JP2004012101A - Waste heat utilization system - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To effectively utilize exhaust heat of a generator 12 throughout the year in regard to an exhaust heat utilizing system utilizing the exhaust heat of the generator 12 in air conditioning. <P>SOLUTION: The exhaust heat utilizing system is provided with an absorption-refrigerator 13 carrying out air conditioning by utilizing the exhaust heat of the generator 12, and a refrigerator 11 provided with a refrigerant circuit carrying out a vapor compression type refrigerating cycle. A supercooling heat exchanger 20 supercooling a refrigerant of the refrigerant circuit by the cold generated by the absorption-refrigerator 13 is provided in the refrigerator 11. <P>COPYRIGHT: (C)2004,JPO

Description

[0001]
TECHNICAL FIELD OF THE INVENTION
The present invention relates to an exhaust heat utilization system that utilizes exhaust heat of a generator.
[0002]
[Prior art]
2. Description of the Related Art Conventionally, for example, a generator for generating necessary electricity in a building such as a hotel or a restaurant is provided, and an exhaust heat utilization system (a cogeneration system) in which exhaust heat of the generator is used for indoor cooling / heating and hot water supply. System) is known.
[0003]
For example, in the system disclosed in JP-A-2002-13759 and the like, the exhaust heat utilization system includes a desiccant air conditioner having a dehumidifying rotor that adsorbs moisture in the air. In this desiccant air conditioner, the sucked outdoor air and indoor air are dehumidified by a dehumidifying rotor and supplied to the room. In this exhaust heat utilization system, the exhaust heat of the generator is used for heating and regeneration of the dehumidifying rotor.
[0004]
[Problems to be solved by the invention]
However, in the above-described conventional apparatus, indoor air conditioning is not required during an intermediate period such as spring or autumn, and no exhaust heat of the generator is used during the intermediate period. As a result, there is a problem that the exhaust heat energy of the generator is not effectively used up throughout the year.
[0005]
The present invention has been made in view of such a point, and an object of the present invention is to provide an exhaust heat utilization system that uses exhaust heat of a generator for air conditioning, and to reduce the exhaust heat of the generator throughout the year. Is to try to use it effectively.
[0006]
[Means for Solving the Problems]
In order to achieve the above object, according to the present invention, at least cold heat is generated by an absorption refrigerating device using exhaust heat of a generator, and the refrigerant in a refrigerant circuit of the refrigerating device can be supercooled by the cold heat. .
[0007]
Specifically, the invention according to claim 1 provides a refrigeration apparatus (11) including a refrigerant circuit in which a refrigerant circulates and performs a vapor compression refrigeration cycle, and power generation for supplying electric power to a compressor of the refrigeration apparatus (11). (12), an absorption refrigeration system (13) having a regenerator (22) for evaporating a refrigerant from an absorbent by exhaust heat of the power generator (12), and at least one generated from the absorption refrigeration system (13). An exhaust heat utilization system including an indoor unit (14) that performs air conditioning of a room (18) by cold heat is an object. The refrigerating device (11) includes a subcooling heat exchanger (20) for subcooling the refrigerant in the refrigerant circuit by the cold generated from the absorption refrigerating device (13).
[0008]
According to the invention, the refrigeration apparatus (11) is supplied with electricity by the generator (12) and is operated throughout the year. Then, in summer, the cold generated by the absorption refrigeration system (13) is supplied to the heat exchanger of the indoor unit (14). Then, heat exchange is performed between the room air and the room air. In winter, the heat generated by the absorption refrigerator and the exhaust heat of the generator (12) are supplied to the heat exchanger of the indoor unit (14). Then, heat exchange is performed with the room air, and the temperature of the room air rises.
[0009]
On the other hand, in the middle of spring or autumn, the cold generated by the absorption refrigeration system (13) is supplied to the supercooling heat exchanger (20) of the refrigeration system (11). Then, the refrigerant in the refrigerant circuit of the refrigerating device (11) is subcooled in the subcooling heat exchanger (20), and the refrigerating effect of the refrigerating device (11) increases. That is, the exhaust heat of the generator (12) is effectively used throughout the year.
[0010]
According to a second aspect of the present invention, in the first aspect of the present invention, there is provided a humidity control device that includes an adsorption element that adsorbs moisture in indoor air, and regenerates the adsorption element by exhaust heat of a generator (12). 15).
[0011]
According to the present invention, in the summer or winter, the indoor unit (18) is air-conditioned by the indoor unit (14) using a part of the exhaust heat of the generator (12). On the other hand, the humidity in the room (18) is adjusted by the humidity controller (15). Then, another part of the exhaust heat of the generator (12) is supplied to the humidity controller (15), and heats and regenerates the adsorption element that adsorbs moisture.
[0012]
According to a third aspect of the present invention, in the first or second aspect of the invention, the heat for transferring the cold generated from the absorption refrigeration unit (13) to the subcooling heat exchanger (20) by a phase-change refrigerant. A transport circuit (60) is provided.
