Thermally driven environmental control unit

Abstract

The present invention regards a thermally driven, environmental control unit including, in a closed fluid-flow, non-pressurized circuit, a mixing heat exchanger, a heat recovery unit, a fractionator/evaporator, and one or more condensers. The system is designed to include at least one solute and a solvent, selected so that the mixture of each solute and the solvent produce an enthalpy change of between about 5 to 30 kJ/mol for cooling and 10 to 200 kJ/mol for heating. A plurality of pumps are integrated into the system to move the solute and the solvent, and a mixture thereof, among the various components of the present invention. The unit further includes a liquid loop coupled with the mixing heat exchanger and an air handler to provide warm or cool supply air. The present invention further regards a process for cooling or heating air using enthalpy change of solution associated with the dissolution of a solute in a solvent, at relatively constant atmospheric pressure, and separation of the solute from the solvent for re-use in the process.

Claims

1. A thermally driven, environmental control unit comprising: a mixing heat exchanger, a fractionator/evaporator column and a condenser, the fractionator/evaporator column and the condenser being in a closed fluid-flow, non-pressurized circuit with the mixing heat exchanger; a solute and a solvent that the control unit is configured to mix to produce a binary mixture and an enthalpy change, wherein the control unit is further configured to have the solute and solvent fed to the mixing heat exchanger and mixed to produce the enthalpy change in the mixing heat exchanger, wherein the solute and the solvent are selected so that the boiling point of the solute is at least 10 C. lower than the boiling point of the solvent; a liquid loop coupled with the mixing heat exchanger and an air handler to provide warm or cool supply air, wherein the control unit is configured so that: a liquid is circulated within the liquid loop, through the mixing heat exchanger; and heat is exchanged between the liquid in the liquid loop and the binary mixture in the mixing heat exchanger; and the control unit is further configured wherein: the binary mixture is supplied to the fractionator/evaporator column, separating the solute as a vapor from the solvent, the solvent is returned to the mixing heat exchanger; and the solute vapor is supplied to the condenser to condense the solute vapor into a liquid form of solute, and subsequently returned to the mixing heat exchanger.

2. The thermally driven, environmental control unit of claim 1, further comprising a first pump between the condenser and the mixing heat exchanger; a second pump between the mixing heat exchanger and the fractionator/evaporator column; and a third pump between the fractionator/evaporator column and the mixing heat exchanger.

3. The thermally driven, environmental control unit of claim 1, wherein the fractionator/evaporator column is coupled with a heat source, providing heat to the fractionator/evaporator column at temperatures higher than the boiling point of the solute but lower than the boiling point of the solvent.

4. The thermally driven, environmental control unit of claim 3, wherein the heat source is waste heat, solar heat, electric heat or fuel combustion heat.

5. The thermally driven environmental control unit of claim 1, wherein the enthalpy change produced by the mixing of the solute and the solvent is between 200 kJ/mol to 30 kJ/mol.

6. The thermally driven environmental control unit of claim 1, further comprising a heat recovery heat exchanger between the evaporator and the mixing heat exchanger to exchange heat between the solvent from the evaporator and the binary mixture from the mixing heat exchanger.

7. The thermally driven environmental control unit of claim 2, further comprising a fourth pump pumping the liquid through the liquid loop.

8. The thermally driven environmental control unit of claim 1, wherein heat is exchanged between the liquid circulating through the liquid loop and air moving through the air handler.

Description

DESCRIPTION OF THE DRAWINGS

(1) FIG. 1 is a schematic representation of an embodiment of the system of the present invention, used for cooling an environment.

(2) FIG. 2 is a schematic representation of an embodiment of the system of the present invention, used for heating an environment.

(3) FIG. 3 is a schematic representation of an embodiment of the system of the present invention, used for selectively cooling and/or heating an environment.

