JP4244900B2 - Refrigeration equipment - Google Patents

Description

  The present invention relates to a refrigeration apparatus, and particularly relates to measures for adjusting the refrigeration capacity of a refrigeration apparatus having a fixed capacity compressor.

  Conventionally, a refrigeration apparatus having a plurality of usage-side heat exchangers and performing a vapor compression refrigeration cycle is known. As this type of refrigeration apparatus, for example, there is a refrigeration apparatus that is provided in a convenience store or the like and includes a use side heat exchanger that cools and heats the inside of the store and a use side heat exchanger that cools food in the store (for example, , See Patent Document 1).

This refrigeration apparatus includes a refrigerant circuit that performs a vapor compression refrigeration cycle. This refrigerant circuit has a heat source system having two compressors and an outdoor heat exchanger, a first system having a use side heat exchanger for refrigeration and freezing, and a second system having a use side heat exchanger for air conditioning. The system is connected in parallel. The two compressors are a variable capacity compressor and a fixed capacity compressor. In particular, in the cooling and refrigeration operation, the variable capacity compressor functions as a first system compression mechanism, and the fixed capacity compressor functions as a second system compression mechanism.
JP 2004-37006 A

  However, the above-described conventional refrigeration apparatus has a problem that the air conditioning capacity cannot be adjusted stepwise. In other words, since the second system for air conditioning uses a fixed capacity compressor, for example, when the outside air temperature fluctuates significantly, it is not possible to just adjust the flow rate by adjusting the opening of the indoor expansion valve. There was a problem that the cooling capacity in the side heat exchanger could not be adjusted according to the load.

  In order to solve the above problems, it is possible to replace the fixed capacity compressor with a variable capacity one or install another fixed capacity compressor, but this raises the problem of cost. Occurs.

  The present invention has been made in view of such points, and an object of the present invention is to provide an intermediate port in a fixed capacity compressor in a refrigeration apparatus having a fixed capacity compressor and a plurality of use side heat exchangers. By adjusting the discharge flow rate of the compressor by allowing the refrigerant to flow in and out, the capacity of the target use side heat exchanger can be adjusted in several stages without changing the capacity of the target use side heat exchanger. It is.

Specifically, the first invention provides a heat source system having a variable capacity compressor (41), a fixed capacity compressor (42), and a heat source side heat exchanger (44) with a use side heat exchanger (51, 61). A refrigeration apparatus including a refrigerant circuit (20) to which a first usage system and a second usage system having the above are connected is assumed. In the refrigeration apparatus of the present invention, the refrigerant discharged from the variable capacity compressor (41) and the fixed capacity compressor (42) dissipates heat in the heat source side heat exchanger (44), and the first utilization system The refrigerant evaporated in the use side heat exchanger (51) is sucked into the fixed capacity compressor (42), and the refrigerant evaporated in the use side heat exchanger (61) of the second usage system is converted into the variable capacity compression. In the operation of being sucked into the compressor (41), a part of the intermediate pressure refrigerant flows from the intermediate port opened to the compression chamber in the compression process of the fixed capacity compressor (42) to the suction side of the fixed capacity compressor (42). In the first state, the liquid refrigerant flowing to the both utilization systems is supercooled by the branch refrigerant branched from a part of the liquid refrigerant, and the subcooled branch refrigerant flows to the intermediate port of the fixed capacity compressor (42). The cooling capacity in the use side heat exchanger (51) of the first use system in the state A second state in which the refrigerant is higher than the first state, a part of the intermediate pressure refrigerant flows from the intermediate port of the fixed capacity compressor (42) to the suction side of the fixed capacity compressor (42), and subcooled by the branch refrigerant portion of the liquid refrigerant branched liquid refrigerant flowing into, the branch refrigerant after supercooling is a state that flows to the suction side of the fixed capacity compressor (42), said first usage There is provided a switching circuit (70) for switching the refrigerant flow of the refrigerant circuit (20) to a third state where the cooling capacity in the utilization side heat exchanger (51) of the system is lower than the first state .

  In said invention, the utilization side heat exchanger (51, 61) of each utilization system | strain is comprised with the cooling heat exchanger which cools the foodstuff etc. in the air conditioning heat exchanger which cools and heats indoors, for example. In the refrigerant circuit (20), the refrigerant circulates to perform a vapor compression refrigeration cycle. In this refrigeration apparatus (10), for example, the opening of the expansion valve and the like of each utilization system is adjusted in accordance with fluctuations in operating conditions such as outside air temperature, and the capacity of each utilization side heat exchanger is adjusted.

