AT11167U1 - CONSUMPTION DEVICE FOR HEAT SUPPLY AND / OR DISPOSAL USING SOLAR ABSORBERS CONNECTED TO HEAT PUMPS AND HYDRAULIC SWITCHING AS A REFRIGERATING COOLING MACHINE THROUGH SOLAR ABSORPTION - Google Patents

Abstract

The invention relates to a device for Wärmezu- and / or heat dissipation to consumers, such as a swimming pool (16), a Raumheizanlage (22) and / or room conditioning system (21) with a solar absorber (1), with at least one liquid heat carrier leading Absorberleitungssystem (1a, 1b), a heat pump (9), an evaporator circuit (2) which connects an absorber line system (1a) of the solar absorber (1) with the evaporator (9a) of the heat pump (9), wherein in the evaporator circuit (2) a pump (5) is provided, wherein the return line (2b, 2b ') of the evaporator circuit (2) with the flow line (2a, 2a') of the evaporator circuit (2) via a bypass line (4) is connected, wherein a mixing valve (3 ), in particular in the return line (2b, 2b ') is provided, with the colder heat transfer medium from the return line (2b, 2b') of the flow line (2a, 2a ') can be mixed.

Description

Austrian Patent Office AT11167U1 2010-05-15

Description: The invention relates to the multifunctional use of heat pumps with solar absorbers connected as energy carriers, wherein the evaporator inlet temperature is limited by bypass circuits or the solar yield from the solar absorbers is supplied directly to the consumers. By hydraulic switching can be operated with the same heat pump, a room air conditioner and the resulting waste heat through the solar absorber are released to the environment.

In heat pumps, the inlet temperature of the heat carrier is limited in the evaporator to a maximum temperature to prevent overheating of the refrigerant in the heat pump and thus damage the heat pump. Typically, this is accomplished by lower-energy (e.g., geothermal energy) power generation and / or heat pump shut-off procedures.

In the present invention, a bypass line in the evaporator circuit is used to maintain the temperature of the low-temperature solar absorber at the desired level. If the direct solar yield is sufficient for the consumer and / or at certain times of day, the heat pump is switched off and fed via a bypass line, the heat energy from the solar absorber directly to the consumer, optionally a heat exchanger can be interposed.

Heat pumps may also be used to generate refrigeration, e.g. be used for room air conditioners, the resulting waste heat is removed via so-called recooler. An intermediate recovery of this waste heat is considered as state of the art. Especially in populated areas, the noise from external recoolers is disturbing, usually at night, where there is not enough heat energy needed to use the waste heat elsewhere. Extremely quiet recoolers are usually very large and very expensive to buy.

In the present invention, the existing heat pump used to generate heat energy for e.g. Space heaters or swimming pools is used as a refrigerator for e.g. Room air conditioners used. In this case, the heat generation is stopped and the condenser circuit is connected to the cooling register of the air conditioner and connected via a bypass line to the evaporator circuit. The condenser circuit upstream of the shut-off valves to the bypass line is connected via a recooling line to the evaporator circuit / absorber circuit to release the waste heat via the solar absorber to the environment. If due to low temperature differences, the waste heat can not be completely dissipated, an external recooler or other heat energy consuming consumer is switched on.

The invention is illustrated in the following drawing, wherein the reference numerals contained therein have the following meaning: 1 solar absorber 1 a absorber circuit 1 b absorber circuit 2 evaporator circuit 2a evaporator side feed line section (evaporator circuit) 2b evaporator side return line section (evaporator circuit) 2a 'absorber side feed line section (evaporator circuit) 2b 'absorber-side return line section (evaporator circuit) 3 first mixing valve 4 first bypass line 5 feed pump (evaporator circuit) 6a, 6b shut-off valves (evaporator circuit) 7a, 7b shut-off valves (return cooling line) 1/7 AT11167U1 2010-05-15 Austrian