[0013]
According to the above invention, the cold generated from the absorption refrigeration system (13) is supplied to the supercooling heat exchanger (20) by the heat transfer circuit (60). And since the diameter of the pipe of the heat transfer circuit (60) is smaller than the case where the heat transfer medium is water, the installation work of the heat transfer circuit (60) is easily performed. Further, since the cold heat is conveyed by the phase-changing refrigerant in the heat transfer circuit (60), the heat loss due to the transfer and the power required for the heat transfer are reduced.
[0014]
According to a fourth aspect of the present invention, in the third aspect of the present invention, the heat transfer circuit (60) includes a refrigerant gas pump (63) for circulating a refrigerant gas.
[0015]
According to the present invention, the refrigerant gas pump (63) sucks the gas refrigerant at the outlet side of the subcooling heat exchanger (20), so that the pressure of the refrigerant in the subcooling heat exchanger (20) decreases. The evaporation temperature decreases. Therefore, the supercooling effect is greater than when a liquid pump that sucks and discharges a liquid refrigerant is provided.
[0016]
According to a fifth aspect of the present invention, in the invention according to any one of the first to fourth aspects, the supercooling heat exchanger (20) is provided outside a casing (19) of the refrigerating device (11). ing.
[0017]
According to the present invention, the supercooling heat exchanger (20) and the heat transfer circuit (60) can be easily attached to the refrigeration system not having the supercooling heat exchanger (20).
[0018]
The invention according to claim 6 is the invention according to any one of claims 1 to 5, wherein the generator (12) is a turbine generator, and the absorption refrigeration device (13) is It is configured to cool the air taken into the turbine generator.
[0019]
According to the above invention, the turbine generator generates power by sucking air and burning fuel. At this time, part of the cold generated from the absorption refrigeration system (13) cools the air taken into the turbine generator. As a result, a rise in the temperature of the intake air is reduced, so that a decrease in the output of the generator (12) is prevented.
[0020]
BEST MODE FOR CARRYING OUT THE INVENTION
(Embodiment 1)
Hereinafter, embodiments of the present invention will be described in detail with reference to the drawings.
[0021]
FIG. 1 shows a first embodiment of a waste heat utilization system according to the present invention. The waste heat utilization system (10) is provided in, for example, a supermarket or a restaurant, and includes, for example, two refrigerators (11), a generator (12), an absorption refrigeration unit (13), and an indoor unit (14). And a humidity controller (15).
[0022]
The refrigerator (11) is a refrigeration apparatus including a refrigerant circuit in which a refrigerant circulates to perform a vapor compression refrigeration cycle. The refrigerator (11) includes a showcase (16) as a use side unit and an outdoor unit (17) as a heat source side unit. The showcase (16) is arranged in the room (18), while the outdoor unit (17) is provided outside the room with a compressor, a condenser and the like (not shown) in a casing (19).
[0023]
The generator (12) is, for example, a gas turbine generator, and is configured to supply electric power to the compressor, the indoor unit (14), the humidity controller (15), and the like of the refrigerator (11). The generator (12) includes a water heater (21), and the exhaust heat is used as hot water by the water heater (21).
[0024]
The absorption refrigeration apparatus (13) includes an absorber (not shown) for absorbing water vapor as a refrigerant vapor into lithium bromide or the like as an absorbing liquid, and absorbs the refrigerant vapor in the absorber to make it thin. A regenerator (22) is provided for evaporating and separating water from the absorbed absorption liquid and concentrating the absorption liquid. Further, the absorption refrigerating apparatus (13) includes a condenser (23) for condensing water vapor and an evaporator (24) for evaporating condensed water.
[0025]
The condenser (23) and the absorber have a heat exchanger (not shown) for exchanging heat with water, and generate hot water. On the other hand, the evaporator (24) also has a heat exchanger (not shown) for exchanging heat with water so as to generate cold water.
[0026]
The water heater (21) of the generator (12) and the regenerator (22) of the absorption refrigeration unit (13) are connected by a hot water pipe (26) and a cold water pipe (27). The hot water pipe (26) is provided with a hot water pump (28) for sending hot water from the water heater (21) to the regenerator (22). A first three-way valve (29) is provided between the hot water pump (28) and the regenerator (22) in the hot water pipe (26). In this manner, the regenerator (22) generates high-pressure refrigerant gas by evaporating the refrigerant from the absorbent by the exhaust heat of the generator (12) supplied through the hot water pipe (16). It has become.
[0027]
And the said refrigerator (11) is provided with the subcooling heat exchanger (20) for supercooling the refrigerant | coolant of the said refrigerant circuit by the cold generated from the said absorption refrigerating apparatus (13).
[0028]
The supercooling heat exchanger (20) is provided in a casing (19) of the outdoor unit (17), and is connected to the absorption refrigeration unit (13) via a heat transfer circuit (30). That is, the temperature of the subcooling heat exchanger (20) and the evaporator (24) is increased by the first pipe (31) through which the cold water cooled by the evaporator (24) flows, and by the subcooling heat exchanger (20). And the second pipe (32) through which the water flows.
[0029]
The first pipe (31) is provided with a first pump (41) for sending cold water from the evaporator (24) to the subcooling heat exchanger (20). A second three-way valve (42) is provided between the first pump (41) and the subcooling heat exchanger (20) in the first pipe (31).
