed when charged for one second with 50 Megawatts of
power. Simple. :eek:
 
  • #34
I didn't see any numbers so I thought maybe throw out these if my memory is correct. You get no more than a million amperes for a microsecond average and the voltage must be small enough so the lightning doesn't bypass your terminals, say ten million volts. Try engineering that. Remember that enormous voltages are available to blow your parts.
 
  • #35
well, maybe one could take a huge electricaly isolated tank of salty water (not very expencive), place a kind of lid that is able to move without much problem (like a piston), place the tank high, place a conducting material (cooper rod) in contact with the water which will be the “intake” from the lightning and another condicting material in contact to the water and ground.
when the lightning came it will break the water molecule by hydrolisys, which will produce a huge volume of gas (H2 and O2, apart), this gas will move the piston which will store it all (theoricaly). this gases can be then used to whatever and the product of combustion is oviouslly water, so it is clean.

sorry for my grammar, english is not my first language…
 
<h2>1. How can we capture energy from lightning?</h2><p>There are currently several proposed methods for capturing energy from lightning. One approach is to use tall towers with conductive materials to attract and channel the lightning into a storage device. Another method involves using a system of large kites with conductive wires to capture the electrical energy from the lightning. </p><h2>2. Is it safe to capture energy from lightning?</h2><p>While capturing energy from lightning can be potentially dangerous, there are safety measures that can be taken to minimize the risk. These include using proper grounding techniques and ensuring that the equipment used is able to withstand the high voltage of lightning strikes.</p><h2>3. What are the potential benefits of capturing energy from lightning?</h2><p>The main benefit of capturing energy from lightning is the potential for a renewable and sustainable source of electricity. Lightning strikes occur frequently and in many different locations, making it a reliable source of energy. Additionally, it does not rely on traditional fossil fuels, reducing carbon emissions and environmental impact.</p><h2>4. Are there any challenges to capturing energy from lightning?</h2><p>There are several challenges to capturing energy from lightning, including the unpredictability of lightning strikes and the high voltage and current associated with them. Additionally, the technology and infrastructure needed for capturing and storing the energy can be expensive and require specialized equipment.</p><h2>5. How much energy can be captured from lightning?</h2><p>The amount of energy that can be captured from lightning varies depending on factors such as the location and frequency of lightning strikes. However, it is estimated that a single lightning bolt can produce enough energy to power a typical household for a month.</p>

1. How can we capture energy from lightning?

There are currently several proposed methods for capturing energy from lightning. One approach is to use tall towers with conductive materials to attract and channel the lightning into a storage device. Another method involves using a system of large kites with conductive wires to capture the electrical energy from the lightning.

2. Is it safe to capture energy from lightning?

While capturing energy from lightning can be potentially dangerous, there are safety measures that can be taken to minimize the risk. These include using proper grounding techniques and ensuring that the equipment used is able to withstand the high voltage of lightning strikes.

3. What are the potential benefits of capturing energy from lightning?

The main benefit of capturing energy from lightning is the potential for a renewable and sustainable source of electricity. Lightning strikes occur frequently and in many different locations, making it a reliable source of energy. Additionally, it does not rely on traditional fossil fuels, reducing carbon emissions and environmental impact.

4. Are there any challenges to capturing energy from lightning?

There are several challenges to capturing energy from lightning, including the unpredictability of lightning strikes and the high voltage and current associated with them. Additionally, the technology and infrastructure needed for capturing and storing the energy can be expensive and require specialized equipment.

5. How much energy can be captured from lightning?

The amount of energy that can be captured from lightning varies depending on factors such as the location and frequency of lightning strikes. However, it is estimated that a single lightning bolt can produce enough energy to power a typical household for a month.

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