JP2010185656A - Air conditioning system - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To improve the overall efficiency of a system by effectively using waste heat for a vapor compression refrigeration cycle. <P>SOLUTION: The system includes a power converter (30) for converting waste heat to power. An air conditioner (20) of the vapor compression refrigeration cycle includes a compressor (61) driven by the power of the power converter (30). A generator (40) is connected to the converter (30), and a motor (50) driving the compressor (61) in cooperation with the power of the converter (30) is connected to the air conditioner (20). The converter (30) includes: a conversion circuit (70) to which a steam generator (72) generating a working medium of overheated steam by waste heat, a steam turbine (73) generating power according to the working medium of overheated steam, a condenser (74) condensing the working medium, and a pump (71) supplying the working medium to the steam generator (72) are connected. <P>COPYRIGHT: (C)2010,JPO&INPIT

Description

    The present invention relates to an air conditioner, and more particularly to an air conditioner that utilizes exhaust heat in a vapor compression refrigeration cycle.

    Conventionally, an air conditioner of a vapor compression refrigeration cycle includes a compressor, an outdoor heat exchanger, an expansion valve, and an indoor heat exchanger, and performs a cooling operation and a heating operation.

    On the other hand, some cogeneration systems include an absorption refrigeration apparatus. This cogeneration system generally generates power by driving a generator with a heat engine such as a diesel engine, a gas engine or a gas turbine, and drives an absorption refrigeration system using exhaust heat of the heat engine to Is generated to perform cooling or the like.

    In this cogeneration system that performs cooling, electricity demand exists throughout the year, whereas cooling operation is performed only in the summer. In other words, since cooling is not necessary in the intermediate period or winter season, even if the refrigeration apparatus is driven by exhaust heat, the generated cooling heat is not used. For this reason, in the conventional cogeneration system, the operation of the refrigeration apparatus is not performed during a period when cooling is unnecessary.

    However, if the refrigeration apparatus is stopped as described above, the exhaust heat from the heat engine is not fully utilized during that time. For example, this problem becomes serious when a cogeneration system is installed in an office building.

    In other words, since there is little demand for hot water supply in office buildings, the exhaust heat is hardly used particularly in the intermediate period, and the exhaust heat must be discarded as it is. For this reason, the conventional cogeneration system has a problem that effective use of energy cannot be achieved. In addition, the conventional cogeneration system has a problem that it is difficult to recover the equipment cost by reducing the operating cost.

    In particular, in an air conditioner of a vapor compression refrigeration cycle, heat is not directly used as a driving source, so that it has not been conventionally used in a cogeneration system. Therefore, there is a problem that the effective use of exhaust heat cannot be achieved.

    The present invention has been made in view of such a point, and an object of the present invention is to effectively utilize exhaust heat in a vapor compression refrigeration cycle and improve the efficiency of the entire apparatus.

<Summary of invention>
The present invention drives the compressor of the air conditioner of the vapor compression refrigeration cycle using exhaust heat.

<Solution>
Specifically, as shown in FIG. 1, the present invention includes a power converter (30) that converts exhaust heat into power, and a compressor (61) that is driven by the power output from the power converter (30). And a vapor compression refrigeration cycle air conditioner (20).
An air conditioner comprising:

    The power converter (30) is connected to a generator (40) and supplies power to the air conditioner (20) during air conditioning, while power is supplied to the generator (40) when the air conditioner (20) is stopped. It may be configured to supply to.

    The power converter (30) may be configured to be connected to a generator (40) and distribute and supply power to the generator (40) and the air conditioner (20).

    The power converter (30) receives the steam generator (72) that generates the superheated steam working medium by exhaust heat and the superheated steam working medium generated by the steam generator (72). The generated steam turbine (73), the condenser (74) that condenses the working medium flowing out from the steam turbine (73), and the working medium condensed by the condenser (74) is supplied to the steam generator (72). A conversion circuit (70) connected to the supply means (71) may be provided.

    The air conditioner (20) may be connected to an electric motor (50) that drives the compressor (61) in cooperation with the power of the power converter (30).

    The condenser (74) of the power converter (30) may be configured to be supplied with cooling water cooled by a cooler and to condense the working medium with the cooling water.

    The condenser (74) of the power converter (30) may be configured to be supplied with outdoor air and to condense the working medium with the outdoor air.

    The condenser (74) of the power converter (30) may be configured to be supplied with indoor air discharged from the room and condense the working medium with the room air.

    The power converter (30) and the air conditioner (20) are formed as separate and independent components, while the power converter (30) and the air conditioner (20) include a power shaft (12 ).

    In addition, the power converter (30) is connected to the generator (40), and when the air conditioner (20) is stopped, the power generator (40) is heated by the heat radiation of the condenser (74) and at the same time the generator (40) It may be configured to drive.

    Further, the power converter (30) and the air conditioner (20) are formed as an integral structure, while the power converter (30) conversion circuit (70) and the air conditioner (20) air conditioning circuit. (60) is configured in an independent circuit, and the condenser (74) of the power converter (30) and the heat source side heat exchanger (63) of the air conditioner (20) are integrated into one. Two heat exchange mechanisms (15) may be configured.

    The air conditioning circuit (60) of the air conditioner (20) may be configured to perform a reversible cycle.

