JP5310243B2 - Shunt - Google Patents

Description

    The present invention relates to a shunt, and more particularly to a shunt connected to a heat exchanger.

    Conventionally, in an air conditioner, as a means for optimizing the refrigerant flow path (refrigerant path) of a heat exchanger, when the heat exchanger is used as an evaporator, the number of parallel connections of the paths through which the refrigerant passes is set to plural. While reducing the pressure loss of the refrigerant, when used as a condenser, the number of parallel connections of paths through which the refrigerant passes is reduced to increase the heat transfer coefficient of the refrigerant.

    In the air conditioner shown in Patent Document 1, the slide valve body of the refrigerant circuit switching valve is moved using the pressure difference of the refrigerant by switching the refrigerant circulation direction of the refrigerant circuit between the cooling operation and the heating operation, thereby heat exchange. The number of refrigerant paths in the container is switched.

    Here, in the refrigerant flow path, the mass flow rate of the refrigerant is constant from the start end to the end unless the refrigerant flow path branches in the middle. On the other hand, when the phase of the refrigerant changes in the refrigerant channel, the volume flow rate of the refrigerant in the refrigerant channel changes accordingly. The specific volume of the gas refrigerant is very large compared to the specific volume of the liquid refrigerant. For this reason, in the heat exchanger operating as an evaporator, the liquid refrigerant evaporates in the refrigerant flow path, so the volume flow rate of the refrigerant increases toward the downstream side, and as a result, the flow rate of the refrigerant increases toward the downstream side. It gets faster and faster. Further, in the heat exchanger that operates as a condenser, since the gas single-phase refrigerant flows into the refrigerant flow path, the volume flow rate of the refrigerant increases on the upstream side, and as a result, the flow rate of the refrigerant becomes faster toward the upstream side. .

JP 2002-228273 A

    However, in the heat exchanger shown in Patent Document 1, the cross-sectional area of the flow path cannot be changed from the upstream side to the downstream side of the refrigerant flow path. Therefore, when the heat exchanger is used as an evaporator, liquid refrigerant increases on the upstream side of the heat exchanger, whereas the cross-sectional area of the refrigerant flow path is large, so that the heat transfer coefficient of the flowing refrigerant decreases. On the other hand, when used as a condenser, there is a problem that the pressure loss of the flowing refrigerant increases because the sectional area of the refrigerant flow path is small while the gas refrigerant increases on the upstream side of the heat exchanger. .

    This invention is made | formed in view of such a point, and it aims at adjusting freely the cross-sectional area according to the state of the refrigerant | coolant which flows the refrigerant | coolant flow path of a heat exchanger from the upstream to the downstream.

    A first invention is a flow divider connected between a refrigerant pipe (15a) of a refrigerant circuit (15) and a heat exchanger (25), and includes a cylindrical casing (31), the casing (31) ), An inflow side port (32) through which refrigerant flows from the refrigerant circuit (15), an outflow side port (33) through which refrigerant flows out to the refrigerant circuit (15), and a plurality of the heat exchangers (25) First connection ports (34a to 34d) connected to the respective inlet sides of the refrigerant paths (26a to 26d), and second connection ports (34e) connected to the outlet sides of the respective refrigerant paths (26a to 26d). 34h) and the first connection port (34a-34d) which is accommodated in the casing (31) so as to be reciprocally movable in the axial direction of the casing (31) and communicates with the inflow side port (32). The number of the second connection ports (34e to 34h) communicating with the outlet port (33) and the number of the second connection ports (34e to 34h) are changed. A switching member (41) partitioned into a medium chamber (35 to 37) and a moving mechanism (40) for moving the switching member (41) are provided.

    In the first invention, the refrigerant circulating in the refrigerant circuit (15) flows into the one refrigerant chamber (35) in the casing (31) from the inflow side port (32). And in one refrigerant | coolant chamber (35), a refrigerant | coolant flows in into a heat exchanger (25) via the 1st connection port (34a-34d) connected with the inflow side port (32). In the heat exchanger (25), the refrigerant exchanges heat with the fluid to be heat exchanged. The refrigerant that has flowed out of the heat exchanger (25) flows into the other refrigerant chamber (36) in the casing (31) from the second connection port (34e to 34h) and from the outflow side port (33) to the refrigerant circuit. To (15). Here, the moving mechanism (40) communicates with the inflow side port (32) in the casing (31) by reciprocating the switching member (41) in the axial direction of the casing (31) in the casing (31). The casing (31) has a plurality of refrigerant chambers (35 to 37) so that the number of one connection port (34a to 34d) and the number of second connection ports (34e to 34h) communicating with the outflow side port (33) are different. ).

    In a second aspect based on the first aspect, the first connection port (34a to 34d) and the second connection port (34e to 34h) are formed side by side in the axial direction of the casing (31), and the movement The mechanism (40) includes a drive unit (47) that reciprocates the switching member (41) in a direction in which the first connection ports (34a to 34d) and the second connection ports (34e to 34h) are arranged.

    In the second aspect of the invention, the drive part (47) reciprocates the switching member (41) in the casing (31) in the axial direction of the casing (31) to communicate with the inflow side port (32). While changing the number of ports (34a to 34d), the number of second connection ports (34e to 34h) communicating with the outflow side port (33) is changed.

    According to a third invention, in the first or second invention, the switching member (41) has an inflow side refrigerant chamber (35) in communication with the inflow side port (32) and an outflow side port (33) in communication. A state in which the inside of the casing (31) is partitioned into the outflow side refrigerant chamber (36) that communicates with a part of the first connection port (34a to 34d) and a part of the second connection port (34e to 34h) The intermediate refrigerant chamber (37), the inflow side refrigerant chamber (35), and the outflow side refrigerant chamber (36) are switched to a state in which the casing (31) is partitioned, and the intermediate refrigerant The number of first connection ports (34a to 34d) communicating with the chamber (37) and the number of second connection ports (34e to 34h) can be changed.

