THERMAL CELL PANEL SYSTEM FOR HEATING AND COOLING AND ASSOCIATED METHODS

Abstract

A thermal cell panel system for heating and cooling using a refrigerant includes a plurality of solar thermal cell chambers, and a piping network for a flow of the refrigerant through the plurality of solar thermal cell chambers. In addition, the system includes a compressor having a motor coupled to a variable frequency drive (“VFD”), where the compressor is coupled to the piping network upstream of the plurality of solar thermal cell chambers and the VFD is configured to adjust a speed of the motor in response to the pressure of the refrigerant within the plurality of solar thermal cell chambers. The piping network includes an inlet manifold coupled to the inlet of each solar thermal cell chamber, and an outlet manifold coupled to the outlet of each solar cell chamber.

Claims

1. A method of operating a thermal cell panel system comprising a plurality of solar thermal cell chambers, a piping network for a flow of a refrigerant through the plurality of solar thermal cell chambers for heating and cooling, and a compressor having a motor coupled to the piping network upstream of the plurality of solar thermal cell chambers, the method comprising: adjusting a speed of the motor in response to a pressure of the refrigerant within the respective solar thermal cell chamber; and recirculating the refrigerant through the piping network from the condenser through the plurality of solar thermal cell chambers, to a condenser coil coupled to the piping network downstream of the plurality of solar thermal cell chambers, to an evaporator coil coupled to the piping network downstream of the condenser coil, and returning to the condenser.

2. The method of operating a thermal cell panel system of claim 1, further comprising selectively opening and closing a pressure valve in fluid communication with the piping network in order to open and close the flow of refrigerant through the housing in response to the pressure of the refrigerant within the housing.

Description

BRIEF DESCRIPTION OF THE DRAWINGS

[0019] FIG. 1 is a schematic of a typical heating and cooling system.

[0020] FIG. 2 is a schematic process diagram of a thermal cell panel system for heating and cooling in which various aspects of the disclosure may be implemented.

[0021] FIG. 3A is a schematic of a heating stage process diagram in which various aspects of the disclosure may be implemented.

[0022] FIG. 3B is a schematic of the thermal cell panel system of FIG. 2 having a heat pump.

[0023] FIG. 4 is a perspective schematic view of a plurality of the solar thermal cell chambers.

[0024] FIG. 5 is a perspective schematic view of the solar thermal cell chamber shown without various components for clarity.

[0025] FIG. 6 is a flowchart illustrating a method of operating the thermal cell panel system illustrated in FIG. 1.

[0026] FIG. 7 is an example of a window unit installed with the thermal solar thermal cell panel system.

DETAILED DESCRIPTION OF PREFERRED EMBODIMENTS

[0027] In the summary of the invention, provided above, and in the descriptions of certain preferred embodiments of the invention, reference is made to particular features of the invention, for example, method steps. It is to be understood that the disclosure of the invention in this specification includes all possible combinations of such particular features, regardless of whether a combination is explicitly described. For instance, where a particular feature is disclosed in the context of a particular aspect or embodiment of the invention, that feature can also be used, to the extent possible, in combination with and/or in the context of other particular aspects and embodiments of the invention, and in the invention generally.

[0028] This invention stretches across two well-known industries, the heating and cooling industry and the solar industry. This invention describes new systems and methods of solar thermal reactions with refrigerants in order to dramatically reduce the need of mechanical and electrical energy to move along the refrigeration circuit. Accordingly, this will significantly reduce the electrical energy required for the heating and cooling cycles of a refrigeration circuit or heat pump.

[0029] Also, the present systems and methods described herein will reduce the need for fossil fuel combustion as a form of heating a structure. The systems and methods, which utilize sun rays and heat as a sort of fuel to cool a building, overcome the obstacles which cause a building temperature to rise and will instead be used be utilized to cool the building. The warmer and sunnier it is outside, the more efficient the present cooling system will be which is the opposite of the operation of conventional cooling systems.