    The air conditioning circuit (60) of the air conditioner (20) is configured to perform only the positive cycle, and the air conditioner (20) is cooled with air cooled by the use side heat exchanger (65). On the other hand, it may be configured to perform heating with air heated by the heat exchange mechanism (15).

    Further, the power converter (30) and the air conditioner (20) are formed as an integral structure, while the working medium of the power converter (30) and the heat working medium of the air conditioner (20) The power converter (30) is composed of the same working medium, and is connected so that the conversion circuit (70) of the power converter (30) and the air conditioner circuit (60) of the air conditioner (20) communicate with each other. The condenser (74) may be configured as a condensing heat exchanger that also serves as a heat source side heat exchanger of the air conditioner (20).

    The air conditioning circuit (60) of the air conditioner (20) is configured to perform a reversible cycle, and the conversion circuit (70) of the power converter (30) and the air conditioning circuit (60) of the air conditioner (20). Means that the working medium of the power converter (30) and the working medium of the air conditioner (20) merge at the inlet of the condenser (74) during the positive cycle of the air conditioner (20), and the outlet of the condenser (74) In this case, the working medium of the power converter (30) and the working medium of the air conditioner (20) are separated, while the working medium that has flowed out of the steam turbine (73) during the reverse cycle is compressed by the compressor (61) and the use side heat exchanger ( 65), may be configured to return to the steam turbine (73) via the supply means (71) and the steam generator (72).

    The air conditioning circuit (60) of the air conditioner (20) is configured to perform only the positive cycle, and the air conditioner (20) is cooled with air cooled by the use side heat exchanger (65). On the other hand, the condenser (74) may be configured to perform heating with the air heated by the working medium of the power converter (30).

    The generator (40) driven by the power generated by the power converter (30) and the compressor (61) of the air conditioner (20) in cooperation with the power generated by the power converter (30) An electric motor (50) for driving, and the power converter (30) includes a steam turbine (73) for generating power, while the electric motor (50), the coupling mechanism (19), and the compressor (61) The coupling mechanism (19), the steam turbine (73), the coupling mechanism (19), and the generator (40) may be coupled in order.

    That is, in the present invention, the power converter (30) converts the exhaust heat into power, and the compressor (61) of the air conditioner (20) is driven by the power output from the power converter (30).

    For example, in the steam generator (72), the power converter (30) generates a superheated steam working medium by exhaust heat. A steam turbine (73) receives the working medium of the superheated steam to generate power. The working medium flowing out of the steam turbine (73) is condensed by the condenser (74) and then returned to the steam generator (72) by the supply means (71).

    The power of the power converter (30) is supplied to the generator (40) when the air conditioner (20) is stopped, and the generator (40) generates power.

    The compressor (61) is driven by the electric motor (50) when there is little exhaust heat.

    The working medium of the power converter (30) is cooled by the cooling water, outdoor air, or indoor air in the condenser (74).

    Moreover, heating operation may be performed by the heat radiation of the condenser (74) of the power converter (30).

    Therefore, according to the present invention, a working medium of superheated steam is generated by exhaust heat, and the compressor (61) of the air conditioner (20) is driven by the power of the power converter (30) generated by the working medium. As a result, the exhaust heat can be used effectively, and at the same time, high efficiency can be achieved by performing bottoming power generation.

    That is, according to the present invention, exhaust heat can be used effectively. As a result, the combustion energy input to the gas turbine or the like can be used effectively, and the efficiency of the entire system in the cogeneration system can be improved.

    In particular, since the air conditioner (20) of the vapor compression refrigeration cycle can be driven by exhaust heat, the efficiency of the air conditioner (20) can be improved.

    Further, if the power of the steam turbine (73) is distributed to the air conditioner (20) and the generator (40), the operation efficiency can be further improved.

    Further, when the electric motor (50) is provided, the air conditioner (20) can be driven reliably even when the exhaust heat is low, and the reliability can be improved.

    Moreover, if the working medium of the said air conditioner (20) and a power converter (30) is made into the same working medium, the simplification of the whole apparatus can be achieved.

    Moreover, if the working medium of the said air conditioner (20) and a power converter (30) is made into a different working medium, the freedom degree of application will become large and the applicable range of an apparatus can be expanded.

    Further, when the cooling fluid is cooled by a cooler such as a cooling tower, the power conversion efficiency can be improved.

    Further, when the working medium of the power converter (30) is cooled with outdoor air, the outdoor air is used, so that the overall configuration can be simplified and the operation can be performed even in winter. .

    In addition, when the working medium of the power converter (30) is cooled with room air, the room air is used, so that the cold heat of the exhaust can be recovered.

    If the air conditioner (20) and the power converter (30) are separate components, the air conditioner (20) and the power converter (30) can be simplified. In other words, the air conditioner (20) and the power converter (30) do not need to be dedicated products, and can be generalized.

    When the heat source side heat exchanger (63) of the air conditioner (20) and the condenser (74) of the power converter (30) are integrated to form a heat exchange mechanism (15), during heating operation, The working medium of the air conditioner (20) can suck the heat released from the working medium of the power converter (30) in the heat exchange mechanism (15). As a result, no cooling fluid is required during heating operation, and high efficiency can be achieved.

    In addition, when heating is performed by heating air with the working medium of the power converter (30) in the heat exchange mechanism (15), power generation can be performed at the same time as the heating operation, thus improving efficiency. Can be achieved. Moreover, the air conditioner (20) may be configured as a cooling only machine, and the configuration can be simplified.