    In the said 3rd invention, the refrigerant | coolant which flowed out from the heat exchanger (25) connected with a 1st connection port (34a-34d) is in a casing (31) via a 2nd connection port (34e-34h). It flows into the intermediate refrigerant chamber (37). In the intermediate refrigerant chamber (37), the refrigerant flows into the heat exchanger (25) through the first connection ports (34a to 34d) communicating with the second connection ports (34e to 34h). In the heat exchanger (25), the refrigerant exchanges heat with the fluid to be heat exchanged.

    According to a fourth invention, in any one of the first to third inventions, the switching member (41) is configured such that the inflow side port (32) is always set to any one of the first connection ports (34a to 34d). The refrigerant chamber (35-37) in the casing (31) is defined so as to communicate and the outflow side port (33) always communicates with any of the second connection ports (34e-34h). Yes.

    In the fourth aspect of the invention, the inflow side port (32) is always in communication with any of the first connection ports (34a to 34d), and the outflow side port (33) is always in communication with any of the second connection ports (34e). To 34h), the switching member (41) is moved so as to communicate with the refrigerant chamber (35 to 37) in the casing (31).

    In a fifth aspect based on any one of the first to fourth aspects, the refrigerant circuit (15) is configured by being filled with an HFO-based refrigerant.

    In the fifth aspect of the invention, when a low-pressure refrigerant such as HFO1234yf is used, the efficiency drop due to the pressure loss in the heat exchanger (25) (especially the evaporator) is significant, and the heat exchanger ( While the number of passes in 25) needs to be optimized for each operating condition, the number of passes can be selected according to the operating conditions by making the number of passes variable.

    According to the first aspect, the number of first connection ports (34a to 34d) communicating with the inflow side port (32) and the number of second connection ports (34e to 34h) communicating with the outflow side port (33) are changed. Thus, the refrigerant flow path of the heat exchanger (25) can be made to have the number of refrigerant paths (26a to 26d) according to the state of the flowing refrigerant from the upstream side to the downstream side. That is, when the gas refrigerant flows, the flow rate of the gas refrigerant is decreased by increasing the number of refrigerant paths and increasing the cross-sectional area of the flow path, while the number of refrigerant paths is decreased when the liquid refrigerant flows. be able to. Thereby, the pressure loss of the refrigerant flowing through the heat exchanger (25) can be reduced, and the heat transfer rate can be increased. As a result, the refrigerant flow path of the heat exchanger (25) can be freely adjusted to have a cross-sectional area corresponding to the state of the refrigerant flowing from the upstream side to the downstream side.

    According to the second aspect, since the switching member (41) is moved by the drive unit (47), the switching member (41) can be easily moved in the casing (31). That is, the communication state between the inflow side port (32) and the first connection port (34a to 34d) and the communication state between the outflow side port (33) and the second connection port (34e to 34h) can be easily switched. it can. Thereby, even if the heat exchanger (25) is in the heat absorption operation or the heat dissipation operation, the heat exchanger (25 connected to the first connection port (34a to 34d) is moved by moving the switching member (41). ) Refrigerant paths (26a to 26d) and the number of refrigerant paths (26a to 26d) of the heat exchanger (25) connected to the second connection ports (34e to 34h) can be freely switched. As a result, the refrigerant flow path of the heat exchanger (25) can be freely adjusted to have a cross-sectional area corresponding to the state of the refrigerant flowing from the upstream side to the downstream side.

    According to the third aspect of the invention, the number of first connection ports (34a to 34d) and the number of second connection ports (34e to 34h) communicating with the intermediate refrigerant chamber (37) are changed. In the middle of the refrigerant flow in the vessel (25), the number of refrigerant paths (26a to 26d) can be changed. That is, the refrigerant flow path of the heat exchanger (25) can be made to have the number of refrigerant paths (26a to 26d) corresponding to the state of the flowing refrigerant from the upstream side to the downstream side. Thereby, the pressure loss of the refrigerant flowing through the heat exchanger (25) can be reduced, and the heat transfer rate can be increased. As a result, the refrigerant flow path of the heat exchanger (25) can be freely adjusted to have a cross-sectional area corresponding to the state of the refrigerant flowing from the upstream side to the downstream side.

    According to the fourth aspect of the invention, since the inflow side port (32) and the outflow side port (33) are always opened, the refrigerant circuit (15) enters the casing (31) through the inflow side port (32). While all the refrigerant to be introduced can flow into the casing (31), all of the refrigerant that flows out to the refrigerant circuit (15) via the outflow side port (33) can flow out. That is, it is possible to reliably prevent the refrigerant flow in the refrigerant circuit (15) connected to the inflow side port (32) and the outflow side port (33) that are in the closed state from staying.

    According to the fifth aspect of the invention, when a low-pressure refrigerant such as HFO1234yf is used, for example, the efficiency drop due to the pressure loss in the heat exchanger (25) (especially the evaporator) is significant, and heat exchange is performed to reduce the pressure loss. On the other hand, the number of passes of the vessel (25) needs to be optimized for each operating condition, but by changing the number of passes, the number of passes according to the operating conditions can be selected.

It is a piping system diagram showing a refrigerant circuit concerning an embodiment. It is a schematic longitudinal cross-sectional view which shows the 1st state of the switching valve which concerns on embodiment. It is a schematic longitudinal cross-sectional view which shows the 2nd state of the switching valve which concerns on embodiment. It is a schematic longitudinal cross-sectional view which shows the 3rd state of the switching valve which concerns on embodiment. It is a schematic longitudinal cross-sectional view which shows the 4th state of the switching valve which concerns on embodiment.

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

    In the present embodiment, as shown in FIG. 1, an air conditioner (10) that performs air conditioning in a living room or the like will be described.

<Configuration of air conditioner>
The air conditioner (10) according to the present embodiment is a separate type air conditioner including an outdoor unit (12) and an indoor unit (11). The air conditioner (10) is provided with a refrigerant circuit (15) which is a closed circuit.

    The refrigerant circuit (15) is filled with a refrigerant using 2,3,3,3-tetrafluoro-1-propene (hereinafter referred to as “HFO-1234yf”). The refrigerant circuit (15) is configured to selectively execute a cooling cycle and a heating cycle. The refrigerant circuit (15) includes a use side circuit (17) provided in the indoor unit (11) and a heat source side circuit (16) provided in the outdoor unit (12). A shunt (30) and an indoor heat exchanger (24) are connected to the use side circuit (17). In the heat source side circuit (16), a compressor (20), a flow divider (30), an outdoor heat exchanger (23), a four-way switching valve (21), and an expansion valve (22) are connected. ing.

