초록 ▼

According to various aspects, exemplary embodiments are disclosed of solar thermal collectors, solar heating systems, and thin plate heat exchangers and absorbers. The thin plate heat exchangers and absorbers may be used for solar applications and/or non-solar applications. In an exemplary embodimen

According to various aspects, exemplary embodiments are disclosed of solar thermal collectors, solar heating systems, and thin plate heat exchangers and absorbers. The thin plate heat exchangers and absorbers may be used for solar applications and/or non-solar applications. In an exemplary embodiment, a solar thermal collector generally includes a first layer comprising polymer and configured to allow sunlight to pass therethrough. A second layer comprises polymer and is configured to absorb thermal energy from sunlight. The second layer includes edges heat sealed to edges of the first layer. A permeable core is disposed between the first and second layers. In operation, a heat transfer fluid may flow through the permeable core and directly contact the second layer, whereby thermal energy is transferrable from the permeable core and the second layer to the heat transfer fluid.

대표청구항 ▼

1. A solar thermal collector comprising: a first layer comprising polymer and configured to allow sunlight to pass therethrough;a second layer comprising polymer and configured to absorb thermal energy from sunlight;a permeable core disposed between the first and second layers whereby a cavity is ma

1. A solar thermal collector comprising: a first layer comprising polymer and configured to allow sunlight to pass therethrough;a second layer comprising polymer and configured to absorb thermal energy from sunlight;a permeable core disposed between the first and second layers whereby a cavity is maintained between the first and second layers that allows fluid flow between the first and second layers;an inlet for allowing a heat transfer fluid to enter the solar thermal collector and flow through the permeable core within the cavity and in direct contact with the second layer, whereby thermal energy is transferrable from the permeable core and the second layer to the heat transfer fluid; andan outlet for allowing the heat transfer fluid to exit the solar thermal collector;wherein the second layer includes edges sealed to edges of the first layer to thereby form an impermeable and/or bag like structure that surrounds the permeable core. 2. The solar thermal collector of claim 1, further comprising one or more outer glazing layers configured to allow sunlight to pass therethrough. 3. The solar thermal collector of claim 2, wherein the first layer, the second layer, and the one or more outer glazing layers comprise thin-film polymers. 4. The solar thermal collector of claim 2, further comprising a frame along outside edges of the one or more outer glazing layers, wherein the frame is configured to maintain a distance of separation between the first layer and the one or more outer glazing layers. 5. The solar thermal collector of claim 4, wherein: the solar thermal collector further comprises one or more gaskets affixed to the frame to help create an airtight space within a framed area housing the solar thermal collector; and/orthe first and second layers and the one or more outer glazing layers are sealed together on both ends to create a water tight collector enclosure. 6. The solar thermal collector of claim 2, wherein: the first and second layers and the one or more glazing layers comprise Ethylene TetrafluoroEthylene (ETFE) or Fluorinated Ethylene Propylene (FEP);the permeable core comprises one or more layers of polytetrafluoroethylene (PTFE) coated fiberglass mesh, black high-density polyethylene netting, woven polypropylene mesh, or high temperature nylon open cell foam;the permeable core is operable for causing flow turbulence in the heat transfer fluid flow as the heat transfer fluid flows through the permeable core within the cavity between the first and second layers; andthe permeable core is operable to at least inhibit the first and second layers from collapsing together under suction and maintain the cavity between the first and second layers for the heat transfer fluid to flow. 7. The solar thermal collector of claim 2, further comprising thermal insulation attached to the second layer, wherein the first and second layers respectively define a top and a bottom of the cavity in which the permeable core is positioned and through which the heat transfer fluid flows. 8. The solar thermal collector of claim 1, wherein the edges of the second layer are heat sealed to the edges of the first layer. 9. The solar thermal collector of claim 1, wherein: the first layer comprises a thin-film polymer having edges;the second layer comprises a thin-film polymer having edges heat sealed to the edges of the thin-film polymer of the second layer to thereby form the impermeable and/or bag like structure in which the permeable core is positioned;the inlet comprises an inlet tube that penetrates the impermeable and/or bag like structure into the cavity between the first and second layer, the inlet tube attached to the second layer by a fitting heat sealed to the second layer; andthe outlet comprises an outlet tube that penetrates the impermeable and/or bag like structure into the cavity between the first and second layer, the outlet tube attached to the second layer by a fitting heat sealed to the second layer. 10. The solar thermal collector of claim 1, wherein: a suction pump is operable for pumping the heat transfer fluid through the solar thermal collector; andthe permeable core is operable to at least inhibit the first and second layers from collapsing together under suction and thereby provides a channel between the first and second layers for the heat transfer fluid to flow. 11. The solar thermal collector of claim 1, wherein: the permeable core is operable to at least inhibit the first and second layers from collapsing together under suction and maintain the cavity between the first and second layers for the heat transfer fluid to flow; and/orthe permeable core comprises one or more layers of mesh operable for causing flow turbulence in the heat transfer fluid flow as the heat transfer fluid flows through the permeable core within the cavity between the first and second layers to aide in heating the heat transfer fluid. 