Radiation modulating apparatus and method
First Claim
1. An apparatus to selectively modify emission or absorption of radiation within a predetermined wavelength range and also modify reflection of radiation within said predetermined wavelength range, said apparatus having a radiation emitting or receiving axis along which said apparatus is adapted to be oriented so that the axis is generally parallel to a major path component of the radiation, said apparatus having a front side and a rear side relative to said axis, with the front side adapted to be positioned to emit or initially receive the radiation, said apparatus comprising:
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Accused Products
Abstract
A pair of planar electrodes spaced from one another by an electrolyte. The front electrode faces the air or vacuum environment and is transparent, and the second electrode is in thermal contact with a heat conducting surface and is reflective. By selectively modifying the voltage between the two electrodes, a partially reflective coating can be deposited on the back face of the front electrode or removed therefrom. With the coating removed, the emission of thermal radiation is minimized, and a major portion of the radiation from sources in the environment is reflected. With the coating present, emitted or reflected radiation interacting with the coating interferes destructively with the radiation emitted or reflected by the second electrode, maximizing thermal emission and absorbing a major portion of any incident radiation.
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Citations
21 Claims
- 1. An apparatus to selectively modify emission or absorption of radiation within a predetermined wavelength range and also modify reflection of radiation within said predetermined wavelength range, said apparatus having a radiation emitting or receiving axis along which said apparatus is adapted to be oriented so that the axis is generally parallel to a major path component of the radiation, said apparatus having a front side and a rear side relative to said axis, with the front side adapted to be positioned to emit or initially receive the radiation, said apparatus comprising:
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2. a. a front substantially transparent electrode having a front face and a rear face, and occupying a plane having a major alignment component substantially perpendicular to said radiation emitting or receiving axis;
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b. a substantially transparent electrolyte positioned behind said front electrode and in electrolytic contact with the rear face of the front electrode; c. a second electrode positioned to be in electrolytic contact with said electrolyte; d. a selectively operable voltage source to impose a voltage between said electrode where the first electrode can be charged either negatively or positively relative to the second electrode to either deposit a partially reflective coating at the rear surface of the first electrode or remove said coating from the rear surface of said electrode; e. said apparatus providing a substantially fully reflective surface spaced behind the rear surface of the first electrode at a predetermined spacing distance along said radiation emitting/receiving axis, whereby with the coating deposited on the rear face of the first electrode, destructive optical interference minimizes surface reflectance of the reflective surface and thus maximizes surface emittance of said apparatus, and with said coating being removed from the rear face of the first electrode, the surface reflectance of the reflective surface is maximized and thus the surface emittance is minimized. - View Dependent Claims (4)
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11. A heat control apparatus to control heat contained in a structure by selectively modifying emission or absorption of radiation within a predetermined wave length range and also modify reflection of radiation within said predetermined wavelength range, said apparatus having a radiation emitting/receiving axis along which said apparatus is adapted to be oriented so that the axis is generally parallel to a major path component of the radiation, said apparatus having a front side and a rear side relative to said axis, with the front side adapted to be positioned to emit or initially receive the radiation, said apparatus comprising:
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a. a front substantially transparent and generally planar electrode having a front face and a rear face, and occupying a plane having a major alignment component substantially perpendicular to said radiation receiving axis; b. a substantially transparent electrolyte positioned behind said front electrode and in electrolytic contact with the rear surface of the front electrode; c. a second substantially planar electrode positioned behind said electrolyte so as to be in electrolytic contact therewith and having a forwardly facing substantially fully reflective surface, and a rear surface in heat exchange contact with said structure; d. a selectively operable voltage source to impose a voltage between said electrodes where the first electrode can be charged either negatively or positively relative to the second electrode to either deposit a partially reflective coating at the rear face of the first electrode or remove said coating from the rear face of said electrode; e. the reflective surface of the second electrode being spaced behind the rear face of the first electrode at a predetermined spacing distance relative to said radiation emitting/receiving axis, whereby with the coating deposited on the rear face of the first electrode, destructive optical interference minimizes surface reflectance of the reflective surface and thus maximizes surface emittance of said apparatus, and with said coating being removed from the rear face of the first electrode, the surface reflectance is maximized and thus the surface emittance is minimized.
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15. A method of selectively modifying emission or absorption of radiation within a predetermined wavelength range and also modifying reflection of radiation within said predetermined wavelength range, where there is a radiation emitting or receiving axis along which said radiation is directed, said method comprising:
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a. providing a front substantially transparent electrode having a front face and a rear face, and occupying an alignment plane; b. providing a substantially transparent electrolyte positioned immediately behind said front electrode and in electrolytic contact with the rear face of the front electrode; c. providing a second electrode positioned to be in electrolytic contact with said electrolyte; d. locating a reflective surface behind the rear face of the first electrode at a predetermined spacing distance relative to the radiation emitting or receiving axis and substantially parallel to said plane; e. locating said two electrodes, said electrolyte, and said reflective surface so that said plane is perpendicular to a major alignment component of said radiation emitting/receiving axis; f. selectively applying a voltage source between said first and second electrodes to cause a coating of the second electrode to be deposited on the rear face of the first electrode, with the result that destructive optical interference minimizes surface reflectance of the reflective surface and thus maximizes surface emittance of said apparatus, and then applying said voltage source to the electrodes to remove the coating from the rear face of the first electrode so that the surface reflectance of the reflective surface is maximized and thus the surface emittance is minimized. - View Dependent Claims (17)
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Specification