DETAILED DESCRIPTION OF THE INVENTION

(4) In one embodiment of the invention of the present system (shown in FIG. 1) the system is designed to provide cooling to an environment, in another embodiment of the invention (shown in FIG. 2) the system is designed to provide heating to an environment, and in a third embodiment of the invention (shown in FIG. 3) the system is designed to selectively provide cooling or heating to an environment.

(5) As hereinabove described and shown in FIGS. 1, 2 and 3, the system of the present invention generally includes, in a closed loop, non-pressurized flow cycle, a mixing heat exchanger 2, a heat recovery unit 4, a fractionator/evaporator column 5 for separating the solute and the solvent, such as a fractionator, and a condenser 6. A liquid loop 40 is coupled with both the mixing heat exchanger 2 and an air handler 9, to provide warm or cool supply air. When the system is used to heat an environment, the condenser 6 is incorporated within the air handler 9; when the system is used for cooling, the condenser 6 is placed apart from the air handler 9; and when the system is used as a heat pump, to selectively supply warm and cold air, one condenser 6-2 is placed in the air handler 9, and a second condenser 6-1 is placed apart from the air handler.

(6) In the cooling embodiment of the present invention shown in FIG. 1 The mixing heat exchanger 2 mixes the solvent (received from the fractionator/evaporator column 5) with the solute (pumped from the condenser 6 by means of line 10) producing an endothermic demand, absorbing heat from the liquid in the liquid loop 40, resulting in a chilled liquid that is returned by means of the liquid loop 40 to the air handler 9. In this embodiment the solvent and solute are selected to produce the endothermic reaction of sufficient enthalpy change to chill the liquid in the liquid loop.

(7) The used binary mixture is then pumped from the mixing heat exchanger 2 to the heat recovery unit 4, by means of line 20, and to the fractionator/evaporator column 5, by means of line 21. The fractionator/evaporator column 5 is coupled with a heat source 8, providing heat to the fractionator/evaporator column 5 at temperatures higher than the boiling point of the solute but lower than the boiling point of the solvent, to separate the solute from the solution. The fractionator/evaporator column 5 may be single stage or multiple stages to achieve a high degree of solute separation, producing a solvent-rich return mixture and a solute vapor; the heat source may be controlled by a control unit to maintain the fractionator/evaporator column 5 at the appropriate operating temperature in view of the specific solute and solvent binary mixture.

(8) The solvent rich mixture resulting from the separation process is then pumped back to the mixing heat exchanger 2 by means of lines 30 and 10 for re-use, exchanging heat with used binary mixture across the heat recovery unit 4. Meanwhile, the solute vapor from the fractionator/evaporator column 5 flows to the condenser 6, by means of line 31, where it condenses by rejecting heat to the environment. The condensate solute is then pumped to the mixing heat exchanger 2 as needed. This cycle is repeated to provide a continuous chilled liquid to the air handler 9. When the system is idle, the condensed solute may be stored in the condenser 6 until required for use by the mixing heat exchanger 2. In this arrangement the condenser 6 acts as a suction reservoir for the pump 1.

(9) The heat source 8 may be waste heat, solar heat, electric heat, or fuel combustion heat. A fuel combustion source can be liquid fuels such as diesel, or gas such as natural gas. Each heating device is designed specifically for the heat source selected. If renewable energy is used, the heating source may combine the renewable source with an electric or fuel combustion unit.

(10) The air handler 9, which generally includes a fan 9A to move return air from the room or environment and supply air back into the room or environment, receives the chilled liquid in the liquid loop 40 from the mixing heat exchanger 2, which chilled liquid exchanges heat with the returned room air A1 as the air passes over the loop, supplying cool air A2 back into the room. The liquid loop 40 may be coiled or otherwise structured within either or both of the mixing heat exchanger 2 and the air handler 9, to maximize the amount of liquid subjected to the solute/solvent reaction in the mixing heat exchanger 2, and the amount of chilled or heated liquid provided within the air handler 9; a pump 11 pumps liquid through the liquid loop 40. In this embodiment the solvent and solute are selected to produce the endothermic reaction of sufficient enthalpy change to cool the liquid in the liquid loop.