[0030] With respect to heating a building, the present systems and methods use the sun rays and thermal energy in the environment, no matter how cold, to heat a building utilizing a refrigeration cycle or heat pump process. The conventional systems are enhanced by the present improvements described herein which assist the heat pump cycle to heat a building without the need for fossil fuels. This in turn reduces greenhouse gases caused by the combustion of fossil fuels that are used to typically heat a building. Furthermore, the present systems and methods significantly reduce thermal pollution caused by the same combustion processes.

[0031] The thermal cell panel system for heating and cooling and associated methods disclosed herein use the sun and environmental thermal energy along with a typical heat pump or air conditioning condensing unit with a variable speed compressor and associated sensors. The system and method detects the outside temperatures, humidity, and weather conditions and interfaces those to the system's internal pressures, temperatures etc., in order to achieve maximum efficiencies. This process resembles artificial environmental intelligence. In addition, the heat pump and the thermal cell panel system are fabricated in one complete and enclosed unit.

[0032] Referring now to FIG. 1, a schematic of a typical heating and cooling system is illustrated and designated 10. The system 10 includes a condenser unit 10 positioned outside the building 14. The condenser unit 10 includes a compressor 16, a condenser coil 18, and a fan 20. The compressor 16 comprises a pump that moves refrigerant between an evaporator coil 24 and the condenser coil 18 to chill the indoor air. The condenser coil 18 releases collected heat into the outside air. The fan 20 blows air over the condenser coil 18 to help dissipate the heat outside the building 14. Coolant lines 22 run from the condenser unit 10 to the evaporator coil 24 inside the building 14 and back to the condenser unit 10. A blower 26 is positioned to circulate air over the evaporator coil 24 in order to disperse the chilled air inside the building 14. A typical gas furnace 28 is also illustrated in FIG. 1 that is used for heating the building 14 through the combustion of natural gas and the blower 26 can be used to disperse the heated air inside the building 14.

[0033] A schematic of a thermal cell panel system for heating and cooling in accordance with the present invention is illustrated in FIG. 2 and generally designated 100. The system 100 includes a plurality of solar thermal cell chambers 102 and a piping network 104 for a flow of the refrigerant through the plurality of solar thermal cell chambers 102. The piping network 104 includes an inlet 106 and outlet 108 to each of the solar thermal cell chambers 108.

[0034] A plurality of pressure valves 110, that are optional and are not required for maximum performance, are in fluid communication with each inlet 106, and each of the pressure valves 110 may be configured to selectively open and close the flow of refrigerant 105 through a respective solar thermal cell chamber 108 in response to a pressure of the refrigerant 105 within the respective solar thermal cell chamber 108.

[0035] The system includes a compressor 112 having a motor 114 coupled to a variable frequency drive (“VFD”) 115. The compressor 112 is coupled to the piping network 104 upstream of the plurality of solar thermal cell chambers 108 and the VFD 115 is configured to adjust a speed of the motor 114 in response to the pressure of the refrigerant 105 within the plurality of solar thermal cell chambers 108.

[0036] The system 100 also includes a condenser coil 116 coupled to the piping network 104 downstream of the plurality of solar thermal cell chambers 108. A fan 117 blows air over the condenser coil 116 to help dissipate the heat of the refrigerant 105. In addition, an evaporator coil 118 is coupled to the piping network 104 downstream of the condenser coil 116 and upstream of the compressor 112.

[0037] Referring now to FIGS. 3A and 3B, a reverse flow of refrigerant 105 through the system 100 is known as the heat pump cycle. The refrigerant 105 is allowed to absorb heat from the cold air and then flow through the pipes 128 of the plurality of solar thermal cell chambers 102. This results in increasing the temperature of the refrigerant 105 even further from external forces allowing a heat pump 115 to absorb heat efficiently during the coldest winter conditions. The system 100 reduces the need to use fossil fuels as a combustion source to heat a structure 114 and releases virtually no thermal pollution or cause greenhouse gas emissions from operation.

