Solar collector system

Information

  • Patent Grant
  • 6244062
  • Patent Number
    6,244,062
  • Date Filed
    Monday, November 29, 1999
    25 years ago
  • Date Issued
    Tuesday, June 12, 2001
    23 years ago
  • Inventors
  • Examiners
    • McDermott; Corrine
    • Jiang; Chen-Wen
    Agents
    • Greer, Burns & Crain, Ltd.
Abstract
A solar collector system for converting solar radiation to thermal energy and electricity has an upper cover with a material that is transparent to solar radiation. A solar energy absorbing structure is disposed under the upper cover and has a heat conducting material such as metal. In addition, a first heat transfer system is disposed in contact with the solar energy absorbing structure and has a material that transfers heat from the solar energy absorbing structure to a first substance flowing within the first heat transfer system. The solar collector system also has electric cells that absorb solar radiation and convert it into electricity. The cells are configured and disposed on at least a portion of the upper cover.
Description




BACKGROUND




The present invention relates generally to a solar collector system for utilizing solar radiation, and in particular, a solar collector system that uses a conductor for warming both water and air conditioning coolant while also using photo cells for generating electricity.




A known dome covered solar collector is disclosed in U.S. Pat. No. 4,149,525 to Prado and is hereby incorporated by reference. This type of solar collector has a sheet of energy absorbing material that has the shape of a step pyramid and is enclosed in a transparent dome. A continuous coil of heat conducting tubing or pipe winds around the pyramid collector. Fluids that pass through the pipe are warmed by heat transferred from the solar collector and through the wall of the pipe. The solar collector has a dome to trap more heat within a cavity between the solar collector and the dome, to reduce convective radiation loss. As a result, the known domed solar collector provides heated fluids for a residential building while eliminating reliance on external connections to a fuel source for heating water, such as natural gas.




The known dome covered solar collector, however, does not include an apparatus for generating electricity to run household equipment such as motors or fans for air conditioners, furnaces or other appliances. A residence using the known domed pyramid solar collector must still use another separate source for a supply of electricity. If an electric company is the outside source supplying the electricity, the residence is dependant upon the actions of that electric company, which could be inconvenient and/or expensive.




In the alternative, a separate solar panel or wind driven electric generator may ultimately be less expensive than a connection to an electric company, but the initial costs may be higher due to installation and equipment required. In addition, both the solar and wind electric generator systems may be difficult to erect and aesthetically unappealing.




The known solar systems also do not provide a method for independent air conditioning systems that do not rely on outside sources for fuel or electricity. More specifically, in conventional mechanical absorption refrigeration systems that use ammonia as the coolant, the ammonia is heated to change the state of the coolant from liquid to vapor or gas in a generator for more efficient release of the heat outside of the area that is to be cooled. The generator is used instead of, or in addition to, a compressor. These systems require a connection to a supply of heating fuel or electricity to run a burner to heat the coolant.




Accordingly, it is an object of the present invention to provide an improved solar collector system that enables a residential building to be more independent of separate gas and electric supplies.




More specifically, an object of the present invention is to provide an improved solar collector system with a dome covered pyramid solar collector that generates electricity to run appliances while also generating heat to provide hot water and air conditioning.




A further object of the present invention is to provide an improved solar collector system with a transparent dome with photovoltaic cells used to generate electricity.




An additional object of the present invention is to provide an improved solar collector system with two separate circuits of piping around a pyramid collector so that one separate heat transfer system is used to change the state of a coolant for use in an air conditioner while the other heat transfer system heats water.




These and other objects of the present invention are discussed or will be apparent from the detailed description of the invention.




SUMMARY OF THE INVENTION




In keeping with one aspect of the invention, a solar collector system is used for converting solar radiation to thermal energy and electricity. This system has an upper cover with a material that is transparent to solar radiation. A solar energy absorbing structure is disposed under the upper cover and has a heat conducting material. A first heat transfer system is disposed in contact with the solar energy absorbing structure and has a material that transfers heat from the solar energy absorbing structure to a first substance flowing within the first heat transfer system. In addition, cells that absorb solar radiation are configured and disposed on at least a portion of the upper cover. The cells use solar radiation to generate electricity.




