JP2010014343A - Refrigerating device - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To perform a defrosting operation without installing a heating unit exclusively used for defrosting such as a heater, in a refrigerating device in which an one-system utilization-side heat exchanger is connected in parallel with a compressor and a heat source-side heat exchanger. <P>SOLUTION: In this refrigerating device, a low-pressure port 11a sucking a low pressure refrigerant, and an intermediate-pressure port 11b sucking an intermediate-pressure refrigerant are disposed in the compressor 11. A switching mechanism 12 constituted to switch a first position for making a discharge port of the compressor 11 communicate with a gas-side end of the heat source-side heat exchanger 13, and making a gas-side end of an utilization-side heat exchanger 42 of a second system communicate with a first suction port 11a of the compressor 11, and a second position for making the discharge port communicate with the gas-side end of the utilization-side heat exchanger 42 of the second system is arranged in a refrigerant circuit 10, and the gas-side end of the utilization-side heat exchanger 32 of the first system is connected with a second suction port 11b. <P>COPYRIGHT: (C)2010,JPO&INPIT

Description

  The present invention relates to a refrigeration apparatus, and more particularly to a refrigeration apparatus in which two utilization side heat exchangers are connected in parallel to a compressor and a heat source side heat exchanger.

  2. Description of the Related Art Conventionally, some refrigeration apparatuses that perform a refrigeration cycle include two systems of use side heat exchangers having different evaporation temperatures connected in parallel to a compressor and a heat source side heat exchanger (for example, Patent Document 1). reference).

  The refrigeration apparatus of Patent Document 1 includes an outdoor unit having a compressor and an outdoor heat exchanger (heat source side heat exchanger), a refrigeration heat exchanger (a use side heat exchanger of the first system), and an expansion mechanism. A refrigeration unit (first usage side unit), a refrigeration unit (second usage side unit), a refrigeration heat exchanger (second usage side heat exchanger), and an expansion mechanism. Yes.

  The discharge port of the compressor is connected to the gas side end of the outdoor heat exchanger, and the liquid side end of the outdoor heat exchanger is connected to the liquid side communication pipe between the outdoor unit and the use side unit. The liquid side communication pipe branches into two and is connected to the refrigeration heat exchanger and the refrigeration heat exchanger via expansion mechanisms, respectively. The gas side end of the refrigeration heat exchanger is connected to a gas side communication pipe between the outdoor unit and the use side unit. Moreover, the gas side edge part of the refrigerating heat exchanger is connected to the said gas side connection piping via the booster compressor. This gas side communication pipe is connected to the suction port of the compressor.

In this refrigeration apparatus, the refrigerant is circulated in the order of the compressor, the outdoor heat exchanger, the expansion mechanism, and the refrigeration heat exchanger, and the refrigerant is the compressor, the outdoor heat exchanger, the expansion mechanism, the refrigeration heat exchanger, and the booster. A refrigeration system circuit that circulates in the order of the compressor is configured. In the refrigeration apparatus, since the booster compressor is provided in the refrigeration system circuit, a refrigerant circuit for different temperature evaporation is configured in which the evaporation temperature of the refrigeration heat exchanger is lower than the evaporation temperature of the refrigeration heat exchanger. become.
JP 2003-004318 A

  In the above refrigeration apparatus, since the evaporation temperature of the refrigeration heat exchanger becomes lower than the evaporation temperature of the refrigeration heat exchanger during operation, the refrigeration heat exchanger is likely to be frosted. In the conventional refrigeration system, in order to cope with frost adhering to the refrigeration heat exchanger, it is necessary to install a heater dedicated to defrost such as a heater in the vicinity of the refrigeration heat exchanger. There was a problem that increased. Further, in the above configuration, even when defrosting of the refrigeration heat exchanger is necessary, there is a problem that the device configuration is similarly complicated and the cost is increased.

  The present invention has been created by paying attention to such problems, and its purpose is to connect a plurality of use side heat exchangers having different evaporation pressures in parallel to the compressor and the heat source side heat exchanger. In the refrigeration apparatus, the defrosting operation can be performed without providing a heater dedicated to the defrost such as a heater.

  The first invention is a refrigeration having a refrigerant circuit (10) in which two utilization side heat exchangers (32, 42) are connected in parallel to a compressor (11) and a heat source side heat exchanger (13). The equipment is assumed.

  In the refrigeration apparatus, the compressor (11) includes a first suction port (11a) and a second suction port (11b) having different suction pressures, and the refrigerant circuit (10) includes the compressor ( The discharge port of 11) and the gas side end of the heat source side heat exchanger (13) communicate with each other, the gas side end of the utilization side heat exchanger (42) of the second system and the first of the compressor (11) A switching mechanism configured to be switchable between a first position where the suction port (11a) communicates and a second position where the discharge port communicates with the gas side end of the use side heat exchanger (42) of the second system. (12), and the gas side end of the use side heat exchanger (32) of the first system is connected to the second suction port (11b).