  Here, for example, when the outside air temperature rises so much that the opening temperature of the expansion valve or the like does not reach during the cooling operation, the refrigerant flow in the refrigerant circuit (20) is switched to the second state by the switching circuit (70). Here, description will be made on the assumption that the capacity of the use side heat exchanger (51) of the first use system is mainly adjusted. In this state, a part of the liquid refrigerant condensed in the heat source side heat exchanger (44) branches, and the remaining liquid refrigerant is supercooled by the branched refrigerant. The supercooled branch refrigerant flows into the intermediate port of the fixed capacity compressor (42) as an intermediate pressure refrigerant. Since the intermediate pressure refrigerant has a smaller specific volume (a larger mass flow rate) than the low-pressure refrigerant sucked into the normal suction port, the discharge flow rate of the fixed capacity compressor (42) increases. On the other hand, the remaining supercooled liquid refrigerant is depressurized by the expansion valve of each usage system and flows to each usage-side heat exchanger (51, 61). In each of the usage-side heat exchangers (51, 61), the refrigerant flow rate increases due to the increase in the discharge flow rate of the above-described fixed capacity compressor (42), and further, the refrigerant is supercooled, so the capacity increases. . Moreover, if the opening degree of the expansion valve of the second usage system is made smaller than the normal opening degree to reduce the flow rate of the refrigerant, the refrigerant flow rate flowing to the usage side heat exchanger (51) of the first usage system is correspondingly reduced. Since it increases, the capacity | capacitance in the utilization side heat exchanger (51) will increase further. In that case, in the utilization side heat exchanger (61) of the second utilization system, the flow rate of the refrigerant decreases, but the capacity hardly fluctuates because the refrigerant is supercooled. That is, in this case, the refrigerant flow rate supplied to the second usage system is decreased by the refrigerant flow rate that is used for supercooling the liquid refrigerant and that flows into the intermediate port of the fixed capacity compressor (42).

  On the other hand, when the outside air temperature greatly decreases to an extent that is not achieved by adjusting the opening of the expansion valve or the like, the refrigerant flow in the refrigerant circuit (20) is switched to the first state by the switching circuit (70). In this state, a part of the intermediate pressure refrigerant of the fixed capacity compressor (42) flows out from the intermediate port and is again sucked into the suction port of the fixed capacity compressor (42). As a result, the discharge flow rate of the fixed capacity compressor (42) decreases and the refrigerant flow rate in each usage-side heat exchanger (51, 61) decreases, so the capacity decreases. Further, in the above case, if the opening of the expansion valve of the first usage system is made smaller than the normal opening and the refrigerant flow rate is decreased, the refrigerant flow rate in the second usage system hardly fluctuates. The refrigerant flow rate in the usage system is reduced. Thereby, the capability of the 1st utilization system falls, without reducing the capability of the 2nd utilization system.

  Moreover, in said invention, when outside temperature falls further in the 1st state mentioned above, the refrigerant | coolant flow of a refrigerant circuit (20) is switched to a 3rd state by the switching circuit (70). In this state, a part of the intermediate pressure refrigerant of the fixed capacity compressor (42) flows from the intermediate port to the suction port, and the branched refrigerant used for supercooling the liquid refrigerant is also on the suction side of the fixed capacity compressor (42). To flow. Here, since the branched refrigerant used for the supercooling is in a low pressure state, the specific volume is larger than the refrigerant in the intermediate pressure state (the mass flow rate is small). There is no fluctuation in the discharge flow rate. And if the opening degree of the expansion valve of a 1st utilization system is made still smaller than the opening degree of a 1st state, and the distribution | circulation flow rate of a refrigerant | coolant is reduced, the capability of a 1st utilization system will fall further. That is, in this case, the refrigerant flow rate supplied to the second usage system is decreased by the refrigerant flow rate that is used for supercooling the liquid refrigerant and that flows into the intermediate port of the fixed capacity compressor (42).

  Further, according to a second aspect of the present invention, in the first aspect of the present invention, in the operation, the usage side heat exchanger (51) of the first usage system cools the room, and the usage side heat exchanger of the second usage system. (61) cools the interior.

  Therefore, according to the first invention, the branched refrigerant used for supercooling the liquid refrigerant is sucked into the intermediate port of the fixed capacity compressor (42), so that the fixed capacity compressor is not performed without performing inverter control or the like. The discharge flow rate of (42) can be increased, and the refrigerant circulation amount in the intended use-side heat exchanger (51, 61) can be increased by appropriately adjusting the flow rate of the expansion valve or the like. Therefore, the capacity in the use side heat exchanger (51, 61) can be increased. Further, since the supercooled liquid refrigerant flows to the use side heat exchangers (51, 61), the capacity can be further increased. In addition, in the other use-side heat exchangers (51, 61), the amount of refrigerant circulation decreases, but the capacity is hardly reduced because the supercooled liquid refrigerant flows.

  Further, since a part of the intermediate pressure refrigerant in the fixed capacity compressor (42) flows out from the intermediate port and is sucked into the fixed capacity compressor (42) again, the fixed capacity compressor is not performed without performing inverter control or the like. The discharge flow rate of (42) can be reduced, and the refrigerant circulation amount in the intended use side heat exchanger (51, 61) can be reduced by appropriately adjusting the flow rate of the expansion valve or the like. Therefore, the capability in the use side heat exchanger (51, 61) can be reduced. In this way, it is possible to increase and decrease the capacity of the target use-side heat exchanger (51, 61) without changing the capacity of the non-target use-side heat exchanger (51, 61).

