A direct exchange heating/cooling system includes a specially designed supplemental air-source heat exchanger (also referred to herein as a High Level Heat Dissipater (“HLHD”). The HLHD is coupled to the primary vapor/hot gas line exiting the system's compressor at a point between the compressor uni
A direct exchange heating/cooling system includes a specially designed supplemental air-source heat exchanger (also referred to herein as a High Level Heat Dissipater (“HLHD”). The HLHD is coupled to the primary vapor/hot gas line exiting the system's compressor at a point between the compressor unit and the sub-surface geothermal heat exchange tubing, and is operable only in the cooling mode of system operation. The HLHD includes heat exchange tubing that is sheltered from rain/moisture and has supply and discharge refrigerant transport tubing with relatively equally sized interior diameters, designed solely for mostly vapor (as opposed to liquid) refrigerant transport. The HLHD incorporates at least two check valves, or the like, so as to force hot compressor discharge gas through the HLHD in the cooling mode, and so as to prohibit geothermally warmed refrigerant gas flow through the HLHD in the heating mode. The HLHD has specially designed heat exchangers and may optionally include a fan.
대표청구항▼
1. A direct exchange heating/cooling system having a heating mode and a cooling mode, the system comprising: a sub-surface geothermal heat exchanger including sub-surface heat exchange tubing; an interior heat exchanger; a primary vapor line extending between the interior heat exchanger and the sub-
1. A direct exchange heating/cooling system having a heating mode and a cooling mode, the system comprising: a sub-surface geothermal heat exchanger including sub-surface heat exchange tubing; an interior heat exchanger; a primary vapor line extending between the interior heat exchanger and the sub-surface geothermal heat exchange tubing; a compressor fluidly communicating with primary vapor line; a refrigerant disposed in the primary vapor line and pressurized by the compressor, the refrigerant having a heating mode refrigerant flow direction through the primary vapor line from the sub-surface geothermal heat exchanger to the compressor and then to the interior heat exchanger, and a cooling mode refrigerant flow direction through the primary vapor line from the compressor to the sub-surface geothermal heat exchanger and then to the interior heat exchanger, the refrigerant in the cooling mode having a waste heat content; a controller for selectively operating the system in the heating and cooling modes; and a supplemental air-source heat exchanger including: a supply line having a supply line inlet fluidly communicating with an upstream point of the primary vapor line, and a supply line outlet; a discharge line having a discharge line inlet in fluid communication with the supply line outlet, and a discharge line outlet fluidly communicating with a downstream point of the primary vapor line, wherein the upstream point is located nearer the compressor than the downstream point; the supply and discharge line providing supplemental heat transfer tubing configured to solely pre-cool the hot gas refrigerant exiting the compressor such that the hot gas in the air-source unit portion is not materially condensed; a flow director associated with the primary vapor line and the supplemental air-source heat exchanger, the flow director having a cooling mode configuration that diverts refrigerant from the primary vapor line to flow through the supply and discharge lines when the refrigerant travels in the cooling mode refrigerant direction, and a heating mode configuration in which refrigerant is blocked from the supply and discharge lines when the refrigerant travels in the heating mode refrigerant flow direction. 2. The system of claim 1, in which each of the supply and discharge lines of the supplemental heat transfer tubing comprises refrigerant grade finned tubing having a ⅜inch outside diameter and approximately 12 to 14 fins per linear inch, and in which the total length of finned tubing in the supply and discharge lines of the supplemental heat transfer tubing is approximately 0.0096 linear feet, plus or minus 5%, per BTU of the cooling load design capacity, where the cooling load design capacity is measured in BTUs. 3. The system of claim 1, in which a fan is provided to generate an air flow across each of the supply and discharge lines of the supplemental heat transfer tubing, where the fan is operatively controlled by at least one of a temperature activated switch which activates the fan when the refrigerant temperature exiting the discharge lines of the supplemental heat transfer tubing is above approximately 100 degrees F., and a pressure activated switch which activates the fan when the refrigerant pressure exiting the discharge lines of the supplemental heat transfer tubing is above approximately 317psi. 4. The system of claim 3, in which the fan has a power draw of no more than approximately 0.325 watts, plus or minus 5%, per each linear foot of finned tubing provided by the supply and discharge lines, and where the fan is configured to have a fan air flow of approximately 0.8333 cubic feet per minute, plus or minus 5%, per each linear foot of finned tubing provided by the supply and discharge lines. 5. The system of claim 2, further comprising an unfinned U-bend segment extending between the supply line outlet and the discharge line inlet. 6. The system of claim 5, in which an initial refrigerant charge is disposed in the system, the system further comprising an additional refrigerant charge for operating the supplemental air-source heat exchanger, wherein the additional refrigerant charge is determined by an overall length of the supply and discharge lines multiplied by 0.0375 pounds per linear foot, plus a total length of the ⅜inch outside diameter finned tubing in the supply and discharge lines multiplied by 0.0375 pounds per linear foot, plus one-half of a total length, in feet, of the unfinned U bend segment. 7. The system of claim 1, further comprising a containment tube configured to shelter the supply and discharge lines from moisture. 8. The system of claim 7, in which the containment tube includes outwardly flared upper and lower portions. 9. The system of claim 1, in which the supply and discharge lines have equally sized interior diameters. 10. The system of claim 1, in which the flow director comprises a first check valve disposed in the primary vapor refrigerant line between the upstream and downstream points and a second check valve disposed in one of the supply and discharge lines.
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