Which high voltage is more dangerous: AC, or DC, and why?

In summary: DC gives you only two shocks: one when you connect, and the other when you disconnect. While contact with AC may prevent you letting go, if the above is true then after getting a grip on DC I think muscle fatigue will set in and you'll be able to let go (but get a parting jolt as you do so).
  • #1
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I wish I had a plot of voltage on the X-axis and danger level on the Y-axis for AC and DC.

I was talking to an engineer at work, he was telling me that DC is more dangerous at high voltage. I said I disagreed with him but did not do into detail as to why I thought so. I did say that I've always heard that DC had a tendency to be more dangerous. His response was that "DC only goes through you once, whereas AC continuously goes back and forth and rattles the heart". I think that with a limited current the body would be seen as a high impedance, and above some current they are going to be equally lethal. I did not make any reference to frequency, so he may have figured I meant only 60Hz as we have supplied here.


My question is: which type of current is inherently more dangerous, and why?
 
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  • #2
Sorry I can't be of more help, but from what I understand if you have an AC supply that is, say, 120 volts, there might be certain times in it's cycle where the voltage may be higher than 120. That being said, AC seems more dangerous because you may be exposed to higher voltages than what you are told.

However, I think the more important thing to think about is what the internal resistance of the source is. At very low internal resistance, even a 12 volt power supply like a car battery can turn deadly (a DC source, but I'm sure the same applies to AC). Thomas Edison believed it to be more dangerous than DC, and AC was used to execute criminals in the late 1800s and early 1900s, although that was used as a smear campaign against Tesla; no idea if he was right.

On another note, very high frequency AC electricity will pass through the outermost layer of the skin (the so-called 'skin effect'), and not enter the vital parts of the body.
 
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  • #3
Edison pushed AC over DC for the electric chair because he was producing DC and did not want his system associated with it. High voltage, with sufficient current capacity is dangerous, AC , DC don't much matter
 
  • #4
Wiki said:
A domestic power supply voltage (110 or 230 V), 50 or 60 Hz alternating current (AC) through the chest for a fraction of a second may induce ventricular fibrillation at currents as low as 60 mA. With direct current (DC), 300 to 500 mA is required.[2]
http://en.wikipedia.org/wiki/Electric_shock#cite_note-whitaker-1

Also, if you were to hang at a very-high voltage AC transmission line, you could be dead, due to capacitive charging current through you.
In DC there is no such current.
 
  • #5
Consider voltages in the hundreds of volts. I'm not sure where I heard this, but I have the notion that while AC delivers a shock every time it changes (that would be twice per cycle), contact with DC gives you only two shocks: one when you connect, and the other when you disconnect. While contact with AC may prevent you letting go, if the above is true then after getting a grip on DC I think muscle fatigue will set in and you'll be able to let go (but get a parting jolt as you do so).

This is not to discount the heating effect of both (i.e., cooking effect), nor other associated dangers.

https://www.physicsforums.com/images/icons/icon2.gif [Broken]As they say, there is no safe level, whether AC or DC.
 
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  • #6
NascentOxygen said:
...contact with DC gives you only two shocks: one when you connect, and the other when you disconnect...

I suppose it depends on what you define 'shocks' as, but I certainly wouldn't say it the way you have put it.
 
  • #7
NascentOxygen said:
Consider voltages in the hundreds of volts. I'm not sure where I heard this, but I have the notion that while AC delivers a shock every time it changes (that would be twice per cycle), contact with DC gives you only two shocks: one when you connect, and the other when you disconnect. While contact with AC may prevent you letting go, if the above is true then after getting a grip on DC I think muscle fatigue will set in and you'll be able to let go (but get a parting jolt as you do so).

This is not to discount the heating effect of both (i.e., cooking effect), nor other associated dangers.

https://www.physicsforums.com/images/icons/icon2.gif [Broken]As they say, there is no safe level, whether AC or DC.

I'm pretty sure you are constantly being injured when you hold onto a high voltage DC line, not just upon contact and removing contact.

I don't know about the muscle grip thing though.
 
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  • #8
NascentOxygen said:
Consider voltages in the hundreds of volts. I'm not sure where I heard this, but I have the notion that while AC delivers a shock every time it changes (that would be twice per cycle), contact with DC gives you only two shocks: one when you connect, and the other when you disconnect.

Sorry, that is not correct.
 
  • #9
V=IR in either case.

Should the "I" exceed your body's limit in either case...you are dead...or best case...serverly burnt.