    If the condenser (74) of the power converter (30) also serves as the heat source side heat exchanger of the air conditioner (20), the configuration of the entire apparatus can be simplified.

    The motor (50), the coupling mechanism (19), the compressor (61), the coupling mechanism (19), the steam turbine (73), the coupling mechanism (19), and the generator (40) are coupled in order. Then, operation switching can be performed smoothly.

It is a circuit diagram of the air conditioner which shows Embodiment 1 of this invention. It is a circuit diagram of the power converter which shows Embodiment 1 of this invention. It is a schematic block diagram of the air conditioning apparatus which shows Embodiment 1 of this invention. It is a circuit diagram of the air conditioning apparatus which shows Embodiment 2 of this invention. It is a circuit diagram of the air conditioning apparatus which shows Embodiment 3 of this invention. It is a circuit diagram of the air conditioning apparatus which shows Embodiment 4 of this invention. It is a circuit diagram of the air conditioning apparatus which shows Embodiment 5 of this invention. It is a circuit diagram of the air conditioning apparatus which shows Embodiment 6 of this invention. It is a circuit diagram of the air conditioning apparatus which shows Embodiment 7 of this invention. It is a circuit diagram of the air conditioning apparatus which shows Embodiment 8 of this invention.

BEST MODE FOR CARRYING OUT THE INVENTION 1

    Hereinafter, Embodiment 1 of the present invention will be described in detail with reference to the drawings.

    As shown in FIGS. 1-3, the air conditioning apparatus (10) of this embodiment comprises the cogeneration system (11). The cogeneration system (11) is installed in an office building.

    The air conditioner (10) includes an air conditioner (20) and a power converter (30), and an auxiliary generator (40) that is a generator (40) and an electric motor (50). The air conditioner (20) and the power converter (30) are formed as separate and independent components.

    The air conditioner (20) includes an air conditioning circuit (60) constituting a vapor compressor (61) refrigeration cycle. The air conditioning circuit (60) includes a compressor (61), a four-way switching valve (62), an outdoor heat exchanger (63) that is a heat source side heat exchanger, an expansion valve (64) that is an expansion mechanism, and use side heat. An indoor heat exchanger (65), which is an exchanger, is connected in order by a pipe (66). The air conditioning circuit (60) is configured such that the working medium is filled and the working medium circulates.

    The outdoor heat exchanger (63) is configured to exchange heat with the outdoor air (21) and the working medium, and the indoor heat exchanger (65) is configured to heat the indoor air (22) and the working medium. Configured to replace. The air conditioning circuit (60) is configured to perform a reversible cycle. That is, the air conditioning circuit (60) is configured to perform a forward cycle cooling operation and a reverse cycle heating operation.

    The compressor (61) includes a piston-type or rotary-type compression mechanism, but does not include a drive source such as an electric motor. In addition, an artificial refrigerant such as R22, R407C, and R410A, a natural refrigerant such as CO2, or a mixed refrigerant thereof is applied to the working medium.

    The power converter (30) includes a closed circuit conversion circuit (70). The conversion circuit (70) of the power converter (30) and the air conditioning circuit (60) of the air conditioner (20) are configured as independent circuits. As shown in FIG. 2, the conversion circuit (70) of the power converter (30) has a pump (71), a steam generator (72), a steam turbine (73), and a condenser (74) in order ( 75) connected and configured. And the said conversion circuit (70) is comprised so that a working medium may be filled and this working medium may circulate.

    For example, water is used as a working medium of the conversion circuit (70) in the power converter (30). However, an artificial refrigerant such as R22, R407C, and R410A, a natural refrigerant such as CO2, or a mixed refrigerant thereof may be applied to the working medium. Furthermore, the working medium of the power converter (30) may be the same working medium as the working medium of the air conditioner (20), or a working medium different from the working medium of the air conditioner (20). Also good.

    The pump (71) constitutes supply means for circulating the working medium, and supplies the working medium to the steam generator (72).

    Exhaust heat is supplied to the steam generator (72) from the exhaust heat source (31) through the heat passage (32). The steam generator (72) is configured to heat the working medium with exhaust heat to generate superheated steam working medium. The exhaust heat source (31) is composed of, for example, a gas turbine, and the exhaust heat of the gas turbine is supplied to the steam generator (72). In addition, the said gas turbine drives a main generator, for example. The power generated by the main generator covers all or part of the power demand of the office building.

    The steam turbine (73) constitutes a conversion mechanism that converts heat into power. The steam turbine (73) is configured to receive the working medium of superheated steam (steam) from the steam generator (72), expand the working medium, and rotate to generate power by the expansion of the working medium. Has been. The steam turbine (73) is connected to the compressor (61) of the air conditioner (20) via the power shaft (12) and is configured to drive the compressor (61).

    The condenser (74) is configured so that a cooling fluid is supplied via the fluid passage (33) and heat-exchanges between the cooling fluid and the working medium (water vapor). And the said condenser (74) is comprised so that the working medium which is water vapor | steam may be condensed. Although not shown, the cooling fluid is composed of cooling water cooled by a cooler such as a cooling tower, for example. The working medium (water) condensed in the condenser (74) is sucked into the pump (71) and supplied from the pump (71) to the steam generator (72).

