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Posted

This is a question about variables having to do with force on a current.

I need correction in my understanding, I don't get the difference when a current is in a wire vs not. 

I have drawn out a scenario, the contraption I drew consists of 5 parts. The positive wire (red), it's insolation with exposure at one end (black), the connecting structure (green), the negative pole(blue), and a power source (inside green).

In this scenario, the positive wire's exposed end is 1mm from the closest end of the negative blue wire. 

The electric field applied is over 3kv to exploit thermionic emission, and induce a spark. If the current was to increase during thermionic emission, would the changing magnetic field push all current away from the center of the current loop?Sketch_20200808_205618.thumb.png.111b2dad3c1adef06755b47bc6afcb18.png

Posted

Force on a current is from an external field. You have not identified such a field.  

 

  On 8/9/2020 at 4:14 AM, DandelionTheory said:

This is a question about variables having to do with force on a current.

I need correction in my understanding, I don't get the difference when a current is in a wire vs not. 

I have drawn out a scenario, the contraption I drew consists of 5 parts. The positive wire (red), it's insolation with exposure at one end (black), the connecting structure (green), the negative pole(blue), and a power source (inside green).

In this scenario, the positive wire's exposed end is 1mm from the closest end of the negative blue wire. 

The electric field applied is over 3kv to exploit thermionic emission, and induce a spark. If the current was to increase during thermionic emission, would the changing magnetic field push all current away from the center of the current loop?Sketch_20200808_205618.thumb.png.111b2dad3c1adef06755b47bc6afcb18.png

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“connecting structure” and “power source”?

Nothing here is a current in a wire.

Posted
  On 8/9/2020 at 3:16 PM, swansont said:

Force on a current is from an external field. You have not identified such a field.  

 

“connecting structure” and “power source”?

Nothing here is a current in a wire.

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I said 

"In this scenario, the positive wire's exposed end is 1mm from the closest end of the negative blue wire. 

The electric field applied is over 3kv to exploit thermionic emission, and induce a spark."

As a physicist, what additional information is required for the scenario to be understood? I do not see external fields on rail guns.

Posted
  On 8/9/2020 at 4:14 AM, DandelionTheory said:

In this scenario, the positive wire's exposed end is 1mm from the closest end of the negative blue wire.

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What gives the red wire a positive charge? It doesn't appear to be connect anything. Or is it supposed to be connected to the green (power source?) through the insulator?

  On 8/9/2020 at 4:14 AM, DandelionTheory said:

The electric field applied is over 3kv to exploit thermionic emission, and induce a spark.

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Where are you expecting the spark to occur? Between the points you have labelled "+" and "-"?

And why do you want a spark at all? Why not just complete the circuit with a wire?

  On 8/9/2020 at 4:14 AM, DandelionTheory said:

If the current was to increase during thermionic emission, would the changing magnetic field push all current away from the center of the current loop?

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I don't think the magnetic field caused by the current will affect the wire carrying that current. But it would affect another, nearby, current-carrying wire.

This is still pretty crude, but is this why you are trying to represent?

Untitled.png.ef3c2d822c7383d3e7736a531f15629d.png

Posted
  On 8/9/2020 at 10:15 PM, DandelionTheory said:

I said 

"In this scenario, the positive wire's exposed end is 1mm from the closest end of the negative blue wire. 

The electric field applied is over 3kv to exploit thermionic emission, and induce a spark."

As a physicist, what additional information is required for the scenario to be understood? I do not see external fields on rail guns.

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A lot.

You refer to “the connecting structure (green)” and “a power source (inside green)” which is where the spark should occur. I asked about them, and you haven’t clarified anything

Thermionic emission comes from a high temperature, not a potential difference

 

  Quote

I do not see external fields on rail guns.

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No? There’s no electric or magnetic field? How do they work?

 

Posted (edited)
  On 8/9/2020 at 11:25 PM, swansont said:

A lot.

You refer to “the connecting structure (green)” and “a power source (inside green)” which is where the spark should occur. I asked about them, and you haven’t clarified anything

Thermionic emission comes from a high temperature, not a potential difference

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616910345_Capture_2020-08-09-16-54-47.thumb.png.91c44e2c0ada9da6a60e38e32a395615.png

  Quote

No? There’s no electric or magnetic field? How do they work?

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The current in each rail acts on the armature and the opposite rail. The circuit is completed by the armature in a rail gun. in the scenario I presented, the thermionic emission, aka electric arc, substitutes the armature. This would complete the circuit right?