In another aspect of the present invention, the first heat transfer system has air conditioning coolant flowing within first pipes made of a material that transfers heat from the solar energy absorbing structure to the air conditioning coolant. Heating the coolant changes the state of the coolant. The coolant then passes over a condenser for efficient release of the heat outside of the area to be cooled.




In an alternative aspect, a second heat transfer system is disposed in contact with the solar energy absorbing structure and has a material that transfers heat from the solar energy absorbing structure to a second substance flowing within the second heat transfer system. The second substance has a different chemical composition than a chemical composition of the first substance. In one embodiment, for example, the first substance is water and the second substance is a coolant for air conditioning, such as ammonia.











BRIEF DESCRIPTION OF THE DRAWING




The above mentioned and other features of this invention and the manner of obtaining them will become more apparent, and the invention itself will be best understood by reference to the following description of a preferred embodiment of the invention in conjunction with the drawings, in which:





FIG. 1

is a perspective view of the solar collector system according to the invention;





FIG. 2

is a diagram showing the appliances connected to a solar collector system according to the invention including a side elevational view of the solar collector system; and





FIG. 3

is a top view of the solar collector system.











DETAILED DESCRIPTION




The above-listed objects are met or exceeded by the present solar collector system which has the following preferred configuration.





FIG. 1

is a perspective view of the solar collector system


100


, which is an improvement of the solar collector described in U.S. Pat. No. 4,149,525 to Prado, incorporated by reference in its entirety. The solar collector system


100


has a solar energy absorbing structure or collector


102


disposed in an enclosure formed by a domed upper cover


24


and a lower cover


55


(not shown in the present figures). The collector


102


is preferably a sheet of heat conducting material in the shape of a step pyramid with a plurality of steps


10


-


21


having vertical faces


26


-


37


and horizontal faces


38


-


49


. The preferred shape of the pyramid is a truncated right square step pyramid with the bottom step


10


being a four foot square while each step is preferably three inches high and three inches less in width from an adjacent lower step, to form a pyramid approximately three feet high. The upper cover


24


is preferably a 40 inch high, dome shaped glass or clear plastic material such as plexiglass that is transparent to solar radiation. The dome shape of the upper cover


24


has an aerodynamic design so that dust does not rest on the cover




The sheet of heat conducting material of the collector


102


is preferably a metal such as copper, but can be aluminum or any other heat conducting material. While the thickness of a copper sheet is not critical to the invention, 0.02 inches thick provides sufficient rigidity at a minimum cost.




The collector


102


also rests on a base plate


22


made of any rigid material, but preferably metal. The preferred configuration of the interior of the collector


102


, base plate


22


and lower cover


55


are disclosed in the '525 patent and will not be repeated here, except to note that the collector


102


may be hollow or filled with heat insulating material, and that the lower cover


55


is preferably heat insulating also.





FIG. 2

is a diagram showing appliances and distribution systems connected to the solar collector system


100


according to the invention, and includes a side elevational view of the solar collector system. Two separate heat transfer systems


104


and


106


transfer heat from the collector


102


. A first heat transfer system


104


has first pipes


23


made of heat conducting material, and a second transfer system


106


has second pipes


108


also made of heat conducting material. The material is preferably a metal such as copper.




Each set of pipes


23


and


108


are configured in generally parallel fashion and are disposed in separate double continuous reverse flow coils that surround and contact each of the steps


10


-


21


, whether a vertical face


26


-


37


or a horizontal face


38


-


49


.




The diameter of the piping is preferably ½″ or less, so that both the inflow and outflow pipes of each double reverse flow coil


23


,


108


can be placed in contact with each step. It will be appreciated that other sizes for the pipes are contemplated for the preferred embodiment, as long as both the inflow and outflow pipes of each double reverse flow coil of pipes


23


,


108


will fit on each step. In a three foot high pyramid, approximately 340 feet of piping is required for each heat transfer system


104


,


106


for a total of 680 feet. It will also be appreciated, however, that other configurations are possible. For example, pipes


23


,


108


could alternate steps or skip steps instead of the configuration in the preferred embodiment.




