starrangers:power
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starrangers:power [2014/04/27 15:17] – weby | starrangers:power [2018/07/31 23:23] (current) – external edit 127.0.0.1 | ||
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=====Power cells===== | =====Power cells===== | ||
- | Most electricity using equipment uses standard size cells. All power cells store power almost without running down when not in use; they have an very long shelf life. Typically they lose about 0.5% of total capacity/ | + | Most electricity using equipment uses standard size cells. All power cells store power almost without running down when not in use; they have an very long shelf life. Typically they lose about 0.5% of total capacity/ |
Smaller Cell types(AA-D) come in two form factors: The normal cylindrical(AA-B)/ | Smaller Cell types(AA-D) come in two form factors: The normal cylindrical(AA-B)/ | ||
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The larger cells(E to H) are box form. | The larger cells(E to H) are box form. | ||
- | The given durations for items are using TL 10 cells, for TL 11(*5 cost) cells multiply by 1.5. If you use old TL 9 cells, they are 2/3 the duration. | + | The given durations/shots and similar |
- | AA cell:These tiny cells operate devices with minimal power requirements, like very small robots or brain implants. $1, 0.0002 lbs. (5 000 AA cells weigh 1 kg.) | + | Energy |
+ | ^Cost^TL^Energy MJ/ | ||
+ | |*5|11|21|5.8|5|-3| | ||
+ | |*1|Advanced 10/Early 11|10.5|2.9|3.5|-5|Most survival/ | ||
+ | |*0.25|10|5.2|1.4|2.5|-7|Most civilian everyday gear| | ||
+ | |*0.1|Advanced 9/Early 10|2.6|0.72|1.75|-9|Still commonly used in cheap gadgets| | ||
+ | |?? | ||
+ | |?? | ||
+ | |?? | ||
+ | |?? | ||
+ | |?? | ||
- | A cell: These small cells are often used in clothing or consumer goods that require low power outputs. They’re about the size of a watch battery, or postage stamp-sized for flexible cells. $2, 0.002 kg. (500 A cells weigh 1 kg.) | + | To make explode: Skill difficulty to make it quickly explode |
- | B cell:These power wearable computers, tiny radios, | + | |
+ | AA cell:These tiny cells operate devices with minimal power requirements, | ||
+ | |||
+ | A cell: These small cells are often used in clothing or consumer goods that require low power outputs. They’re about the size of a watch battery, or postage stamp-sized for flexible cells. $0.4, 0.002 kg. (500 A cells weigh 1 kg.) | ||
+ | |||
+ | B cell:These power wearable computers, tiny radios, | ||
C cell:These are the most common energy source for personal beam weapons, tools and high-power electronics. Equipment designed for larger or smaller cells often has an adapter for C-cell operation. Each cell is about the same size as a pistol magazine. $10, 0.2 kg. | C cell:These are the most common energy source for personal beam weapons, tools and high-power electronics. Equipment designed for larger or smaller cells often has an adapter for C-cell operation. Each cell is about the same size as a pistol magazine. $10, 0.2 kg. | ||
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E cell:These power small vehicles, battlesuits, | E cell:These power small vehicles, battlesuits, | ||
- | F cell:These power medium vehicles and small cannon-sized beam weapons. They’re about the size of a compact car engine. $20, | + | F cell:These power medium vehicles and small cannon-sized beam weapons. They’re about the size of a compact car engine. $20, |
- | G cell:These power large vehicles and medium cannon-sized beam weapons. They’re about the size of a large car engine. $200, | + | G cell:These power large vehicles and medium cannon-sized beam weapons. They’re about the size of a large car engine. $200, |
- | H cell:These power huge vehicles and large cannon-sized beam weapons. They’re about the size of a small car. $2, | + | H cell:These power huge vehicles and large cannon-sized beam weapons. They’re about the size of a small car. $2, |
=====Power generation===== | =====Power generation===== | ||
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Power in civilized locations comes normally from huge fusion plants, but there are options for traveling power. | Power in civilized locations comes normally from huge fusion plants, but there are options for traveling power. | ||
- | Internal Combustion Engines (TL6): | + | Internal Combustion Engines (TL6): |
Portable Gasoline Generator(TL7): | Portable Gasoline Generator(TL7): | ||
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Fuel Cells (TL8):Fuel cells use an electrochemical process to convert chemical energy directly into electricity, | Fuel Cells (TL8):Fuel cells use an electrochemical process to convert chemical energy directly into electricity, | ||
- | Portable Methanol Fuel Cell (TL8): A suitcase-sized generator. It uses 1 gallon | + | Portable Methanol Fuel Cell (TL8): A suitcase-sized generator. It uses 1.25 liters |
- | Semi-Portable Hydrogen Fuel Cell (TL8): A large cart capable of powering a whole household | + | Semi-Portable Hydrogen Fuel Cell (TL8): A large cart capable of powering a workshop |
- | Solar Panels: | + | Solar Panels: |
- | Solar Power Array (TL9): This semi-portable array of solar panels is a generator that provides external power. It takes a minute to deploy, and covers about 400 square | + | Solar Power Array (TL9): This semi-portable array of solar panels is a generator that provides external power. It takes a minute to deploy, and covers about 40 square |
- | Fission Generators (TL9): Fission reactors produce power by splitting the nucleus of heavy fissionable elements such as uranium. The reactor and electric generator designs available at TL9 are much more compact and far less expensive than TL7-8 reactors. (They are still heavy, due to the shielding required.) A typical semi-portable system fits in a truck bed, and provides external power for five years before maintenance and refueling (50% of cost). $100,000, 450 kg. LC2 | + | Fission Generators (TL9): Fission reactors produce power by splitting the nucleus of heavy fissionable elements such as uranium. The reactor and electric generator designs available at TL9 are much more compact and far less expensive than TL7-8 reactors. (They are still heavy, due to the shielding required.) A typical semi-portable system fits in a truck bed, and provides external power for five years before maintenance and refueling (50% of cost). It produces up to 2.5 MW. $100,000, 450 kg. LC2 |
Fusion Generators (TL10): When fusion reactors first appear at TL9, they are gigantic installations that require heavy radiation shielding and frequent maintenance. At TL10+ fusion reactors produce less radiation (due to the use of harder-to-ignite but more efficient aneutronic fusion reactions) and are significantly lighter. | Fusion Generators (TL10): When fusion reactors first appear at TL9, they are gigantic installations that require heavy radiation shielding and frequent maintenance. At TL10+ fusion reactors produce less radiation (due to the use of harder-to-ignite but more efficient aneutronic fusion reactions) and are significantly lighter. | ||
- | Semi-Portable Fusion Reactor(TL10): | + | Semi-Portable Fusion Reactor(TL10): |
+ | |||
+ | Advanced Semi-Portable Fusion Reactor(TL11): | ||
- | Portable Fusion Reactor (TL11): This is a compact reactor using antimatter or exotic matter (such as muons) to catalyze a fusion reaction. $500,000, 2.3 kg Its internal fuel supply operates it for up to 10 years; refueling and maintenance is $50,000. LC2 | + | Portable Fusion Reactor (TL11): This is a compact reactor using antimatter or exotic matter (such as muons) to catalyze a fusion reaction. It produces up to 50 kw. $500,000, 2.3 kg Its internal fuel supply operates it for up to 10 years; refueling and maintenance is $100,000. LC2 |
starrangers/power.1398611863.txt.gz · Last modified: 2018/07/31 23:23 (external edit)