JP7414961B2 - Indoor unit and air conditioner - Google Patents

Description

The present disclosure relates to an indoor unit and an air conditioner.

BACKGROUND ART Conventionally, indoor units are known that include a plurality of indoor heat exchangers connected in parallel to each other in a refrigerant circuit.

In the indoor unit described in Japanese Unexamined Patent Publication No. 2019-138506 (Patent Document 1), two heat exchangers are arranged side by side along the extending direction of each refrigerant flow path, and the refrigerant of each heat exchanger is A pair of header pipes each connected to both ends of the flow path are arranged between the two heat exchangers. In the above-mentioned indoor unit, the connection portion between the header pipe and the refrigerant pipe (connect pipe) that connects the pair of header pipes and the extension pipe is also arranged between the two heat exchangers. That is, in the indoor unit, the pair of header pipes and the connecting portion between the connect pipe and the header pipe are arranged at the center of the indoor unit in the extending direction.

In addition, the indoor units of household air conditioners are equipped with multiple indoor heat exchangers connected in parallel to each other and multiple blowers that blow air to each heat exchange room unit, and the air volume of each indoor blower is changed. Indoor units are known that are installed to create a temperature difference in the air blown out.

Japanese Patent Application Publication No. 2019-138506

The indoor unit of a typical household air conditioner is fixed to a wall surface with the refrigerant flow path extending along the horizontal direction. Furthermore, generally, the insertion hole formed in the wall surface for passing the extension pipe is formed at a position away from the center of the wall surface in the horizontal direction.

Therefore, when the indoor unit described in Patent Document 1 is adopted as an indoor unit of a home air conditioner, the connect pipe or extension pipe is connected to a pair of header pipes arranged at the center of the indoor unit in the above-mentioned extending direction. It is necessary to arrange it between the above-mentioned insertion hole. As a result, the indoor unit requires a space for accommodating the connect pipe or extension pipe disposed between the pair of header pipes and the insertion hole, resulting in an increase in size of the indoor unit.

In order to suppress the increase in size of the indoor unit, it is necessary to reduce the volume of at least one heat exchanger. In this case, the heat exchange performance of the indoor unit deteriorates.

The main purpose of the present disclosure is to provide an indoor unit that is less bulky and less degraded in performance than the above-mentioned indoor units when used as an indoor unit of a household air conditioner, and an air conditioner equipped with the indoor unit. Our goal is to provide a harmonizing machine.

The indoor unit according to the present disclosure includes a first pipe and a second pipe through which a refrigerant flows into or out of the indoor unit, and a first heat exchanger connected between the first pipe and the second pipe. , a second heat exchanger connected in parallel with the first heat exchanger to the first pipe and the second pipe. The first heat exchanger and the second heat exchanger are provided so that the refrigerant flowing in the first direction and the gas flowing in the direction intersecting the first direction exchange heat. The first pipe, the second pipe, and the first heat exchanger are arranged so as to sandwich the second heat exchanger in the first direction. The indoor unit includes a first pipe line connecting the first pipe and the first heat exchanger, a second pipe line connecting the second pipe and the first heat exchanger, and a second pipe line connecting the first pipe and the first heat exchanger. The heat exchanger further includes a third pipe line that connects the heat exchanger to the heat exchanger, and a fourth pipe line that connects the second pipe and the second heat exchanger. Each of the third pipe line and the fourth pipe line is located on the opposite side of the first heat exchanger with respect to the second heat exchanger in the first direction, and the first pipe and the second pipe are arranged. It is arranged in the first area where

According to the present disclosure, even when used as an indoor unit of a household air conditioner, an indoor unit is suppressed from increasing in size and a decrease in performance is suppressed compared to the above-mentioned indoor units, and an air conditioner equipped with the indoor unit. We can provide equipment.