12. The solar thermal collector of claim 1, wherein: the first layer is clear, transparent, and/or light-transmissive;the second layer is dark colored and/or opaque; andthe permeable core is dark colored and/or opaque. 13. The solar thermal collector of claim 1, wherein the solar thermal collector is made of only polymers. 14. The solar thermal collector of claim 1, wherein: the solar thermal collector is made of only polymers approved for use with potable water;the first and second layers are sealed together along all their perimeter edges such that the impermeable and/or bag like structure surrounding the permeable core is water tight;the solar thermal collector is foldable into a first compact configuration and unfoldable into a second generally flat configuration for use to heat or pre-heat potable water;the solar thermal collector is configured to withstand temperatures of over 200° C. (392° F.) and/or a maximum predicted temperature for dry stagnation at about 235° F.; andthe solar thermal collector is freeze burst resistant such that exposure to freezing temperature does not harm the solar thermal collector, whereby potable water may be circulated through the solar collector that is directly pumped or drawn through cross-linked polyethylene (PEX) piping from one or more holding tanks thereby eliminating a need for a heat exchanger. 15. A solar water heating system comprising the solar thermal collector of claim 1, a non-pressurized storage tank, and an outlet pipe from the solar collector that drains into the non-pressured storage tank, wherein the system is configured such that a gravity siphon is established after water has flowed through the solar thermal collector and through the outlet pipe, whereby the gravity siphon allows the solar water heating system to run passively without a circulation pump. 16. A solar water heating system comprising the solar thermal collector of claim 1, the system further comprising: an input line for supplying water to be heated to the solar thermal collector;an output line for returning heated water from the solar thermal collector; anda clear tube over portions of the input and output lines that will be exposed to freezing temperatures and sunlight. 17. The system of claim 16, wherein: the input and output lines are made of freeze burst resistant materials such that the input and output lines may freeze overnight and unfreeze when heated by sunlight;the clear tube is operable as a glazing layer to add thermal insulation and speed the unfreezing of the input and output lines;an air gap separates the input and output lines from the clear tube, which air gap is operable as a thermal insulator for the input and output lines; andinternal heat conductors are disposed within the input and output lines, whereby the internal heat conductors are operable for extending thawing regions of the input and output hoses beyond where sunlight hits the input and output lines. 18. The solar thermal collector of claim 1, wherein: the first and second layers are sealed together along all their perimeter edges such that the impermeable and/or bag like structure surrounding the permeable core is water tight;the heat transfer fluid is a heat transfer liquid; andthe solar thermal collector is configured to allow the heat transfer fluid liquid to enter the solar thermal collector, flow through the permeable core within the cavity, and directly contact the first and second layers. 19. A solar thermal collector comprising: a first layer comprising polymer and configured to allow sunlight to pass therethrough;a second layer comprising polymer and configured to absorb thermal energy from sunlight, the second layer including edges sealed to edges of the first layer;a permeable core disposed between the first and second layers whereby a cavity is maintained between the first and second layers that allows fluid flow between the first and second layers; andan inlet for allowing a heat transfer fluid to enter the solar thermal collector and flow through the permeable core and in direct contact with the second layer, whereby thermal energy is transferrable from the permeable core and the second layer to the heat transfer fluid;an outlet for allowing the heat transfer fluid to exit the solar thermal collector;one or more outer glazing layers configured to allow sunlight to pass therethrough; andthermal insulation attached to the second layer; wherein:the one or more glazing layers includes edges heat sealed to the first layer along a perimeter of the one or more glazing layers;a flap is attached to the one or more glazing layers at a location adjacent but slightly away from one of the edges of the one or more glazing layers heat sealed to the first layer;the flap is also attached to the thermal insulation; anda riser over which the flap passes. 20. A solar thermal collector comprising: a first layer comprising polymer and configured to allow sunlight to pass therethrough;a second layer comprising polymer and configured to absorb thermal energy from sunlight, the second layer including edges sealed to edges of the first layer;a permeable core disposed between the first and second layers whereby a cavity is maintained between the first and second layers that allows fluid flow between the first and second layers; andan inlet for allowing a heat transfer fluid to enter the solar thermal collector and flow through the permeable core and in direct contact with the second layer, whereby thermal energy is transferrable from the permeable core and the second layer to the heat transfer fluid;an outlet for allowing the heat transfer fluid to exit the solar thermal collector;one or more outer glazing layers configured to allow sunlight to pass therethrough; andthermal insulation attached to the second layer; wherein:outside edges of the one or more glazing layers and first and second layers are sealed thereby creating tubes along the outside edges into which are positioned supports; andthe supports are attached to the thermal insulation in such a manner as to make the one or more glazing layers taut.