(11) The heating embodiment shown in FIG. 2 is similar to the cooling embodiment of FIG. 1 described above, except that the condenser 6 may be housed in the air handler 9 to cause heat recovered from the solute vapor during condensation in the condenser 6 to supplement heating of the return room air A1 in the air handler, resulting in warm air A2 being supplied back into the room. In this embodiment, the solute and solvent are selected to give a negative enthalpy change when mixed. Therefore, the mixing heat exchanger 2 mixes the solute into the solvent producing an exothermic process, providing heating by expelling heat to the liquid in the liquid loop 40, resulting in a heated liquid that is returned by means of the liquid loop 40 to the air handler 9. The solvent and solute are selected to have sufficient enthalpy change during the mixing process to heat the liquid in the liquid loop.

(12) Pumps 1, 3 and 7 are incorporated into the system to deliver solute from the condenser 6 to the mixing heat exchanger 2 (shown as pump 1, delivering the solute by means of line 12); to deliver the solute-solvent mixture from the mixing heat exchanger 2 to the heat recovery unit 4 and the fractionator/evaporator column 5 (shown as pump 3, delivering dissolved solute in solution by means of line 20); and to deliver the solvent-rich binary mixture from the fractionator/evaporator column 5 to the heat recovery unit 4 and back to the mixing heat exchanger 2 (shown as pump 7, delivering the solvent-rich binary mixture by means of line 30). Pump 11 is used to circulate the liquid in the liquid loop 40.

(13) For a heat pump as shown in FIG. 3, providing a selective heating and cooling system, the system may have one solvent and two solutes, wherein the solutes have different boiling points (at least 10 C. difference), and both are lower than the solvent boiling point by at least 10 C. This system includes two condensers 6-1, 6-2, one for each of the solutes, with one condenser 6-1 intended to condense and store the solute intended for cooling, and another condenser 6-2 (intended to condense and store the solute intended for the heating system) housed in the air handler 9. The system further includes two control valves 100 to direct the right solute to and from the condensers 6-1, 6-2, by means of lines 32, 33 and 12, respectively, depending on whether a cooling or a heating operation is selected, and two pumps 1C, 1H, each being associated with a condenser to deliver solute to the mixing heat exchanger 2.

(14) The operation of the system of the present invention may be coupled to a room thermostat that will signal the pumps 1, 3, 7, 11 and the air handler fan 9A to start or stop, depending on the actual and the desired temperature of the room, as measured and set at the thermostat.

(15) Integral to design of the system of the present invention is the choice of solute(s) and solvent. The solute(s) and the solvent should be selected so that the solute has a lower boiling point than that of the solvent (at least 10 C., but above the normal practical operating temperature of the mixing heat exchanger 2). The greater the differences between the boiling point of the solute(s) and that of the solvent will allow them to be easily separated in the system of the present invention. Furthermore, the solute and solvent should be selected to have large positive or negative enthalpy change of solution. For heating this enthalpy change may be between 10 kJ/mol and 200 kJ/mol; for cooling this enthalpy change may be between 5 kJ/mol and 30 kJ/mol. Examples of solutes and solvents are provided in Table 1 for heating systems, and Table 2 for cooling systems.

