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Heat pipe: Difference between revisions

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{{:Infobox:Heat pipe}}
{{:Infobox:Heat pipe}}


The '''heat pipe''' can transport heat over longer distances and connect devices which produce and use heat. Currently this is limited to [[heat exchanger]]s and [[nuclear reactor]]s.
The '''heat pipe''' can transport heat over longer distances and connect devices which produce and use heat. Currently, this is limited to [[heat exchanger]]s, [[nuclear reactor]]s, and [[heating tower]]s{{SA}}.


Heat pipes have a heat capacity of 1 MJ/°C. Thus, they can theoretically buffer 500 MJ of heat energy across their working range of 500°C to 1000°C, making them a space-efficient energy store. However, because temperature needs a drop of greater than 1 degree before it will "flow," you can't raise them all the way to 1000°C or drain them all the way to 500°C, so the practical energy capacity will depend on the layout.
Heat pipes have a heat capacity of 1 MJ/°C. Thus, they can theoretically buffer 500 MJ of heat energy across their working range of 500°C to 1000°C, making them a space-efficient energy store. However, because temperature needs a drop of greater than 1 degree before it will "flow," you can't raise them all the way to 1000°C or drain them all the way to 500°C, so the practical energy capacity will depend on the layout.


As heat pipes rise in temperature, they will give off a very low-distance glow.
As heat pipes rise in temperature, they will give off a very low-distance glow. On the planet [[Aquilo]]{{SA}}, heat pipes are a necessity due to the freezing temperatures, as buildings will freeze over and stop working if high temperature heat pipes are not near them.


== Heat pipe throughput ==
== Heat pipe throughput ==
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For any heat pipe entity with one input connection on one side and one output connection on another, this entity with lower the temperature by <code>1 + (P / 15) °C</code> with P being the power going through this entity expressed in MW.
For any heat pipe entity with one input connection on one side and one output connection on another, this entity with lower the temperature by <code>1 + (P / 15) °C</code> with P being the power going through this entity expressed in MW.


Since a nuclear power plant can have at most 500°C difference between the hottest (a [[nuclear reactor]]) and coldest (a [[heat exchanger]]) points of the system, that means that we can express the maximum length of a straight line of heat pipe as <code>500 / (1 + P/15)</code>.
Since a nuclear power plant can have at most 500°C difference between the hottest (a nuclear reactor) and coldest (a heat exchanger) points of the system, that means that we can express the maximum length of a straight line of heat pipe as <code>500 / (1 + P/15)</code>.


For example let's take a single [[nuclear reactor]] outputting 40MW of heat power to a single line of heat pipes. The furthest that line can go is <code>500 / (1 + 40/15)</code> which is around 136 heat pipes long.
For example let's take a single nuclear reactor outputting 40MW of heat power to a single line of heat pipes. The furthest that line can go is <code>500 / (1 + 40/15)</code> which is around 136 heat pipes long.


 
A nuclear reactor can also be used to transfer heat in a similar manner as a heat pipe, whether or not it's fueled. In this case, the reactor will drop the temperature by <code>1 + (P / 387) °C</code>, with P again being the power in MW going through the entity. Note that this is an approximation, the actual value measured is supposed to be 200000/517 or about 386.847.
An unfueled nuclear reactor can also be used as a heat pipe. In this case, the reactor will drop the temperature by <code>1 + (P / 387) °C</code>, with P again being the power in MW going through the entity. Note that this is an approximation, the actual value measured is supposed to be 200000/517 or about 386.847.


That being said, the nuclear reactor entity is also much bigger, meaning that we must compare it to 5 lines of 5 heat pipes instead of just a single one. The nuclear reactor will thus lower the temperature 5 times less with near-zero power going through it, and nearly 26 times less when approaching infinite power, compared to those lines of heat pipes.
That being said, the nuclear reactor entity is also much bigger, meaning that we must compare it to 5 lines of 5 heat pipes instead of just a single one. The nuclear reactor will thus lower the temperature 5 times less with near-zero power going through it, and nearly 26 times less when approaching infinite power, compared to those lines of heat pipes.
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== See also ==
== See also ==
* [[Power production#Nuclear power|Power production]]
* [[Power production#Nuclear power|Power production]]
* [[Heating tower]]{{SA}}
* [[Heat exchanger]]
* [[Heat exchanger]]



Latest revision as of 06:59, 27 October 2024

Heat pipe.png
Heat pipe

Heat pipe anim.gif

Recipe

Time.png
1
+
Copper plate.png
20
+
Steel plate.png
10
Heat pipe.png
1

Total raw

Time.png
1
+
Copper plate.png
20
+
Steel plate.png
10

Map color

Health

Quality normal.png 200
Quality uncommon.png 260 Quality rare.png 320
Quality epic.png 380 Quality legendary.png 500

Resistances

Explosion: 0/30%
Fire: 0/90%
Impact: 0/30%

Stack size

50

Dimensions

1×1

Maximum temperature

1000 °C

Mining time

0.1

Prototype type

heat-pipe

Internal name

heat-pipe

Required technologies

Nuclear power (research).png

Produced by

Assembling machine 1.png
Assembling machine 2.png
Assembling machine 3.png
Player.png

The heat pipe can transport heat over longer distances and connect devices which produce and use heat. Currently, this is limited to heat exchangers, nuclear reactors, and heating towers.

Heat pipes have a heat capacity of 1 MJ/°C. Thus, they can theoretically buffer 500 MJ of heat energy across their working range of 500°C to 1000°C, making them a space-efficient energy store. However, because temperature needs a drop of greater than 1 degree before it will "flow," you can't raise them all the way to 1000°C or drain them all the way to 500°C, so the practical energy capacity will depend on the layout.

As heat pipes rise in temperature, they will give off a very low-distance glow. On the planet Aquilo, heat pipes are a necessity due to the freezing temperatures, as buildings will freeze over and stop working if high temperature heat pipes are not near them.

Heat pipe throughput

Heat pipes are acting very similarly to fluid pipes: they each hold an amount of heat energy and there is a limit to how much energy can go through each of them for a given duration.

For any heat pipe entity with one input connection on one side and one output connection on another, this entity with lower the temperature by 1 + (P / 15) °C with P being the power going through this entity expressed in MW.

Since a nuclear power plant can have at most 500°C difference between the hottest (a nuclear reactor) and coldest (a heat exchanger) points of the system, that means that we can express the maximum length of a straight line of heat pipe as 500 / (1 + P/15).

For example let's take a single nuclear reactor outputting 40MW of heat power to a single line of heat pipes. The furthest that line can go is 500 / (1 + 40/15) which is around 136 heat pipes long.

A nuclear reactor can also be used to transfer heat in a similar manner as a heat pipe, whether or not it's fueled. In this case, the reactor will drop the temperature by 1 + (P / 387) °C, with P again being the power in MW going through the entity. Note that this is an approximation, the actual value measured is supposed to be 200000/517 or about 386.847.

That being said, the nuclear reactor entity is also much bigger, meaning that we must compare it to 5 lines of 5 heat pipes instead of just a single one. The nuclear reactor will thus lower the temperature 5 times less with near-zero power going through it, and nearly 26 times less when approaching infinite power, compared to those lines of heat pipes.

As an example, a single line of 100 nuclear reactors (or 500 tiles) will only lower the temperature by about 360°C while carrying 1GW.

History

  • 0.17.67:
    • Heat pipes (also in reactors and heat exchangers) glow with high temperatures.
  • 0.15.11:
    • Changed heat transfer mechanics, prior to this heat would flow better following the order of heat pipe placement

See also