    In short, in the air conditioner (10), as shown in FIG. 3, the power converter (30) receives exhaust heat from the exhaust heat source (31) and outputs power, and the power of the power converter (30) is output. Is supplied to the compressor (61) of the air conditioner (20), and is configured as a so-called exhaust heat drive type.

    The auxiliary generator (40) is connected to the steam turbine (73) via a power shaft (13). The auxiliary generator (40) is configured to generate power by being driven by the power of the steam turbine (73) when the air conditioner (20) has stopped the air conditioning operation. Further, the auxiliary generator (40) is configured to generate power by receiving a part of the power of the steam turbine (73) because the driving power of the compressor (61) is small when the air conditioning load is small. . The generated power of the auxiliary generator (40) is merely a part of the demand power of the office building and does not bear the main power.

    The electric motor (50) is connected to the compressor (61) via a power shaft (14). When the exhaust heat is low, the electric motor (50) cooperates with the power of the steam turbine (73) when the capacity of the compressor (61) is insufficient with the power of the steam turbine (73). It is comprised so that it may drive.

<Action>
Next, the operation | movement operation | movement of the air conditioning apparatus (10) in the cogeneration system (11) mentioned above is demonstrated.

    The air conditioner (10) is driven by the thermal energy of the combustion exhaust gas, and generates cold and warm heat. That is, the gas turbine that is the exhaust heat source (31) is driven by the combustion gas, and the combustion exhaust gas of the combustion gas is supplied to the power converter (30). On the other hand, the power generated by the gas turbine is transmitted to the main generator. The electric power generated by the main generator is supplied to the office building.

    The operation of the power converter (30) in the air conditioner (10) will be described with reference to FIG.

    First, when the pump (71) is driven, water as a working medium is supplied to the steam generator (72). Since the exhaust heat is supplied to the steam generator (72) from the exhaust heat source (31) via the heat passage (32), the exhaust heat and the working medium are heated in the steam generator (72). In exchange, a working medium of superheated steam is generated.

    The working medium of this superheated steam is supplied to the steam turbine (73). In the steam turbine (73), the working medium of superheated steam (steam) expands, and the expansion of the working medium causes the steam turbine (73) to rotate to generate power.

    The working medium flowing out of the steam turbine (73) flows to the condenser (74). Since the cooling fluid is supplied to the condenser (74), the cooling fluid and the working medium exchange heat in the condenser (74), and the working medium is condensed. The condensed working medium is sucked into the pump (71), and the above operation is repeated.

    Next, during air conditioning, the power generated in the steam turbine (73) is transmitted to the compressor (61) of the air conditioner (20) via the power shaft (12), and the compressor (61) is driven. To do. When the compressor (61) is driven, the working medium of the air conditioner (20) is compressed and discharged from the compressor (61).

    Therefore, the operation of the cooling operation (forward cycle) will be described. Since the four-way switching valve (62) is switched to the solid line side in FIG. 1, the working medium discharged from the compressor (61) is transferred to the outdoor heat exchanger (63 ). The working medium exchanges heat with the outdoor air (21) in the outdoor heat exchanger (63), condenses, expands in the expansion valve (64), and then flows into the indoor heat exchanger (65). Further, the working medium evaporates by exchanging heat with the indoor air (22) in the indoor heat exchanger (65), cools the indoor air (22), and returns to the compressor (61). This circulation operation is repeated to cool the room.

    On the other hand, the operation of the heating operation (reverse cycle) will be described. The four-way switching valve (62) is switched to the broken line side in FIG. Then, as indicated by a chain line arrow in FIG. 1, the working medium discharged from the compressor (61) flows into the indoor heat exchanger (65). The working medium is condensed by exchanging heat with the indoor air (22) in the indoor heat exchanger (65), and warms the indoor air (22). Thereafter, the working medium is expanded by the expansion valve (64), then flows to the outdoor heat exchanger (63), exchanges heat with the outdoor air (21), evaporates, and returns to the compressor (61). This circulation operation is repeated to heat the room.

    Further, when the air conditioner (20) has stopped operating, that is, for example, when there is no air conditioning load in the intermediate period, the power generated in the steam turbine (73) is transmitted via the power shaft (12). It is transmitted to the auxiliary generator (40). Then, the auxiliary generator (40) is driven to generate power. The power generated by the auxiliary generator (40) simply supplements a part of the power demand of the office building.

    In addition, when the air conditioning load is small, the driving power of the compressor (61) in the air conditioner (20) is small, so that part of the power of the steam turbine (73) is transmitted to the compressor (61) and other power Is distributed to the auxiliary generator (40). And this auxiliary generator (40) generates electric power with a part of motive power of a steam turbine (73).

    Further, when the exhaust heat is low, the motor (50) is driven when the capacity of the compressor (61) is insufficient with the power of the steam turbine (73). The power of the electric motor (50) is transmitted to the compressor (61) and drives the compressor (61) in cooperation with the power of the steam turbine (73).

<Effect of Embodiment 1>
As described above, according to the present embodiment, the working medium of superheated steam is generated by exhaust heat, and the compressor (61) of the air conditioner (20) is generated by the power of the power converter (30) generated by the working medium. ) Is driven, effective utilization of the exhaust heat can be achieved, and at the same time high efficiency can be achieved by performing bottoming power generation.