  Furthermore, according to the first invention, a part of the intermediate pressure refrigerant is discharged from the fixed capacity compressor (42) and directly returned to the suction side, and a part of the branched refrigerant used for supercooling the liquid refrigerant Since the flow is returned to the suction side of the fixed capacity compressor (42), if the flow rate of the expansion valve or the like is appropriately adjusted, the refrigerant circulation amount in the intended use side heat exchanger (51, 61) is further reduced. be able to. Therefore, the capacity of the use side heat exchanger (51, 61) can be further reduced. As a result, capacity adjustment can be performed in more stages without separately performing inverter control or the like.

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

<< Embodiment of the Invention >>
The refrigeration apparatus (10) of this embodiment is installed in a convenience store or the like, and performs air conditioning in the store and cooling in the showcase. As shown in FIG. 1, this refrigeration apparatus (10) includes an outdoor unit (11), an air conditioning unit (12), a refrigerated showcase (13), and a supercooling heat exchanger (80). . In the refrigeration apparatus (10), the refrigerant circuit (20) is configured by connecting the air conditioning unit (12), the refrigerated showcase (13), and the like to the outdoor unit (11) by piping. The refrigerant circuit (20) is configured to perform a vapor compression refrigeration cycle by circulating the refrigerant.

<Outdoor unit>
The outdoor unit (11) includes two compressors (41, 42), an outdoor heat exchanger (44) that is a heat source side heat exchanger, a receiver (45), and an outdoor expansion valve ( 46). These compressors (41, 42), outdoor heat exchanger (44),..., Outdoor expansion valve (46) constitute a heat source system of the refrigeration apparatus (10).

  The two compressors (41, 42) are a variable capacity compressor (41) and a fixed capacity compressor (42), and both are constituted by a hermetic high-pressure dome type scroll compressor. The variable capacity compressor (41) is a compressor whose capacity is variable stepwise or continuously when the electric motor is inverter-controlled, and mainly constitutes a refrigerant compression mechanism that circulates in the refrigerated showcase (13) side. ing. On the other hand, the fixed capacity compressor (42) is a compressor in which the electric motor is always driven at a constant rotational speed and the capacity cannot be changed, and constitutes a refrigerant compression mechanism mainly circulating in the air conditioning unit (12) side. ing. The two compressors (41, 42) are connected in parallel to each other. The fixed capacity compressor (42) has an intermediate port that opens to the compression chamber in the compression process, in addition to the normal suction port and discharge port, although not shown.

  One end of a common discharge pipe (21) is connected to the discharge side of the variable capacity compressor (41) and the fixed capacity compressor (42) via a first branch pipe (21a) and a second branch pipe (21b), respectively. Is connected. The other end of the discharge pipe (21) is connected to a first port of a first four-way switching valve (43) that is a flow path switching means. The second branch pipe (21b) is provided with a check valve (CV2) that allows only the flow of refrigerant from the fixed capacity compressor (42) toward the discharge pipe (21). The discharge pipe (21) is provided with an oil separator (47). On the other hand, on the suction side of the variable capacity compressor (41) and the fixed capacity compressor (42), a common first suction pipe (through a first branch pipe (27a) and a second branch pipe (27b), respectively ( 27) one end is connected. The other end of the first suction pipe (27) is connected to a second gas side communication pipe (33) disposed outside the outdoor unit (11) via a gas side closing valve (40). . The second branch pipe (27b) on the suction side is provided with a check valve (CV1) that allows only the flow of refrigerant from the first suction pipe (27) toward the fixed capacity compressor (42).

  The third port of the first four-way selector valve (43) is connected to a gas side end which is one end of the outdoor heat exchanger (44) via the first outdoor gas pipe (22). The liquid side end which is the other end of the exchanger (44) is connected to one end of an outdoor liquid pipe (23) which is a liquid line. The other end of the outdoor liquid pipe (23) passes through the receiver (45), and then the liquid side communication pipe (29) disposed outside the outdoor unit (11) via the liquid side shut-off valve (40). It is connected to the. In the outdoor liquid pipe (23), a check valve (CV3) that allows only the flow of refrigerant toward the receiver (45) is provided upstream of the receiver (45), and downstream of the receiver (45) A check valve (CV4) that allows only the flow of refrigerant from (45) to the shutoff valve (40) is provided.

  An auxiliary liquid pipe (25) that bypasses the receiver (45) and the check valve (CV3) on the upstream side is connected to the outdoor liquid pipe (23). The auxiliary liquid pipe (25) is provided with an outdoor expansion valve (46). Further, a branch liquid pipe (26) is connected to the outdoor liquid pipe (23). One end of this branch liquid pipe (26) is connected between the receiver (45) and the upstream check valve (CV3), and the other end is connected to the downstream check valve (CV4) and the closing valve (40). ) Is connected between. The branch liquid pipe (26) is provided with a check valve (CV5) that allows only a refrigerant flow from the closing valve (40) side toward the receiver (45) side.

  One end of the second suction pipe (28) is connected to the second port of the first four-way selector valve (43). The other end of the second suction pipe (28) is connected between the check valve (CV1) and the fixed capacity compressor (42) in the second branch pipe (27b). One end of the second outdoor gas pipe (24) is connected to the fourth port of the first four-way selector valve (43). The other end of the second outdoor gas pipe (24) is connected to a first gas side connecting pipe (31) disposed outside the outdoor unit (11) via a gas side closing valve (40). Yes.