  In the first aspect of the invention, when the switching mechanism (12) is set to the first position, the heat source side heat exchanger (13) is used as a condenser, and the use side heat exchangers (32, 42) of the above systems are used as evaporators. The cooling operation can be performed. Specifically, at this time, the gas side end of the use side heat exchanger (32) of the first system communicates with the second suction port (11b), and the discharge port and the heat source side of the compressor (11). The gas side end portion of the heat exchanger (13) communicates, and the gas side end portion of the second use side heat exchanger (42) communicates with the first suction port (11a) of the compressor (11). The liquid side end of the heat source side heat exchanger (13) and the liquid side end of each use side heat exchanger (32, 42) communicate with each other.

  Therefore, the refrigerant is discharged from the compressor (11), condensed in the heat source side heat exchanger (13), and circulated through the refrigerant circuit (10) in a cycle where it evaporates in each use side heat exchanger (32, 42). Therefore, air can be cooled in the use side heat exchanger (32, 42). At this time, the use side heat exchanger (32) of the first system communicates with the second suction port (11b) of the compressor (11), and the use side heat exchanger (42) of the second system becomes the compressor (11 ), The utilization side heat exchangers (32, 42) of each system are in different states of the evaporation temperature.

  Further, when the switching mechanism (12) is set to the second position, the defrosting operation using the second-system use-side heat exchanger (42) as a condenser and the first-system use-side heat exchanger (32) as an evaporator. It can be performed. Specifically, at this time, the gas side end of the first system use side heat exchanger (32) communicates with the second suction port (11b) of the compressor (11) and the compressor (11) The discharge port communicates with the gas side end of the second system use side heat exchanger (42). Moreover, since the use side heat exchangers (32, 42) of each system are connected in parallel to the heat source side heat exchanger (13), the liquid side ends thereof communicate with each other.

  Accordingly, the refrigerant is discharged from the compressor (11), condensed in the second use side heat exchanger (42), and evaporated in the first use side heat exchanger (32). 10) Cycle. At this time, the heat source side heat exchanger (13) may function as an evaporator or may be stopped. Thus, by setting the switching mechanism (12) to the second position, the defrosting operation can be performed when the use side heat exchanger (32, 42) of the second system is frosted.

  In a second aspect based on the first aspect, the first suction port (11a) is a low pressure port through which the low pressure refrigerant is sucked into the compressor (11), and the second suction port (11b) is the compression port. The machine (11) is characterized by an intermediate pressure port into which an intermediate pressure refrigerant having a pressure higher than that of the low pressure refrigerant and lower than that of the high pressure refrigerant is sucked.

  In the second aspect of the invention, during the cooling operation performed by setting the switching mechanism (12) to the first position, the second-system use-side heat exchanger (42) communicating with the first suction port (11a) Thus, the first use side heat exchanger (32) communicating with the second suction port (11b) is on the intermediate pressure side. For this reason, the evaporation temperature of the utilization side heat exchanger (42) of the second system is lower than the evaporation temperature of the utilization side heat exchanger (32) of the first system. In this state, the first system can be considered as a refrigeration system and the second system as a refrigeration system.

  When the switching mechanism (12) is set to the second position, the refrigerant is discharged from the compressor (11) and condensed in the use side heat exchanger (42) of the second system, and the use side heat exchange of the first system. Since the refrigerant circuit (10) circulates in a cycle that evaporates in the cooler (32), the use side heat exchanger (42) of the refrigeration system (low temperature side) can be defrosted. Contrary to the second invention, when the first suction port (11a) is an intermediate pressure port and the second suction port (11b) is a low pressure port, the use side heat exchanger of the refrigeration system (high temperature side). (32) will be defrosted.

  According to a third aspect, in the second aspect, the switching mechanism (12) is configured such that the gas side end of the heat source side heat exchanger (13) and the first suction port of the compressor (11) are in the second position. (11a) is configured to communicate with the refrigerant circuit (10) with the refrigerant flow of the heat source side heat exchanger (13) in a state where the switching mechanism (12) is set to the second position. A refrigerant circulation stop mechanism (14, CV1) for stopping is provided.

  In the third aspect of the invention, when the switching mechanism (12) is set to the second position, the gas side end of the heat source side heat exchanger (13) and the first suction port (low pressure) of the compressor (11) are arranged. While the port) (11a) is configured to communicate, the refrigerant flow in the heat source side heat exchanger (13) is stopped by the refrigerant flow stop mechanism (14, CV1). When the refrigerant circulation stop mechanism (14, CV1) is not provided, the heat source side heat exchanger (13) can also be used as an evaporator when the defrost operation is performed with the switching mechanism in the second position. Without using the side heat exchanger (13), the use side heat exchanger (42) of the second system is used as a condenser, and the use side heat exchanger (32) of the first system is used as an evaporator. The use side heat exchanger (42) of the second system can be defrosted while cooling the air with the use side heat exchanger (32).

  According to a fourth aspect of the present invention, in the second or third aspect of the present invention, the high-pressure refrigerant and the intermediate pressure are provided with a high-pressure refrigerant flow path (16a) through which the high-pressure refrigerant flows and an intermediate pressure refrigerant flow path (16b) through which the intermediate-pressure refrigerant flows. A refrigerant heat exchanger (16) for exchanging heat with the refrigerant, wherein the high-pressure refrigerant channel (16a) is connected to a liquid side pipe (57) of the refrigerant circuit (10), and the intermediate-pressure refrigerant channel (16b) Is branched from the liquid side pipe (57) and connected to a branch pipe (60) having a pressure reducing mechanism (61) on the upstream side of the pressure reducing mechanism (61), and the branch pipe (60) is connected to the intermediate pressure port. It is connected to (11b).