1 is a diagram showing a refrigerant circuit of an air conditioner according to Embodiment 1. FIG. 1 is a diagram showing an example of installation of an air conditioner according to Embodiment 1. FIG. FIG. 3 is a partial perspective view showing a first heat exchanger and a second heat exchanger of the indoor unit according to the first embodiment. 4 is a view seen from arrow IV in FIG. 3. FIG. 4 is a view taken along arrow VV in FIG. 3. FIG. FIG. 6 is a schematic diagram for explaining the structure of the first piping and the second piping of the indoor unit shown in FIGS. 3 to 5. FIG. FIG. 7 is a schematic diagram for explaining the structure of the first pipe and the second pipe of the indoor unit according to the second embodiment. FIG. 7 is a schematic diagram for explaining the structure of the first pipe and the second pipe of the indoor unit according to the third embodiment. It is a graph showing the pipe diameter and the pressure loss gradient in the pipe for a pipe through which a gas-liquid two-phase refrigerant flows.

Embodiments of the present disclosure will be described below with reference to the drawings.
Embodiment 1.
<Configuration of air conditioner>
As shown in FIG. 1, the air conditioner 100 includes an indoor unit 1, an outdoor unit 20, and extension pipes 25 and 26. The air conditioner 100 is formed with a refrigerant circuit in which refrigerant circulates. The refrigerant circuit mainly includes a first heat exchanger 2A, a second heat exchanger 2B, a compressor 21, a four-way valve 24, an outdoor heat exchanger 22, a pressure reduction device 23, and extension pipes 25 and 26.

As shown in FIG. 1, inside the indoor unit 1, a part of the refrigerant flow path of the refrigerant circuit is arranged. The indoor unit 1 mainly includes a first heat exchanger 2A, a second heat exchanger 2B, a first pipe 3, a second pipe 4, a first blower 5A, and a second blower 5B. The first heat exchanger 2A and the second heat exchanger 2B exchange heat between the refrigerant and indoor air. The first heat exchanger 2A and the second heat exchanger 2B are connected in parallel to each other in the refrigerant circuit. One end of the first pipe 3 forms a first inlet/outlet that is one end of a refrigerant flow path arranged inside the indoor unit 1 . One end of the second pipe 4 forms a second inlet/outlet, which is the other end of the refrigerant flow path arranged inside the indoor unit 1 .

The first blower 5A sends indoor air to the first heat exchanger 2A. The second blower 5B sends indoor air to the second heat exchanger 2B. The air volume of the first blower 5A is controlled independently of the air volume of the second blower 5B. The first blower 5A and the second blower 5B may be axial blowers or once-through blowers. The detailed configuration of the indoor unit 1 will be described later.

Outdoor unit 20 includes a compressor 21 , an outdoor heat exchanger 22 , a pressure reducing device 23 , and a four-way valve 24 . The outdoor heat exchanger 22 exchanges heat between the refrigerant and outdoor air.

By switching the circulation direction of the refrigerant in the refrigerant circuit by the four-way valve 24, heating operation and cooling operation are switched. In the heating operation, the refrigerant circulates in the order of the compressor 21, the four-way valve 24, the outdoor heat exchanger 22, the pressure reducing device 23, the extension pipe 25, the first heat exchanger 2A and the second heat exchanger 2B, and the extension pipe 26. do. In the cooling operation, the refrigerant circulates in the order of the compressor 21, the four-way valve 24, the extension pipe 26, the first heat exchanger 2A and the second heat exchanger 2B, the extension pipe 25, the pressure reduction device 23, and the outdoor heat exchanger 22. do. A liquid phase refrigerant (hereinafter referred to as liquid refrigerant) flows through the extension pipe 25 during both heating operation and cooling operation. Gas-phase refrigerant (hereinafter referred to as gas refrigerant) flows through the extension pipe 26 during both heating operation and cooling operation. In FIG. 1, solid line arrows indicate the direction of refrigerant flow during heating operation, and dotted line arrows indicate the direction of refrigerant flow during cooling operation.