[0030]
The indoor unit (14) is provided in the room (18), and is configured to perform air conditioning of the room (18) by at least cold generated from the absorption refrigeration device (13). The indoor unit (14) includes an indoor heat exchanger (not shown). The indoor heat exchanger is connected to an evaporator (24) of an absorption heat exchanger (13) and a condenser ( 23) and an absorber (not shown).
[0031]
That is, the indoor heat exchanger and the second three-way valve (42) of the first pipe (31) are connected by the third pipe (33). On the other hand, the indoor heat exchanger and the second pipe (32) are connected by a fourth pipe (34). By driving the first pump (41), the cooling water cooled by the evaporator (24) is supplied to the first pipe (31), the second three-way valve (42) and the third pipe (33). The hot water heated by the indoor heat exchanger is sent to the indoor heat exchanger of the indoor unit (14) via the fourth pipe (34) and the second pipe (32) to the evaporator (24). I try to put it back.
[0032]
Further, one end of a fifth pipe (35) through which hot water heated by the condenser (23) and the absorber flows is connected to the condenser (23) of the absorption refrigeration apparatus (13). Further, the absorber (not shown) is connected to one end of the fifth pipe (35). In each of the following embodiments, a circuit for connecting the absorber and the fifth pipe (35) is not shown.
[0033]
On the other hand, the other end of the fifth pipe (35) is connected to the third pipe (33). The fifth pipe (35) is provided with a second pump (44) for sending hot water from the condenser (23) toward the indoor unit (14). Further, a motor-operated valve (45), which is an on-off valve, is provided between the second pump (44) in the fifth pipe (35) and a junction with the third pipe (33).
[0034]
On the other hand, one end of a sixth pipe (36) through which warm water flows from the indoor unit (14) is connected to the condenser (23). The other end of the sixth pipe (36) is connected to the fourth pipe (34). By driving the second pump (44) in this way, the hot water heated by the condenser (23) and the absorber is passed through the fifth pipe (35), the electric valve (45), and the third pipe (33). To the indoor heat exchanger of the indoor unit (14), and cool water whose temperature has decreased in the indoor heat exchanger is absorbed by the condenser (23) and the absorber through the fourth pipe (34) and the sixth pipe (36). I'm trying to return it to the container
[0035]
The humidity controller (15) is provided in a room (18), has an adsorption element (not shown) for adsorbing moisture in indoor air, and regenerates the adsorption element by exhaust heat of a generator (12). It is configured as follows. The adsorbing element is constituted by, for example, a dehumidifying rotor provided with an adsorbent. The humidity controller (15) includes a regenerative heat exchanger (not shown). The regenerative heat exchanger and the first three-way valve (29) are connected by a seventh pipe (37) through which hot water from the water heater (21) of the generator (12) flows. Further, one end of an eighth pipe (38) through which water from the regenerative heat exchanger flows is connected to the regenerative heat exchanger. On the other hand, the other end of the eighth pipe (38) is connected to the cold water pipe (27).
[0036]
-Operation of waste heat utilization system-
Next, the operation of the exhaust heat utilization system according to the present invention will be described. In the exhaust heat utilization system (10), the generator (12) continuously generates power, and the refrigerator (11) is constantly operated by the power generated by the generator (12). At night, since air conditioning is not required, the generator (12) generates power only according to the power load of the refrigerator (11).
[0037]
As shown in FIG. 2, in the summer, the indoor air is mainly cooled by the indoor unit (14) and the indoor air is dehumidified by the humidity controller (15) mainly by the exhaust heat of the generator (12). . That is, the opening of the first three-way valve (29) is adjusted so that the hot water flowing through the hot water pipe (26) flows to both the absorption refrigeration system (13) and the seventh pipe (37). I do.
[0038]
Then, the second three-way valve (42) is switched so that the cold water flowing from the absorption refrigeration system (13) through the first pipe (31) mainly flows to the third pipe (33). Further, the electric valve (45) is closed.
[0039]
At this time, the hot water of the water heater (21) generated by the exhaust heat of the generator (12) flows through the hot water pipe (26) by driving the hot water pump (28). Part of the hot water flowing through the hot water pipe (26) is supplied from the first three-way valve (29) to the humidity controller (15) through the seventh pipe (37). In the humidity controller (15), indoor air is dehumidified by the adsorption element. Then, the adsorption element that has adsorbed the moisture of the indoor air is heated and regenerated by the hot water supplied from the generator (12). The cold water whose temperature has been reduced by regenerating the adsorption element returns to the water heater (21) through the eighth pipe (38) and the cold water pipe (27). Then, the water returned to the water heater (21) is heated again by the exhaust heat.
[0040]
On the other hand, another part of the hot water flowing through the hot water pipe (26) is supplied to the regenerator (22) of the absorption refrigeration system (13). Then, the absorbent absorbs water vapor in the absorber, generates water vapor in the regenerator (22), condenses water in the condenser (23), and evaporates water in the evaporator (24). As a result, hot water is generated by the heat of the condenser (23), while cold water is generated by the cold of the evaporator (24).
[0041]
In addition, since the refrigerator (11) is constantly operating, it is desirable to supply waste heat to the absorption refrigeration unit (13) with priority.