  The outdoor heat exchanger (44) is, for example, a cross fin type fin-and-tube heat exchanger, and an outdoor fan (48) and an outdoor air temperature sensor (49) are arranged close to each other. The outdoor air temperature sensor (49) constitutes temperature detection means for detecting the temperature of outdoor air taken in by the outdoor fan (48). The outdoor heat exchanger (44) is configured to exchange heat between the refrigerant and the outdoor air.

  The first four-way selector valve (43) includes a first state (state indicated by a solid line in FIG. 1) in which the first port and the third port communicate with each other and the second port and the fourth port communicate with each other; The first port and the fourth port communicate with each other, and the second port and the third port communicate with each other (a state indicated by a broken line in FIG. 1).

<Air conditioning unit>
The air conditioning unit (12) is configured to perform air conditioning by heating and cooling the inside of the store. The air conditioning unit (12) includes an air conditioning heat exchanger (51) which is a use side heat exchanger and an air conditioning expansion valve (52) which is an expansion mechanism. An electronic expansion valve is used for the air conditioning expansion valve (52). A liquid side communication pipe (29) is connected to a liquid side end which is one end of the air conditioning heat exchanger (51) via an air conditioning expansion valve (52). On the other hand, the 1st gas side connection piping (31) is connected to the gas side edge part which is the other end of the said air-conditioning heat exchanger (51). And the said air-conditioning unit (12), liquid side connection piping (29), and 1st gas side communication piping (31) comprise the 1st utilization system connected to the heat-source system of a freezing apparatus (10).

  The air conditioning heat exchanger (51) is, for example, a cross fin type fin-and-tube heat exchanger, and the air conditioning fan (55) and the room temperature sensor (56) are arranged close to each other. The room temperature sensor (56) constitutes temperature detection means for detecting the temperature of the indoor air (in-store air) taken in by the air conditioning fan (55). The air conditioning heat exchanger (51) is provided with an air conditioning heat exchange sensor (53) as temperature detecting means for detecting an evaporation temperature or a condensation temperature, which is a refrigerant temperature in the air conditioning heat exchanger (51). A gas temperature sensor (54) is provided on the gas side as temperature detecting means for detecting the temperature of the gas refrigerant. And the said air-conditioning heat exchanger (51) is comprised so that a refrigerant | coolant and room air may heat-exchange. That is, the air conditioning heat exchanger (51) functions as an evaporator during cooling operation and functions as a condenser during heating operation.

<Refrigerated showcase>
The refrigerated showcase (13) is configured to refrigerate (cool) food and the like. The refrigerated showcase (13) includes a refrigerated heat exchanger (61) that is a use side heat exchanger and a refrigerated expansion valve (62) that is an expansion mechanism. An electronic expansion valve is used for the refrigeration expansion valve (62). One end of the branch liquid pipe (32) is connected to the liquid side end which is one end of the refrigeration heat exchanger (61) via the refrigeration expansion valve (62). The other end of the branch liquid pipe (32) is connected to the middle of the liquid side connecting pipe (29). On the other hand, the second gas side communication pipe (33) is connected to the gas side end which is the other end of the refrigeration heat exchanger (61). The refrigerated showcase (13), the branch liquid pipe (32), and the second gas side connecting pipe (33) are connected to the heat source system of the refrigeration apparatus (10) in parallel with the first usage system. It constitutes a usage system.

  The refrigeration heat exchanger (61) is, for example, a cross fin type fin-and-tube heat exchanger, and a refrigeration fan (65) and a refrigeration temperature sensor (66) are arranged close to each other. The refrigeration temperature sensor (66) constitutes temperature detection means for detecting the temperature of the air in the showcase (inside air) taken in by the refrigeration fan (65). The refrigeration heat exchanger (61) is provided with a refrigeration heat exchange sensor (63) as temperature detection means for detecting the evaporation temperature, which is the refrigerant temperature in the refrigeration heat exchanger (61), and the gas side A gas temperature sensor (64) is provided as temperature detecting means for detecting the temperature of the gas refrigerant. The refrigeration heat exchanger (61) is configured to exchange heat between the refrigerant and the air in the showcase. That is, this refrigeration heat exchanger (61) always functions as an evaporator.

<Supercooling heat exchanger>
The said supercooling heat exchanger (80) is provided in the liquid side connection piping (29) which connects an outdoor unit (11) and an air-conditioning unit (12). The supercooling heat exchanger (80) is constituted by a so-called plate heat exchanger or a cascade heat exchanger, and a first passage (81) and a second passage (82) are formed therein. A liquid side communication pipe (29) is connected to the first passage (81), and a supercooling pipe (76) is connected to the second passage (82). This supercooling pipe (76) has one end on the inlet side connected to the outdoor unit (11) side from the supercooling heat exchanger (80) in the liquid side communication pipe (29), and the other end on the outlet side is the outdoor side. Connected to unit (11). The supercooling pipe (76) is provided with a supercooling expansion valve (77) as an expansion mechanism on the inlet side of the supercooling heat exchanger (80).

