Difference between revisions of "Element:TNT"
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{{ infobox Element | {{ infobox Element | ||
| icon = TNT.png | | icon = TNT.png | ||
| − | | longname = | + | | longname = Trinitrotoluene |
| image = | | image = | ||
| Line 38: | Line 38: | ||
==Creation== | ==Creation== | ||
| − | + | * Spawning by brush. | |
| − | + | * Mixing [[Element:CLST|Clay Dust (CLST)]] and [[Element:NITR|Nitroglycerin (NITR)]] | |
| + | |||
==Properties== | ==Properties== | ||
| − | Trinitrotoluene (abbreviated TNT) is a relatively hot burning pressure explosive. | + | Trinitrotoluene (abbreviated TNT) is a relatively hot burning pressure explosive. When it explodes, TNT forms [[Element:FIRE|Fire (FIRE)]] (16.6%), [[Element:SMKE|Smoke (SMKE)]] (16.6%) and [[Element:EMBR|Ember / Sparks (EMBR)]] (4.4%) for effect.<br> |
| + | Upon detonation, most of the TNT is removed (62.16%) without creating any particles. | ||
| + | |||
| + | When detonated, each particle of TNT adds 0.5 pressure to the cell it occupied.<br> | ||
| + | Then, depending on which particle was generated (if any at all), temperatures rise by 2226.6 degrees (Fire and Smoke particles) or 3059.85 degrees. (Embers/Sparks) | ||
| + | |||
| + | However, directly after the reaction the mean temperature rise is only 1409 degrees. This is mainly due to temperature being dissipated into the surrounding particles during the reaction.<br> Since 62.16% of the TNT is destroyed, only 37.84% of the temperature generated will remain after detonation and the other is lost to the void. | ||
| + | |||
| + | Depending on the [[Element_conductivities|conductivity]] of elements in contact with the TNT, more or less heat will be transferred to that element. A higher heat conductivity means a lower temperature overall after detonation. | ||
| + | |||
| + | Upon ignition, the smoke is almost instantaneously converted into Fire (351.85 °C) because of the surrounding heat.<br> | ||
| + | Also, due to the high temperatures, some Fire will be converted into [[Element:PLSM|Plasma (PLSM)]]. (2499.85 °C) | ||
| + | |||
==Uses and applications== | ==Uses and applications== | ||
| − | Bombs, demolition simulations | + | Bombs, demolition simulations, conventional pyrotechnics |
[[Category:Elements]] | [[Category:Elements]] | ||
[[Category:Explosives]] | [[Category:Explosives]] | ||
Revision as of 23:27, 3 May 2013
| Properties | |
|---|---|
| Section | unknown Expression error: Unrecognized punctuation character "{". |
| Spawn temperature | 22°C |
| Heat Conductivity | 35.2% |
| Relative weight | 100 |
| Gravity | 0.00 |
| Acid dissolve rate | 0.1% |
| Flammability | 0 |
| State | Solid |
| Source code | |
Creation
- Spawning by brush.
- Mixing Clay Dust (CLST) and Nitroglycerin (NITR)
Properties
Trinitrotoluene (abbreviated TNT) is a relatively hot burning pressure explosive. When it explodes, TNT forms Fire (FIRE) (16.6%), Smoke (SMKE) (16.6%) and Ember / Sparks (EMBR) (4.4%) for effect.
Upon detonation, most of the TNT is removed (62.16%) without creating any particles.
When detonated, each particle of TNT adds 0.5 pressure to the cell it occupied.
Then, depending on which particle was generated (if any at all), temperatures rise by 2226.6 degrees (Fire and Smoke particles) or 3059.85 degrees. (Embers/Sparks)
However, directly after the reaction the mean temperature rise is only 1409 degrees. This is mainly due to temperature being dissipated into the surrounding particles during the reaction.
Since 62.16% of the TNT is destroyed, only 37.84% of the temperature generated will remain after detonation and the other is lost to the void.
Depending on the conductivity of elements in contact with the TNT, more or less heat will be transferred to that element. A higher heat conductivity means a lower temperature overall after detonation.
Upon ignition, the smoke is almost instantaneously converted into Fire (351.85 °C) because of the surrounding heat.
Also, due to the high temperatures, some Fire will be converted into Plasma (PLSM). (2499.85 °C)
Uses and applications
Bombs, demolition simulations, conventional pyrotechnics