[0042]
Cold water generated by the cold heat of the evaporator (24) passes through the first pipe (31), the second three-way valve (42), and the third pipe (33) by driving the first pump (41). Then, it is supplied to the indoor heat exchanger of the indoor unit (14). Then, the indoor air is cooled in the indoor heat exchanger. The water heated in the indoor heat exchanger returns to the evaporator (24) through the fourth pipe (34) and the second pipe (32). The water returned to the evaporator (24) is cooled again.
[0043]
When the air-conditioning load of the room (18) decreases, the opening of the second three-way valve (42) is adjusted so that the cold water is supplied not only to the indoor unit (14) but also to the refrigerator (11). To make it flow. The cold water supplied to the subcooling heat exchanger (20) of the refrigerator (11) subcools the refrigerant flowing in the refrigerant circuit of the refrigerator (11). The warm water heated in the supercooling heat exchanger (20) returns to the evaporator (24) through the second pipe (32).
[0044]
FIG. 5 shows a refrigeration cycle performed by the refrigerator (11) in a Mollier diagram (pressure-enthalpy diagram). During normal times when no chilled water is supplied from the absorption refrigeration system (13) to the supercooling heat exchanger (20), the refrigeration cycle is performed from point A, to points B, C, D, and A in this order.
[0045]
Then, when cold water is supplied from the absorption refrigeration system (13) to the supercooling heat exchanger (20), the condensed refrigerant is supercooled, so that the point C shifts to the point C 'on the left side, and The degree of supercooling increases only in the cooling portion (point C-point C '). That is, the refrigeration cycle is performed from point A in the order of point B, point C ′, point D ′, and point A.
[0046]
In this way, in summer, the exhaust heat of the generator (12) allows the air conditioning of the room (18) by the indoor unit (14) and the dehumidification of the room (18) by the humidity controller (15), respectively. Done. When the air conditioning load of the room (18) is relatively small, the refrigerant in the refrigerant circuit of the refrigerator (11) is subcooled.
[0047]
Note that hot water generated by heating by the condenser (23) and the absorber may be supplied to the humidity controller (15) and used for regeneration of the adsorption element.
[0048]
Next, as shown in FIG. 3, in the winter season, the indoor air is heated by the indoor unit (14) and the indoor air is humidified by the humidity controller (15) by the exhaust heat of the generator (12). Further, the refrigerant in the refrigerant circuit of the refrigerator (11) is supercooled. That is, similarly to the case of the summer, the opening degree of the first three-way valve (29) is adjusted so that the hot water flowing through the hot water pipe (26) is connected to the absorption refrigeration system (13) side and the seventh pipe (37). And flow to both sides. Further, the second three-way valve (42) is switched so that the cold water from the absorption refrigeration system (13) flows only to the refrigerator (11). Further, the motor-operated valve (45) is opened.
[0049]
At this time, the hot water of the water heater (21) flows through the hot water pipe (26) by driving the hot water pump (28). Part of the hot water flowing through the hot water pipe (26) is supplied from the first three-way valve (29) to the humidity controller (15) through the seventh pipe (37). The warm water supplied to the humidity controller (15) humidifies the indoor air by heating and regenerating the adsorption element that has adsorbed the moisture. The cold water whose temperature has been reduced by regenerating the adsorption element returns to the water heater (21) through the eighth pipe (38) and the cold water pipe (27). Then, the water returned to the water heater (21) is heated again by the exhaust heat.
[0050]
On the other hand, another part of the hot water flowing through the hot water pipe (26) is supplied to the regenerator (22) of the absorption refrigeration system (13). Then, while hot water is generated by the heat of the condenser (23) and the absorber, cold water is generated by the cold of the evaporator (24).
[0051]
The hot water generated by the heat of the condenser (24) and the absorber passes through the fifth pipe (35), the electric valve (45), and the third pipe (33) by driving the second pump (44). Then, it is supplied to the indoor heat exchanger of the indoor unit (14). Then, the indoor air is heated in the indoor heat exchanger. The water whose temperature has dropped in the indoor heat exchanger returns to the condenser (23) and the absorber through the fourth pipe (34) and the sixth pipe (36). The water returned to the condenser (23) and the absorber is heated again.
[0052]
Then, the cold water generated by the cold heat of the evaporator (24) is supplied to the subcooling heat exchanger (20) of the refrigerator (11) by driving the first pump (41). In the supercooling heat exchanger (20), heat exchange is performed between the cold water supplied from the evaporator (24) side and the refrigerant flowing through the refrigerant circuit of the refrigerator (11), and the refrigerant in the refrigerant circuit is removed. Supercooled. The warm water heated in the supercooling heat exchanger (20) returns to the evaporator (24) through the second pipe (32).
[0053]
In this way, in winter, the exhaust heat of the generator (12) allows the indoor unit (14) to air-condition the room (18), the humidifier (15) to humidify the room (18), and the refrigerator. Subcooling of the refrigerant flowing through the refrigerant circuit of (11) is performed.