  In the fourth aspect of the invention, the high-pressure liquid refrigerant whose degree of supercooling is increased by the refrigerant heat exchanger (16) is supplied to the use side heat exchangers (32, 42).

  According to the present invention, the first position during the cooling operation using the heat source side heat exchanger (13) as a condenser and the use side heat exchanger (32, 42) as an evaporator and the use side heat of the second system. The switching mechanism (12) can be used to switch the second position during the defrost operation using the exchanger (42) as a condenser and the first system use-side heat exchanger (32) as an evaporator. Therefore, it is not necessary to provide a heater for exclusive use of defrost such as a heater for the defrost operation, so that it is possible to prevent the problem that the apparatus configuration is complicated and the cost is increased.

  According to the second aspect of the invention, since the first suction port (11a) of the compressor (11) is a low pressure port and the second suction port (11b) is an intermediate pressure port, the switching mechanism (12) is a first mechanism. During the cooling operation performed by setting the position, the use side heat exchanger (32) of the first system is on the high temperature side, and the use side heat exchanger (42) of the second system is on the low temperature side. When the switching mechanism is set to the second position, the use side heat exchanger (42) of the second system on the low temperature side can be defrosted. Also in the present invention, it is not necessary to provide a heater for exclusive use of defrost such as a heater for the defrost operation, so that the problem that the apparatus configuration becomes complicated and the cost becomes high can be prevented.

  According to the third aspect of the invention, the refrigerant flow stop mechanism (14, CV1) for stopping the refrigerant flow of the heat source side heat exchanger (13) with the switching mechanism (12) set to the second position is provided. Accordingly, it is possible to perform a heat recovery operation for cooling the first-side use-side heat exchanger (32) while defrosting the second-side use-side heat exchanger (42).

  According to the fourth aspect of the invention, the refrigerant heat exchanger (16) that increases the degree of supercooling of the high-pressure liquid refrigerant is provided, so that the refrigeration capacity of each use-side heat exchanger (32, 42) during operation is increased. It becomes possible.

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

  The refrigeration apparatus (1) of this embodiment is a refrigeration apparatus installed in a store such as a convenience store, and cools the refrigerated showcase and the inside of the freezer showcase. The refrigeration apparatus (1) includes an outdoor unit (2), a refrigeration unit (3), and a refrigeration unit (4). The outdoor unit (2) is installed outdoors, and the refrigeration unit (3) and the refrigeration unit (4) are installed in the store. The refrigeration unit (3) cools the interior of the refrigerated showcase, and the refrigeration unit (4) is configured to cool the interior of the refrigerated showcase.

  The refrigeration apparatus (1) includes an outdoor circuit (20) in the outdoor unit (2), a refrigeration circuit (30) in the refrigeration unit (3), and a refrigeration circuit (40) in the refrigeration unit (4). Is provided. In the refrigeration apparatus (1), the refrigerant circuit (10) of the vapor compression refrigeration cycle is configured by connecting these circuits (20, 30, 40) with pipes.

  In the refrigerant circuit (10), the refrigeration circuit (30) and the refrigeration circuit (40) are connected in parallel to the outdoor circuit (20). The refrigeration circuit (30) is connected to the outdoor circuit (20) via the first liquid side connecting pipe (5a) and the first gas side connecting pipe (6a), and the refrigeration circuit (40) is connected to the second liquid side connecting pipe (5a). The side connection pipe (5b) and the second gas side connection pipe (6b) are connected to the outdoor circuit (20). The refrigerant circuit (10) has two circuits on the refrigeration system side and the refrigerant system side.

<Outdoor unit>
The outdoor circuit (20) of the outdoor unit (2) includes a compressor (11), a four-way switching valve (12), an outdoor heat exchanger (13), an outdoor expansion valve (14), a receiver (15), A cooling heat exchanger (refrigerant heat exchanger) (16) is provided. The outdoor circuit (20) is provided with two liquid side shutoff valves (17a, 17b) and two gas side shutoff valves (18a, 18b).

  In the outdoor circuit (20), one end of the first liquid side communication pipe (5a) is connected to the first liquid side closing valve (17a), and the second liquid side communication valve is connected to the second liquid side closing valve (17b). One end of the tube (5b) is connected. One end of the first gas side communication pipe (6a) is connected to the first gas side stop valve (18a), and one end of the second gas side communication pipe (6b) is connected to the second gas side stop valve (18b). Is connected.