    That is, according to this embodiment, the exhaust heat of the exhaust heat source (31) such as a gas turbine can be effectively used. As a result, the combustion energy input to the gas turbine or the like can be used effectively, and the efficiency of the entire system in the cogeneration system (11) can be improved.

    In particular, since the air conditioner (20) of the vapor compression refrigeration cycle can be driven by exhaust heat, the efficiency of the air conditioner (20) can be improved.

    Further, since the power of the steam turbine (73) is distributed to the air conditioner (20) and the auxiliary generator (40), the operation efficiency can be further improved.

    Further, since the electric motor (50) is provided, the air conditioner (20) can be reliably driven even when there is little exhaust heat, and the reliability can be improved.

    Moreover, if the working medium of the said air conditioner (20) and a power converter (30) is made into the same working medium, the simplification of the whole apparatus can be achieved.

    Moreover, if the working medium of the said air conditioner (20) and a power converter (30) is made into a different working medium, the freedom degree of application will become large and the applicable range of an apparatus can be expanded.

    Further, when the cooling fluid is cooled by a cooler such as a cooling tower, the power conversion efficiency of the power converter (30) can be improved.

    If the air conditioner (20) and the power converter (30) are separate components, the air conditioner (20) and the power converter (30) can be simplified. In other words, the air conditioner (20) and the power converter (30) do not need to be dedicated products, and can be generalized.

Form 2 for carrying out the invention

    Next, a second embodiment of the present invention will be described in detail based on the drawings.

    As shown in FIG. 4, the air conditioner (10) of the present embodiment has an air conditioner instead of the air conditioner (20) and the power converter (30) in the first embodiment as separate components. (20) and the power converter (30) are integrally configured.

    That is, the air conditioning circuit (60) of the air conditioner (20) and the conversion circuit (70) of the power converter (30) constitute an independent circuit, but the air conditioner (20) and the power converter (30) is formed as an integral component. Furthermore, the outdoor heat exchanger (63) of the air conditioner (20) and the condenser (74) of the power converter (30) are integrally formed to constitute one heat exchange mechanism (15).

    A fluid passage (33) is connected to the heat exchange mechanism (15). In the heat exchange mechanism (15), the working medium of the air conditioner (20), the working medium of the power converter (30), and the cooling fluid flow separately. And the said heat exchange mechanism (15) is comprised so that the working medium of an air conditioner (20), the working medium of a power converter (30), and a cooling fluid may each heat-exchange.

    Therefore, during the cooling operation, the working medium of the air conditioner (20) and the cooling fluid exchange heat, the working medium condenses, and the working medium of the power converter (30) exchanges heat with the cooling fluid. The working medium condenses.

    During heating operation, the working medium of the power converter (30) exchanges heat with the working medium of the air conditioner (20), or the working medium of the power converter (30) is the working medium of the air conditioner (20). Then, heat exchange with the cooling fluid is performed, the working medium of the power converter (30) is condensed, and the working medium of the air conditioner (20) is evaporated.

    In addition, when the air conditioner (20) has stopped operating, the working medium of the power converter (30) exchanges heat with the cooling fluid and condenses.

    As described above, according to the present embodiment, during the heating operation of the air conditioner (20), the working medium of the air conditioner (20) is radiated from the working medium of the power converter (30) in the heat exchange mechanism (15). Can be inhaled. As a result, no cooling fluid is required during heating operation, and high efficiency can be achieved. Other configurations, operations, and effects are the same as those in the first embodiment. The steam turbine (73) and the compressor (61) are connected via a power shaft (12, 14) and an electric motor (50).

Form 3 for carrying out the invention

    Next, Embodiment 3 of the present invention will be described in detail based on the drawings.

    As shown in FIG. 5, in the air conditioner (10) of the present embodiment, the air conditioner (20) has only a forward cycle instead of the air conditioner (20) having a reversible cycle in the second embodiment. It is comprised so that it may perform.

    That is, in the air conditioner (20), the four-way selector valve (62) in the second embodiment is omitted, and the compressor (61), the outdoor heat exchanger (63), the expansion valve (64), and the indoor heat exchanger ( 65) are connected in order, and only cooling operation (forward cycle) is performed. That is, the outdoor heat exchanger (63) is a condenser (74), and the indoor heat exchanger (65) is an evaporator.

    On the other hand, an air passage (23) through which room air passes is connected to the indoor heat exchanger (65) of the air conditioner (20).

    The air passage (23) and the fluid passage (33) through which the cooling fluid flows are communicated with the room and the outdoors via a four-way switching valve (16) that is an air switching mechanism. That is, a cooling fluid composed of air flows through the fluid passage (33), and the downstream end of the heat exchange mechanism (15) is connected to one port of the four-way switching valve (16). Moreover, indoor air flows through the air passage (23), and the downstream end of the indoor heat exchanger (65) is connected to one port of the four-way switching valve (16).

    The other two ports of the four-way switching valve (16) communicate with the room and the outdoors. In other words, the four-way switching valve (16) has a state in which the air passage (23) communicates with the room and the fluid passage (33) communicates with the outside (at the time of cooling operation), and the air passage (23) is outdoors. And the fluid passage (33) is configured to switch to a state (during heating operation) communicating with the room.