  In the supercooling heat exchanger (80), the liquid refrigerant branching from the liquid side connecting pipe (29) to the second passage (82) through the supercooling pipe (76) is the liquid refrigerant in the first passage (81). The liquid refrigerant in the first passage (81) is supercooled by evaporating with heat exchange. That is, the said supercooling heat exchanger (80) comprises the supercooling means which supercools the liquid refrigerant of a 1st utilization system and a 2nd utilization system.

<Capability switching circuit>
The refrigeration apparatus (10) of the present embodiment includes an intermediate-pressure refrigerant switching circuit (70) as a feature of the present invention. This switching circuit (70) is provided in the outdoor unit (11), and is connected to a second four-way switching valve (71) that is a channel switching means, and four connected to the second four-way switching valve (71). And connecting pipes (72, 73, 74, 75).

  The first connection pipe (72) has one end connected to an intermediate port (not shown) of the fixed capacity compressor (42) and the other end connected to a second port of the second four-way selector valve (71). ing. The second connection pipe (73) has one end connected to the second suction pipe (28) and the other end connected to the third port of the second four-way selector valve (71). One end of the third connection pipe (74) is connected to the fourth port of the second four-way switching valve (71), and the other end is connected to the supercooling pipe (76) via the gas-side closing valve (40). It is connected. The fourth connection pipe (75) has one end connected to the first port of the second four-way selector valve (71) and the other end connected to the middle of the second connection pipe (73). The first connecting pipe (72) and the fourth connecting pipe (75) are provided with solenoid valves (SV1, SV2) that are on-off valves, respectively.

  The second four-way selector valve (71) has a first state (state indicated by a solid line in FIG. 1) in which the first port and the third port communicate with each other and the second port and the fourth port communicate with each other; The first port and the fourth port communicate with each other, and the second port and the third port communicate with each other (a state indicated by a broken line in FIG. 1).

  When the second four-way switching valve (71) is switched to the first state, the switching circuit (70) is configured so that the gas refrigerant evaporated in the supercooling heat exchanger (80) is in a fixed pressure compressor (42 ) And the second four-way selector valve (71) switches to the second state, the gas refrigerant in the intermediate pressure state flows out from the intermediate port of the fixed capacity compressor (42), and the second suction It is configured to be sucked again through the pipe (28) into the suction port of the fixed capacity compressor (42). That is, the switching circuit (70) increases or decreases the refrigerant discharge flow rate in the fixed capacity compressor (42) by switching the flow of the intermediate pressure refrigerant into and out of the intermediate port in the fixed capacity compressor (42). .

  The refrigeration apparatus (10) includes a controller (90) that switches between cooling and heating of the air conditioning heat exchanger (51) and switching the cooling capacity of the air conditioning heat exchanger (51) during cooling in several stages. . The controller (90) is configured to switch between cooling and heating the air conditioning heat exchanger (51) by switching the first four-way switching valve (43). Further, the controller (80) is configured to mainly perform the second four-way switching valve (71) and each solenoid valve (SV1, SV2) of the switching circuit (70) and the supercooling expansion valve (77) during cooling. By switching between the air conditioning expansion valve (52) and the refrigeration expansion valve (62), the air conditioning heat exchanger (51) is in the second state, high capacity operation, normal operation, and first state, first low capacity operation. And it switches to the 2nd low capacity driving | operation which is a 3rd state. In addition, each said driving | operation has the cooling capability low as it goes from a high capability driving | operation to a 2nd low capability driving | operation.

-Driving action-
Next, the operation of the refrigeration apparatus (10) described above will be described. This refrigeration apparatus (10) has a heating / refrigeration operation in which the refrigerant condenses in the air conditioning heat exchanger (51) and the refrigerant evaporates in the outdoor heat exchanger (44) and the refrigeration heat exchanger (61), and the outdoor heat. The refrigerant is condensed in the exchanger (44), and can be switched to a cooling / refrigeration operation in which the refrigerant evaporates in the air conditioning heat exchanger (51) and the refrigeration heat exchanger (61).

<Heating and refrigeration operation>
In this heating / refrigeration operation, the indoor air is heated by the air conditioning unit (12) to heat the interior of the store, and at the same time, the indoor air is cooled in the refrigerated showcase (13).

  First, as shown in FIG. 2, the controller (90) sets the first four-way switching valve (43) to the second state, the outdoor expansion valve (46) and the refrigeration expansion valve (62) to a predetermined opening degree. Each of the air conditioning expansion valves (52) is set to a fully open state. The controller (90) sets the solenoid valves (SV1, SV2) and the supercooling expansion valve (77) of the switching circuit (70) to the closed state. In this state, when the variable capacity compressor (41) and the fixed capacity compressor (42) are driven, the gas refrigerant discharged from both compressors (41, 42) merges in the discharge pipe (21), and the first The four-way switching valve (43) sequentially flows through the second outdoor gas pipe (24) and the first gas side communication pipe (31) to the air conditioning heat exchanger (51).