[0054]
Next, as shown in FIG. 4, in the middle of spring or autumn, the refrigerant in the refrigerant circuit of the refrigerator (11) is supercooled by the exhaust heat of the generator (12). That is, the first three-way valve (29) is switched so that the hot water flowing through the hot water pipe (26) flows only to the absorption refrigeration system (13). Further, the second three-way valve (42) is switched so that the cold water from the absorption refrigeration system (13) flows only to the refrigerator (11). Then, the electric valve (45) is closed.
[0055]
At this time, the hot water of the water heater (21) flows through the hot water pipe (26) by driving the hot water pump (28). The hot water flowing through the hot water pipe (26) is supplied to the regenerator (22) of the absorption refrigeration system (13). Then, hot water is generated by the heat of the condenser (23) and the like, and cold water is generated by the cold of the evaporator (24).
[0056]
Then, the cold water generated by the cold heat of the evaporator (24) is supplied to the subcooling heat exchanger (20) of the refrigerator (11) by driving the first pump (41). The supercooling heat exchanger (20) supercools the refrigerant flowing in the refrigerant circuit of the refrigerator (11). The warm water heated in the supercooling heat exchanger (20) returns to the evaporator (24) through the second pipe (32).
[0057]
In this way, in the intermediate period, the refrigerant flowing through the refrigerant circuit of the refrigerator (11) is supercooled by the exhaust heat of the generator (12), and the cooling capacity of the refrigerator (11) is improved.
[0058]
-Effects of Embodiment-
As described above, according to this embodiment, the supercooling heat exchanger (20) for supercooling the refrigerant flowing in the refrigerant circuit of the refrigerator (11) by the cold generated from the absorption refrigeration system (13) is provided. Therefore, not only in summer and winter, but also in the middle of spring and autumn when air conditioning and humidity control in the room (18) are not required, the exhaust heat of the generator (12) is transferred to the refrigerator (11). It can be used to subcool the refrigerant in the refrigerant circuit. As a result, the exhaust heat of the generator (12) can be effectively used throughout the year to efficiently use the generated energy, and the refrigeration efficiency of the refrigerator (11) can be improved to reduce its running cost. Becomes possible.
[0059]
Furthermore, in summer, when the air conditioning load of the room (18) is small, a part of the chilled water from the evaporator (24) is sent to the supercooling heat exchanger (20) to effectively use the surplus chilled heat. can do.
[0060]
In addition, the exhaust heat of the generator (12) can be heated and regenerated by heating the adsorption element of the humidity controller (15) in summer or winter, so that the exhaust heat of the generator (12) can be more effectively used. It can be used for
[0061]
In the supermarket, defrosting the indoor air can reduce frost formation in the showcase (16), thereby saving energy in the refrigerator (11), and reducing the cold aisle in the vicinity of the showcase (16). Occurrence can be prevented and comfort can be improved. In a restaurant, by maintaining the room at an appropriate humidity, comfort can be improved and generation of mold in the room can be suppressed.
[0062]
In addition, since the generator (12) is operated continuously even at night, it is possible to improve the operating rate of the generator (12) and shorten its amortization period. In addition, since the starting and stopping of the generator (12) are not repeated, it is possible to suppress a loss in power generation efficiency and a decrease in the life of the generator due to the repeated starting and stopping.
[0063]
(Embodiment 2)
FIG. 6 shows a second embodiment of the waste heat utilization system according to the present invention. In the following embodiments, the same parts as those in FIG. 1 are denoted by the same reference numerals, and detailed description thereof will be omitted.
[0064]
The humidity controller (15) includes a dehumidifying rotor (51), which is an adsorption element, and a regenerative heat exchanger (52) for heating and regenerating the dehumidifying rotor in the casing (50), as in the first embodiment. Have. Further, in the casing (50), an air supply fan (55) for sucking outdoor air into the casing (50) and supplying the air indoors, and sucking room air into the casing (50) and exhausting the air outdoors. Exhaust fan (56) is provided.
[0065]
Further, in the second embodiment, the humidity controller (15) includes a cooling heat exchanger (53) for cooling dehumidified air to which moisture has been adsorbed by the dehumidification rotor (51). The cooling heat exchanger (53) is connected to the evaporator (24) of the absorption refrigeration unit (13) via piping or the like (not shown), and operates during the operation of the humidity controller (15). It is configured to supply the cold water from 24) to the cooling heat exchanger (53).
[0066]
A sensible heat rotor (54) is provided between the dehumidification rotor (51) and the cooling heat exchanger (53). Then, the sensible heat of the dehumidified air that has passed through the dehumidification rotor (51) and has been heated by the heat of adsorption is sent to the regenerative heat exchanger (52) by the sensible heat rotor (54), thereby regenerating the dehumidification rotor (51). To use it.
[0067]
In this way, the outdoor air (OA) sucked into the casing (50) by the operation of the air supply fan (55) is adsorbed by the dehumidifying rotor (51), passes through the sensible heat rotor (54), and is sensible heat. Is robbed. Subsequently, the dehumidified air is cooled by the cooling heat exchanger (53) supplied with cold water from the absorption refrigeration system (13), and is supplied to the room (18) as air supply (SA).