    Therefore, during the cooling operation of the air conditioner (20), the four-way selector valve (16) is switched to the solid line side in FIG. 5, and the indoor air is cooled by the indoor heat exchanger (65) as in the second embodiment. The cooled room air is supplied to the room through the four-way switching valve (16). On the other hand, the cooling fluid (air) absorbs the condensation heat of the air conditioner (20) and the condensation heat of the power converter (30) in the heat exchange mechanism (15), and passes through the four-way switching valve (16). Released outside the room.

    Further, during the heating operation, the air conditioner (20) stops operating, and the four-way selector valve (16) switches to the broken line side in FIG. Then, the cooling fluid is heated by the heat of condensation of the working fluid in the power converter (30), this cooling fluid is supplied to the room, and the room is heated. Furthermore, during this heating operation, the auxiliary generator (40) is driven by the power generated by the steam turbine (73) to generate power.

    As described above, according to the present embodiment, power generation can be performed simultaneously with the heating operation, so that the efficiency can be improved. Moreover, the air conditioner (20) may be configured as a cooling only machine, and the configuration can be simplified. Other configurations, operations, and effects are the same as those of the second embodiment.

Form 4 for carrying out the invention

    Next, a fourth embodiment of the present invention will be described in detail based on the drawings.

    As shown in FIG. 6, in the air conditioner (10) of the present embodiment, the air conditioner (60) of the air conditioner (20) and the conversion circuit (70) of the power converter (30) are connected to each other in the second embodiment. Instead of configuring an independent circuit, the air conditioning circuit (60) and the conversion circuit (70) are configured to communicate with each other.

    That is, one port of the four-way switching valve (62) in the air conditioning circuit (60) is connected between the steam turbine (73) and the condenser (74) of the conversion circuit (70), and the air conditioning circuit (60 ) Is connected between the condenser (74) and the pump (71) of the conversion circuit (70). And the condenser (74) of the said power converter (30) is comprised by the condensation heat exchanger which serves as the outdoor heat exchanger (63) of an air conditioner (20).

    Further, the same working medium is used as the working medium of the air conditioning circuit (60) and the conversion circuit (70).

    Further, the pipe (75) on the inlet side of the condenser (74) in the conversion circuit (70) is located between the connection part of the air conditioning circuit (60) and the condenser (74), and the on-off valve (17 ) Is provided. Further, the pipe (75) on the outlet side of the condenser (74) in the conversion circuit (70) is located between the connection part of the air conditioning circuit (60) and the condenser (74), and the on-off valve (18 ) Is provided. The two on-off valves (17, 18) constitute a working medium switching mechanism.

    Accordingly, the operation of the air conditioner (10) in the present embodiment is as follows.

    First, during the cooling operation (during the positive cycle), the two on-off valves (17, 18) are open. Then, in the air conditioning circuit (60) of the air conditioner (20), the working medium is discharged from the compressor (61), merges with the working medium of the conversion circuit (70) via the four-way switching valve (62), and is condensed. In the vessel (74), heat is exchanged with the cooling fluid to condense. Thereafter, the working medium flowing out of the condenser (74) is divided into a conversion circuit (70) and an air conditioning circuit (60). The working medium of the air conditioning circuit (60) passes through the expansion valve (64), evaporates by exchanging heat with room air in the indoor heat exchanger (65), and returns to the compressor (61). Repeat this action.

    On the other hand, in the conversion circuit (70) of the power converter (30), the working medium is discharged from the pump (71), exchanges heat with the exhaust heat in the steam generator (72), and becomes superheated steam. ). Thereafter, the working medium of the conversion circuit (70) merges with the working medium of the air conditioning circuit (60), and is condensed by exchanging heat with the cooling fluid in the condenser (74). Subsequently, the working medium flowing out of the condenser (74) is divided into a conversion circuit (70) and an air conditioning circuit (60), and the working fluid of the conversion circuit (70) returns to the pump (71). Repeat this action.

    In addition, during the heating operation (during reverse cycle), the two on-off valves (17, 18) are both closed. 6, in the conversion circuit (70) of the power converter (30), the working medium is discharged from the pump (71), and the exhaust heat and heat are discharged from the steam generator (72). The steam turbine (73) is rotated by replacing it with superheated steam. Thereafter, the working medium flows to the compressor (61) through the four-way switching valve (62) of the air-conditioning circuit (60), and passes through the four-way switching valve (62) to the indoor heat exchanger (65) in the indoor air and heat. It is exchanged and condensed, and returns to the pump (71) through the expansion valve (64). Repeat this action.

    As described above, according to the present embodiment, the configuration of the entire apparatus can be simplified. Other configurations, operations, and effects are the same as those of the second embodiment.

Form 5 for carrying out the invention

    Next, a fifth embodiment of the present invention will be described in detail based on the drawings.

    As shown in FIG. 7, in the air conditioner (10) of the present embodiment, the air conditioner (20) has only a positive cycle, instead of the air conditioner (20) having a reversible cycle in the fourth embodiment. It is comprised so that it may perform.

    That is, in the air conditioner (20), the four-way switching valve (62) in the second embodiment is omitted, and the compressor (61), the condenser (74), the expansion valve (64), and the indoor heat exchanger (65). Are connected in order, and only cooling operation (forward cycle) is performed. That is, the indoor heat exchanger (65) serves as an evaporator.

    On the other hand, an air passage (23) through which room air passes is connected to the indoor heat exchanger (65) of the air conditioner (20).