  In the air conditioning heat exchanger (51), the gas refrigerant is condensed by exchanging heat with room air, and the room air is heated. Thereby, the inside of a store is heated. The condensed liquid refrigerant flows to the liquid side connection pipe (29) via the air conditioning expansion valve (52), a part of the liquid refrigerant is branched to the branch liquid pipe (32), and the rest is the supercooling heat exchanger (80). Flows to the outdoor unit (11). The liquid refrigerant in the outdoor unit (11) passes through the branch liquid pipe (26), passes through the receiver (45), flows to the auxiliary liquid pipe (25), and is decompressed by the outdoor expansion valve (46). The decompressed refrigerant is evaporated by exchanging heat with outdoor air in the outdoor heat exchanger (44), and then the first outdoor gas pipe (22), the first four-way switching valve (43), and the second suction pipe ( The air is sucked into the fixed capacity compressor (42) again through 28). On the other hand, the liquid refrigerant flowing to the branch liquid pipe (32) is depressurized by the refrigeration expansion valve (62), then evaporates by exchanging heat with the internal air in the refrigeration heat exchanger (61), and the internal air Is cooled. Thereby, the refrigerator in a store | warehouse | chamber is performed. The evaporated gas refrigerant flows into the outdoor unit (11) through the second gas side connecting pipe (33), and is sucked again into the variable capacity compressor (41) through the first suction pipe (27).

<Cooling operation>
In the cooling and refrigeration operation, the indoor air is cooled by the air conditioning unit (12) to cool the interior of the store, and at the same time, the indoor air is cooled by the refrigerated showcase (13). In this cooling and refrigeration operation, the air conditioning heat exchanger (51) is configured to be switchable between a high-capacity operation, a first low-capacity operation, and a second low-capacity operation on the basis of the normal operation. Here, after explaining the operation | movement at the time of a normal driving | operation first, other driving | operation operation | movement is demonstrated.

  First, in the case of normal operation, as shown in FIG. 3, the controller (90) causes the first four-way switching valve (43) to be in the first state, the outdoor expansion valve (46) to be in the closed state, and the air conditioning expansion valve. (52) and the refrigeration expansion valve (62) are respectively set to normal predetermined opening degrees. The controller (90) sets the solenoid valves (SV1, SV2) and the supercooling expansion valve (77) of the switching circuit (70) to the closed state. In this state, when the variable capacity compressor (41) and the fixed capacity compressor (42) are driven, the gas refrigerant discharged from both compressors (41, 42) merges in the discharge pipe (21), and the first The four-way switching valve (43) flows through the first outdoor gas pipe (22) to the outdoor heat exchanger (44) and exchanges heat with the outdoor air to condense. The condensed liquid refrigerant flows through the outdoor liquid pipe (23), the receiver (45), and then flows to the liquid side communication pipe (29). After passing through the supercooling heat exchanger (80), this liquid refrigerant is partly diverted to the branch liquid pipe (32), and the rest is decompressed by the air conditioning expansion valve (52), and the air conditioning heat exchanger (51) To flow.

  In the air conditioning heat exchanger (51), the refrigerant exchanges heat with room air to evaporate, and the room air is cooled. Thereby, the inside of the store is cooled. Then, the evaporated gas refrigerant flows to the outdoor unit (11) through the first gas side connecting pipe (31), and the second outdoor gas pipe (24), the first four-way switching valve (43), and the second suction. It is sucked again into the fixed capacity compressor (42) through the pipe (28) in sequence. On the other hand, the liquid refrigerant flowing to the branch liquid pipe (32) is depressurized by the refrigeration expansion valve (62), then evaporates by exchanging heat with the internal air in the refrigeration heat exchanger (61), and the internal air Is cooled. Thereby, the refrigerator in a store | warehouse | chamber is performed. The evaporated gas refrigerant flows into the outdoor unit (11) through the second gas side connecting pipe (33), and is sucked again into the variable capacity compressor (41) through the first suction pipe (27).

  Next, for example, when the outside air temperature becomes high and the cooling capacity is increased from the normal operation, the operation is switched to the high capacity operation. As shown in FIG. 4, in the high-capacity operation, the second connection four-way valve (71) of the switching circuit (70) is set to the first state by the controller (90) from the state during the normal operation. Set the solenoid valve (SV1) of the pipe (72) to the open state and the solenoid valve (SV2) of the fourth connection pipe (75) to the closed state, and set the supercooling expansion valve (77) to the specified opening. Set. Further, the controller (90) sets the refrigeration expansion valve (62) to a predetermined opening smaller than the normal opening.

  In this operation, the branched refrigerant that has been branched from the liquid side connection pipe (29) to the supercooling pipe (76) is depressurized by the supercooling expansion valve (77), and then the first passage by the supercooling heat exchanger (80). The liquid refrigerant (81) is supercooled and evaporated. The evaporated gas refrigerant flows to the outdoor unit (11), and sequentially passes through the third connection pipe (74), the second four-way switching valve (71), and the first connection pipe (72), and then the fixed capacity compressor (42). Inhaled into the middle port. Here, since the refrigerant sucked into the intermediate port is in the intermediate pressure state, the specific volume becomes smaller and the mass flow rate increases than the low-pressure state refrigerant sucked into the suction port. Thereby, the discharge flow rate of the refrigerant in the fixed capacity compressor (42) increases.