(16) TABLE-US-00001 TABLE 1 Examples of Binary Mixtures For Heating Application with Their Properties Mixing BP BP .sub.solH Temperature Solute ( C.) Solvent ( C.) (kJ/mol) ( C.) BP Titanium tetrachloride 136.4 Tributyl phosphate 289 161 25 152.6 Tin tetrachloride 205 Tributyl phosphate 289 130 25 84 Bromine 58.8 Phosphorus sulfochloride 125 99 25 66.2 Titanium tetrachloride 136.4 s- octyl acetate 211 97.1 23 74.6 Piperidine (39.3) 106 Allyl isothiocynate 148 92.1 17 42 Butyl formate 106 Titanium tetrachloride 136.4 55.7 23 30.4 i- Amyl formate 125 Titanium tetrachloride 136.4 54.8 23 11.4 Ethyl formate 54 Tin tetrachloride 205 38.1 17 151 Ethyl acetate (35.2) 77.1 Tin tetrachloride 205 34.1 17 127.9 Arsenic trichloride 130.2 Dimethyl sulfoxide 189 33.6 25 58.8 i-Butyl acetate 126 Tin tetrabromide 205 29.7 16 79 Pyridine (40.2) 115.2 Propionic acid 141 26.3 25 25.8 Water 100 Triethylene glycol (79.2) 288 21.3 25 188 Ethylacetate (35.2) 77.1 Tin tetrabromide 205 26 17 127.9 Ethylene glycol dimethyl ether 85 Water 100 23.4 25 15 Butylamine (32.6) 77 Water 100 19.1 25 23

(17) TABLE-US-00002 TABLE 2 Examples of Binary Mixtures For Cooling Applications with Their Properties Mixing BP BP .sub.solH Temperature Solute ( C.) Solvent ( C.) (kJ/mol) ( C.) BP Water (44.0) 100 Amyl acetate 149 11.4 25 49 Water (44.0) 200 Butyl acetate 117 10.2 25 17 Nitroethane (41.6) 114 Cyclohexane 80.74 10.5 25 33.26 Thiazole 117 Cyclohexane 80.74 10.5 25 36.26 Cyclopentanol (57.8) 139 Cyclohexane 80.74 19.5 25 58.26 i-Propyl alcohol (45.6) 82.5 i-Octane 99 22 25 16.5 Perfluoro-n-heptane (36.4) 83 i-Octane 99 11.3 25 16 Ethyl alcohol (42.6) 78.37 Nonane 150 25.1 30 71.63 Acetone (30.8) 56 Cyclohexane 80.74 10.3 20 24.74 Ethyl alcohol (42.6) 78.37 Heptane 98.42 25.1 30 20.05 N,N-Diethylformamide 177.6 Cyclohexane 80.74 11.5 25 96.86 N,N-Dimethylacetamide 165 Cyclohexane 80.74 12.7 25 84.26 N,N-Dimethylpropionamide 175 Cyclohexane 80.74 11.5 25 94.26 N-Methylpyrrolidone 204.3 Cyclohexane 80.74 10.9 25 123.56 Propyl alcohol (47.5) 97 Dodecane 214 24.5 30 117 Hexane (31.6) 67 Furfural 162 10 27 95 Acetone (30.8) 56 Hexadecane 271 10.5 25 215 Heptane (36.6) 98.42 N,N-Dimethylformamide 153 11.3 25 54.58 Methyl alcohol (37.4) 65 Benzene 80.1 14.6 25 15.1 Ethyl alcohol (42.6) 78.37 Bromobenzene 156 16.7 25 77.63 Methyl alcohol (37.4) 65 Carbon tetrachloride 76.72 18.7 20 11.72 Ethyl alcohol (42.6) 78.37 Dichloroethyl ether 178.2 10 25 99.83 Octane (41.5) 125 Dichloroethyl ether 178.2 10.5 25 53.2 Propyl alcohol (47.5) 97 Dichloroethyl ether 178.2 11.3 25 81.2 Butyl alcohol (52.3) 118 Ethylbenzene 136 16.7 25 18 i-Propyl alcohol (45.6) 82.5 Ethylbenzene 136 17.6 25 53.5 Propyl alcohol (47.5) 97 Ethylbenzene 136 14.6 25 39 t-Butyl alcohol (47.7) 82 Heptane 98.42 27.3 30 16.42 t-Butyl alcohol (47.7) 82 Hexadecane 271 15.7 30 189 t-Butyl alcohol (47.7) 82 i-Octane 99 23.8 30 17 i-Propyl alcohol (45.6) 82.5 Toluene 110.6 18 25 28.1 Methyl alcohol (37.4) 65 Toluene 110.6 13.2 25 45.6