    As in the third embodiment, the air passage (23) and the fluid passage (33) through which the cooling fluid flows are communicated with the interior and the exterior via a four-way switching valve (16) that is an air switching mechanism. Yes. That is, in the fluid passage (33), a cooling fluid composed of air flows, and the downstream end of the condenser (74) is connected to one port of the four-way switching valve (16). Moreover, indoor air flows through the air passage (23), and the downstream end of the indoor heat exchanger (65) is connected to one port of the four-way switching valve (16).

    The other two ports of the four-way switching valve (16) communicate with the room and the outdoors. In other words, the four-way switching valve (16) has a state in which the air passage (23) communicates with the room and the fluid passage (33) communicates with the outside (at the time of cooling operation), and the air passage (23) is outdoors. And the fluid passage (33) is configured to switch to a state (during heating operation) communicating with the room. In addition, the on-off valve (17, 18) of Embodiment 4 is not provided.

    Accordingly, during the cooling operation of the air conditioner (20), the four-way selector valve (16) is switched to the solid line side in FIG. 7, and in the air conditioner circuit (60) as in the fourth embodiment, the working medium is a compressor. It is discharged from (61), merged with the working medium of the conversion circuit (70), and condensed in the condenser (74). Thereafter, the working medium is divided into a conversion circuit (70) and an air conditioning circuit (60). The working medium of the air conditioning circuit (60) evaporates in the indoor heat exchanger (65) through the expansion valve (64). Return to the compressor (61).

    On the other hand, in the conversion circuit (70) of the power converter (30), the working medium is discharged from the pump (71), becomes superheated steam in the steam generator (72), and rotates the steam turbine (73). Then, the said working medium merges with the working medium of an air-conditioning circuit (60), and condenses with a condenser (74). Subsequently, the working medium is divided into a conversion circuit (70) and an air conditioning circuit (60), and the working fluid of the conversion circuit (70) returns to the pump (71). Repeat this action.

    Further, during the heating operation, the air conditioner (20) stops the operation, and the four-way switching valve (16) is switched to the broken line side in FIG. Then, the cooling fluid is heated by the heat of condensation of the working fluid in the power converter (30), this cooling fluid is supplied to the room, and the room is heated. Furthermore, during this heating operation, the auxiliary generator (40) is driven by the power generated by the steam turbine (73) to generate power.

    As described above, according to the present embodiment, power generation can be performed simultaneously with the heating operation, so that the efficiency can be improved. Moreover, the air conditioner (20) may be configured as a cooling only machine, and the configuration can be simplified. Other configurations, operations, and effects are the same as those in the fourth embodiment.

Form 6 for carrying out the invention

    Next, a sixth embodiment of the present invention will be described in detail based on the drawings.

    As shown in FIG. 8, the air conditioner (10) of the present embodiment has a plurality of indoor heats instead of the air conditioner (20) of the third embodiment having one indoor heat exchanger (65). An exchange (65) is provided.

    In other words, the air conditioner (20) is configured in a so-called multi-type, and the exhaust heat source (31) is installed on the roof of the building (80), and the power converter (30) and the air conditioner (20) A compressor (61), an outdoor heat exchanger (63), and the like are installed on the roof of the building (80). An indoor heat exchanger (65) is installed in each room (81) of the building (80), and the indoor heat exchanger (65) is connected to the outdoor heat exchanger (63) or the like by a pipe (66). Yes. Other configurations, operations, and effects are the same as those in the third embodiment.

Form 7 for carrying out the invention

    Next, a seventh embodiment of the present invention will be described in detail with reference to the drawings.

    As shown in FIG. 9, in the air conditioner (10) of the present embodiment, the first embodiment directly connects the compressor (61), the steam turbine (73), the generator (40), and the electric motor (50). Instead of this, a connecting mechanism (19) is provided.

    That is, a connecting mechanism (19) is provided on the power shaft (14) that connects the electric motor (50) and the compressor (61). The power shaft (12) that connects the compressor (61) and the steam turbine (73) is provided with a connection mechanism (19). The power shaft (13) that connects the steam turbine (73) and the generator (40) is provided with a connection mechanism (19).

    Accordingly, the power output from the steam turbine (73) is transmitted to the compressor (61) and the generator (40) via the connection mechanism (19), and the power output from the electric motor (50) is transmitted to the connection mechanism ( 19) to the compressor (61). As a result, the operation can be switched smoothly. Other configurations, operations, and effects are the same as those in the third embodiment.

Form 8 for carrying out the invention

    Next, an eighth embodiment of the present invention will be described in detail with reference to the drawings.

    As shown in FIG. 10, in the air conditioner (10) of the present embodiment, instead of the seventh embodiment provided with the generator (40) and the electric motor (50), the electric motor (50) 40).

    That is, the electric motor (50) generates power with the output power of the steam turbine (73) in a state where no power is output to the compressor (61). Other configurations, operations, and effects are the same as those of the seventh embodiment.

Other forms for carrying out the invention

    In the first embodiment, the cooling fluid may be outdoor air. That is, the working medium of the power converter (30) may be cooled with outdoor air. In this case, since outdoor air is used, the overall configuration can be simplified, and operation can be performed even in winter.

    In the first embodiment, the cooling fluid may be room air. That is, the working medium of the power converter (30) may be cooled with room air. In this case, since the indoor air is used, the cold heat of the exhaust can be recovered.