    In the refrigerant circuit (15), the discharge side of the compressor (20) is connected to the A port of the four-way switching valve (21). The D port of the four-way selector valve (21) is connected to one end of the flow divider (30). The other end of the flow divider (30) is connected to the expansion valve (22). The C port of the four-way switching valve (21) is connected to one end of the flow divider (30). The other end of the flow divider (30) is connected to the expansion valve (22).

    The compressor (20) is configured as a so-called fully enclosed type of variable capacity type. The compressor (20) compresses the refrigerant sucked from the suction side and discharges it to the discharge side.

    The four-way selector valve (21) includes a first state (state indicated by a solid line in FIG. 1) in which the A port and the D port communicate and the B port and the C port communicate, and the A port and the C port communicate with each other. It can be switched to a second state (state indicated by a broken line in FIG. 1) in which the B port and the D port communicate with each other.

    The outdoor heat exchanger (23) exchanges heat between outdoor air sucked by an outdoor fan (not shown) and refrigerant. The outdoor heat exchanger (23) is provided between the D port of the four-way switching valve (21) and the expansion valve (22) in the refrigerant circuit (15). The outdoor heat exchanger (23) includes a heat exchanger body (25).

    The indoor heat exchanger (24) exchanges heat between indoor air sucked by an indoor fan (not shown) and refrigerant. The indoor heat exchanger (24) is provided between the C port of the four-way switching valve (21) and the expansion valve (22) in the refrigerant circuit (15). The indoor heat exchanger (24) includes a heat exchanger body (25).

    As shown in FIGS. 2 to 5, the heat exchanger body (25) is configured as a cross fin type fin-and-tube heat exchanger. The heat exchanger body (25) constitutes a heat exchanger according to the present invention. The heat exchanger body (25) is formed to have four first to fourth heat transfer tubes (26a to 26d). Each of the heat transfer tubes (26a to 26d) is a refrigerant flow passage formed in a tubular shape through which the refrigerant flows, and constitutes a refrigerant path according to the present invention. Both ends of each heat transfer tube (26a to 26d) are connected to the flow divider (30) via the connection tube (27).

    The flow divider (30) is configured to cause the refrigerant flowing through the refrigerant circuit (15) to flow into the heat exchanger body (25) of the outdoor and indoor heat exchangers (23, 24), and the flow divider according to the present invention. Is configured. One shunt (30) is provided for each of the outdoor and indoor heat exchangers (23, 24). The flow divider (30) includes a flow divider casing (31), an upper port (32), a lower port (33), a connection port group (34), a switching valve (41), and a moving mechanism (40). It consists of and.

    The flow divider casing (31) is formed in a vertically long, substantially cylindrical shape having a hollow inside. The shunt casing (31) constitutes a casing according to the present invention. The shunt casing (31) is surrounded by a side surface surrounding the side periphery, a lower bottom surface, and an upper upper surface to form an internal space. The shunt casing (31) has an upper port (32) formed above the side surface, and a lower port (33) formed below the upper port (32). In addition, the shunt casing (31) has a connection port group (34) formed on a side surface at a position facing the upper port (32) and the lower port (33). The shunt casing (31) houses therein a switching valve (41) and a moving shaft (45). The moving shaft (45) is connected to the drive motor (47) via a gear (46) outside the shunt casing (31).

    The upper and lower ports (32, 33) are ports to which the refrigerant pipe (15a) of the refrigerant circuit (15) is connected. The upper and lower ports (32, 33) allow the refrigerant flowing through the refrigerant circuit (15) to flow into the flow divider casing (31), while allowing the refrigerant after flowing out of the heat exchanger body (25) to flow through the flow divider casing (31). ) To return to the refrigerant circuit (15). One upper port (32) is formed above the side surface of the flow distributor casing (31), and is connected to the refrigerant pipe (15a) extending from the expansion valve (22) of the refrigerant circuit (15). The lower port (33) of the flow divider (30) connected to the outdoor heat exchanger (23) is connected to the refrigerant pipe (15a) extending from the D port of the four-way switching valve (21), while The lower port (33) of the flow divider (30) connected to the heat exchanger (24) is connected to the C port of the four-way switching valve (21). That is, the refrigerant pipe (15a) of the refrigerant circuit (15) communicates with the inside of the flow divider casing (31) via the upper and lower ports (32, 33).

    The connection port group (34) is a port to which the heat exchanger body (25) is connected. The connection port group (34) includes eight ports of first to eighth ports (34a to 34h).

    The first to eighth ports (34a to 34h) are ports to which the first to fourth heat transfer tubes (26a to 26d) of the heat exchanger body (25) are connected via the connection tube (27). The first to eighth ports (34a to 34h) allow the refrigerant in the shunt casing (31) to flow into the heat exchanger body (25) via the connection pipe (27), while the heat exchanger body (25) The refrigerant after flowing out is returned to the shunt casing (31). The first to eighth ports (34a to 34h) are arranged in the axial direction of the flow divider casing (31) from the upper side to the lower side at positions facing the upper and lower ports (32, 33) on the side surface of the flow divider casing (31). Are formed in series in order. Specifically, one end sides of the first to fourth heat transfer tubes (26a to 26d) are connected to the first to fourth ports (34a to 34d), respectively, and the fifth to eighth ports (34e to 34h) are connected to the first to fourth ports (34a to 34d). The other end sides of the first to fourth heat transfer tubes (26a to 26d) are connected to each other. That is, both ends of the first heat transfer tube (26a) are connected to the first and fifth ports (34a, 34e), and the second heat transfer tube (26b) is connected to the second and sixth ports (34b, 34f). Both ends of the third heat transfer tube (26c) are connected to the third and seventh ports (34c, 34g), and the fourth transfer port is connected to the fourth and eighth ports (34d, 34h). Both ends of the heat pipe (26d) are connected.