The first heat transfer system


104


transfers heat from the solar energy absorbing structure


102


to a first substance flowing within the first heat transfer system, while the second heat transfer system


106


transfers beat from the solar energy absorbing structure to a second substance flowing within the second heat transfer system. In the preferred embodiment, one of the substances is water or water treated with anti-corrosion and/or antifreeze additives. The other substance is preferably a coolant such as ammonia for a conventional absorption air conditioner.




The pipes


23


and


108


enter and exit through sealed openings in the base plate


22


. The first pipes


23


are connected to a cold water supply


118


, a hot water storage


120


, and pumps


122


,


124


. The first pipes


23


may also be connected to a conventional heat storage system which includes temperature sensing devices, photoelectric sensing devices, auxiliary energy sources and a further distribution system (not shown). The rate of flow through the pipes


23


may be controlled by valves


126


or other known methods.




As depicted in

FIG. 2

, the second pipes


108


are preferably connected to a conventional absorption air conditioner


128


that requires the heating of a coolant, such as ammonia, to change it from liquid to vapor or gas for more efficient condensation at a condenser


132


. This type of air conditioner may or may not have a compressor


134


for further efficient condensing of the vapor. The flow of coolant may be controlled by valves


136


. Second pipes


108


may also have pumps


142


,


144


to maintain flow. In an alternative embodiment, only one double reverse flow coil with first pipes


23


is provided and the coil is used to flow the air conditioning coolant rather than water. Furthermore, it will be appreciated that any chemical or composition that is used for coolant and requires heating could be used as coolant rather than ammonia in this system.




Referring again to

FIGS. 1 and 2

, the upper cover


24


also has photovoltaic cells


110


that absorb solar radiation disposed on at least a portion of the upper cover


24


to generate electricity. The cells


110


are preferably arranged in a horizontal band


112


around the upper cover


24


and are attached to an interior face of the upper cover


24


by adhesion. It will be appreciated that other types of solar cells or small solar panels that generate electricity could be used. It will also be appreciated that the cells


110


can be attached to the upper cover


24


by other means rather than adhesion, and that the cells may be attached to the exterior or embedded within the upper cover


24


instead of attached to an interior face.




The cells


110


are preferably opaque while being at least partially transparent to allow some solar radiation to penetrate through the cells to reach the collector


102


. The vertical width of the band


112


is preferably {fraction (3/10)} the height of the upper cover and is positioned so that the lower periphery


114


of the band


112


is positioned generally ⅖ of the height of the upper cover from the bottom


116


of the upper cover


24


.




Referring again to

FIG. 2

, the cells


110


are connected to wires (not shown) that lead to a junction box


138


by conventional methods. The junction box is preferably connected to a battery


140


, motors in pumps


122


,


124


for running the water through the first pipes


23


, pumps


142


,


144


for running the coolant through second pipes


108


, fan


146


in the air conditioner


128


and a furnace/duct fan


148


, also by conventional methods.




It will be appreciated that other electrical appliances, motors, outlets etc. can be connected to the junction box


138


so that the entire electrical supply for the residential building can potentially originate from the cells


110


rather than electric lines leading to an electric company, separate solar panels or wind driven generators. The band


112


of cells


110


are expected to supply approximately over 500 watts to approximately 2 kilowatts of electricity. This is enough electricity to power a heater motor or a typical air conditioner motor. Line voltage of 110 v at 6 amps can also be supplied. In another embodiment, instead of a junction box


138


, the cells


110


can be used to supply current directly to an appliance by conventional methods.





FIG. 3

is a top view of the collector system


100


and depicts the top view of the band


112


in a ring. With this configuration, generally, the orientation of the solar collector system


100


is not important for positioning the cells since the cells


110


are symmetrically positioned on all four sides of the solar collector system. It will be appreciated that while the band


112


is the preferred configuration for the cells, other configurations are possible as long as the cells face the sun at least a portion of the upper cover


24


.