As shown in FIG. 2, the indoor unit 1 of the air conditioner 100 is fixed to a wall surface of a wall 200 facing indoors, in which an insertion hole 201 is formed. The indoor unit 1 is arranged so that the direction (first direction) in which the refrigerant flows in the first heat exchanger 2A and the second heat exchanger 2B is along the horizontal direction. In the indoor unit 1, a suction port (not shown) for sucking indoor air is formed, for example, above the first heat exchanger 2A and the second heat exchanger 2B. In the indoor unit 1, an unillustrated outlet for blowing air indoors is formed, for example, below the first heat exchanger 2A and the second heat exchanger 2B.

The insertion hole 201 penetrates the wall 200 and communicates the indoor and outdoor spaces. The extension pipe 25 and the extension pipe 26 are passed through the insertion hole 201 . One end of the extension pipe 25 is connected to the first pipe 3 of the indoor unit 1 via a connect pipe 27. One end of the extension pipe 26 is connected to the second pipe 4 of the indoor unit 1 via a connect pipe 27. The other ends of the extension piping 25 and the extension piping 26 are connected to the outdoor unit 20.

The indoor unit 1 shown in FIG. 2 is arranged so as not to overlap the insertion hole 201 when viewed from a direction perpendicular to the wall surface. Between the indoor unit 1 and the insertion hole 201, for example, there is a pipe section connecting between the first inlet and outlet, which is one end of the first pipe 3, and the above-mentioned one end of the extension pipe 25, and a pipe part, which is one end of the second pipe 4. A connect pipe 27 having a pipe section connecting between a certain second inlet and outlet and the above-mentioned one end of the extension pipe 26 is arranged. Note that the indoor unit 1 may be arranged so as to overlap the insertion hole 201 when viewed from a direction perpendicular to the wall surface.

<Indoor unit configuration>
3 to 6 are diagrams for explaining the indoor unit 1 according to the first embodiment. Note that in FIGS. 3 to 5, illustrations of the first blower 5A, the second blower 5B, and the casing of the indoor unit 1 are omitted. In FIG. 6, dotted lines surrounding the first heat exchanger 2A, the second heat exchanger 2B, the first piping 3, and the second heat exchanger 2B illustrate the outline of the indoor unit 1.

As shown in FIGS. 1, 3 to 6, the refrigerant flow path arranged inside the indoor unit 1 includes a first heat exchanger 2A, a second heat exchanger 2B, a first pipe 3, a second It mainly includes a pipe 4, a first pipe 3A, a second pipe 4A, a third pipe 3B, and a fourth pipe 4B.

As shown in FIG. 3, each of the first heat exchanger 2A and the second heat exchanger 2B is configured so that the refrigerant flowing in the first direction A and the air flowing in the direction intersecting the first direction A exchange heat. It is set in. The second heat exchanger 2B is arranged in line with the first heat exchanger 2A in the first direction A.

Each of the first heat exchanger 2A and the second heat exchanger 2B includes a plurality of heat exchanger tubes extending in the first direction A and fins connected to each heat exchanger tube. Each of the first heat exchanger 2A and the second heat exchanger 2B is, for example, a fin-and-tube type heat exchanger.

As shown in FIGS. 4 to 6, each of the plurality of heat exchanger tubes of the first heat exchanger 2A is connected in series to each other via the first connection part 7A, and has at least one refrigerant flow path (the first 1 refrigerant flow path). The first refrigerant flow path has a plurality of first connection parts 7A. Each of the plurality of heat exchanger tubes of the second heat exchanger 2B is connected to each other in series via the second connection portion 7B, and forms at least one refrigerant flow path (second refrigerant flow path). The second refrigerant flow path has a plurality of second connection parts 7B. In addition, in FIG. 6, only some of the plurality of first connection parts 7A and second connection parts 7B are illustrated. Each first connection portion 7A is arranged in the second region R2 or the third region R3. Each second connection portion 7B is arranged in the second region R2 or the first region R1. In the second region R2, the plurality of first connection parts 7A are arranged to face the plurality of second connection parts 7B. The outer shape of each first connecting portion 7A and each second connecting portion 7B is U-shaped. In the refrigerant circuit, the first refrigerant flow path and the second refrigerant flow path are connected in parallel to each other.