    The switching valve (41) is a valve that partitions the internal space of the flow distributor casing (31) into first to third refrigerant chambers (35 to 37), and constitutes the switching member (41) according to the present invention. ing. The switching valve (41) is accommodated in the flow distributor casing (31). The switching valve (41) is configured to be capable of reciprocating in the vertical direction (direction along the axial direction of the flow divider casing (31)) in the flow divider casing (31). The switching valve (41) includes an upper valve body (42), a lower valve body (43), and a rod portion (44).

    The upper valve body (42) is a valve body that switches the communication state between the upper port (32) and the first to fourth ports (34a to 34d). The upper valve body (42) is formed in a flat plate shape that is substantially the same outer shape as the horizontal sectional shape inside the flow distributor casing (31), and is installed on the upper side inside the flow distributor casing (31).

    The lower valve body (43) is a valve body that switches a communication state between the lower port (33) and the fifth to eighth ports (34e to 34h). The lower valve body (43) is formed in a flat plate shape that is substantially the same outer shape as the horizontal cross-sectional shape inside the flow distributor casing (31), and the upper valve body (31) is formed on the lower side inside the flow distributor casing (31). 42). The lower valve body (43) and the upper valve body (42) are integrally formed by being connected via a rod portion (44). That is, the upper valve body (42), the rod portion (44), and the lower valve body (43) are configured to be movable together.

    The moving mechanism (40) is for moving the switching valve (41). The moving mechanism (40) includes a moving shaft (45), a gear (46), and a drive motor (47). The drive motor (47) constitutes a drive unit according to the present invention.

    The moving shaft (45) is formed in a rod-shaped shaft member, has a front end connected to the back surface of the lower valve body (43), and a rear end extending to the outside of the flow distributor casing (31). A rack portion (45a) is formed on the outer peripheral surface of the moving shaft (45). The moving shaft (45) is connected to the gear (46) and the drive motor (47) via the rack part (45a). The gear (46) is connected to the drive motor (47). The gear (46) is configured to rotate with the rotation of the drive motor (47). That is, as the drive motor (47) rotates, the gear (46) rotates, and at the same time, the rotational force of the gear (46) moves through the rack portion (45a) meshing with the gear (46). The movement axis (45) moves by transmitting to (45). An adjustment spring (48) for adjusting the movement of the switching valve (41) is provided in the flow divider casing (31). The adjustment spring (48) has an upper end attached to the back surface of the lower valve body (43) and a lower end attached to the bottom surface inside the flow distributor casing (31). By this adjustment spring (48), the switching valve (41) is always subjected to a spring force directed toward the bottom surface of the flow divider casing (31).

    The switching valve (41) switches the upper port (32), the lower port (33), and the first to eighth ports (34a to 34h) to four communication states depending on the position in the flow divider casing (31). The switching valve (41) constitutes a switching member according to the present invention. Specifically, the upper port (32) and the first to fourth ports (34a to 34d) communicate with each other in the first refrigerant chamber (35), while the fifth to eighth ports (34e to 34h) and the lower port (33) ) In the second refrigerant chamber (36) (state shown in FIG. 2) is defined as the first state. The upper port (32) and the first to third ports (34a to 34c) communicate with each other in the first refrigerant chamber (35), while the seventh port (34g) and the fourth to sixth ports (34d to 34f) are the first ports. The state (state shown in FIG. 3) in which the third refrigerant chamber (37) communicates and the eighth port (34h) and the lower port (33) communicate in the second refrigerant chamber (36) is referred to as a second state. The upper port (32) communicates with the first and second ports (34a, 34b) in the first refrigerant chamber (35), while the fifth and sixth ports (34e, 34f) and the third and fourth ports (34c, 34d) communicate with each other in the third refrigerant chamber (37), and the seventh and eighth ports (34g, 34h) and the lower port (33) communicate with each other in the second refrigerant chamber (36) (FIG. 4). The state shown in FIG. Further, the upper port (32) and the first port (34a) communicate with each other in the first refrigerant chamber (35), while the fifth port (34e) and the second to fourth ports (34b to 34d) are in the third refrigerant chamber. The state (shown in FIG. 5) in which the sixth to eighth ports (34f to 34h) and the lower port (33) communicate with each other in the second refrigerant chamber (36) is defined as the fourth state. .

-Driving action-
The operation of the air conditioner (10) will be described. This air conditioner (10) switches between a cooling operation and a heating operation. During the cooling operation, in the refrigerant circuit (15), the outdoor heat exchanger (23) performs a condensation operation, and the indoor heat exchanger (24) performs an evaporation operation. Further, during the heating operation, in the refrigerant circuit (15), the indoor heat exchanger (24) performs a condensation operation, and the outdoor heat exchanger (23) performs an evaporation operation.

<Cooling operation of air conditioner>
The operation of the air conditioner (10) during the cooling operation will be described with reference to FIG. During the cooling operation, the four-way selector valve (21) is set to the first state (the state indicated by the solid line in FIG. 1). When the compressor (20) is operated in this state, the refrigerant circulates in the refrigerant circuit (15) to perform a refrigeration cycle. At that time, in the refrigerant circuit (15), the outdoor heat exchanger (23) serves as a condenser, and the indoor heat exchanger (24) serves as an evaporator.

    The high-pressure refrigerant discharged from the compressor (20) flows into the outdoor heat exchanger (23) through the four-way switching valve (21), dissipates heat to the outdoor air, and is condensed. The high-pressure refrigerant flowing out of the outdoor heat exchanger (23) is depressurized when passing through the expansion valve (22), and then flows into the indoor heat exchanger (24). In the indoor heat exchanger (24), the flowing refrigerant absorbs heat from the indoor air and evaporates. The refrigerant flowing out of the indoor heat exchanger (24) is sucked into the compressor (20) through the four-way switching valve (21). The gas refrigerant sucked into the compressor (20) is compressed to a predetermined pressure to become a high-pressure refrigerant, and then discharged from the compressor (20).