Also...what was said a month ago in a similar thread...that notion that AC has certain cylces and this and that is rubbish. Our body clocks and the clock of an AC sin wave have nothing in common. Also, RMS value of AC is all that matters in my opinion.
 
  • #10
Let's look at this mathematically.

Say we have a 120 volt battery with a body resitance of 2000 ohms.

This produces a current of .06 amps and a power of 7.2 watts.

Now let's take a wall receptacle with 120 volts RMS.

This also produces a current of .06 amps RMS and 7.2 watts

7.2 watts = 7.2 watts.

Watts are not available in RMS last time I checked. Watts...are watts.
 
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  • #11
psparky said:
V=IR in either case.

Should the "I" exceed your body's limit in either case...you are dead...or best case...serverly burnt.

Also...what was said a month ago in a similar thread...that notion that AC has certain cylces and this and that is rubbish. Our body clocks and the clock of an AC sin wave have nothing in common. Also, RMS value of AC is all that matters in my opinion.

You're right about the RMS AC value determining how much damage you take, but doesn't muscle respond to electrical signals differently based on the signal characteristics?

I would think that either AC or DC current would sort of saturate the muscles/nerves ion channels (just a guess), such that they are unresponsive, but I would guess that the right amplitude and frequency could cause the muscles to behave in a unique way.
 
  • #12
psparky said:
Let's look at this mathematically.

Say we have a 120 volt battery with a body resitance of 2000 ohms.

This produces a current of .06 amps and a power of 7.2 watts.

Now let's take a wall receptacle with 120 volts RMS.

This also produces a current of .06 amps RMS and 7.2 watts

7.2 watts = 7.2 watts.

Watts are not available in RMS last time I checked. Watts...are watts.

Perhaps skin moisture and other body properties have different capacitances such that their impedance is not 2000 ohms across all frequencies.

Also, does dielectric breakdown depend on if the field is AC or DC? Because I know that the skin layer breaks down once a voltage threshold is reached, and then the impedance drastically reduces and causes much more harm.
 
  • #13
I was a;ways taught that DC was more dangerous because if you caught it on the palm of your hand you would clamp on, but with AC your muscles would spasm and you'd let go of the cable.
 
  • #14
It's amazing to hear all the theories...as no one seems to have concrete proof. I think I could give a contradiction to every one of the points above...including my own!

Perhaps all the details given above only matter if you are at the threshold of electricution...around the .1 amp or whatever it is. This seems to be typcially in the 120 volt range. But at 480 volts AC or DC...if you are in the wrong place at the wrong time...you dead...Fred.

Perhaps someone should do a simulation to put this to rest once and for all...(and when I say this...I am joking...DO NOT TRY THIS AT HOME...you will likely die!)

But...lets say someone really had to know the difference. If they had a death wish...they could plug two wires into a 120 volt receptacle and hold on for 3 seconds and let go...record how they felt.

Then for DC...they could hook up 10 twelve volt car batteries in series...hold on to the wires for 3 seconds as well...and then record how they felt. Assuming they could let go...maybe they couldn't!

If someone were insane enough to do this...a spotter near by would be recommended to disconnect the wire in the case you couldn't let go after 3 seconds.

Have both set ups in place as well during experiment...so your body would have exact same moisture in it and on your hands.

Again...do not try this because you will likely die. But it's a cool thought I think.
 
  • #15
psparky said:
It's amazing to hear all the theories...as no one seems to have concrete proof. I think I could give a contradiction to every one of the points above...including my own!

Perhaps all the details given above only matter if you are at the threhold of electricution...around the .1 amp or whatever it is. This seems to be typcially in the 120 volt range. But at 480 volts AC or DC...if you are in the wrong place at the wrong time...you dead...Fred.

Perhaps someone should do a simulation to put this to rest once and for all...(and when I say this...I am joking...DO NOT TRY THIS AT HOME...you will likely die!)

But...lets say someone really had to know the difference. If they had a death wish...they could plug two wires into a 120 volt receptacle and hold on for 3 seconds and let go...record how they felt.

Then for DC...they could hook up 10 twelve volt car batteries in series...hold on to the wires for 3 seconds as well...and then record how they felt.

If someone were insane enough to do this...a spotter near by would be recommended to disconnect the wire in the case you couldn't let go after 3 seconds.

Have both set ups in place as well during experiment...so your body would have exact same moisture in it and on your hands.

Again...do not try this because you will likely die. But it's a cool thought I think.

I think we need a bioengineer or neuroscientist who understands both biological effects and electrical effects to give the full story.