As shown in FIGS. 4 and 5, the outer shape of each fin of the first heat exchanger 2A and the second heat exchanger 2B when viewed from the first direction is, for example, W-shaped. Note that in the first heat exchanger 2A and the second heat exchanger 2B shown in FIGS. 3 to 5, the panel member PA is fixed to the area where the fins are not arranged when viewed from the first direction. The panel member PA is fixed, for example, to both ends of each of the first heat exchanger 2A and the second heat exchanger 2B in the first direction A. The panel member PA of the second heat exchanger 2B is provided with insertion holes through which the first portion 33 of the first conduit 3A and the first portion 43 of the second conduit 4A, which will be described later, are inserted. Thereby, the first portion 33 of the first conduit 3A and the first portion 43 of the second conduit 4A are positioned with respect to the second heat exchanger 2B. The white dotted line in FIG. 4 indicates the outer shape of the fins of the second heat exchanger 2B. The white dotted line in FIG. 5 indicates the boundary line of the outer shape of the fins of the first heat exchanger 2A. The panel member PA is also fixed to the casing of the indoor unit 1, for example. In this case, each of the first heat exchanger 2A and the second heat exchanger 2B is fixed to the casing of the indoor unit 1 by a panel member PA. Further, each of the first heat exchanger 2A and the second heat exchanger 2B includes, for example, a plurality of heat exchangers, and each of the heat exchangers is arranged in a line in the direction of air flow and connected to each other in series. It may be assembled by In this case, the panel member PA may have the role of positioning each heat exchanger. In addition, each of the 1st heat exchanger 2A and the 2nd heat exchanger 2B may be comprised by one heat exchanger.

As shown in FIGS. 3 and 6, the first pipe 3 and the second pipe 4 are pipes through which the refrigerant flows into or out of the indoor unit 1. The refrigerant flows into the indoor unit 1 through one of the first pipe 3 and the second pipe 4, and flows out from the indoor unit 1 through the other of the first pipe 3 and the second pipe 4. As described above, one end of the first pipe 3 is connected to the one end of the extension pipe 25. One end of the second pipe 4 is connected to the one end of the extension pipe 26 . The other end of the first pipe 3 is connected to one end of each of a first pipe line 3A and a third pipe line 3B, which will be described later, via a branch part 3C. The other end of the second pipe 4 is connected to one end of each of a second pipe line 4A and a fourth pipe line 4B, which will be described later, via a branch portion 4C. In addition, in FIG. 6, the solid line arrows shown below the first pipe 3 and the second pipe 4 indicate the direction of refrigerant flow during heating operation, and the dotted line arrows indicate the flow direction of refrigerant during cooling operation. There is.

During the heating operation, the gas refrigerant flows into the indoor unit 1 from the second pipe 4, and the liquid refrigerant flows out of the indoor unit 1 from the first pipe 3. During the cooling operation, liquid refrigerant flows into the indoor unit 1 from the first pipe 3, and gas refrigerant flows out of the indoor unit 1 from the second pipe 4.

As shown in FIGS. 3 and 6, the first pipe 3 and the second pipe 4 are arranged on one side (Fig. and on the right side of each page of FIG. 6).

As shown in FIGS. 3 and 6, the first inlet/outlet which is one end of the first pipe 3, the second inlet/outlet which is one end of the second pipe 4, and the first heat exchanger 2A are connected in the first direction. A is arranged to sandwich the second heat exchanger 2B. In other words, the length of the first pipe line 3A connecting the first heat exchanger 2A and the first inlet and the second pipe line 4A connecting the first heat exchanger 2A and the second outlet are It is longer than the length of the third pipe line 3B that connects the second heat exchanger 2B and the first outflow port, and the length of the fourth pipe line 4B that connects the second heat exchanger 2B and the second outflow port.

