Difference between revisions of "Photovoltaics"

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'''Photovoltaics''' (or PV) is the generation of electric currents from electromagnetic radiation using the [[photovoltaic effect]] (compare [[solar_concentrator#Thermoelectric_Generators|solar-thermal electricity]]).
 
  
A PV cell is the basic unit of a PV array. It is usually made of a [[silicon]] substrate coated with a thin film. These are mounted together with supporting structure to form [[solar_panel|PV panel]].<ref>G.D.J. Harper - ''Domestic solar energy: a guide for the home owner'' 2009. ISBN 978-1-84797-060-2 p. 140</ref>
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'''[[w:Photovoltaics|Photovoltaics]]''' (or PV) is the generation of electric currents from electromagnetic radiation using the [[photovoltaic effect]] (compare [[solar_concentrator#Thermoelectric_Generators|solar-thermal electricity]]).
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[[File:Solar cell tile.JPG|right|frameless|50x50px|alt=|link=Create a settlement]]
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A PV cell is the basic unit of a PV array. It is usually made of a [[silicon]] substrate coated with a thin film. These are mounted together with supporting structure to form [[solar_panel|PV panel]].<ref>G.D.J. Harper - ''Domestic solar energy: a guide for the home owner'' 2009. ISBN 978-1-84797-060-2 p. 140</ref> A number of technologies are available, but costs vary widely and increase sharply with high efficiencies.
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==Technologies==
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Thin film technologies are generally less expensive than the others, as well as being  lighter.  Some versions have reached 23% efficiency
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 +
Single junction gallium arsenide are up to 28% efficiency.
 +
 
 +
Multijunction cells, three and four junction cells have reached about 36% efficiency without concentrators and up to 46% with concentrators.
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Crystalline silicon cells, 25-26 %, 22% for commercially available products (2019).
 +
 
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Emerging technologies: Perovskite cells may reach over 30% efficiency for very low costs.  Still in development.
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Multijunction cells can be over 100 times more expensive than less efficient crystalline silicon cells or thin film cells.
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==Use on  Mars==
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===Roll out films===
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[[File:Rolls of solar cells.jpg|thumb|Roll out film solar arrays]]
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Flexible solar cells can be attached to a flexible backing and packed into large rolls.  These can be unrolled directly onto the martian surface for a very simple deployment method.  Flexible film cells are less efficient and the variations in the sun's angle during the days reduce the available energy.  This might be the best technology for automated deployment in the early stages of the settlement.  An example are the [http://www.renovagen.com/ Renovagen] rapid roll products
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[[File:Solar array.jpg|thumb|A power station made with sun tracking solar array.  The central battery has a charging station for vehicles.]]
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===Sun tracking panels===
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[[w:Solar_tracker|Sun tracking]] can increase the input energy over a year by up to 40% for the same installed capacity.  However the tracking mechanisms can be heavy and are moving parts that can fail over time.  Might best be used after crews have arrived and there are maintenance facilities set up.  Sun tracking may be less useful during dusty seasons, when a large part of the incident light is diffuse light.
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===Back-up power for rovers===
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Rovers can be partly covered with solar cells for emergency back-up power.  This is a feature of the NASA MMSEV design.<ref>https://en.wikipedia.org/wiki/Space_Exploration_Vehicle</ref> 
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===Power stations===
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Solar panels and batteries can be combined into local charging power stations allowing for operating rovers and other equipment in remote locations.  A series of power stations could be built along a long road between two remote locations and allow for extended range of operations.
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===Power for landed ships===
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Ships landing on Mars will require power.  Du to the heat or re entry, solar cells on the exterior of ships may not be possible, and solar panels designed to be deployed in space may not be capable of being deployed under martian gravity.  Although an established Mars settlement may be able to provide power to landed ships, the first ships on Mars could be required to rapidly deploy solar panels to provide the power needed for their operation.  Batteries can provide some service, but not for the number of years the first ships will be on Mars.
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==Maintenance==
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Photovoltaic arrays will be subject to damage from dust, as well as a reduction capacity from dust deposits.  Some form of cleaning mechanism would be useful.  For a settlement, this work may be done by the colonists themselves.  Solar tracking systems require even more maintenance.
  
 
==References==
 
==References==
 
<references />
 
<references />
  
[[Category:Energy]]
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[[Category:Sources]]

Revision as of 08:21, 2 August 2019

Photovoltaics (or PV) is the generation of electric currents from electromagnetic radiation using the photovoltaic effect (compare solar-thermal electricity).

A PV cell is the basic unit of a PV array. It is usually made of a silicon substrate coated with a thin film. These are mounted together with supporting structure to form PV panel.[1] A number of technologies are available, but costs vary widely and increase sharply with high efficiencies.

Technologies

Thin film technologies are generally less expensive than the others, as well as being lighter. Some versions have reached 23% efficiency

Single junction gallium arsenide are up to 28% efficiency.

Multijunction cells, three and four junction cells have reached about 36% efficiency without concentrators and up to 46% with concentrators.

Crystalline silicon cells, 25-26 %, 22% for commercially available products (2019).

Emerging technologies: Perovskite cells may reach over 30% efficiency for very low costs. Still in development.

Multijunction cells can be over 100 times more expensive than less efficient crystalline silicon cells or thin film cells.

Use on Mars

Roll out films

Roll out film solar arrays

Flexible solar cells can be attached to a flexible backing and packed into large rolls. These can be unrolled directly onto the martian surface for a very simple deployment method. Flexible film cells are less efficient and the variations in the sun's angle during the days reduce the available energy. This might be the best technology for automated deployment in the early stages of the settlement. An example are the Renovagen rapid roll products

A power station made with sun tracking solar array. The central battery has a charging station for vehicles.

Sun tracking panels

Sun tracking can increase the input energy over a year by up to 40% for the same installed capacity. However the tracking mechanisms can be heavy and are moving parts that can fail over time. Might best be used after crews have arrived and there are maintenance facilities set up. Sun tracking may be less useful during dusty seasons, when a large part of the incident light is diffuse light.

Back-up power for rovers

Rovers can be partly covered with solar cells for emergency back-up power. This is a feature of the NASA MMSEV design.[2]

Power stations

Solar panels and batteries can be combined into local charging power stations allowing for operating rovers and other equipment in remote locations. A series of power stations could be built along a long road between two remote locations and allow for extended range of operations.

Power for landed ships

Ships landing on Mars will require power. Du to the heat or re entry, solar cells on the exterior of ships may not be possible, and solar panels designed to be deployed in space may not be capable of being deployed under martian gravity. Although an established Mars settlement may be able to provide power to landed ships, the first ships on Mars could be required to rapidly deploy solar panels to provide the power needed for their operation. Batteries can provide some service, but not for the number of years the first ships will be on Mars.

Maintenance

Photovoltaic arrays will be subject to damage from dust, as well as a reduction capacity from dust deposits. Some form of cleaning mechanism would be useful. For a settlement, this work may be done by the colonists themselves. Solar tracking systems require even more maintenance.

References

  1. G.D.J. Harper - Domestic solar energy: a guide for the home owner 2009. ISBN 978-1-84797-060-2 p. 140
  2. https://en.wikipedia.org/wiki/Space_Exploration_Vehicle