Other than that, I think its clear that high voltage at any frequency is dangerous when it can put enough current through your body. There are a lot of variables that determine how dangerous electrical shock is to a person more than just frequency. Just one example, if the potential is between your left hand and your right foot, you will have a much higher chance of dying than if the potential is between your right thumb and right index finger.

And having seen books from the 1950s and 1960s on experiments done with radiation and other health hazards, I'm pretty sure there are already studies that give data on what conditions are dangerous and lethal.
 
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  • #16
NascentOxygen said:
Consider voltages in the hundreds of volts. I'm not sure where I heard this, but I have the notion that while AC delivers a shock every time it changes (that would be twice per cycle), contact with DC gives you only two shocks: one when you connect, and the other when you disconnect.
berkeman said:
Sorry, that is not correct.
I speak from experience on the AC description. I haven't experienced a shock from DC (touch wood) so cannot vouch for that.
 
  • #17
psparky said:
Say we have a 120 volt battery with a body resitance of 2000 ohms.
It depends on what one understands by "dangerous". The OP never said full body conduction, nor to limiting interest to the extent of heating to the point of cooking.

Most deaths from contact with electricity are due to disturbance of the heart rhythm, not organ overheating. Contact can be fleeting and injury only superficial, but unless the heart is returned to an effective beat, death is inevitable.

Some initial trials using electrocution as capital punishment were particular gruesome, some tests reported insufficient voltage, some clearly way too much current.
 
  • #18
I've felt both 130VDC and 120 VAC with my fingertips many times.

They both "tingle". I cannot tell one from the other. Do not try it.

Regarding "unable to let go", either will cause that effect.
Old timey electricians routinely brush a circuit with the back of their hand before touching it. That's to verify it is truly de-energized. They use backof hand so that contracting muscles will naturally pull their fingers away not lock them around it.
They will use a fingertip to test a circuit for voltage, but old electricians usually have the strong, callused hands of a workingman so their skin is tougher than average folks.

Anybody know of a study on the neurological effects? I was unable to find one.
 
  • #19
jim hardy said:
I've felt both 130VDC and 120 VAC with my fingertips many times.

They both "tingle". I cannot tell one from the other.
But was that smooth DC, or just rectified AC?
Do not try it.
I don't intend to!
Regarding "unable to let go", either will cause that effect.
Old timey electricians routinely brush a circuit with the back of their hand before touching it.
The same way as those on the land test an electric stock fence before climbing through, and not just once, either, especially in the face of reassurance that it really truly honestly is "OFF". :biggrin:
 
  • #20
NascentOxygen said:
I speak from experience on the AC description. I haven't experienced a shock from DC (touch wood) so cannot vouch for that.

Not sure what kind of experience you are talking about. All you learn from getting shocked is, not to do that again.

I would expect damage/pain from an AC source would be very similar to its RMS equivelent in DC.

BTW, just for the record, I once took 500V DC through about a cm of my little finger. Quite painfull and left a burn. I have also taken a few 120VAC shocks, with nothing other then pain as a reminder.
 
  • #21
Artificially induced fluctuations in nerve potentials can cause them to fire at the wrong time. Both alternating and direct current sources can cause arrhythmia and subsequent cardiac arrest. I wouldn't say either one is safer in that regard. Just in general, high voltage is high voltage. Once you get to the point where you're putting a certain amount of energy into tissue, you get damage.

The safety of AC or DC depends more on ensuring that shocks don't happen in the first place, and there are various ways to accomplish that in either case. In the end, it's all about ensuring that you do not experience a potential gradient over your body.

Suggesting that either AC or DC provides an innate advantage in safety is a naive argument at best. We have Thomas Edison to blame for this. Don't trust anyone who would electrocute an elephant to make a buck.
 
  • #22
I remember reading that while in terms of energy delivered they are not different (burns are basically the same), several times smaller AC current can kill someone for the reason already mentioned - it induces ventricular fibrillation.

Edit: ventricular fibrillation can be induced by 60 mA AC and 200-300 mA DC. See http://hypertextbook.com/facts/2000/JackHsu.shtml. No idea how reliable this source is.
 
  • #23
I just listened to a 4 hour seminar yesterday on arc flash...and how when it happens it essentially just like a bomb.

Just like a bomb...an arc flash has a sonic boom, massive heat and flying metal parts. Any one of them can kill you in a second even if you are in full protective gear.

The boom alone can shatter ribs and destroy organs, or blast you back into a lethal sharp object...the heat can melt your skin and give your 3rd degrees burns over more than half your body in a split second...which pretty much means your dead soon...and flying metal parts can give lethal puncture wounds.