As shown in FIG. 6, the internal region of the indoor unit 1 includes a first region R1, a second region R2, and a third region R3, which are divided by a first heat exchanger 2A and a second heat exchanger 2B. have. The first region R1 is a region located on the first pipe 3 and second pipe 4 side with respect to the second heat exchanger 2B in the first direction A. In other words, the first region R1 is a region located on the opposite side of the first heat exchanger 2A with respect to the second heat exchanger 2B in the first direction A. The second region R2 is a region located between the first heat exchanger 2A and the second heat exchanger 2B in the first direction A. The third region R3 is a region located on the opposite side of the second heat exchanger 2B with respect to the first heat exchanger 2A in the first direction A.

The second region R2 includes a portion of each of the first pipe line 3A and the second pipe line 4A, the first connection part 7A of the first heat exchanger 2A, and the second connection part 7B of the second heat exchanger 2B. is located. The first connection portion 7A of the first heat exchanger 2A is arranged in the third region R3. The first region R1 includes other parts of each of the first pipe line 3A and the second pipe line 4A, the entirety of each of the third pipe line 3B and the fourth pipe line 4B, and the second heat exchanger 2B. The second connecting portion 7B, the first pipe 3, and the second pipe 4 are arranged.

As shown in FIGS. 4 and 6, the first heat exchanger 2A has a first port 13A forming one end of the first refrigerant flow path and through which the refrigerant flows in and out, and the other end of the first refrigerant flow path. It further has a second port 14A through which refrigerant flows in and out. The first heat exchanger 2A has, for example, one first port 13A and two second ports 14A. Note that the first heat exchanger 2A only needs to have at least one first port 13A and at least one second port 14A; You may do so.

As shown in FIGS. 3 and 6, the first port 13A and the second port 14A are provided on one side of the first heat exchanger 2A in the first direction A (on the right side of the paper in each figure). That is, the first port 13A and the second port 14A are located on the first pipe 3 and second pipe 4 sides in the first direction A, and are located on one side of the first heat exchanger 2A facing the second heat exchanger 2B. provided at the end. The first port 13A and the second port 14A face the second region R2.

As shown in FIG. 5, one second port 14A is arranged, for example, in line with the first port 13A in the vertical direction. The first port 13A is arranged, for example, on the windward side of the one second port 14A.

As shown in FIGS. 5 and 6, the second heat exchanger 2B has a third port 13B forming one end of the second refrigerant flow path and through which the refrigerant flows in and out, and the other end of the second refrigerant flow path. It further has a fourth port 14B through which refrigerant flows in and out. The second heat exchanger 2B has, for example, one third port 13B and two fourth ports 14B. Note that the second heat exchanger 2B only needs to have at least one third port 13B and at least one fourth port 14B; You may do so.

As shown in FIGS. 3 and 6, the third port 13B and the fourth port 14B are provided on one side of the second heat exchanger 2B in the first direction A (on the right side of the paper in each figure). That is, the third port 13B and the fourth port 14B are provided at one end of the second heat exchanger 2B facing the first piping 3 and second piping 4 side in the first direction A. The third port 13B and the fourth port 14B face the first region R1.

As shown in FIG. 4, one fourth port 14B is arranged, for example, in line with the third port 13B in the vertical direction. The third port 13B is arranged, for example, on the windward side of the fourth port 14B.

Each of the first heat exchanger 2A and the second heat exchanger 2B has, for example, the same configuration. The first port 13A shown in FIG. 4 is arranged to overlap in the first direction A with the third port 13B shown in FIG. Similarly, the second port 14A shown in FIG. 4 is arranged to overlap in the first direction A with the fourth port 14B shown in FIG. Note that each of the first heat exchanger 2A and the second heat exchanger 2B may have different configurations.