  The said compressor (11) is comprised by positive displacement compressors, such as a scroll compressor, for example. The compressor (11) is a compressor that is supplied with electric power through an inverter and has a variable operating capacity by changing the output frequency of the inverter. The compressor (11) includes a compression chamber (not shown) therein, and a low pressure port (first suction port) (11a) for supplying low pressure refrigerant to the compression chamber from a low pressure position of the compression chamber. An intermediate pressure port for supplying intermediate pressure refrigerant (refrigerant whose pressure is higher than the low pressure of the refrigerant circuit and lower than the high pressure) to the compression chamber from the middle of compression in the compression chamber (intermediate pressure position) A second suction port) (11b).

  One end of the first suction pipe (51) is connected to the low pressure port (11a) of the compressor (11), and the other end of the first suction pipe (51) is connected to the four-way switching valve (12). ing. One end of the second suction pipe (52) is connected to the intermediate pressure port (11b) of the compressor (11), and the other end of the second suction pipe (52) is connected to the first gas side closing valve (18a). It is connected to the. Thus, the first gas side communication pipe (6a) communicates with the intermediate pressure port (11b) of the compressor (11). Thus, in the compressor (11), the suction pipes (51, 52) are connected to the plurality of suction ports (11a, 11b). Each suction pipe (51, 52) communicates with the use side heat exchanger (32, 42), which is an evaporator of multiple systems with different evaporation temperatures, so the compressor (11) and the outdoor heat exchanger (heat source side heat exchange) The use side heat exchangers (32, 42) are connected in parallel to the (heater) (12).

  One end of a discharge pipe (53) is connected to the discharge side of the compressor (11). The other end of the discharge pipe (53) is connected to the first four-way switching valve (12).

  The outdoor heat exchanger (13) is a cross-fin type fin-and-tube heat exchanger, and heat exchange is performed between the refrigerant and the outdoor air in the outdoor heat exchanger (13). It has become. An outdoor fan (18) is provided in the vicinity of the outdoor heat exchanger (13). Outdoor air is sent to the outdoor heat exchanger (13) by the outdoor fan (18).

  The outdoor heat exchanger (13) has a gas side end (upper end in the figure) connected to the four-way switching valve (12) via the first outdoor gas pipe (54). 12) is connected to the second gas side shut-off valve (18b) by a second outdoor gas pipe (55). The liquid side end (lower end in the figure) of the outdoor heat exchanger (13) is connected to the first to fourth outdoor liquid pipes (56 to 59) and the liquid side connecting pipes (5a, 5b). And it is connected to the liquid side edge part of each utilization side heat exchanger (32, 42).

  The receiver (15) and the supercooling heat exchanger (16) are provided in the outdoor liquid pipes (56 to 59). Specifically, the liquid side end of the outdoor heat exchanger (13) is connected to the top of the receiver (15) via the first outdoor liquid pipe (56). This first outdoor liquid pipe (56) allows the flow of refrigerant from the outdoor heat exchanger (13) to the receiver (15) and prohibits the reverse refrigerant flow (CV1). Is provided.

  One end of the second outdoor liquid pipe (57) is connected to the bottom of the receiver (15). The other end of the second outdoor liquid pipe (57) is branched into two, and the second outdoor liquid pipe first branch pipe (57a) is connected to the first liquid side via the first liquid side shut-off valve (17a). Connected to the communication pipe (5a), the second outdoor liquid pipe second branch pipe (57b) is connected to the second liquid side communication pipe (5b) via the second liquid side shut-off valve (17b). In the second outdoor liquid pipe second branch pipe (57b), the refrigerant flow from the receiver (15) toward the second liquid side shut-off valve (18b) is allowed while the refrigerant flow in the reverse direction is prohibited. An outdoor second check valve (CV2) is provided.

  In the second outdoor liquid pipe second branch pipe (57b), one end of the third outdoor liquid pipe (58) is provided between the outdoor second check valve (CV2) and the second liquid side shut-off valve (17b). Is connected. The other end of the third outdoor liquid pipe (58) is connected between the outdoor first check valve (CV1) and the top of the receiver (15) in the first outdoor liquid pipe (56). The third outdoor liquid pipe (58) is provided with an outdoor third check valve (CV3). The outdoor third check valve (CV3) is configured to allow the flow of the refrigerant toward the receiver (15) while prohibiting the flow of the refrigerant in the reverse direction.

  One end of a fourth outdoor liquid pipe (59) is connected between the outdoor heat exchanger (13) and the first outdoor check valve (CV1) in the first liquid pipe (56). The other end of the fourth outdoor liquid pipe (59) is connected to the second outdoor liquid pipe (57). The fourth expansion pipe (59) is provided with the outdoor expansion valve (14). The outdoor expansion valve (14) is an electronic expansion valve whose opening degree can be adjusted.

  The supercooling heat exchanger (16) has a high-pressure refrigerant channel (16a) through which high-pressure refrigerant flows and an intermediate-pressure refrigerant channel (16b) through which intermediate-pressure refrigerant flows. Configured to replace. The high-pressure refrigerant flow path (16a) is provided in the middle of the second outdoor liquid pipe (57) which is a pipe constituting a part of the liquid side pipe of the refrigerant circuit (10). The high-pressure refrigerant channel (16a) is disposed between the connection point of the second outdoor liquid pipe (57) with the fourth outdoor liquid pipe (59) and the receiver (13). The intermediate pressure refrigerant flow path (16b) branches from the downstream side of the high pressure refrigerant flow path (16a) in the second outdoor liquid pipe (57) and has a pressure reducing valve (pressure reducing mechanism) (61). It is provided in the middle of the pipe (60). The intermediate pressure branch pipe (60) is connected to the second suction pipe (52) and communicates with the first gas side communication pipe (6a). Further, the intermediate pressure refrigerant channel (16b) is located downstream of the pressure reducing valve (61) in the path of the intermediate pressure branch pipe (60).