Patent Office 8a, 8b Shut-Off Valves (Bypass Line) 9 Heat Pump 9a Evaporator 9b Capacitor 10a, 10b Shut-Off Valves (Condenser Circuit) 11 Condenser Circuit 11a Condenser-side Supply Line Section (Condenser Circuit) 11b Condenser-side Return Line Section (Condenser Circuit) 11a 'Consumer-side Supply Line Section (Condenser Circuit) 11b' Consumer-side Return Line Section (Condenser Circuit) 12 Second mixing valve (condenser circuit) 13 Feed pump (condenser circuit) 14 Heat exchanger 15 Consumer circuit 15a, 15b Shut-off valve (consumer 1) 16 Consumers 1 17a, 17b Shut-off valve (solar circuit) 18 Consumer circuit 18a, 18b Shut-off valve (consumer 2 19 Consumer circuit 19a, 19b Shut-off valve (consumer 3 ) 20 Solar circuit 20a Solar circuit Flow 20b Solar circuit Return 21 Consumer 2 21a Supply line Consumer 2 - Supply 21a Supply line Consumer 2 - Return line to 22 consumers 3 22a supply line consumer - supply line 22a supply line consumer - return 23 bypass line 23a bypass line flow 23b bypass line return 24 return cooling line 24a return cooling line flow 24b return cooling line return 25 supply line external recooler 25a, 25b shut-off valve supply line external recooler 26a, 26b shut-off valve evaporator 27 check valve 28 shut-off valve Pump bypass 29 External recooler 30 Second bypass line (consumer-side condenser circuit) 31 Pump bypass 32 Conveyor pump Solar circuit 33 Heat exchanger 34 Short-circuit line 35 Load 4 T1 Temperature sensor T2, T3 Outside temperature sensor In heat production, the thermal energy gained via the solar absorber 1 is transferred via the supply line by means of a pump 5 2a, 2a 'of the evaporator circuit 2 to the evaporator 9a of the heat pump 9, where heat energy is transferred to the refrigerant of the heat pump 9. The cooled heat transfer medium is led via the return 2b, 2b 'of the evaporator 2 back into the absorber circuit 1a, where heat energy is absorbed again. The shut-off valves 6a, 6b in the evaporator circuit 2 and the shut-off valves 26a, 26b on the evaporator 9a are open. The shut-off valves 7a, 7b of the recooling line 24, the shut-off valves 8a, 8b of the bypass line 23 and the shut-off valves 25a, 25b of the supply line to the external recooler 29 are closed.

A mixing valve 3 regulates the temperature of the heat carrier in the flow line 2a, 2a 'of the evaporator circuit 2 by colder heat transfer from the return 2b, 2b' of the evaporator circuit 2 via a bypass line 4 in the flow line 2a, 2a 'of the evaporator circuit 2 is mixed, wherein the control of the mixing valve via the temperature of the heat carrier in the flow line 2a, 2a 'of the evaporator circuit 2 takes place.

The condenser circuit 11 of the heat pump 9 is connected in the present case to a heat exchanger 14, in turn, the output side to the consumer 16, 22, e.g. a swimming pool and / or a space heater, is connected. The circulation of the heat carrier in the condenser circuit 11 is effected by a pump 13. The shut-off valves 10a, 10b in the condenser circuit 11 are open, the shut-off valve 28 in the pump bypass 31 and the mixing valve 12 to the bypass line 30 are closed.

The shut-off valves 19a, 19b, 15a, 15b regulate the distribution of heat energy to the individual consumers. The valves 18a, 18b in the supply line to the consumer 18, e.g. Room air conditioner, are closed.

The optimal use of solar energy absorbed in the solar absorber 1 is controlled by the flow rate of the pump 5, which is controlled by the temperature of the heat carrier in the flow line 2a, 2a 'of the evaporator circuit 2 and / or by the outside temperature. If the solar yield of the solar absorber 1 is sufficient to directly supply one or more consumers, the heat pump 9 is switched off, the shut-off valves 26a, 26b on the evaporator 9a of the heat pump 9 and the mixing valve 3 in the evaporator circuit 2 are closed to the bypass line 4, and the shut-off valves 8a, 8b of the bypass line 23 are opened. In the condenser circuit 11, the shut-off valves 10a, 10b and the mixing valve 12 are closed towards the bypass line, the shut-off valve 28 in the pump bypass 31 is opened. All other valves remain in the previously described position.

In the figure, the solar absorber 1 is designed as a two-line system, with an absorber circuit 1a with the evaporator circuit 2 and the other absorber circuit 1b are connected directly to the consumer 16. The shut-off valves 17a, 17b in the solar circuit 20 are opened with sufficient solar yield.

If the heat pump used for refrigeration, the valves 19a, 19b, 15a, 15b in the leads to the consumers 16, 22 are closed and the valves 18a, 18b of the consumer 21 is opened. The shut-off valves 10a, 10b in the condenser circuit and the shut-off valves 6a, 6b in the evaporator circuit are closed, the shut-off valves 8a, 8b of the bypass line and the shut-off valves 26a, 26b on the evaporator 9a of the heat pump 9 are open.