[0038] Furthermore, the system 100 is dramatically more efficient than any source of combustion and will significantly reduce the cost of heating a building 114. The system 100 is a relatively simple and inexpensive retro fit to a conventional heat pump 115 or air conditioning condensing unit 12. In addition, the system 100 installs virtually identically to a conventional heat pump 115 or condensing unit 12 and works with practically any furnace or air handler. The system 100 reduces the need for the furnace 28 to use combusted fossil fuels but utilizes the blower section 26 of these components making the combustion chambers obsolete.

[0039] Referring now to FIG. 4, the piping network 104 may also include an inlet manifold 120 coupled to the inlet 106a, 106b, 106c of the respective solar thermal cell chamber 108a, 108b, 108c. In addition, an outlet manifold 122 may be coupled to the outlet 124a, 124b, 124c of the respective solar thermal cell chamber 108a, 108b, 108c, and a bypass 126 in fluid communication with the inlet manifold 120 and outlet manifold 122. The bypass 126 is configured to direct a fluid flow from the inlet manifold 120 to the outlet manifold 122 to bypass the plurality of solar thermal cell chambers 108 when the pressure valves 110 are closed. As stated above, the pressure valves 110 are optional and are not required for maximum performance. The solar thermal cell chambers 108a, 108b, 108c, which hold gained thermal energy for extended and prolonged periods of time 12-24 hours in many cases with no direct solar or thermal gain.

[0040] The piping network 104 includes pipes 128 through each of the thermal cell chambers 108 and the pipes 128 may have heat sink aluminum sleeves 130. The pipes 128 and the heat sink aluminum sleeves 130 may also be coated with a thermal absorbing material 132. Sensors 125a, 125b, 125c having pressure and/or temperature capabilities are within each solar thermal cell chamber 108a, 108b, 108c, and may be in communication with the respective pressure valve 110a, 110b, 110c. As stated above, the pressure valves 110a, 110b, 110c are optional and are not required for maximum performance. Once the temperature exceeds the corresponding refrigerant pressure, the respective pressure valve 110a, 110b, 110c are opened. In addition, the sensors 125a, 125b, 125c are in communication with the compressor 112 in order to adjust a speed of the motor 114 in response to the pressure of the refrigerant.

[0041] Referring now to FIG. 5, a housing 152 for each of the solar thermal cell chambers 108 is insulated 140 and has an interior surface 144 coated with a reflective material 146. In a particular aspect, the solar thermal cell chambers 108 have a U-shaped bottom portion 142 to reflect solar energy to the pipes 128 and tempered glass 148 secured over a top portion to retain heat with the solar thermal cell chamber 108. The solar thermal cell chambers may also have a plurality of drain holes 150 and the piping 128 may comprises copper piping.

[0042] As explained above, the thermal cell chambers 108 include a series of pipes 128 running a circuit through the housings 152 which may be lined with highly reflective material 146, which is many times more reflective mirrored film than any other ever developed. Each pipe 128 running through the thermal cell chambers 108 may be fitted with a heat sink aluminum sleeve 130. The sleeve 130 may be made of any material with high thermal transfer properties.

[0043] The heat sink sleeves 130 and pipes 128 may also be coated with a compound or coating 132, which has been specifically developed to absorb many spectrums of solar rays and absorb energy from those rays into thermal energy and into the pipes 128. The U-shaped bottom portion 142 and pipes 128 may be encased in a highly insulated housing 152 to collect and maintain the thermal energy collected. The tempered glass covering 148 may be comprised of carbon filtered ultra, clear glass with little or no light refraction properties. The high temperature double wall insulated housing 152 may also have drain holes 150 and thermal expansion release holes 154. The use of specialized reflective films and coatings applied to the heat sinks and pipes directs all phases and rays of solar activity into thermal heat gain on the specialized coated materials, even in direct sunshine and through clouds in which certain rays are found.