<Heating operation of air conditioner>
The operation of the air conditioner (10) during the heating operation will be described with reference to FIG. During the heating operation, the four-way selector valve (21) is set to the second state (the state indicated by the broken line in FIG. 1). When the compressor (20) is operated in this state, the refrigerant circulates in the refrigerant circuit (15) to perform a refrigeration cycle. At that time, in the refrigerant circuit (15), the indoor heat exchanger (24) serves as a condenser, and the outdoor heat exchanger (23) serves as an evaporator.

    The high-pressure refrigerant discharged from the compressor (20) flows into the indoor heat exchanger (24) through the four-way switching valve (21), dissipates heat to the indoor air, and condenses. The high-pressure refrigerant that has flowed out of the indoor heat exchanger (24) is decompressed when passing through the expansion valve (22), and then flows into the outdoor heat exchanger (23) through the four-way switching valve (21). In the outdoor heat exchanger (23), the refrigerant that has flowed in absorbs heat from the outdoor air and evaporates. The refrigerant flowing out of the outdoor heat exchanger (23) is sucked into the compressor (20) through the four-way switching valve (21). The gas refrigerant sucked into the compressor (20) is compressed to a predetermined pressure to become a high-pressure refrigerant, and then discharged from the compressor (20).

-Operation of shunt-
Next, the operation of the flow divider (30) will be described. In the cooling operation of the air conditioner (10), the shunt (30) is connected to the heat exchanger body (25) that operates as a condenser, and the heat exchanger body (25 that operates as an evaporator). ) Has two operations. Each will be described.

    First, in the flow divider (30) connected to the heat exchanger body (25) operating as a condenser, the switching valve (41) can be switched to the first to fourth states. In addition, you may make it perform the switching operation | movement of a 1st-4th state during the driving | operation of an air conditioning apparatus (10). In the flow divider (30), the refrigerant flows in the direction indicated by the broken-line arrows in FIGS.

    When the flow divider (30) is set to the first state (FIG. 2), in the flow divider casing (31), the second refrigerant chamber (36) is interposed between the lower valve body (43) and the bottom surface of the flow divider casing (31). ) Is formed, and the first refrigerant chamber (35) is formed between the upper valve body (42) and the upper surface of the flow distributor casing (31). In the flow divider (30) connected to the heat exchanger body (25) operating as a condenser, the first refrigerant chamber (35) constitutes the outflow side refrigerant chamber according to the present invention, while the second refrigerant chamber. (36) constitutes the inflow side refrigerant chamber according to the present invention. The high-pressure gaseous refrigerant discharged from the compressor (20) flows from the lower port (33) into the second refrigerant chamber (36) of the flow divider casing (31). The lower port (33) at this time constitutes an inflow side port according to the present invention. In the second refrigerant chamber (36), the high-pressure gas refrigerant is diverted to the other end side of the first to fourth heat transfer tubes (26a to 26d) via the fifth to eighth ports (34e to 34h). That is, the fifth to eighth ports (34e to 34h) constitute the first connection port according to the present invention. At this time, the gas refrigerant is divided into four heat transfer tubes (refrigerant paths). In the first to fourth heat transfer tubes (26a to 26d), the gas refrigerant radiates heat to the air outside the heat transfer tubes (26a to 26d) and condenses. The liquid refrigerant that has flowed out of the first to fourth heat transfer tubes (26a to 26d) flows into the first refrigerant chamber (35) via the first to fourth ports (34a to 34d). That is, the first to fourth ports (34a to 34d) constitute a second connection port according to the present invention. In the first refrigerant chamber (35), all the refrigerants that have flowed in join together and flow out from the upper port (32) to the refrigerant circuit (15). The upper port (32) at this time constitutes an outflow side port according to the present invention.

    When the flow divider (30) is set to the second state (FIG. 3), in the flow divider casing (31), the second refrigerant chamber (36) is interposed between the lower valve body (43) and the bottom surface of the flow divider casing (31). ) Is formed, and a first refrigerant chamber (35) is formed between the upper valve body (42) and the upper surface of the flow divider casing (31), and the upper valve body (42) and the lower valve body (43) A third refrigerant chamber (37) is formed therebetween. The third refrigerant chamber (37) constitutes an intermediate refrigerant chamber according to the present invention. The high-pressure gaseous refrigerant discharged from the compressor (20) flows from the lower port (33) into the second refrigerant chamber (36) of the flow divider casing (31). In the second refrigerant chamber (36), the high-pressure gas refrigerant is caused to flow into the other end side of the fourth heat transfer tube (26d) through the eighth port (34h). In the fourth heat transfer tube (26d), the gas refrigerant radiates heat to the air outside the fourth heat transfer tube (26d). The refrigerant flowing out of the fourth heat transfer tube (26d) flows into the third refrigerant chamber (37) of the flow divider casing (31) through the fourth port (34d). In the third refrigerant chamber (37), the introduced refrigerant is caused to flow into the other end side of the first to third heat transfer tubes (26a to 26c) via the fifth to seventh ports (34e to 34g). That is, the fifth to eighth ports (34e to 34h) constitute the first connection port according to the present invention. In the first to third heat transfer tubes (26a to 26c), the heat is transferred to the air outside the heat transfer tubes (26a to 26c) and condensed. The condensed refrigerant flowing out from the first to third heat transfer tubes (26a to 26c) flows into the first refrigerant chamber (35) of the flow divider casing (31) via the first to third ports (34a to 34c). . That is, the first to fourth ports (34a to 34d) constitute a second connection port according to the present invention. In the first refrigerant chamber (35), the condensed refrigerant that has flowed in flows out from the upper port (32) to the refrigerant circuit (15).