Via a heat exchanger 14, the load 21 is connected to the load-side supply and return line section 11a ', 11b', wherein the pump 13 in the consumer-side supply line section 11a 'of the condenser circuit 11, the heat transfer medium via the bypass lines 23 and the evaporator side supply and return line sections 2a, 2b to the evaporator 9a of the heat pump 9 promotes.

By the mixing valve 12 in the consumption-side return line section 11 b 'of the con-densatorkreislaufes 11 is by admixing colder heat transfer from the return line section 11 b' via the bypass line 30 in the absorber side flow line section 11 a 'the temperature of the heat carrier regulated to overheat the To prevent refrigerant in the heat pump 9. The heat generated by the process of the heat pump waste heat in the condenser 9b of the heat pump 9, the condenser side feed and return line sections 11a, 11b, the recooling lines 24 and the absorber side pre and 3/7

Claims (22)

Austrian Patent Office AT11167U1 2010-05-15 return lines 2a ', 2b' of the evaporator circuit 2 passed and discharged in the absorber line system 1a of the solar absorber to the environment. The valves 7a, 7b of the recooling lines are opened, the shut-off valves 25a, 25b and the mixing valve in the absorber-side return line section 2b 'of the evaporator circuit 2 control the distribution of dissipated waste heat between the solar absorber 1 and the external recooler 29. Claims 1. Device for heat supply and / or heat dissipation to consumers, such as a swimming pool (16), a space heating system (22) and / or room air conditioning system (21) with a solar absorber (1), with at least one absorber duct system leading to a liquid heat carrier (1a, 1b), a heat pump (9 ), an evaporator circuit (2) which connects an absorber line system (1a) of the solar absorber (1) with the evaporator (9a) of the heat pump (9), wherein in the evaporator circuit (2) a pump (5) is provided, characterized in that the return line (2b, 2b ') of the evaporator circuit (2) with the flow line (2a, 2a') of the evaporator circuit (2) Via a bypass line (4) is connected, wherein a mixing valve (3), in particular in the return line (2b, 2b ') is provided, with the colder heat transfer medium from the return line (2b, 2b') of the flow line (2a, 2a ') can be mixed. 2. Apparatus according to claim 1, characterized in that the solar absorber (1) is designed as a two-line absorber, wherein two separate Absorberleitungssysteme (1a, 1b) are present, which supply different consumers with different temperatures with different heat transfer. 3. A device according to claim 2, characterized in that an absorber line system (1 a) the evaporator circuit (2) of the heat pump (9) and the other absorber line system (1 b) supplies a solar circuit (20) with directly connected consuming (16). 4. Apparatus according to claim 3, characterized in that a condenser circuit (11) the condenser (9b) of the heat pump (9) via a feed line (11a, 11a ', 21a, 22a) and a return line (11b, 11b', 21b, 22b) connects to one or more consumers (16, 21, 22). 5. Apparatus according to claim 4, characterized in that a heat exchanger (14) is provided, which connects the condenser circuit (11) with the consumption circuits (33, 34). 6. Device according to one of claims 1 to 5, characterized in that the consumers (16, 21, 22) shut-off valves (15a, 15b, 17a, 17b, 18a, 18b, 19a, 19b) are connected upstream. 7. Device according to one of claims 4 to 6, characterized in that in the flow line (11 a, 11 a ', 21 a, 22 a) and in the return line (11 b, 11 b', 21 b, 22 b) of the condenser circuit (11) shut-off valves (10 a , 10b) for separating the condenser-side flow and return line sections (11a, 11b) from the consumer-side flow and return line sections (11a1, 11b ', 21a, 21b, 22a, 22b) are provided, and that shut-off valves (6a, 6b) in the Supply line (2a, 2a ') and in the return line (2b, 2b') of the evaporator circuit (2) for separating the absorber side flow and return line sections (2a ', 2b') of the evaporator side supply and return line sections (2a, 2b) are, wherein the consumption-side flow and return line sections (11a ', 11b') of the condenser circuit (11) via bypass lines (23) with the evaporator side supply and return line sections (2a, 2b) of the evaporator circuit (2) Heat pump (9) are connected and the capacitor-side flow and return line sections (11a, 11b) of the condenser circuit (11) via Rückkühlleitungen (24) with the absorber side supply and return line sections (2a1, 2b ') of the evaporator circuit (2) are connected. 4/7 Austrian Patent Office AT11167U1 2010-05-15 8. The device according to claim 7, characterized in that the recooling lines (24) with an additional cooling device (29), in particular glycol recooler are connected to Abwärmevernichtung. 