[0068]
On the other hand, the room air (RA) sucked into the casing (50) by the operation of the exhaust fan (56) passes through the sensible heat rotor (54) and is heated, and further hot water is generated from the generator (12). It is heated by the supplied regenerative heat exchanger (52). Subsequently, the heated air is exhausted to the outside after heating and regenerating the dehumidifying rotor (51).
[0069]
Therefore, according to this embodiment, the indoor (18) can be efficiently dehumidified in summer.
[0070]
(Embodiment 3)
FIG. 7 shows a third embodiment of the present invention. In the first embodiment, hot and cold heat generated in the condenser (23) and the evaporator (24) of the absorption refrigeration system (13) is transported to the indoor unit (14) and the refrigerator (11) using water as a medium. In contrast to this, the transfer is performed by a refrigerant that changes in phase.
[0071]
That is, the waste heat utilization system (10) of the third embodiment includes a heat transfer circuit (10) that transfers the cold generated from the absorption refrigeration unit (13) to the subcooling heat exchanger (20) by the phase-change refrigerant. 60) is provided. In the first pipe (31) of the heat transfer circuit (60), a first refrigerant transfer pump (61) is provided instead of the first pump (41) in the first embodiment. Further, a second refrigerant transport pump (62) is provided in the sixth pipe (36) instead of the second pump (44) in the first embodiment.
[0072]
Thus, as in the first embodiment, in summer, the liquid refrigerant cooled by the evaporator (24) is sent to the indoor unit (14) by the operation of the first refrigerant transport pump (61), and The air is cooled. In winter, the gas refrigerant heated by the condenser (23) and the absorber (not shown) is sent to the indoor unit (14) by the operation of the second refrigerant transport pump (62), and the indoor air is removed. Heated. Further, the operation of the first refrigerant transport pump (61) supplies the liquid refrigerant from the evaporator (24) to the subcooling heat exchanger (20), and subcools the refrigerant in the refrigerant circuit. In the interim period, the liquid refrigerant from the evaporator (24) is supplied to the subcooling heat exchanger (20) by the operation of the first refrigerant transport pump (61).
[0073]
Therefore, according to this embodiment, the cold generated from the absorption refrigeration system (13) is conveyed to the supercooling heat exchanger (20) by the phase-change refrigerant, so that the piping of the heat conveyance circuit (60) is provided. The diameter of (31, 32) can be smaller than when the heat transfer medium is water. As a result, installation work of the heat transfer circuit (60) can be easily performed. Further, since the cold heat is transferred by the phase-changing refrigerant in the heat transfer circuit (60), the heat loss associated with the heat transfer and the power required for the heat transfer are reduced as compared with the case where the heat transfer is performed by water. can do.
[0074]
(Embodiment 4)
FIG. 8 shows Embodiment 4 of the present invention, in which the heat transfer circuit (60) includes a refrigerant gas pump (63) for circulating the refrigerant gas. That is, in the third embodiment, the first refrigerant transport pump (61) that sucks and discharges the liquid refrigerant is provided in the first pipe (31), whereas the gas refrigerant is sucked in the second pipe (32). And a refrigerant gas pump (63) for discharging the liquid.
[0075]
According to this embodiment, the refrigerant gas pump (63) sucks the gas refrigerant at the outlet side of the subcooling heat exchanger (20), so that the pressure of the refrigerant in the supercooling heat exchanger (20) decreases. Decreases the evaporation temperature. Therefore, the supercooling effect can be increased as compared with the case where a liquid pump for sucking and discharging the liquid refrigerant is provided.
[0076]
Instead of the refrigerant gas pump (63), part of the refrigerant is evaporated by the exhaust heat of the generator (12) or the heat from the absorption refrigeration unit (13), and the volume change of the refrigerant accompanying the phase change is reduced. A so-called heat-driven pump may be used. Thus, since the power generated by the generator (12) is not used for the purpose of circulating the refrigerant in the heat transfer circuit (60), energy saving of the entire system can be achieved.
[0077]
(Embodiment 5)
FIG. 9 shows a fifth embodiment of the present invention. In Embodiment 3 described above, the supercooling heat exchanger (20) is provided in the casing (19) of the outdoor unit (17) of the refrigerator (11). The refrigerator (11) is provided outside the casing (19) of the outdoor unit (17). That is, a part of the refrigerant circuit is exposed to the outside of the casing (19), and the subcooling heat exchanger (20) is connected to the exposed part.
[0078]
According to this embodiment, when the exhaust heat utilization system (10) is configured by using the refrigerator (11) not provided with the supercooling heat exchanger (20) in advance, the supercooling heat is applied to the refrigerator (11). The exchanger (20) and the heat transfer circuit (60) can be easily attached.
[0079]
In each of the above embodiments, a gas turbine generator is applied as a power generator, but the power generator may be constituted by, for example, another internal combustion engine, a fuel cell, or the like.
[0080]
(Embodiment 6)
FIG. 10 shows a sixth embodiment of the present invention. In the third embodiment, the absorption refrigeration system (13) is configured to cool the air taken into the gas turbine generator as the generator (12). Have been.