  On 8/9/2020 at 10:30 PM, Strange said:

 

This is still pretty crude, but is this why you are trying to represent?

Untitled.png.ef3c2d822c7383d3e7736a531f15629d.png

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Arc and wires would move perpendicular to magnetic field. Rail guns work this way, if the current is in flux over time. When the arc reaches a point past the bounds of the box, the wires have moved while the arc can return to the battery. I would assume this can be repeated. The original scenario had the wires bent away from each other because I assumed the arc would take the shortest path and would be forced downward away from the center of the current loop while the current in the wires would be forced away from the center of the current loop at each given slice of time.

Edited by DandelionTheory
Posted
  On 8/9/2020 at 11:59 PM, DandelionTheory said:

Arc and wires would move perpendicular to magnetic field. Rail guns work this way, if the current is in flux over time.

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The rails could push each other apart, and the two rails can push on the projectile. But I'm not sure how or if that applies to a single wire.

  On 8/9/2020 at 11:59 PM, DandelionTheory said:

When the arc reaches a point past the bounds of the box

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Where is the box? It doesn't appear in your diagram.

  On 8/9/2020 at 11:59 PM, DandelionTheory said:

the wires have moved while the arc can return to the battery

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If the wires move apart then you may not be able to support the arc (depending on voltage, available current, humidity and many other factors) and so the circuit would break.

  On 8/9/2020 at 11:59 PM, DandelionTheory said:

The original scenario had the wires bent away from each other because I assumed the arc would take the shortest path and would be forced downward away from the center of the current loop while the current in the wires would be forced away from the center of the current loop at each given slice of time.

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The arc will take the shortest path, which is a straight line. This seems inconsistent with your "forced downward". You need to calculate the strength of the magnetic field generated by the wires and see if it is enough to displace the path of the electrons. (I am guessing not, based purely on the size of the coils and magnets in old CRT tubes)

The current in the wires would remain in the wires, it can't be "forced" anywhere. Do you mean the wires would be deflected by the magnetic field generated by the spark? Any such effect would be tiny. But it depends on how the wires fixed, their stiffness, the current involved, etc.

 

I think this is all too vague (and confusing; you keep introducing new things when answering questions) to make any useful conclusions. You need to be more specific about the voltage, current, length of the wire and their mechanical properties, air pressure, temperature, relative humidity, 

Posted
  On 8/9/2020 at 11:59 PM, DandelionTheory said:

616910345_Capture_2020-08-09-16-54-47.thumb.png.91c44e2c0ada9da6a60e38e32a395615.png

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That's Schottky emission, which is a combination of thermal effects and a voltage

There's nothing to prevent you from putting a voltage on this, but that basic description of thermionic emission refers to having the thermal energy exceed the work function. IOW, saying it's an arc discharge is fine (that covers both effects), but specifying that it's thermionic emission is misleading. 

https://en.wikipedia.org/wiki/Thermionic_emission

 

  14 hours ago, DandelionTheory said:

 

The current in each rail acts on the armature and the opposite rail. The circuit is completed by the armature in a rail gun. in the scenario I presented, the thermionic emission, aka electric arc, substitutes the armature. This would complete the circuit right?

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And that gives you a field.

 

  14 hours ago, DandelionTheory said:

Arc and wires would move perpendicular to magnetic field.

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What magnetic field? You didn't specify one.

 

 

Posted (edited)
  On 8/10/2020 at 11:24 AM, Strange said:

The rails could push each other apart, and the two rails can push on the projectile. But I'm not sure how or if that applies to a single wire.

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In the original scenario, the wires are bent away from each other; up is also a direction the wires are forced.

  On 8/10/2020 at 11:24 AM, Strange said:

Where is the box? It doesn't appear in your diagram.

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This was in reference to the picture strange posted.

  On 8/10/2020 at 11:24 AM, Strange said:

If the wires move apart then you may not be able to support the arc (depending on voltage, available current, humidity and many other factors) and so the circuit would break.

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Agreed. The initial spark is a factor of humidity, voltage, atmosphere pressure, dielectric breakdown, and some more. From what I've learned about Jacobs ladder papers, the current supplied maintains the arc.

  On 8/10/2020 at 11:24 AM, Strange said:

The arc will take the shortest path, which is a straight line. This seems inconsistent with your "forced downward". You need to calculate the strength of the magnetic field generated by the wires and see if it is enough to displace the path of the electrons.