    As described above, the present invention is useful for an air conditioner.

10 Air conditioner
11 Cogeneration system
20 Air conditioner
30 Power converter
31 Waste heat source
40 Auxiliary generator
50 electric motor
60 Air conditioning circuit
61 Compressor
63 Outdoor heat exchanger
64 expansion valve
65 Indoor heat exchanger
70 Conversion circuit
71 Pump (supply means)
72 Steam generator
73 Steam turbine
75 condenser

Claims (17)

A power converter (30) that converts waste heat into power,
An air conditioner comprising: a vapor compression refrigeration cycle air conditioner (20) including a compressor (61) driven by power output from the power converter (30). In claim 1,
The power converter (30) is connected to the generator (40) and supplies power to the air conditioner (20) during air conditioning, while supplying power to the generator (40) when the air conditioner (20) is stopped. It is comprised as follows, The air conditioning apparatus characterized by the above-mentioned. In claim 1,
The power converter (30) is connected to a generator (40), and is configured to distribute and supply power to the generator (40) and the air conditioner (20). Harmony device. In claim 1,
The power converter (30) includes a steam generator (72) that generates superheated steam working medium by exhaust heat, and steam that generates power by receiving the superheated steam working medium generated by the steam generator (72). A turbine (73), a condenser (74) for condensing the working medium flowing out of the steam turbine (73), and supply means for supplying the working medium condensed in the condenser (74) to the steam generator (72) ( 71) and an air conditioner characterized by comprising a conversion circuit (70) connected thereto. In claim 1,
The air conditioner (20) is connected to an electric motor (50) that drives the compressor (61) in cooperation with the power of the power converter (30). In claim 4,
The air conditioner characterized in that the condenser (74) of the power converter (30) is configured to be supplied with cooling water cooled by a cooler and to condense the working medium with the cooling water. In claim 4,
The condenser (74) of the power converter (30) is configured to be supplied with outdoor air and to condense the working medium with the outdoor air. In claim 4,
The air conditioner characterized in that the condenser (74) of the power converter (30) is configured to be supplied with room air discharged from the room and to condense the working medium with the room air. In claim 1,
The power converter (30) and the air conditioner (20) are formed as separate and independent components, while the power converter (30) and the air conditioner (20) are connected by a power shaft (12). An air conditioner characterized by being made. In claim 4,
The power converter (30) is connected to the generator (40). When the air conditioner (20) is stopped, the power converter (30) is heated by the heat radiation of the condenser (74), and at the same time, drives the generator (40). It is comprised in the air conditioning apparatus characterized by the above-mentioned. In claim 4,
While the power converter (30) and the air conditioner (20) are formed into an integral component,
The conversion circuit (70) of the power converter (30) and the air conditioning circuit (60) of the air conditioner (20) are configured as independent circuits, and the condenser (74) of the power converter (30). And the heat source side heat exchanger (63) of the air conditioner (20) are integrated to form one heat exchange mechanism (15). In claim 11,
The air conditioner (60) of the air conditioner (20) is configured to perform a reversible cycle. In claim 11,
The air conditioning circuit (60) of the air conditioner (20) is configured to perform only the positive cycle,
The air conditioner (20) is configured to cool with the air cooled by the use side heat exchanger (65) and to heat with the air heated by the heat exchange mechanism (15). An air conditioner characterized. In claim 4,
While the power converter (30) and the air conditioner (20) are formed into an integral component,
The working medium of the power converter (30) and the heat working medium of the air conditioner (20) are composed of the same working medium, and the conversion circuit (70) of the power converter (30) and the air conditioning circuit of the air conditioner (20) (60) are connected so as to communicate with each other, and the condenser (74) of the power converter (30) is configured as a condensation heat exchanger that also serves as a heat source side heat exchanger of the air conditioner (20). An air conditioner characterized by that. In claim 14,
The air conditioning circuit (60) of the air conditioner (20) is configured to perform a reversible cycle,
The conversion circuit (70) of the power converter (30) and the air conditioning circuit (60) of the air conditioner (20) include the working medium of the power converter (30) and the air conditioner (20 during the forward cycle of the air conditioner (20). ) At the inlet of the condenser (74), and at the outlet of the condenser (74), the working medium of the power converter (30) and the working medium of the air conditioner (20) are shunted, while the reverse cycle Sometimes the working medium flowing out of the steam turbine (73) returns to the steam turbine (73) via the compressor (61), the use side heat exchanger (65), the supply means (71) and the steam generator (72). An air conditioner characterized by being configured. In claim 14,
The air conditioning circuit (60) of the air conditioner (20) is configured to perform only the positive cycle,
The air conditioner (20) cools with the air cooled by the use side heat exchanger (65), while the condenser (74) heats with the air heated by the working medium of the power converter (30). An air conditioner configured to perform. In claim 1,
A generator (40) driven by the power generated by the power converter (30) and an electric motor driving the compressor (61) of the air conditioner (20) in cooperation with the power generated by the power converter (30) (50) is provided,
The power converter (30) includes a steam turbine (73) that generates power,
The motor (50), the coupling mechanism (19), the compressor (61), the coupling mechanism (19), the steam turbine (73), the coupling mechanism (19), and the generator (40) are coupled in order. An air conditioner characterized.

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