  The four-way switching valve (12) constituting the switching mechanism of the present invention has a discharge pipe (53) at the first port, an outdoor heat exchanger (13) at the second port, and a second port at the third port. The 1st suction pipe (51) and the 4th port are respectively connected with the 2nd gas side closing valve (18b). The four-way selector valve (12) has a first position (state indicated by a solid line in FIG. 1) in which the first port and the second port communicate with each other and the third 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. The second position (state indicated by a broken line in FIG. 1) is switchable.

  When the four-way selector valve (12) is set to the first position, the discharge port of the compressor (11) communicates with the gas side end of the outdoor heat exchanger (13) and the second gas side communication pipe (6b ) And the low pressure port (11a) of the compressor (11) communicate with each other. When the four-way selector valve (12) is set to the second position, the discharge port and the second gas side communication pipe (6b) communicate with each other and the gas side end of the outdoor heat exchanger (13) and the compression are connected. The low pressure port (11a) of the machine (11) communicates. When the four-way selector valve (12) is set to the second position, the outdoor expansion valve (14) and the outdoor first check valve (CV1) provided in the first outdoor liquid pipe (56) The refrigerant flow in the heat exchanger (13) is stopped. That is, the outdoor expansion valve (14) and the outdoor first check valve (CV1) block the refrigerant flow in the outdoor heat exchanger (13) when the four-way switching valve (12) is set to the second position. A refrigerant circulation stop mechanism is configured.

<Refrigerated unit>
The refrigeration circuit (30) of the refrigeration unit (3) is provided with a refrigeration expansion valve (31) and a refrigeration heat exchanger (32).

  The refrigeration heat exchanger (32) is a cross-fin type fin-and-tube heat exchanger, and in this refrigeration heat exchanger (32), heat is generated between the refrigerant and the air in the refrigeration showcase. Exchange is performed. A refrigerator fan (38) is provided near the refrigeration heat exchanger (32). Air in the showcase is sent to the refrigeration heat exchanger (32) by the fan (38) in the refrigerator.

  The refrigeration heat exchanger (32) constitutes one of a plurality of use side heat exchangers (32, 42) connected in parallel to the compressor (11) and having different evaporation pressures. The refrigeration heat exchanger (32) has a liquid side end (lower end in the figure) connected to the first liquid side connecting pipe (5a) and a gas side end (upper end in the figure) connected to the first gas side communication. Connected to the pipe (6a). Therefore, the gas side end of the refrigeration heat exchanger (32) communicates with the intermediate pressure port (11b) of the compressor (11).

  The refrigeration heat exchanger (32) has a liquid side end connected to the first liquid side communication pipe (5a) via the refrigeration expansion valve (31) and the refrigeration solenoid valve (SV1). The refrigeration expansion valve (31) is composed of a temperature-sensitive expansion valve whose opening degree is adjusted according to the detected temperature of the temperature-sensitive cylinder (33), and the temperature-sensitive cylinder (33) is a refrigeration heat exchanger ( 32) is provided at the gas side end which is the refrigerant outflow side.

<Refrigeration unit>
The refrigeration circuit (40) of the refrigeration unit (4) includes a refrigeration expansion valve (41) and a refrigeration heat exchanger (42).

  The refrigeration heat exchanger (42) is a cross fin type fin-and-tube heat exchanger, and in the refrigeration heat exchanger (42), heat is generated between the refrigerant and the air in the refrigeration showcase. Exchange is performed. A freezer fan (48) is provided in the vicinity of the refrigeration heat exchanger (42). The air in the showcase is sent to the refrigeration heat exchanger (42) by the freezer fan (48).

  The refrigeration heat exchanger (42) is connected in parallel to the compressor (11) and constitutes one of a plurality of use side heat exchangers (32, 42) having different evaporation pressures. The refrigeration heat exchanger (42) has a liquid side end (lower end in the figure) at the time of cooling operation connected to the second liquid side connecting pipe (5b) and a gas side end (upper end in the figure). It is connected to the 2 gas side connecting pipe (6b). Therefore, the gas side end of the refrigeration heat exchanger (42) communicates with the low pressure port (11a) of the compressor (11) when the four-way switching valve (12) is set to the first position, and the four-way When the switching valve (12) is set to the second position, it communicates with the discharge port of the compressor (11).

  In the refrigeration heat exchanger (42), the liquid side end during the cooling operation is connected to the second liquid side communication pipe (5b) via the refrigeration expansion valve (41) and the refrigeration solenoid valve (SV2). Yes. The refrigeration expansion valve (41) is composed of a temperature-sensitive expansion valve whose opening degree is adjusted according to the detected temperature of the temperature-sensitive cylinder (43), and the temperature-sensitive cylinder (43) is a refrigeration heat exchanger ( It is provided at the end on the gas side during the cooling operation in 42).