Referring again to

FIG. 1

, the positioning of the solar collector system


100


for maximum heat generation for the two heat transfer systems


104


,


106


is unimportant in warm climates, such as the southern U.S. In the northern U.S., however, where relatively low average temperatures prevail, it is preferred to orient the collector


102


such that edge


25


formed by the intersection of sides


6


and


7


is pointed south. In this embodiment, sides


7


and


8


will collect radiation in the early morning hours. The vertical faces


26


-


37


of each step will be the predominant collecting surface because of the position of the sun during this period. Some radiation will be reflected onto the horizontal faces


38


-


49


. As the sun rises, both horizontal and vertical faces will receive direct sunlight. Some of the radiation will be absorbed by the copper surface of the collector


102


and some radiation will be reflected onto another surface. During the middle portion of the day, sides


6


and


7


will comprise the major collecting surfaces. In the late afternoon, sides


6


and


9


will be the major collecting surfaces. Again, because of the position of the sun, the vertical faces of these sides will receive the majority of the solar radiation.




In yet another embodiment, select portions of the horizontal faces


38


-


49


, vertical faces


26


-


37


and pipes


23


,


108


are coated with a black material such as black paint to increase absorption and decrease reradiation or reflectivity of the treated surface. It will be appreciated that the entire collector could be coated with black material.




The operation should now be apparent to those skilled in the art. During daylight hours, the entire surface of the collector


102


is heated while the cells


110


absorb solar radiation and convert it to electricity, which flows to junction box


138


. The electricity generated by the cells


110


is received by the junction box


138


and stored in a battery


140


. Pumps


122


,


124


,


142


and


144


; fans


146


,


148


and compressor


134


all receive electricity from the battery


140


or junction box


138


by conventional methods.




In the first heat transfer system


104


, a pump


122


pumps cold water from a supply


118


, to the coil


23


at pipe


50


(shown in FIG.


2


). While ascending and then descending through each step of the collector


102


, the heat absorbed by the collector is transferred to the substance or liquid contained in the pipes


23


. Then the recently heated water exits the coil


23


through pipe


51


(also shown in FIG.


2


). A pump


124


may pump the heated water to a hot water supply


120


or other water fixtures (not shown), such as bathtubs, sinks, and showers, for example.




In the second heat transfer system


106


, liquid or vapor ammonia carrying heat received from the evaporator


130


is carried through pipe


150


into coil pipes


108


. The collector


102


acts as a generator for the typical absorption ammonia air conditioner. The collector


102


filter heats the ammonia to change the state of the ammonia from a warm liquid/vapor to hot gas. While the generator in the solar collector system


100


generally replaces a compressor, this gas could also be compressed by a compressor


134


for even further efficient release of heat. After being received by the air conditioner, the heat is released from the gas by flowing it through the condensor


132


and past fan


146


. The condensor changes the hot gas back to a cold liquid, which then proceeds back to the evaporator


130


. Other components of the conventional absorption ammonia air conditioner known in the art are not shown. It will be appreciated that other coolants that require heating could be substituted for the ammonia.




The many advantages of this invention are now apparent. A small solar collector system


100


has photovoltaic cells


110


on the domed upper cover


24


to generate electricity for large appliances while the collector


102


heats water in first pipes


23


for hot water and heaters, and heats coolant in second pipes


108


for air conditioning so that a residential building can potentially be independent of connections to utility companies.




While various embodiments of the present invention have been described, it should be understood that other modifications, substitutions and alternatives may be apparent to one of ordinary skill in the art. Such modifications, substitutions and alternatives can be made without departing from the spirit and scope of the invention, which should be determined from the appended claims.



