Difference between revisions of "Photovoltaic Cell"
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− | |Type = | + | |Type = Power Supply |
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In most cases PV cells are gathered into an large array to provide more power. Most PV cells are about 1cm square. | In most cases PV cells are gathered into an large array to provide more power. Most PV cells are about 1cm square. | ||
− | + | These cells are mounted on a light aluminum or flexible plastic backing with a transparent cover to protect the cells from incidental damage. This is sufficient for light weight consumer goods. For industrial use the cells are mounted on a heavier backing and given a stronger (but more transparent) cover. | |
+ | === Photovoltaic Power Efficiencies === | ||
{| class="wikitable sortable" | {| class="wikitable sortable" | ||
|+ Photovoltaic cell per m<sup>2</sup> | |+ Photovoltaic cell per m<sup>2</sup> | ||
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− | + | == History & Background ([[Dossier]]) == | |
− | + | Usually discovered around {{TL|5}}, PV cells become commercially available at {{TL|6}}. Primitive PV cells are highly inefficient (1% or worse) usually because the semiconductor material is sensitive to a single or limited array of wavelengths. At {{TL|7}} this efficiency has improved to 6%, 15% at {{TL|8}}, and, with the addition of multiple layer crystal systems, 40% at {{TL|9}}. | |
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− | + | Photovoltaic cells are an especially well adapted power source for [[Space Station]]s which are orbiting near a star: the PV panels may face constantly the star and receive a constant light radiation, thus giving a constant power output. PV panels having very long lifetimes (up to 30 years at {{TL|9}}), they make an interesting power source for such isolated stations. | |
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=== Image Repository === | === Image Repository === | ||
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{{Intermediate}} | {{Intermediate}} | ||
{{Detail}} | {{Detail}} | ||
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{{Sources | {{Sources | ||
|S1= {{Ludography cite|name= Referee's Manual|page=64}} | |S1= {{Ludography cite|name= Referee's Manual|page=64}} |
Revision as of 22:54, 15 December 2018
Photovoltaic Cell | |
---|---|
TBD | |
Type | Power Supply |
Tech Level | TL–6 |
Cost | kCr150 |
Size | 12.0 liters |
Weight | 8.0 kg |
Manufacturer | Various |
Reference | TBD |
Per m2 |
A Photovoltaic Cell is a device that converts light energy into electricity via the photovoltaic effect, where the photons trigger the release of electrons in a semi-conductor material. These devices are also know as Photoelectic or Solar cells, the latter based upon the usual source of light to power them.
Description (Specifications)
In most cases PV cells are gathered into an large array to provide more power. Most PV cells are about 1cm square.
These cells are mounted on a light aluminum or flexible plastic backing with a transparent cover to protect the cells from incidental damage. This is sufficient for light weight consumer goods. For industrial use the cells are mounted on a heavier backing and given a stronger (but more transparent) cover.
Photovoltaic Power Efficiencies
TL | Weight (kg) |
Cost kCr |
Output (kW) |
---|---|---|---|
6 | 8 | 150 | 3 |
7 | 6 | 80 | 3 |
8 | 4 | 45 | 3 |
9 | 3 | 25 | 2.5 |
10 | 2 | 12 | 1.8 |
11 | 1 | 6 | 1.4 |
History & Background (Dossier)
Usually discovered around TL–5, PV cells become commercially available at TL–6. Primitive PV cells are highly inefficient (1% or worse) usually because the semiconductor material is sensitive to a single or limited array of wavelengths. At TL–7 this efficiency has improved to 6%, 15% at TL–8, and, with the addition of multiple layer crystal systems, 40% at TL–9.
Photovoltaic cells are an especially well adapted power source for Space Stations which are orbiting near a star: the PV panels may face constantly the star and receive a constant light radiation, thus giving a constant power output. PV panels having very long lifetimes (up to 30 years at TL–9), they make an interesting power source for such isolated stations.
Image Repository
No information yet available.
References & Contributors (Sources)
This article is missing content for one or more detailed sections. Additional details are required to complete the article. You can help the Traveller Wiki by expanding it. |
- Marc Miller. Referee's Manual (Game Designers Workshop, 1987), 64.
- Frank Chadwick, Dave Nilsen. Fire, Fusion, & Steel (Game Designers Workshop, 1994), 65.
- David Golden, Guy Garnett. Fire, Fusion & Steel (Imperium Games, 1997), 81,112.
- Greg Porter. Central Supply Catalog (Imperium Games, 1996), 60.
- Marc Miller. T5 Core Rules (Far Future Enterprises, 2013), 625,644.
- Traveller Wiki Editorial Team
- Author & Contributor: Lord (Marquis) and Master of Sophontology Maksim-Smelchak of the Ministry of Science