-Driving action-
Next, the operation state of this refrigeration apparatus will be described (refrigerated refrigeration operation).
In this refrigeration apparatus, basically, a refrigeration operation is performed in which the inside of the refrigerator showcase and the refrigerator showcase are simultaneously cooled. At this time, the compressor (11) is operated in the outdoor unit (2), the four-way switching valve (12) is set to the first position, the outdoor expansion valve (14) is closed, and the intermediate pressure branch pipe ( The pressure reducing valve (61) of 60) is adjusted to a predetermined opening. In the refrigeration unit (3), the refrigeration solenoid valve (SV1) is opened and the refrigeration expansion valve (31) is adjusted to a predetermined opening. Further, in the refrigeration unit (4), the refrigeration solenoid valve (SV2) is opened and the refrigeration expansion valve (41) is adjusted to a predetermined opening.

  During this refrigeration operation, as shown in FIG. 2, the gas refrigerant discharged from the compressor (11) flows into the outdoor heat exchanger (13) through the four-way switching valve (12), and this outdoor In the heat exchanger (13), heat is exchanged with outdoor air to condense. The condensed liquid refrigerant passes through the first outdoor liquid pipe (56), the receiver (15) and the second outdoor liquid pipe (57), and the first liquid side connecting pipe (5a) and the second liquid side connecting pipe (5b). Divide into

  The liquid refrigerant flowing through the first liquid side connecting pipe (5a) flows into the refrigeration unit (3). In the refrigeration unit (3), the liquid refrigerant is decompressed by the refrigeration expansion valve (31) to become a two-phase refrigerant, and flows into the refrigeration heat exchanger (32). The refrigerant exchanges heat with the air in the refrigerated showcase in the refrigerated heat exchanger (32) and evaporates, and then flows out of the refrigerated heat exchanger (32). The gas refrigerant flowing out of the refrigeration heat exchanger (32) passes from the first gas side communication pipe (6a) through the second suction pipe (52) to the compressor (11) from the intermediate pressure port (11b). ) Is inhaled.

  On the other hand, the liquid refrigerant flowing through the second liquid side connecting pipe (5b) flows into the refrigeration unit (4). In the refrigeration unit (4), the liquid refrigerant is decompressed by the refrigeration expansion valve (41) to become a two-phase refrigerant and flows into the refrigeration heat exchanger (42). The refrigerant exchanges heat with the air in the freezer showcase in the refrigeration heat exchanger (42) and evaporates, and then flows out of the refrigeration heat exchanger (42). The gas refrigerant flowing out of the refrigeration heat exchanger (42) passes from the second gas side communication pipe (6b) through the first suction pipe (51) to the compressor (11) from the low pressure port (11a). Inhaled.

  During this refrigeration operation, the liquid refrigerant is supercooled in the high-pressure refrigerant flow path (16a) of the supercooling heat exchanger (16), so the cooling capacity of the refrigerated heat exchanger (32) and refrigeration heat exchanger (42) Will improve. Further, the intermediate pressure refrigerant evaporates in the intermediate pressure refrigerant flow path (16b) of the supercooling heat exchanger (16), and this intermediate pressure refrigerant is combined with the intermediate pressure refrigerant flowing through the second suction pipe (52) in the compressor (11). Into the intermediate pressure port (11b).

  In this refrigeration system (1), the gas refrigerant evaporated in the refrigeration heat exchanger (32) is drawn into the compressor (11) from the intermediate pressure port (11b), and the gas refrigerant evaporated in the refrigeration heat exchanger (42) The compressor (11) is sucked from the low pressure port (11a). Since the suction pressure of the low pressure port (11a) is lower than the suction pressure of the intermediate pressure port (11b), the different temperature at which the evaporation temperature of the refrigeration heat exchanger (42) is lower than the evaporation temperature of the refrigeration heat exchanger (32) An evaporation refrigeration cycle is performed to cool the air in the refrigerated showcase and the air in the refrigerated showcase.

(Refrigerated operation)
The refrigeration operation is an operation that only cools the interior of the refrigerated showcase. At this time, the setting of each valve is the same as the refrigeration operation except that the refrigeration electromagnetic valve (SV2) of the refrigeration unit (4) is closed.

  In this state, the refrigerant discharged from the compressor (11) is a refrigerant circuit in a cycle in which the outdoor heat exchanger (13) is a condenser and the refrigerated heat exchanger (32) is an evaporator as shown in FIG. Circulate (10). And the inside of a refrigerator showcase is cooled when a refrigerant | coolant evaporates with a refrigerator heat exchanger (32). During this refrigeration operation, the supercooling heat exchanger (16) is used in the same manner as during the refrigeration operation.

(Freezing operation)
The freezing operation is an operation in which only the inside of the freezer showcase is cooled. At this time, the setting of each valve is the same as the refrigeration operation except that the refrigeration solenoid valve (SV1) of the refrigeration unit (3) is closed.