9. Apparatus according to claim 7 or 8, characterized in that the consumer-side supply and return line sections (11a1, 11b ') of the condenser circuit (11) via a bypass line (30) are connected, wherein a mixing valve (12) in particular in the return line section (11b ') is provided, with the colder heat transfer medium from the return line section (11 b') the feed line section (11a1) can be admixed. 10. A method for heat supply and / or removal to consumers, such as a swimming pool (16), a space heating system (22) and / or room air conditioning system (21), with a device according to any one of claims 1-9 with a solar absorber (1 ) comprising at least one absorber line system (1a, 1b) leading to a liquid heat carrier, a heat pump (9), an evaporator circuit (2) connecting an absorber line system (1a) of the solar absorber (1) to the evaporator (9a) of the heat pump (9) , wherein in the evaporator circuit (2) a pump (5) is provided, characterized in that as overheating protection for the heat pump (9) the limitation of the refrigerant temperature of the heat pump (9) by admixing colder heat carrier from the return line (2b, 2b ') the evaporator circuit (2) to the flow line (2a, 2a ') of the evaporator circuit (2) via a mixing valve (3). 11. The method according to claim 10, characterized in that the mixing valve (3) according to the temperature of the heat carrier in the flow line (2a, 2a ') of the evaporator circuit (2) is regulated. 12. The method according to claim 10 or 11, characterized in that the delivery rate of the pump (5) of the evaporator circuit (2) with increasing the temperature of the heat carrier in the flow line (2a, 2a ') is increased. 13. The method according to claim 12, characterized in that the delivery rate of the pump (5) is regulated in dependence on the outside temperature. 14. The method according to claim 9-13, characterized in that at high heat supply by the solar radiation of the solar circuit (20) by opening the valves (17a, 17b) and with low heat supply by solar radiation additionally the condenser circuit (11) by opening the valves ( 15a, 15b) for supplying the load (16) goes into operation. 15. The method according to any one of claims 9-14, characterized in that the heat of the air conditioner (21) via the circuit, the supply and return line (21a, 21b) of the air conditioner (21), from the consumer-side supply and return line sections (11a ', 11b'), from the bypass lines (23) and the evaporator-side feed and return line sections (2a, 2b), the evaporator (9a) of the heat pump (9) is supplied. 16. The method according to claim 15, characterized in that as overheating protection for the heat pump (9) the limitation of the refrigerant temperature of the heat pump (9) by admixing colder heat transfer medium from the consumer-side return line section (11b1) of the condenser circuit (11) to the consumer-side supply line section (11a ') of the condenser circuit (11) via the mixing valve (12). 17. The method according to claim 16, characterized in that the mixing valve (12) is controlled according to the temperature of the heat carrier in the consumer-side flow line section (11a1) of the condenser circuit (11). 18. The method according to any one of claims 9-17, characterized in that the delivery rate of the pump (13) of the condenser circuit (11) with increasing temperature of the heat carrier in the flow line (11a, 11a ') is increased. 5/7 Austrian Patent Office AT 11 167 U1 2010-05-15 19. The method according to any one of claims 15-18, characterized in that the waste heat from the heat pump (9) via the circuit consisting of the condenser-side feed and return line sections (11a, 11b) of the condenser circuit (11), from the return cooling lines ( 24), from the absorber-side feed and return line sections (2a ', 2b') and the absorber line system (1a) and / or the circuit (25) of an additional cooling device (29), in particular glycol recooler consists, is discharged. 20. The method according to claim 19, characterized in that a division of the waste heat energy to be delivered between the solar absorber (1) and another additional device (29) for waste heat destruction by means of the valves (25a, 25b) and a mixing valve (3) in dependence on the outside temperature and the temperature of the heat carrier in the flow line (24a) of the recooling line (24) is controlled. 21. The method according to any one of claims 9-14, characterized in that the valves (8a, 8b) in the bypass lines (23) and the valves (26a, 26b) in the evaporator line (2) in dependence on outside temperature and / or timing and / or the operating state of the heat pump (9) are regulated. 22. The method according to claim 21, characterized in that for direct use of the absorber (1) when the heat pump (9) of the evaporator circuit (2) via a bypass line (23) to the condenser circuit (11) is connected, wherein the valves (26a, 26b) are closed and the valves (8a, 8b) are opened. For this 1 sheet drawings 6/7