    When the flow divider (30) is set to the third state (FIG. 4), the high-pressure gaseous refrigerant discharged from the compressor (20) flows from the lower port (33) to the second refrigerant chamber of the flow divider casing (31). Flows into (36). In the second refrigerant chamber (36), the high-pressure gas refrigerant is caused to flow into the other end side of the third and fourth heat transfer tubes (26c, 26d) via the seventh and eighth ports (34g, 34h). At this time, since the gas refrigerant is divided into two heat transfer tubes (refrigerant paths), the cross-sectional area of the refrigerant flow path is increased, and the flow velocity is reduced. In the third and fourth heat transfer tubes (26c, 26d), the gas refrigerant dissipates heat to the air outside the heat transfer tubes (26c, 26d), and a part of them is condensed to be in a liquid state. The refrigerant flowing out from the third and fourth heat transfer tubes (26c, 26d) flows into the third refrigerant chamber (37) of the flow distributor casing (31) through the third and fourth ports (34c, 34d). In the third refrigerant chamber (37), the introduced refrigerant is caused to flow into the other end side of the first and second heat transfer tubes (26a, 26b) via the fifth and sixth ports (34e, 34f). That is, the fifth to eighth ports (34e to 34h) constitute the first connection port according to the present invention. In the first and second heat transfer tubes (26a, 26b), the gas refrigerant dissipates heat to the air outside the heat transfer tubes (26a, 26b) and condenses. The condensed refrigerant flowing out from the first and second heat transfer tubes (26a, 26b) flows into the first refrigerant chamber (35) of the flow divider casing (31) through the first and second ports (34a, 34b). . That is, the first to fourth ports (34a to 34d) constitute a second connection port according to the present invention. In the first refrigerant chamber (35), the introduced condensed refrigerant merges and flows out from the upper port (32) to the refrigerant circuit (15). When the amount of refrigerant flowing through the refrigerant circuit (15) is reduced by controlling the air conditioning capability of the air conditioner (10), the shunt (30) connected to the heat exchanger body (25) operating as a condenser ) Is set to the third state.

    When the flow divider (30) is set to the fourth state (FIG. 5), the high-pressure gaseous refrigerant discharged from the compressor (20) flows from the lower port (33) to the second refrigerant chamber of the flow divider casing (31). Flows into (36). And in a 2nd refrigerant | coolant chamber (36), a high voltage | pressure gas refrigerant is made to flow into the other end side of a 2nd-4th heat exchanger tube (26b-26d) via a 6th-8th port (34f-34h). At this time, since the gas refrigerant is divided into three heat transfer tubes (refrigerant paths), the cross-sectional area of the refrigerant flow path is increased, and the flow velocity is decreased. In the second to fourth heat transfer tubes (26b to 26d), the gas refrigerant dissipates heat to the air outside the heat transfer tubes (26b to 26d), and most of them condense into a liquid state. The refrigerant that has flowed out of the heat transfer tubes (26b to 26d) flows into the third refrigerant chamber (37) of the flow distributor casing (31) through the second to fourth ports (34b to 34d). In the third refrigerant chamber (37), the introduced refrigerant is caused to flow into the other end side of the first heat transfer tube (26a) through the fifth port (34e). That is, the fifth to eighth ports (34e to 34h) constitute the first connection port according to the present invention. Note that most of the refrigerant flowing into the first heat transfer tube (26a) is in a liquid state. In the first heat transfer tube (26a), part of the gas refrigerant dissipates heat to the air outside the first heat transfer tube (26a) and condenses. At this time, since the condensed refrigerant passes through one heat transfer tube (refrigerant path), the cross-sectional area of the refrigerant flow path is reduced and the heat transfer coefficient of the refrigerant is increased. The condensed refrigerant flowing out from the first heat transfer pipe (26a) flows into the first refrigerant chamber (35) of the flow divider casing (31) through the first port (34a). That is, the first to fourth ports (34a to 34d) constitute a second connection port according to the present invention. In the first refrigerant chamber (35), the condensed refrigerant that has flowed in flows out from the upper port (32) to the refrigerant circuit (15).

    Next, in the flow divider (30) connected to the heat exchanger body (25) operating as an evaporator, the switching valve (41) can be switched to the first to fourth states. In addition, you may make it perform the switching operation | movement of a 1st-4th state during the driving | operation of an air conditioning apparatus (10). In this flow divider (30), the refrigerant flows in the direction indicated by the solid arrow in FIGS.

    When the flow divider (30) is set to the first state (FIG. 2), in the flow divider casing (31), the second refrigerant chamber (36) is interposed between the lower valve body (43) and the bottom surface of the flow divider casing (31). ) Is formed, and the first refrigerant chamber (35) is formed between the upper valve body (42) and the upper surface of the flow distributor casing (31). In the flow divider (30) connected to the heat exchanger body (25) operating as an evaporator, the first refrigerant chamber (35) constitutes the inflow side refrigerant chamber according to the present invention, while the second refrigerant chamber. (36) constitutes the outflow side refrigerant chamber according to the present invention. The low-pressure liquid refrigerant that has passed through the expansion valve (22) flows from the upper port (32) into the first refrigerant chamber (35) of the flow divider casing (31). The upper port (32) at this time constitutes an inflow side port according to the present invention. In the first refrigerant chamber (35), the low-pressure liquid refrigerant is diverted to one end side of the first to fourth heat transfer tubes (26a to 26d) via the first to fourth ports (34a to 34d). That is, the first to fourth ports (34a to 34d) constitute a first connection port according to the present invention. At this time, since the gas refrigerant is divided into four heat transfer tubes (refrigerant paths), the cross-sectional area of the refrigerant flow path is increased, and the flow velocity is decreased. In the first to fourth heat transfer tubes (26a to 26d), the liquid refrigerant absorbs heat from the air outside the heat transfer tubes (26a to 26d) and evaporates. The gas refrigerant that has flowed out of the first to fourth heat transfer tubes (26a to 26d) flows into the second refrigerant chamber (36) via the fifth to eighth ports (34e to 34h). That is, the fifth to eighth ports (34e to 34h) constitute a second connection port according to the present invention. In the second refrigerant chamber (36), all the refrigerant that has flowed in joins and flows out from the lower port (33) to the refrigerant circuit (15). The lower port (33) at this time constitutes an outflow side port according to the present invention. Moreover, when the refrigerant | coolant circulation amount which flows through a refrigerant circuit (15) is decreased by the air-conditioning capability control etc. of an air conditioning apparatus (10), a flow divider (30) is set to a 1st state.