Claims
  • 1. A solar collector system for converting solar radiation to thermal energy and electricity, comprising:an upper cover having a material that is transparent to solar radiation; a solar energy absorbing structure disposed under said upper cover and having a heat conducting material; a first heat transfer system disposed in contact with said solar energy absorbing structure and having a material that transfers heat from said solar energy absorbing structure to a first substance flowing within said first heat transfer system; cells that absorb solar radiation, said cells being configured and disposed on at least a portion of said upper cover, said cells converting said solar radiation into electricity; wherein said upper cover is a dome and said cells are arranged in a horizontal band around said dome, said dome further including a bottom and a top, and wherein said band further has a vertical width that is generally {fraction (3/10)} the height of said upper cover, and said band further includes a lower periphery positioned generally ⅖ of the height of said upper cover from said bottom of said upper cover.
  • 2. The solar collector system according to claim 1, wherein said solar energy absorbing structure is a sheet of said heat conducting material formed into the shape of a pyramid, and wherein said first heat transfer system further includes first pipes forming a double reverse flow coil spiraling around said pyramid.
  • 3. The solar collector system according to claim 2, wherein said pyramid is a right step pyramid having a plurality of steps with vertical and horizontal faces, said faces forming generally right angles, wherein said first pipes generally conform to said shape of said step pyramid and contact each successive step of said step pyramid.
  • 4. A solar collector system according to claim 1, wherein said first substance is a coolant used in an air conditioner.
  • 5. A solar collector system according to claim 4, wherein said coolant is ammonia.
  • 6. A solar collector system for converting solar radiation to thermal energy and electricity, comprising:an upper cover having a material that is transparent to solar radiation; a solar energy absorbing structure disposed under said upper cover and having a heat conducting material; a first heat transfer system disposed in contact with said solar energy absorbing structure and having a material that transfers heat from said solar energy absorbing structure to a first substance flowing within said first heat transfer system; and cells that absorb solar radiation: said cells converting said solar radiation into electricity; wherein said cells are further attached to an interior face of said upper cover.
  • 7. The solar collector system according to claim 6, wherein said solar energy absorbing structure is a sheet of said heat conducting material formed into the shape of a pyramid, and wherein said first heat transfer system further includes first pipes forming a double reverse flow coil spiraling around said pyramid.
  • 8. The solar collector system according to claim 7, wherein said pyramid is a right step pyramid having a plurality of steps with vertical and horizontal faces, said faces forming generally right angles, wherein said first pipes generally conform to said shape of said step pyramid and contact each successive step of said step pyramid.
  • 9. A solar collector system according to claim 6, wherein said first substance is a coolant used in an air conditioner.
  • 10. A solar collector system according to claim 9, wherein said coolant is ammonia.
  • 11. A solar collector system for converting solar radiation to thermal energy and electricity, comprising:an upper cover having a material that is transparent to solar radiation; a solar energy absorbing structure disposed under said upper cover and having a heat conducting material; a first heat transfer system disposed in contact with said solar energy absorbing structure and having a material that transfers heat from said solar energy absorbing structure to a first substance flowing within said first heat transfer system; cells that absorb solar radiation, said cells being configured and disposed on at least a portion of said upper cover, said cells converting said solar radiation into electricity; and a second heat transfer system disposed in contact with said solar energy absorbing structure and having a material that transfers heat from said solar energy absorbing structure to a second substance flowing within said second heat transfer system.
  • 12. The solar collector system according to claim 11, wherein said second substance is a coolant for an air conditioning system, and heating of said second substance changes the physical state of said second substance for cooling air.
  • 13. The solar collector system according to claim 12, wherein said first substance is water and said second substance is ammonia.
  • 14. The solar collector system according to claim 11, wherein said first heat transfer system further includes first pipes and said second heat transfer system further includes second pipes positioned in generally parallel orientation to said first pipes.
  • 15. The solar collector system according to claim 14, wherein said solar energy absorbing structure is a sheet of said heat conducting material formed into the shape of a pyramid, and wherein said first pipes and said second pipes are both double reverse flow coils spiraling around said pyramid.
  • 16. The solar collector system according to claim 11, wherein said solar energy absorbing structure is a sheet of said heat conducting material formed into the shape of a pyramid, and wherein said first heat transfer system further includes first pipes forming a double reverse flow coil spiraling around said pyramid.
  • 17. The solar collector system according to claim 16, wherein said pyramid is a right step pyramid having a plurality of steps with vertical and horizontal faces, said faces forming generally right angles, wherein said first pipes generally conform to said shape of said step pyramid and contact each successive step of said step pyramid.
  • 18. A solar collector system according to claim 11, wherein said first substance is a coolant used in an air conditioner.