  Part of the liquid refrigerant in the first passage (81) subcooled by the supercooling heat exchanger (80) was diverted to the branch liquid pipe (32), and the rest was decompressed by the air conditioning expansion valve (52). Later it evaporates in the air conditioning heat exchanger (51). Here, although the air-conditioning expansion valve (52) remains open during normal operation, the amount of refrigerant flow increases as the discharge flow rate of the fixed capacity compressor (42) increases. Therefore, in the air conditioning heat exchanger (51), in addition to the flow of the supercooled liquid refrigerant, the refrigerant flow rate increases, so that the cooling capacity is improved. On the other hand, in the refrigeration heat exchanger (61), since the opening of the refrigeration expansion valve (62) is set smaller than that during normal operation, the refrigerant flow rate decreases, but the supercooled liquid refrigerant flows. The cooling capacity is almost the same as that during normal operation.

  In other words, in this high capacity operation, a part of the refrigerant supplied to the refrigeration heat exchanger (61) is used for supercooling the liquid refrigerant, and then sucked into the intermediate port of the fixed capacity compressor (42) so that the air conditioning heat. The refrigerant flow rate in the exchanger (51) is increased. Thereby, the cooling capacity of the air conditioning unit (12) can be increased without substantially changing the cooling capacity of the refrigerated showcase (13). In the present embodiment, the opening degree of the refrigeration expansion valve (62) is reduced, but the normal opening degree may be maintained. In this case, in the air conditioning heat exchanger (51) and the refrigeration heat exchanger (61), the refrigerant flow rate corresponding to the increase in the discharge flow rate of the fixed capacity compressor (42) flows, and in addition, the refrigerant is supercooled. Therefore, capacity can be increased in both heat exchangers (51, 61).

  Next, for example, when the outside air temperature is lowered and the cooling capacity is lowered compared to the normal operation, the operation is switched to the first low capacity operation. As shown in FIG. 5, in the first low-capacity operation, the controller (90) changes the second four-way switching valve (71) of the switching circuit (70) to the second state from the state during normal operation. Set the solenoid valve (SV1) of the 1 connection pipe (72) to the open state, the solenoid valve (SV2) of the 4th connection pipe (75) to the closed state, and close the expansion valve (77) for supercooling Set to. The controller (90) sets the air conditioning expansion valve (52) to a predetermined opening that is smaller than the normal opening.

  In this operation, the gas refrigerant in an intermediate pressure state in the fixed capacity compressor (42) flows from the intermediate port to the first connection pipe (72), and passes through the second four-way switching valve (71) and the second connection pipe (73). Through the second suction pipe (28), it is sucked into the fixed capacity compressor (42) again. Thereby, since the discharge flow rate of the refrigerant in the fixed capacity compressor (42) decreases, the refrigerant flow rate of the air conditioning heat exchanger (51) also decreases. Therefore, the cooling capacity of the air conditioning unit (12) can be reduced as compared with the normal operation.

  Further, when the outside air temperature becomes lower and the cooling capacity is lowered than during the first low capacity operation, the operation is switched to the second low capacity operation. As shown in FIG. 6, in this second low-capacity operation, the solenoid valve (SV2) of the fourth connecting pipe (75) is opened by the controller (90) from the state during the first low-capacity operation. Set each of the cooling expansion valves (77) to the open state. Further, the controller (90) sets the air conditioning expansion valve (52) to a predetermined opening smaller than that during the first low-capacity operation.

  In this operation, the branched refrigerant supercooled by the supercooling heat exchanger (80) passes from the second four-way selector valve (71) through the fourth connection pipe (75) and is fixed at the second connection pipe (73). After joining with the intermediate pressure refrigerant of the capacity compressor (42), the refrigerant is sucked again into the fixed capacity compressor (42) through the second suction pipe (28). Thereby, since the discharge flow rate of the refrigerant in the fixed capacity compressor (42) is further reduced, the refrigerant flow rate of the air conditioning heat exchanger (51) is further reduced. Therefore, the cooling capacity in the air conditioning unit (12) can be further reduced.

  Thus, the refrigerant circulation amount in the air conditioning heat exchanger (51) can be increased or decreased by flowing the refrigerant in or out through the intermediate port of the fixed capacity compressor (42). Therefore, the cooling capacity of the air conditioning heat exchanger (51) can be adjusted in several stages.

-Effect of the embodiment-
As described above, according to the present embodiment, in the cooling operation, a part of the liquid refrigerant supplied to the refrigeration heat exchanger (61) is used for supercooling the remaining liquid refrigerant, and the gas after being supercooled Since the refrigerant is sucked into the intermediate port of the fixed capacity compressor (42), the discharge flow rate of the fixed capacity compressor (42) can be increased without performing inverter control or the like, and the air conditioning heat exchanger (51 ) In the refrigerant circulation amount can be increased. Therefore, the cooling capacity in the air conditioning heat exchanger (51) can be increased. Further, since the supercooled liquid refrigerant flows to the air conditioning heat exchanger (51), the cooling capacity can be further increased. At that time, in the refrigerated heat exchanger (61), the refrigerant circulation rate decreases, but the supercooled liquid refrigerant flows in the same manner as the air conditioning heat exchanger (51), so the cooling capacity in the refrigerated showcase (13) Is hardly reduced.