    When the flow divider (30) is set to the second state (FIG. 3), in the flow divider casing (31), the second refrigerant chamber (36) is interposed between the lower valve body (43) and the bottom surface of the flow divider casing (31). ) Is formed, and a first refrigerant chamber (35) is formed between the upper valve body (42) and the upper surface of the flow divider casing (31), and the upper valve body (42) and the lower valve body (43) A third refrigerant chamber (37) is formed therebetween. The third refrigerant chamber (37) constitutes an intermediate refrigerant chamber according to the present invention. The low-pressure liquid refrigerant that has passed through the expansion valve (22) flows from the upper port (32) into the first refrigerant chamber (35) of the flow divider casing (31). And in a 1st refrigerant | coolant chamber (35), a low voltage | pressure liquid refrigerant is made to flow into the one end side of a 1st-3rd heat exchanger tube (26a-26c) via a 1st-3rd port (34a-34c). In the first to third heat transfer tubes (26a to 26c), the liquid refrigerant absorbs heat from the air outside the heat transfer tubes (26a to 26c), and a part thereof evaporates. The refrigerant flowing out from the first to third heat transfer tubes (26a to 26c) flows into the third refrigerant chamber (37) of the flow divider casing (31) through the fifth to seventh ports (34e to 34g). In the third refrigerant chamber (37), the introduced refrigerant is diverted to one end side of the fourth heat transfer tube (26d) through the fourth port (34d). That is, the first to fourth ports (34a to 34d) constitute a first connection port according to the present invention. In the fourth heat transfer tube (26d), the liquid refrigerant absorbs heat from the air outside the fourth heat transfer tube (26d) and evaporates. The gas refrigerant that has flowed out of the fourth heat transfer tube (26d) flows into the second refrigerant chamber (36) through the eighth port (34h). That is, the fifth to eighth ports (34e to 34h) constitute a second connection port according to the present invention. In the second refrigerant chamber (36), all the refrigerant that has flowed in joins and flows out from the lower port (33) to the refrigerant circuit (15).

    When the flow divider (30) is set to the third state (FIG. 4), the low-pressure liquid refrigerant that has passed through the expansion valve (22) flows from the upper port (32) to the first refrigerant chamber (35) of the flow divider casing (31). ). And in a 1st refrigerant | coolant chamber (35), a low-pressure liquid refrigerant is made to flow into the one end side of a 1st and 2nd heat exchanger tube (26a, 26b) via a 1st and 2nd port (34a, 34b). In the first and second heat transfer tubes (26a, 26b), the liquid refrigerant absorbs heat from the air outside the heat transfer tubes (26a, 26b), and a part thereof evaporates. The refrigerant flowing out from the first and second heat transfer tubes (26a, 26b) flows into the third refrigerant chamber (37) of the flow divider casing (31) through the fifth and sixth ports (34e, 34f). In the third refrigerant chamber (37), the introduced refrigerant is divided into one end side of the third and fourth heat transfer tubes (26c, 26d) through the third and fourth ports (34c, 34d). That is, the first to fourth ports (34a to 34d) constitute a first connection port according to the present invention. In the third and fourth heat transfer tubes (26c, 26d), the liquid refrigerant absorbs heat from the air outside the heat transfer tubes (26c, 26d) and evaporates. The gas refrigerant that has flowed out of the third and fourth heat transfer tubes (26d) flows into the second refrigerant chamber (36) through the seventh and eighth ports (34g, 34h). That is, the fifth to eighth ports (34e to 34h) constitute a second connection port according to the present invention. In the second refrigerant chamber (36), all the refrigerant that has flowed in joins and flows out from the lower port (33) to the refrigerant circuit (15).

    When the flow divider (30) is set to the fourth state (FIG. 5), the low-pressure liquid refrigerant that has passed through the expansion valve (22) passes from the upper port (32) to the first refrigerant chamber (35) of the flow divider casing (31). ). And in a 1st refrigerant | coolant chamber (35), a low voltage | pressure liquid refrigerant is poured into the one end side of a 1st heat exchanger tube (26a) via a 1st port (34a). In the first heat transfer tube (26a), the liquid refrigerant absorbs heat from the air outside the first heat transfer tube (26a), and a part thereof evaporates. At this time, since the liquid refrigerant passes through one heat transfer tube (refrigerant path), the cross-sectional area of the refrigerant flow path is reduced and the heat transfer coefficient of the refrigerant is increased. The refrigerant flowing out from the first heat transfer tube (26a) flows into the third refrigerant chamber (37) of the flow divider casing (31) through the fifth port (34e). In the third refrigerant chamber (37), the introduced refrigerant is diverted to one end side of the second to fourth heat transfer tubes (26b to 26d) via the second to fourth ports (34b to 34d). That is, the first to fourth ports (34a to 34d) constitute a first connection port according to the present invention. At this time, since the gas refrigerant is divided into three heat transfer tubes (refrigerant paths), the cross-sectional area of the refrigerant flow path is increased, and the flow velocity is decreased. In the second to fourth heat transfer tubes (26b to 26d), the liquid refrigerant absorbs heat from the air outside the heat transfer tubes (26b to 26d) and evaporates. The gas refrigerant that has flowed out of the second to fourth heat transfer tubes (26b to 26d) flows into the second refrigerant chamber (36) via the sixth to eighth ports (34f to 34h). That is, the fifth to eighth ports (34e to 34h) constitute a second connection port according to the present invention. In the second refrigerant chamber (36), all the refrigerant that has flowed in joins and flows out from the lower port (33) to the refrigerant circuit (15).

-Effect of the embodiment-
According to the above embodiment, the shunt (30) is configured to change the number of ports communicating with the lower port (33) and the number of ports communicating with the upper port (32). The number of refrigerant paths (26a to 26d) corresponding to the state of the flowing refrigerant (liquid or gas) can be increased from the upstream side to the downstream side. That is, when the gas refrigerant flows, the flow rate of the gas refrigerant is decreased by increasing the number of refrigerant paths and increasing the cross-sectional area of the flow path, while the number of refrigerant paths is decreased when the liquid refrigerant flows. be able to. Thereby, while being able to reduce the pressure loss of the refrigerant | coolant which flows through a heat exchanger main body (25), a heat transfer rate can be made high. Further, since the switching valve (41) is moved by the drive motor (47), the switching valve (41) can be easily moved in the flow distributor casing (31). That is, the communication state between the lower port (33) and the fifth to eighth ports (34e to 34h) and the communication state between the upper port (32) and the first to fourth ports (34a to 34d) are easily switched. be able to. Accordingly, even when the heat exchanger body (25) is in an evaporation operation or a condensation operation, the number of ports communicating with the lower port (33) and the upper port (32) can be increased by moving the switching valve (41). The number of ports communicating with can be switched freely. Subsequently, since the communication state of the four ports in the third refrigerant chamber (37) is switched, the number of refrigerant paths can be changed in the middle of the refrigerant flow in the heat exchanger body (25). Thereby, it can change to the cross-sectional area according to the state of the refrigerant | coolant which flows through the refrigerant | coolant flow path of a heat exchanger main body (25). As a result, the refrigerant flow path of the heat exchanger body (25) can be freely adjusted to have a cross-sectional area corresponding to the state of the refrigerant flowing from the upstream side to the downstream side.