[0081]
That is, the generator (12) is provided with a heat exchanger (65) for cooling the intake air. One end of a ninth pipe (39) through which the liquid refrigerant cooled by the evaporator (24) of the absorption refrigeration system (13) flows is connected to the heat exchanger (65). An end of the ninth pipe (39) is joined to the first pipe (31) between the first refrigerant transport pump (61) and the second three-way valve (42). On the other hand, one end of a tenth pipe (40) through which the refrigerant heated in the heat exchanger (65) flows is connected to the heat exchanger (65). The other end of the tenth pipe (40) is connected to the second pipe (32).
[0082]
The generator (12) generates power by inhaling air and burning gas as a fuel. At this time, part of the liquid refrigerant cooled by the evaporator (24) of the absorption refrigeration system (13) is supplied to the heat exchanger (65) through the ninth pipe (39). The liquid refrigerant supplied to the heat exchanger (65) exchanges heat with the intake air, and the intake air is cooled. Then, the refrigerant heated in the heat exchanger (65) returns to the evaporator (24) through the tenth pipe (40).
[0083]
As a result, the rise in the temperature of the intake air sucked into the generator (12) is reduced, so that the output of the generator (12) can be prevented from lowering even when the outdoor temperature is high, such as in summer.
[0084]
(Embodiment 7)
FIG. 11 shows a seventh embodiment of the present invention. In each of the above embodiments, the hot water is once generated by using the exhaust heat of the generator (12), and the hot water is supplied to the absorption refrigeration apparatus (13). The exhaust heat of the machine (12) is directly supplied to the absorption refrigeration system (13).
[0085]
The exhaust port of the generator (12) is connected to the regenerator (22) of the absorption refrigeration system (13) via a pipe. Then, by supplying the exhaust gas of the generator (12) to the regenerator (22), the absorption liquid of the regenerator (22) is directly heated by the heat of the exhaust gas to generate steam. The exhaust gas is exhausted from the regenerator (22) after radiating heat to the absorbent in the regenerator (22).
[0086]
The fifth pipe (35) has one end connected to the condenser (23) and the absorber (not shown), and the other end connected to the fourth pipe (34). The eighth pipe (38) has one end connected to the fifth pipe (35) and the other end connected to the humidity controller (15).
[0087]
The sixth pipe (36) is provided with a third three-way valve (43) in addition to the second refrigerant transport pump (62). The seventh pipe (37) has one end connected to the sixth pipe (36) via the third three-way valve (43), and the other end connected to the humidity controller (14).
[0088]
The heat transfer circuit (60) is configured to transfer the cold generated from the absorption refrigeration unit (13) to the subcooling heat exchanger (20) by the phase-change refrigerant, as in the third embodiment. Have been.
[0089]
Thus, as in the first embodiment, in summer, the liquid refrigerant cooled by the evaporator (24) is sent to the indoor unit (14) by the operation of the first refrigerant transport pump (61), and The air is cooled. Further, by switching the third three-way valve (43) so that the seventh pipe (37) and the sixth pipe (36) communicate with each other, and operating the second refrigerant transport pump (62), the condenser ( 23) and the gas refrigerant heated by the absorber (not shown) is sent to the humidity controller (14), and the adsorption element is heated and regenerated.
[0090]
In winter, the third three-way valve (43) is switched so that the third pipe (33) and the sixth pipe (36) communicate with each other, and the second refrigerant transport pump (62) is operated to condense. The gas refrigerant heated by the device (23) and the absorber is sent to the indoor unit (14), and the indoor air is heated. Further, the operation of the first refrigerant transport pump (61) supplies the liquid refrigerant from the evaporator (24) to the subcooling heat exchanger (20), and subcools the refrigerant in the refrigerant circuit. In the interim period, the liquid refrigerant from the evaporator (24) is supplied to the subcooling heat exchanger (20) by the operation of the first refrigerant transport pump (61).
[0091]
Therefore, according to this embodiment, the exhaust heat of the generator (12) is supplied directly to the regenerator (22) instead of being transported by hot water. Can be reduced. Further, since a heat exchanger and a hot water tank for generating hot water are not required, the apparatus can be simplified.
[0092]
In the above embodiments, two refrigerators (11) are provided, but the present invention is not limited to this, and one refrigerator (11) may be provided. Alternatively, a number of refrigerators (11) may be provided, and each refrigerator (11) may be connected to the one absorption refrigeration apparatus (13) via a pipe.
[0093]
In each of the above embodiments, both the condenser (23) and the absorber (not shown) are connected to the indoor unit (14), but as another embodiment of the invention according to claim 1, At least one of the condenser (23) and the absorber may be connected to the indoor unit (14) or the like.
[0094]
【The invention's effect】
As described above, according to the first aspect of the present invention, an absorption refrigeration system including a refrigeration system, a generator for supplying power to the refrigeration system, and a regenerator for evaporating the refrigerant from the absorbent by exhaust heat of the generator. For an exhaust heat utilization system including an apparatus and an indoor unit that performs indoor air conditioning by at least cold generated from the absorption refrigeration apparatus, the refrigeration apparatus supercools the refrigerant in the refrigerant circuit by the cold generated from the absorption refrigeration apparatus. The super-cooled heat exchanger of this type allows the exhaust heat of the generator to be transferred to the refrigerant circuit of the refrigeration system not only in summer and winter, but also in the middle of spring or autumn when indoor air conditioning is not required. Can be used to supercool. As a result, it is possible to effectively utilize the exhaust heat of the generator throughout the year, efficiently use the generated energy, and reduce the running cost of the refrigeration system.