As shown in FIG. 1, FIG. 3 to FIG. A second pipe line 4A connects the heat exchanger 2A, a third pipe line 3B connects the first pipe 3 and the second heat exchanger 2B, and a second pipe line 4 connects the second heat exchanger 2B. It further includes a fourth conduit 4B. The first pipe line 3A and the third pipe line 3B are connected in parallel to the first pipe line 3. The second pipe line 4A and the fourth pipe line 4B are connected in parallel to the second pipe line 4.

As shown in FIGS. 3 to 6, the first conduit 3A has a first bent portion 31, a second bent portion 32, a first portion 33, a second portion 34, and a third portion 35. . The entire first bent portion 31, second bent portion 32, second portion 34, and third portion 35, as well as a portion including one end of the first portion 33, are arranged in the second region R2. The other part including the other end of the first portion 33 is arranged in the first region R1. The remainder of the first portion 33 is arranged in line with the second heat exchanger 2B in a direction intersecting the first direction A. As shown in FIGS. 3 and 4, the remaining portion of the first portion 33 is located outside the fins of the second heat exchanger 2B and is not connected to the fins. The first portion 33 is arranged above the fins of the second heat exchanger 2B, for example.

One end of the first bent portion 31 is connected to the one end of the first portion 33 . The other end of the first bent portion 31 is connected to one end of the second portion 34 . One end of the second bent portion 32 is connected to the other end of the second portion 34 . The other end of the second bent portion 32 is connected to one end of the third portion 35 . The other end of the third portion 35 is connected to the first port 13A. In the first pipe line 3A, the first bent part 31 is located closer to the first pipe 3 than the second bent part 32. The second bent portion 32 is located closer to the first port 13A than the first bent portion 31. The center of curvature of the first bent portion 31 is located on the second heat exchanger 2B side with respect to the first bent portion 31. The center of curvature of the second bent portion 32 is located on the first heat exchanger 2A side with respect to the second bent portion 32. The radius of curvature of the first bent portion 31 is, for example, equal to the radius of curvature of the second bent portion 32.

As shown in FIGS. 3 to 6, the first bent portion 31, the second bent portion 32, the first portion 33, the second portion 34, and the third portion 35 have an S-shape in the second region R2. have. The first bent portion 31 is arranged in line with the second bent portion 32 in a direction intersecting the first direction A. A portion of the first bent portion 31 is arranged to overlap a portion of the second bent portion 32 in a direction intersecting the first direction A. Specifically, the portion of the first bent portion 31 that is connected to the second portion 34 is connected to the second portion 34 of the second bent portion 32 in a direction intersecting the first direction A. It is placed so that it overlaps with the other parts. On the other hand, the portion of the first bent portion 31 that is connected to the first portion 33 is connected to the portion of the second bent portion 32 that is connected to the third portion 35 in the direction intersecting the first direction A. They are not arranged so that they overlap. In the indoor unit 1 shown in FIG. 5, a portion of the first bent portion 31 is arranged to overlap a portion of the second bent portion 32 in the horizontal direction intersecting the first direction A.

As shown in FIG. 6, the first conduit 3A further includes, for example, a third bent portion 36 and a fourth portion 37. The other end of the first portion 33 is connected to one end of the third bent portion 36 . The other end of the third bent portion 36 is connected to one end of the fourth portion 37. The other end of the fourth portion 37 is connected to the other end of the first pipe 3 on the side opposite to the first inlet and outlet via the branch portion 3C. In this case, the fourth portion 37, the third bent portion 36, the first portion 33, the first bent portion 31, the second portion 34, the second bent portion 32, and the third portion 35 are 1 are connected in series in the above described order toward the heat exchanger 2A side.