  In this state, the refrigerant discharged from the compressor (11) is a refrigerant circuit in a cycle in which the outdoor heat exchanger (13) is a condenser and the refrigeration heat exchanger (42) is an evaporator as shown in FIG. Circulate (10). And the inside of the refrigerator showcase is cooled by evaporating the refrigerant in the refrigeration heat exchanger (42). During this refrigeration operation, the supercooling heat exchanger (16) is used in the same manner as during the refrigeration operation. Therefore, the intermediate pressure refrigerant is injected into the compressor (11) from the intermediate pressure port (11b).

(Defrost operation)
In this refrigeration apparatus, a defrosting operation for removing frost attached to the refrigeration heat exchanger (42) can be performed. During this defrost operation, the four-way selector valve (12) is switched to the second position, the outdoor expansion valve (14) is closed, and the refrigeration solenoid valve (SV1) and the freezing solenoid valve (SV2) are opened. Is done. The refrigeration expansion valve (41) is set to fully open, and the refrigeration expansion valve (31) is adjusted to a predetermined opening. In order for the supercooling heat exchanger (16) to function even during the defrost operation, the pressure reducing valve (61) of the intermediate pressure branch pipe (60) is adjusted to a predetermined opening. Moreover, the fan (38) in a refrigerator and the fan (48) in a freezer are rotating. The fan (48) in the freezer is preferably rotated at a low speed so as not to blow hot air into the freezer showcase. In some cases, the fan (48) in the freezer may be stopped during the defrost operation. Good.

  When the compressor (11) is started in this state, as shown in FIG. 5, the refrigerant discharged from the compressor (11) passes through the second gas side connecting pipe (6b) and is refrigerated in the refrigeration unit (4). It flows into the heat exchanger (42). In the refrigeration heat exchanger (42), the high-temperature refrigerant dissipates heat and condenses. Thereby, the frost adhering to the heat exchanger tubes and fins of the refrigeration heat exchanger (42) is melted. The gas refrigerant evaporated in the refrigeration heat exchanger (42) flows from the second liquid side connecting pipe (5b) through the third outdoor liquid pipe (58) to the receiver (15). The refrigerant in the receiver (15) flows from the second outdoor liquid pipe (57) into the refrigeration unit (3) through the first liquid side connecting pipe (5a). In the refrigeration unit (3), the refrigerant is reduced in pressure by the refrigeration expansion valve (31) to become a two-phase refrigerant, and further evaporated in the refrigeration heat exchanger (32) by exchanging heat with the air in the refrigerator showcase. The refrigerant evaporated in the refrigeration heat exchanger (32) is drawn from the intermediate pressure port (11b) from the first gas side communication pipe (6a) through the second suction pipe (52) to the compressor (11).

  As the refrigerant circulates as described above, a refrigeration cycle is performed in which the refrigeration heat exchanger (42) is a condenser and the refrigeration heat exchanger (32) is an evaporator, and the refrigeration heat exchanger (42) Defrosted. At the time of this defrost operation, the refrigerant is only compressed from the intermediate pressure to the high pressure in the compressor (11), and the compression ratio is smaller than when the refrigerant is compressed from the low pressure to the high pressure. The amount of heat released at (42) does not increase too much. If the amount of heat released is large, the frost melts unevenly and may remain unmelted. However, in this embodiment, the frost in the refrigeration heat exchanger (42) gradually melts, so the possibility of unmelted is reduced. .

-Effect of the embodiment-
According to the present embodiment, the compressor (11) is provided with the low-pressure port (11a) for sucking low-pressure refrigerant and the intermediate-pressure port (11b) for sucking intermediate-pressure refrigerant. Side heat exchangers (32, 42) are connected. During defrost operation, the refrigerant discharged from the compressor (11) circulates in the refrigerant circuit (10) in a refrigeration cycle using the refrigeration heat exchanger (42) as a condenser and the refrigeration heat exchanger (32) as an evaporator. It is configured to do. Therefore, it is possible to perform defrosting by changing the operation state of the refrigerant circuit (10) without providing a defrost-dedicated heater such as a heater, thereby preventing an increase in the cost of the device (1). .

  In addition, the compression ratio is reduced by compressing the refrigerant from the intermediate pressure to the high pressure during the defrost operation. This makes it possible to remove frost adhering to the refrigeration heat exchanger (42) uniformly, and to operate while suppressing the power supplied to the compressor (11).

-Modification of the embodiment-
In the above embodiment, as another aspect of the defrost operation, the refrigeration heat exchanger (42) is used as a condenser by closing the refrigeration solenoid valve (SV1) and adjusting the opening degree of the outdoor expansion valve (14), and the outdoor heat It is also possible to perform an operation for defrosting the refrigeration heat exchanger (42) by a refrigeration cycle using the exchanger (13) as an evaporator.

<< Other Embodiments >>
About the said embodiment, it is good also as the following structures.

  For example, in the above embodiment, the refrigeration heat exchanger (42) is defrosted, but the refrigerant discharged from the compressor (11) is supplied to the refrigeration heat exchanger (32) during the reverse cycle defrost operation. Thus, the refrigerant circuit (10) can be configured so that the defrost operation of the refrigeration heat exchanger (32) can be performed. In this case, in FIG. 1, the reference numeral (4) is a refrigeration unit, the reference numeral (3) is a refrigeration unit, the first suction port indicated by reference numeral (11a) is an intermediate pressure port, and the second suction port indicated by reference numeral (11b) is a low pressure port. .