[0095]
According to the invention according to claim 2, the indoor device has an adsorption element that adsorbs moisture in the indoor air, and a humidity controller that regenerates the adsorption element by exhaust heat of the power generator. Since the adsorbing element of the humidity controller for controlling the humidity can be heated and regenerated, the exhaust heat of the generator can be more effectively used.
[0096]
According to the third aspect of the present invention, by providing the heat transfer circuit for transferring the cold generated from the absorption refrigeration system to the subcooling heat exchanger by the phase-change refrigerant, the diameter of the pipe of the heat transfer circuit is reduced. Since the transfer medium is smaller than the case where the transfer medium is water, installation work of the heat transfer circuit can be easily performed. Further, since the cold heat is transported by the phase-change refrigerant, the heat loss due to the transport and the power required for the thermal transport can be reduced.
[0097]
According to the invention according to claim 4, since the heat transfer circuit includes the refrigerant gas pump for circulating the refrigerant gas, the pressure of the refrigerant in the supercooling heat exchanger decreases, and the evaporation temperature of the refrigerant decreases. The supercooling effect can be increased as compared with the case where a pump for sucking and discharging the liquid refrigerant is provided.
[0098]
According to the invention according to claim 5, by providing the subcooling heat exchanger outside the casing of the refrigeration apparatus, the supercooling heat exchanger and the heat transfer are provided for the refrigeration apparatus without the supercooling heat exchanger. The circuit can be easily attached.
[0099]
According to the invention according to claim 6, the generator is a turbine generator, and the absorption refrigeration unit cools the air taken into the turbine generator, so that part of the cold generated from the absorption refrigeration unit However, since the air taken into the turbine generator is cooled, the rise in the temperature of the intake air can be reduced, and a decrease in the output of the generator can be prevented.
[Brief description of the drawings]
FIG. 1 is a circuit diagram showing an exhaust heat utilization system according to Embodiment 1 of the present invention.
FIG. 2 is a circuit diagram showing flows of hot and cold heat in summer.
FIG. 3 is a diagram corresponding to FIG. 2 showing flows of hot and cold heat in winter.
FIG. 4 is a diagram corresponding to FIG. 2 showing flows of hot and cold heat in an intermediate period.
FIG. 5 is a Mollier diagram showing a refrigeration cycle performed in a refrigerator.
FIG. 6 is a schematic diagram schematically showing a humidity controller according to a second embodiment.
FIG. 7 is a circuit diagram showing a waste heat utilization system according to a third embodiment.
FIG. 8 is a circuit diagram showing a waste heat utilization system according to a fourth embodiment.
FIG. 9 is a circuit diagram showing a waste heat utilization system according to a fifth embodiment.
FIG. 10 is a circuit diagram showing a waste heat utilization system according to a sixth embodiment.
FIG. 11 is a circuit diagram showing a waste heat utilization system according to a seventh embodiment.
[Explanation of symbols]
(10) Waste heat utilization system
(11) Refrigerator (refrigerator)
(12) Generator
(13) Absorption refrigeration system
(14) Indoor unit
(15) Humidifier
(18) Indoor
(19) Casing
(20) Subcooling heat exchanger
(22) Regenerator
(60) Heat transfer circuit
(63) Refrigerant gas pump

Claims (6)

A refrigeration apparatus (11) including a refrigerant circuit in which a refrigerant circulates to perform a vapor compression refrigeration cycle;
A generator (12) for supplying electric power to the compressor of the refrigeration apparatus (11),
An absorption refrigerating device (13) having a regenerator (22) for evaporating a refrigerant from an absorbent by exhaust heat of the generator (12);
An exhaust heat utilization system including an indoor unit (14) that performs air conditioning of a room (18) by at least cold generated from the absorption refrigeration device (13),
The refrigerating apparatus (11) includes a supercooling heat exchanger (20) for subcooling a refrigerant in a refrigerant circuit by cold generated from the absorption refrigerating apparatus (13). system. In claim 1,
An exhaust heat utilization system comprising: an adsorption element that adsorbs moisture in indoor air; and a humidity controller (15) that regenerates the adsorption element by exhaust heat of a generator (12). In claim 1 or 2,
A heat transfer circuit (60) for transferring the cold generated from the absorption refrigeration unit (13) to the supercooling heat exchanger (20) by a phase-change refrigerant; . In claim 3,
The exhaust heat utilization system, wherein the heat transfer circuit (60) includes a refrigerant gas pump (63) for circulating a refrigerant gas. In any one of claims 1 to 4,
The exhaust heat utilization system, wherein the supercooling heat exchanger (20) is provided outside a casing (19) of the refrigerating device (11). In any one of claims 1 to 5,
The generator (12) is a turbine generator,
The exhaust heat utilization system, wherein the absorption refrigeration unit (13) is configured to cool air taken into the turbine generator.

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