  In the cooling operation, part of the intermediate pressure refrigerant in the fixed capacity compressor (42) is discharged from the intermediate port and again sucked into the fixed capacity compressor (42), so that inverter control or the like is not performed. The discharge flow rate of the fixed capacity compressor (42) can be reduced, and the refrigerant circulation rate in the air conditioning heat exchanger (51) can be reduced. Therefore, the cooling capacity in the air conditioning heat exchanger (51) can be reduced.

  Further, in addition to flowing out a part of the intermediate pressure refrigerant from the fixed capacity compressor (42) described above, a part of the liquid refrigerant supplied to the air conditioning heat exchanger (51) is used to supercool the remaining liquid refrigerant. Since the gas refrigerant after being used and supercooled is sucked into the fixed capacity compressor (42), the amount of refrigerant circulating in the air conditioning heat exchanger (51) can be further reduced. Therefore, the cooling capacity of the air conditioning heat exchanger (51) can be further reduced.

  In particular, the refrigerant flow into and out of the intermediate port in the fixed capacity compressor (42) is switched by a switching circuit (70) comprising a second four-way switching valve (71) and solenoid valves (SV1, SV2). Therefore, the discharge flow rate of the fixed capacity compressor (42) can be increased or decreased reliably and easily.

<< Other Embodiments >>
The present invention may be configured as follows with respect to the above embodiment.

  For example, in the above-described embodiment, the second use system is configured by the refrigerated showcase (13). Instead, the second usage system may be configured by a refrigerated showcase that freezes food in the warehouse. You may make it comprise with a heat exchanger.

  In the above embodiment, the fixed capacity compressor (42) and the air conditioning heat exchanger (51) correspond to each other, but instead, the fixed capacity compressor (42) and the refrigeration heat exchanger (61). ) May correspond to each other. In that case, the cooling capacity in the refrigerated showcase (13) can be adjusted in several stages.

《Reference example》
As a reference example for reference of the present invention, the variable capacity compressor (41) may be changed to a fixed capacity type or may be omitted. That is, when the variable capacity compressor (41) is omitted, the refrigerant is circulated to the air conditioning heat exchanger (51) and the refrigeration heat exchanger (61) by one fixed capacity compressor (42).

  As described above, the present invention is useful as a refrigeration apparatus having a fixed capacity compressor and connected to a plurality of usage side heat exchangers.

It is a refrigerant circuit figure showing the refrigerating device concerning an embodiment. It is a refrigerant circuit figure which shows the refrigerant | coolant flow at the time of heating-refrigeration operation. It is a refrigerant circuit figure which shows the refrigerant | coolant flow at the time of normal air_conditioning | cooling refrigeration operation. It is a refrigerant circuit figure which shows the refrigerant | coolant flow at the time of a high capacity | capacitance air_conditioning | cooling operation. It is a refrigerant circuit figure which shows the refrigerant | coolant flow at the time of the 1st low capacity | capacitance air_conditionaing | cooling operation. It is a refrigerant circuit figure which shows the refrigerant | coolant flow at the time of the 2nd low capacity | capacitance air_conditioning | cooling operation.

Explanation of symbols

10 Refrigeration equipment
20 Refrigerant circuit
42 Fixed capacity compressor
44 Outdoor heat exchanger (heat source side heat exchanger)
51 Air conditioning heat exchanger (use side heat exchanger)
61 Refrigerated heat exchanger (use side heat exchanger)
70 switching circuit

Claims (2)

A heat source system having a variable capacity compressor (41), a fixed capacity compressor (42), and a heat source side heat exchanger (44), a first usage system having a usage side heat exchanger (51, 61) and a second usage system A refrigeration apparatus comprising a refrigerant circuit (20) connected to a system,
The refrigerant discharged from the variable capacity compressor (41) and the fixed capacity compressor (42) dissipates heat in the heat source side heat exchanger (44), and the utilization side heat exchanger (51) of the first utilization system. The refrigerant evaporating in the above is sucked into the fixed capacity compressor (42), and the refrigerant evaporated in the use side heat exchanger (61) of the second utilization system is sucked into the variable capacity compressor (41) In the first state, a part of the intermediate pressure refrigerant flows from the intermediate port opened to the compression chamber in the compression process of the fixed capacity compressor (42) to the suction side of the fixed capacity compressor (42); subcooled by the branch refrigerant portion of the liquid refrigerant branched liquid refrigerant flowing to, a state in which the flow branches refrigerant after the subcooling to the intermediate port of the fixed capacity compressor (42), said first usage The cooling capacity in the use side heat exchanger (51) of the system is higher than that in the first state. In the second state, a part of the intermediate pressure refrigerant flows from the intermediate port of the fixed capacity compressor (42) to the suction side of the fixed capacity compressor (42), and the liquid refrigerant flowing to both the utilization systems is supplied to the liquid refrigerant. A partly branched refrigerant is supercooled, and the supercooled branched refrigerant flows to the suction side of the fixed capacity compressor (42), and the usage side heat exchanger (51 ) Is provided with a switching circuit (70) for switching the refrigerant flow of the refrigerant circuit (20) to the third state where the cooling capacity in (1) is lower than the first state . In claim 1,
In the above operation, the use side heat exchanger (51) of the first use system cools the room, and the use side heat exchanger (61) of the second use system cools the inside of the refrigerator. apparatus.

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