  Moreover, although the refrigerant circuit (10) using one compressor (11) was demonstrated in the said embodiment, you may make it the structure which connected the several compressor in parallel. Furthermore, although the said embodiment demonstrated the refrigerant circuit (10) which connected the refrigerator unit (3) and the freezing unit (4) to the outdoor unit (2) one by one, the refrigerator unit (3) and the freezing unit (4) One or both may be connected in parallel to the outdoor unit (2).

  In the above embodiment, the refrigeration unit (3) and the refrigeration unit (4) have the same circuit configuration, but the refrigerant on the outlet side of the refrigeration heat exchanger (42) is sucked into the refrigeration unit (4). A booster compressor for compression may be provided, and the discharge side of the booster compressor may be connected to the suction side of the compressor (11) of the outdoor unit (1).

  In addition, the above embodiment is an essentially preferable illustration, Comprising: It does not intend restrict | limiting the range of this invention, its application thing, or its use.

  As described above, the present invention is useful for a refrigeration apparatus in which two utilization side heat exchangers are connected in parallel to a compressor and a heat source side heat exchanger.

It is a refrigerant circuit figure of the refrigerating device concerning the embodiment of the present invention. It is a circuit diagram which shows the flow of the refrigerant | coolant at the time of the refrigeration freezing operation | movement of the freezing apparatus of FIG. It is a circuit diagram which shows the flow of the refrigerant | coolant at the time of the refrigerating operation of the freezing apparatus of FIG. It is a circuit diagram which shows the flow of the refrigerant | coolant at the time of the freezing operation of the freezing apparatus of FIG. It is a circuit diagram which shows the flow of the refrigerant | coolant at the time of defrost of the freezing apparatus of FIG.

Explanation of symbols

1 Refrigeration equipment
10 Refrigerant circuit
11 Compressor
11a Low pressure port (first suction port)
11b Intermediate pressure port (second suction port)
12 Four-way selector valve (switching mechanism)
13 Outdoor heat exchanger (heat source side heat exchanger)
16 Supercooling heat exchanger (refrigerant heat exchanger)
16a High-pressure refrigerant flow path
16b Intermediate pressure refrigerant flow path
32 Refrigerated heat exchanger (use side heat exchanger)
42 Refrigeration heat exchanger (use side heat exchanger)
60 Intermediate pressure branch piping (Branch piping)
61 Pressure reducing valve (pressure reducing mechanism)
CV1 outdoor first check valve (refrigerant flow stop mechanism)

Claims (4)

The refrigeration apparatus having a refrigerant circuit (10) in which two systems of use side heat exchangers (32, 42) are connected in parallel to the compressor (11) and the heat source side heat exchanger (13),
The compressor (11) includes a first suction port (11a) and a second suction port (11b) having different suction pressures,
The refrigerant circuit (10) is configured such that the discharge port of the compressor (11) and the gas side end of the heat source side heat exchanger (13) communicate with each other and the gas side of the second use side heat exchanger (42). A first position where the end communicates with the first suction port (11a) of the compressor (11), and a first position where the discharge port communicates with the gas-side end of the second system heat exchanger (42). A switching mechanism (12) configured to be switchable between two positions is provided.
A refrigerating apparatus, wherein a gas side end of a use side heat exchanger (32) of the first system is connected to the second suction port (11b). In claim 1,
The first suction port (11a) is a low-pressure port through which the compressor (11) sucks low-pressure refrigerant, and the second suction port (11b) has a pressure higher than that of the low-pressure refrigerant by the compressor (11). A refrigeration apparatus comprising an intermediate pressure port for sucking in an intermediate pressure refrigerant having a pressure lower than that of the high pressure refrigerant. In claim 2,
The switching mechanism (12) is configured such that the gas side end of the heat source side heat exchanger (13) and the first suction port (11a) of the compressor (11) communicate with each other in the second position. ,
The refrigerant circuit (10) is provided with a refrigerant circulation stop mechanism (14, CV1) for stopping the refrigerant flow of the heat source side heat exchanger (13) with the switching mechanism (12) set to the second position. A refrigeration apparatus characterized by the above. In claim 2 or 3,
A refrigerant heat exchanger (16) having a high-pressure refrigerant channel (16a) through which high-pressure refrigerant flows and an intermediate-pressure refrigerant channel (16b) through which intermediate-pressure refrigerant flows is provided to exchange heat between the high-pressure refrigerant and the intermediate-pressure refrigerant. ,
The high-pressure refrigerant channel (16a) is connected to the liquid side pipe (57) of the refrigerant circuit (10),
The intermediate pressure refrigerant channel (16b) branches from the liquid side pipe (57) and is connected to a branch pipe (60) having a pressure reducing mechanism (61) on the upstream side of the pressure reducing mechanism (61). A refrigeration apparatus characterized in that a pipe (60) is connected to the intermediate pressure port (11b).

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