  • 19. A solar collector system according to claim 18, wherein said coolant is ammonia.
  • 20. A solar collector system for converting solar radiation to thermal energy, comprising:an upper cover having a material that is transparent to solar radiation; a solar energy absorbing structure disposed under said upper cover and having a heat conducting material; a first heat transfer system disposed in contact with said solar energy absorbing structure having air conditioning coolant flowing within first pipes made of a material that transfers heat from said solar energy absorbing structure to said air conditioning coolant, wherein heating said coolant changes the state of said coolant; and cells that absorb solar radiation, said cells configured and disposed on at least a portion of said upper cover, said cells converting said solar radiation into electricity.
  • 21. The solar collector system according to claim 20, wherein said solar energy absorbing structure is a sheet of said heat conducting material formed into the shape of a pyramid, and wherein said first pipes further form a double reverse flow coil spiraling around said pyramid.
  • 22. The solar collector system according to claim 21, wherein said pyramid is a right step pyramid having a plurality of steps with vertical and horizontal faces, said faces form generally right angles, wherein said first pipes generally conform to said shape of said step pyramid and contact each successive step of said step pyramid.
  • 23. A solar collector system according to claim 20, wherein said upper cover further has the configuration of a dome and said cells are disposed in a horizontal band around said dome.
  • 24. A solar collector system for converting solar radiation to thermal energy, comprising:an upper cover having a material that is transparent to solar radiation; a solar energy absorbing structure disposed under said upper cover and having a heat conducting material; a first heat transfer system disposed in contact with said solar energy absorbing structure having air conditioning coolant flowing within first pipes made of a material that transfers heat from said solar energy absorbing structure to said air conditioning coolant, wherein heating said coolant changes the state of said coolant; and a second heat transfer system separate from said first heat transfer system, said second heat transfer system including second pipes disposed in contact with said solar energy absorbing structure and having a material that transfers heat from said solar energy absorbing structure to a substance flowing within said second heat transfer system.
  • 25. The solar collector system according to claim 24, wherein said coolant is ammonia and said second substance is water.
  • 26. The solar collector system according to claim 24, wherein said second pipes are positioned in generally parallel orientation to said first pipes.
  • 27. The solar collector system according to claim 24, wherein said solar energy absorbing structure is a sheet of said heat conducting material formed into the shape of a pyramid, and wherein said first pipes further form a double reverse flow coil spiraling around said pyramid.
  • 28. The solar collector system according to claim 27, wherein said pyramid is a right step pyramid having a plurality of steps with vertical and horizontal faces, said faces form generally right angles, wherein said first pipes generally conform to said shape of said step pyramid and contact each successive step of said step pyramid.
  • 29. A solar collector system for converting solar radiation to thermal energy comprising:an upper cover having a material that is transparent to solar radiation, a solar energy absorbing structure disposed under said upper cover and having a heat conducting material; a first heat transfer system disposed in contact with said solar energy absorbing structure and having a material that transfers heat from said solar energy absorbing structure to a first substance flowing within said first heat transfer system; a second heat transfer system disposed in contact with said solar energy absorbing structure and having a material that transfers heat from said solar energy absorbing structure to a second substance flowing within said second heat transfer system, said second substance having a different chemical composition than a chemical composition of said first substance; and said solar energy absorbing structure is a sheet of said heat conducting material formed into the shape of a pyramid, and wherein said first heat transfer system further includes first pipes forming a first double reverse flow coil spiraling around said pyramid, and wherein said second heat transfer system further includes second pipes forming a second double reverse flow coil spiraling around said pyramid, said first pipes being disposed generally parallel to said second pipes.
  • 30. The solar collector system according to claim 29, wherein said pyramid is a right step pyramid having a plurality of steps with vertical and horizontal faces, said faces forming generally right angles, wherein said first pipes and said second pipes generally conform to said shape of said step pyramid and contact each successive step of said step pyramid.
  • 31. A solar collector system according to claim 29, further comprising cells that absorb solar radiation, said cells configured and disposed on at least a portion of said upper cover, said cells converting said solar radiation into electricity.
  • 32. A solar collector according to claim 31, wherein said upper cover further has the configuration of a dome and said cells are disposed in a horizontal band around said dome.
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Number Name Date Kind
4149525 Prado Apr 1979
4249520 Orillion Feb 1981
4376435 Pittman Mar 1983
4448039 Hutchins May 1984
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4616487 Franklin Oct 1986
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Entry
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Small Ammonia Refrigerator, publication date unknown.
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