[0044] Referring now to FIG. 6, a method of operating a thermal cell panel system comprising a plurality of solar thermal cell chambers, a piping network for a flow of a refrigerant through the plurality of solar thermal cell chambers for heating and cooling, and a compressor having a motor coupled to the piping network upstream of the plurality of solar thermal cell chambers, is disclosed. The method is generally designated 200 and begins at 202. The method includes adjusting a speed of the motor, at 204, in response to a pressure of the refrigerant within the respective solar thermal cell chamber.

[0045] The method also includes, at 206, recirculating the refrigerant though the piping network from the condenser through the plurality of solar thermal cell chambers, to a condenser coil coupled to the piping network downstream of the plurality of solar thermal cell chambers, to an evaporator coil coupled to the piping network downstream of the condenser coil, and returning to the condenser. The method ends at 208.

[0046] As explained above, the refrigerant 105 from the heat pump or condensing coil 116 is diverted from the compressor 112 prior to the condensing coils 116 through the panel and piping circuit described above. The refrigerant 105 flows through the series of pipes 128 and after it is compressed by variable speed compressor 112, the refrigerant 105 flows through the solar thermal cell chamber 108 described above. The warm high pressure refrigerant 105 flows through the hot pipes 128 and the pressure in the refrigerant 105 dramatically rises. The reaction by the gas causes an increase in pressure ahead of the compressor 112 is detected and the compressor 112 can significantly reduce its speed and compression which in turn reduces the electrical use.

[0047] The system 100 and method 200 described herein has little or nothing to do with a transfer of heat, which is the key component to conventional solar collection. The present invention describes the warm refrigerant 105 flowing through an even warmer chamber (i.e., the solar thermal cell chamber 108), in order to cause a state change reaction forcing an increase in the pressure of the refrigerant 105 but pulling very little thermal energy away from the heated solar thermal cell chamber 108.

[0048] In addition, the system 100 and method 200 can be applied to many forms of HVAC equipment including but not limited to P-TAC units, window units, roof top units, residential and commercial units, industrial units, etc. For example, a window unit 160 is shown in FIG. 7 with the solar thermal cell chambers 102. Further, the system 100 and method can be used in pool heaters, water heaters, fluid and solid heating systems etc.

[0049] Accordingly, this allows the reaction to continue much longer than a conventional solar collection system in which the heat is transferred to a colder liquid in an effort to transfer the collected thermal energy. This new system and method described herein in which there is a pressure increase but little if any thermal transfer lasts much longer than any solar based unit because the heat is stored inside the insulated solar thermal cell chamber 108 allowing for optimal use well after the sun is no longer shining on the system.

[0050] Even on cloudy days, certain spectrums of the sun are absorbed to increase the pressure and collect the thermal energy within the solar thermal cell chamber 108. This system 100 can reduce the electrical consumption dramatically when compared to conventional cooling methods. Using this system 100 when it is sunnier and the outdoor conditions are warmer can have even more dramatic savings as the pressure from external forces will be greater. This is specifically when cooling capacity is at its greatest. One of the important factors of the system 100 is being able to exploit the characteristic that the rising pressure of the refrigerant 105 causes little or no absorption of heat. This factor is significant as a refrigeration cycle is an equilibrium of heat absorbed and heat released. In other words, heat cannot be added to a refrigeration cycle or the equilibrium will be altered. The system 100 operates on using thermal energy for a pressure increase and not thermal transfer.

[0051] In general, the foregoing description is provided for exemplary and illustrative purposes; the present invention is not necessarily limited thereto. Rather, those skilled in the art will appreciate that additional modifications, as well as adaptations for particular circumstances, will fall within the scope of the invention as herein shown and described and of the claims appended hereto.