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Perfect. That's the answer. But "forced away from the center of the current loop" is more specific.

If the initial arc is at shortest path, maintain arc with increased current, which increases magnetic field and displaces arc and current in wires. When arc's contact with the ground wire reaches the length of the ground wire, disengage current supplied and calculate total displacement.

I cannot assume further if this isn't agreed upon as the intent of the op.

Edited by DandelionTheory
Posted
  On 8/12/2020 at 3:29 AM, DandelionTheory said:
  On 8/10/2020 at 11:24 AM, Strange said:

Where is the box? It doesn't appear in your diagram.

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This was in reference to the picture strange posted.

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There is no box in my diagram, either! 🙂

  On 8/12/2020 at 3:29 AM, DandelionTheory said:

Agreed. The initial spark is a factor of humidity, voltage, atmosphere pressure, dielectric breakdown, and some more. From what I've learned about Jacobs ladder papers, the current supplied maintains the arc.

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But if you increase the gap, you will rapidly stop the spark. Unless you keep increasing the voltage. (Operating at a lower pressure might help.)

  On 8/12/2020 at 3:29 AM, DandelionTheory said:

Perfect. That's the answer. But "forced away from the center of the current loop" is more specific.

If the initial arc is at shortest path, maintain arc with increased current, which increases magnetic field and displaces arc and current in wires. When arc's contact with the ground wire reaches the length of the ground wire, disengage current supplied and calculate total displacement.

Expand  

If you force the electrons to take a longer path in the arc, then you will need even higher voltage to maintain the arc.

This does not necessarily mean that the current will increase. Calculating the resistivity of a plasma is extremely complicated. I suspect (but I really don't know) that the current would be roughly constant if you increase both the voltage and the spark gap.

  On 8/12/2020 at 3:29 AM, DandelionTheory said:

In the original scenario, the wires are bent away from each other

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If they are at 90º (as it seems from your diagram) then the force between them will be zero.

(And, generalising from that, I *think* the net force within a closed loop will be zero -- but my math skills aren't up to proving that, or I don't have time, at least!)

Posted (edited)
  On 8/12/2020 at 7:28 AM, Strange said:

There is no box in my diagram, either! 

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Oh, haha. 

  On 8/12/2020 at 7:28 AM, Strange said:

If you force the electrons to take a longer path in the arc, then you will need even higher voltage to maintain the arc.

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That too.

  On 8/12/2020 at 7:28 AM, Strange said:

This does not necessarily mean that the current will increase. Calculating the resistivity of a plasma is extremely complicated. I suspect (but I really don't know) that the current would be roughly constant if you increase both the voltage and the spark gap.

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I'm not calculating current increase, the question is: does the magnetic field increase due to current increase maintaining the spark gap, and does that additional current increase in the spark gap translate to force on the wires?

I'm heavily leaning on current due to this 

1545751676_Capture_2020-08-10-06-27-23.thumb.png.8b9cf3b5e2f9f5ae65920d7fae70453a.png

Edited by DandelionTheory
Posted
  On 8/12/2020 at 11:56 PM, DandelionTheory said:

I'm not calculating current increase, the question is: does the magnetic field increase due to current increase maintaining the spark gap, and does that additional current increase in the spark gap translate to force on the wires?

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You need to increase the voltage to maintain the arc. That will not necessarily increase the current.

You may need to increase the voltage further to increase the current. 

How the current relates to voltage and size of gap is beyond me.

And what force this might generate is beyond me too.

  On 8/12/2020 at 11:56 PM, DandelionTheory said:

I'm heavily leaning on current due to this 

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Can you provide the source?

Posted
  On 8/13/2020 at 8:31 AM, Strange said:

Can you provide the source?

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I found it through Google search:

https://www.google.com/url?sa=t&source=web&rct=j&url=https://web5.uottawa.ca/www10/every_2012/document/20120404083003001.pdf&ved=2ahUKEwi7muHPhpjrAhXkLX0KHY5QCyoQFjAfegQIBxAB&usg=AOvVaw3_RHdoHQ4dwiVhXQq_5FB9

  On 8/13/2020 at 8:31 AM, Strange said:

You need to increase the voltage to maintain the arc. That will not necessarily increase the current.

You may need to increase the voltage further to increase the current.

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Thank you.

  On 8/13/2020 at 8:31 AM, Strange said:

And what force this might generate is beyond me too

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Do you know what direction I would need to go to find that out? 

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