Ac or Dc it will not matter. And I didn't even mention being shocked.

Protective suits do a pretty good job with the fire aspect of protecting your skin...but the force of the boom and lethal flying objects it can not protect you from.

Which brings me to the left hand rule. Most disconnect switches and so forth have their handle on the right hand side of the box. Instead of standing right in front of it when you open it up...use your left hand instead and put your body out of harms way. If something does go wrong...you will likely be much safer. If you open it with your right hand...it's like someone pointing a gun directly at you. If you open with left hand...not so much.

And obviously, you need to be trained and certified before opening any higher voltage box...but even in your residential boxes and disconnects...better safe than sorry.

And incidentally, it is against the law to get shocked. There is no reason you should be working on any energized parts. The reason I say that...is that if you destroy someone's equipment...a lawyer will be asking you why a particular device was energized...and you won't have a leg to stand on. Possibly literally. Strangely, there is one exception. If you can prove that a device is more dangerous when de-energized...this is the only case. Funny, I know.
 
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  • #24
I just listened to a 4 hour seminar yesterday on arc flash...and how when it happens it essentially just like a bomb.

If you've never seen the result of a switchgear explosion, well it's like a bomb went off. Everything is blown apart, steel is deformed and covered with black soot. I remember vividly an incandescent light bulb that had been heated to point the glass softened and it deformed into something worthy of Salvador Dali.

I always told new employees "Copper vapor follows the same gas laws as dynamite vapor. It expands according to the available energy. Don't ever roll those dice. "
 
  • #25
First Question - Why are you asking? OSHA basically regulates all power systems with voltages over 50 V as hazardous. There are too many other variables in human safety ( Connection Points, Skin Resistance, total energy of the source, etc) to really make it worth worrying about AC vs DC.
Did you know that falls from ladders and elevated points are the most common injury to electricians - the shock makes them fall. DC / AC doesn't matter.
 
  • #26
How electronic DC current could be dangerous to humans?Human body suppose to exhibit ionic conductivity only?Salts do not conduct electrons...
 
  • #27
Back in 1979, I was a summer intern at a division of GM while I was a graduate student. I worked in advanced engineering (R&D). I was working on a lab bench. The edge of the bench top nearest me had a metal strip. I did not realize at first that this strip was grounded (earthed). I was placing a probe on a 115V 60 Hz live wire when my hand slipped. My finger contacted the live 115V rms ac mains, with my elbow contacting the grounded metal strip at the edge of the bench top.

I felt the shock from my finger to my elbow. That section of my arm gave me a pulsating sensation. I could literally feel the 60 Hz frequency. I was able to let go. Maybe the muscles in the forearm were still functional, or maybe the other muscles beyond the elbow gave me the ability to let go.

It was frightening. For a couple of hours I felt an adrenaline rush, and could not think of anything else. I've never been shocked by dc so I cannot make a comparison. But I definitely felt the 60 Hz line frequency.

Frankly I don't mess with either. They both scare me.

Claude
 
  • #28
High voltage is dangerous and costly.

instant-death-200-fine-445x299.jpg
 

1. Which type of voltage, AC or DC, is more commonly used in households?

AC (alternating current) is the type of voltage that is commonly used in households. This is because AC is able to be easily transformed to different voltage levels, making it more efficient for long-distance transmission and distribution.

2. Is AC or DC more dangerous to the human body?

In general, AC is considered to be more dangerous to the human body than DC (direct current). This is because AC can cause muscle contractions, making it more likely for someone to be unable to let go of an electrical source. DC, on the other hand, can cause a single muscle contraction, making it easier to release the electrical source.

3. Why is AC more likely to cause electrocution than DC?

AC is more likely to cause electrocution because it can cause the muscles to contract and release multiple times in a short period of time, making it difficult for someone to let go of an electrical source. DC, on the other hand, only causes a single muscle contraction, making it easier to release the source of electricity.

4. Are there any situations where DC may be more dangerous than AC?

Yes, in some cases, DC can be more dangerous than AC. This is because DC can cause a continuous flow of electricity, which can lead to tissue damage and nerve damage. In contrast, AC causes the muscles to contract and release, which can help prevent tissue damage.

5. Which type of voltage, AC or DC, is used in high-voltage power lines?

High-voltage power lines typically use AC (alternating current) for transmission. This is because AC can be easily transformed to different voltage levels, making it more efficient for long-distance transmission and distribution. However, DC is becoming more commonly used in high-voltage power lines due to advancements in technology and the ability to convert DC to higher voltage levels.

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