    Further, since the upper port (32) and the lower port (33) are always open, all the refrigerant flowing from the refrigerant circuit (15) into the casing (31) through the upper and lower ports (32, 33) is casing. While being able to flow into (31), all of the refrigerant flowing out to the refrigerant circuit (15) can be discharged through the lower and upper ports (33, 32). That is, it is possible to reliably prevent the refrigerant flow in the refrigerant circuit (15) connected to the closed lower port (33) and upper port (32) from staying.

    Further, when using a low-pressure refrigerant such as HFO1234yf, for example, the efficiency drop due to the pressure loss in the heat exchanger body (25) (especially the evaporator) is significant, and the heat exchanger body (25) for reducing the pressure loss While it is necessary to optimize the number of passes for each operating condition, by changing the number of passes, it is possible to operate under optimum conditions.

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

    Although the said embodiment demonstrated the refrigerant circuit (15) which has a flow divider (30) corresponding to the heat exchanger main body (25) provided with the four heat exchanger tubes (26a-26d), a heat exchanger main body (25 The number of the heat transfer tubes (26a to 26d) included in) may be changed as appropriate. In this case, the number of first connection ports (34a to 34d) and second connection ports (34e to 34h) of the flow divider (30) is also changed according to the number of heat transfer tubes (26a to 26d). Further, if the number of heat transfer tubes (26a to 26d) is increased, the number of refrigerant paths in the heat exchanger body (25) can be changed in a wider range.

    Further, in the above embodiment, the shunt (30) is provided with eight first connection ports (34a to 34d) and second connection ports (34e to 34h), which are arranged in order. The arrangement of each port may be changed as appropriate.

    Moreover, although the said embodiment demonstrated the air conditioning apparatus which has a refrigerant circuit filled with the HFO type refrigerant | coolant as a refrigerant | coolant, an HFO type refrigerant is only an example and the refrigerant circuit (15) to which this invention is applied has other refrigerant | coolants. May be filled.

    In the above embodiment, the example in which the flow divider (30) of the present invention is connected to both the outdoor heat exchanger (23) and the indoor heat exchanger (24) has been described. However, the flow divider (30) You may make it connect to either one of a heat exchanger (23) and an indoor heat exchanger (24).

    In the above embodiment, the moving mechanism (40) is used as the means for moving the switching valve (41). However, other moving means may be used in the present invention.

    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 shunt connected to a heat exchanger.

DESCRIPTION OF SYMBOLS 15 Refrigerant circuit 15a Refrigerant pipe 25 Heat exchanger main body 26a-26d 1st-4th heat exchanger tube 31 Divider casing 32 Upper port 33 Lower port 34a-34h 1st-8th port 35 1st refrigerant | coolant chamber 36 2nd refrigerant | coolant chamber 37 third refrigerant chamber 40 moving mechanism 41 switching valve 47 drive motor

Claims (5)

A shunt connected between the refrigerant pipe (15a) of the refrigerant circuit (15) and the heat exchanger (25),
A cylindrical casing (31);
An inflow port (32) formed in the casing (31) through which refrigerant flows from the refrigerant circuit (15), an outflow port (33) through which refrigerant flows out to the refrigerant circuit (15), and the heat exchanger ( 25) a first connection port (34a to 34d) connected to each inlet side of the plurality of refrigerant paths (26a to 26d), and a second connected to the outlet side of each refrigerant path (26a to 26d). Connection port (34e-34h),
In the casing (31), the number of first connection ports (34a to 34d) communicated with the inflow side port (32) and the outflow side port are accommodated so as to be reciprocally movable in the axial direction of the casing (31). A switching member (41) for partitioning the casing (31) into a plurality of refrigerant chambers (35-37) so that the number of second connection ports (34e-34h) communicating with (33) changes, And a moving mechanism (40) for moving the switching member (41). In claim 1,
The first connection port (34a to 34d) and the second connection port (34e to 34h) are formed side by side in the axial direction of the casing (31),
The moving mechanism (40) includes a drive unit (47) that reciprocates the switching member (41) in a direction in which the first connection ports (34a to 34d) and the second connection ports (34e to 34h) are arranged. A shunt characterized by. In claim 1 or 2,
The switching member (41) is connected to the inflow side refrigerant chamber (35) that communicates with the inflow side port (32) and the outflow side refrigerant chamber (36) that communicates with the outflow side port (33) in the casing (31). A middle refrigerant chamber (37) in which a part of the first connection port (34a to 34d) and a part of the second connection port (34e to 34h) communicate with each other, and the inflow side refrigerant chamber ( 35) and a state in which the inside of the casing (31) is partitioned into the outflow side refrigerant chamber (36), and
A current divider configured to be able to change the number of first connection ports (34a to 34d) communicating with the intermediate refrigerant chamber (37) and the number of second connection ports (34e to 34h). In any one of Claims 1-3,
In the switching member (41), the inflow side port (32) always communicates with any of the first connection ports (34a to 34d), and the outflow side port (33) always has any of the second connection ports ( 34e to 34h) is configured to partition the refrigerant chamber (35 to 37) in the casing (31) so as to communicate with the casing (31). In any one of Claims 1-4,
The said refrigerant circuit (15) is filled with the HFO type refrigerant | coolant, and is comprised, It is characterized by the above-mentioned.

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