Each pipe diameter (inner diameter) of the first bent part 31, second bent part 32, first part 33, second part 34, and third part 35 of the first pipe line 3A is, for example, 3.5 mm or more and 6.5 mm. It is as follows. The pipe diameters of the first bent portion 31, the second bent portion 32, the first portion 33, the second portion 34, and the third portion 35 are, for example, constant. Each outer diameter of the first bent portion 31, second bent portion 32, first portion 33, second portion 34, and third portion 35 of the first pipe line 3A is less than the outer diameter of the connect pipe 27.

As shown in FIGS. 5 and 6, the sum of the lengths (pipe length) of the first bent portion 31, the second portion 34, and the second bent portion 32 of the first pipe line 3A is, for example, It is shorter than each maximum width of the exchanger 2A and the second heat exchanger 2B in the direction intersecting the first direction A.

As shown in FIGS. 3 to 6, the second conduit 4A has a first bent portion 41, a second bent portion 42, a first portion 43, a second portion 44, and a third portion 45. . The entirety of the first bent portion 41, the second bent portion 42, the second portion 44, and the third portion 45, as well as a portion including one end of the first portion 43, are arranged in the second region R2. The other part including the other end of the first portion 43 is arranged in the first region R1. The remainder of the first portion 43 is arranged in line with the second heat exchanger 2B in the direction intersecting the first direction A. As shown in FIGS. 3 and 4, the remaining portion of the first portion 43 is located outside the fins of the second heat exchanger 2B and is not connected to the fins.

One end of the first bent portion 41 is connected to the one end of the first portion 43 . The other end of the first bent portion 41 is connected to one end of the second portion 44 . One end of the second bent portion 42 is connected to the other end of the second portion 44 . The other end of the second bent portion 42 is connected to one end of the third portion 45 . The other end of the third portion 45 is connected to the second port 14A. In the second pipe line 4A, the first bent part 41 is located closer to the second pipe 4 than the second bent part 42. The second bent portion 42 is located closer to the second port 14A than the first bent portion 41. The center of curvature of the first bent portion 41 is located on the second heat exchanger 2B side with respect to the first bent portion 41. The center of curvature of the second bent portion 42 is located on the first heat exchanger 2A side with respect to the second bent portion 42. The radius of curvature of the first bent portion 41 is, for example, equal to the radius of curvature of the second bent portion 42.

As shown in FIGS. 3 to 6, the first bent portion 41, the second bent portion 42, the first portion 43, the second portion 44, and the third portion 45 have an S-shape in the second region R2. have. The first bent portion 41 is arranged in line with the second bent portion 42 in a direction intersecting the first direction A. A portion of the first bent portion 41 is arranged to overlap a portion of the second bent portion 42 in a direction intersecting the first direction A. Specifically, the portion of the first bent portion 41 that is connected to the second portion 44 is connected to the second portion 44 of the second bent portion 42 in a direction intersecting the first direction A. It is placed so that it overlaps with the other parts. On the other hand, the portion of the first bent portion 41 that is connected to the first portion 43 is connected to the portion of the second bent portion 42 that is connected to the third portion 45 in the direction intersecting the first direction A. They are not arranged so that they overlap. In the indoor unit 1 shown in FIG. 5, a portion of the first bent portion 41 is arranged to overlap with a portion of the second bent portion 42 in a direction intersecting the first direction A.

In the second region R2, at least a portion of the second conduit 4A is arranged in line with at least a portion of the first conduit 3A in a direction intersecting the first direction A. In the second region R2, at least a portion of the second conduit 4A is arranged to overlap with at least a portion of the first conduit 3A, for example, in a direction intersecting the first direction A. At least a portion of the first bent portion 41 is arranged to overlap with at least a portion of the first bent portion 31, for example, in a direction intersecting the first direction A. At least a portion of the second bent portion 42 is arranged to overlap with at least a portion of the second bent portion 32, for example in a direction intersecting the first direction A. In the indoor unit 1 shown in FIG. 5, at least a portion of the first bent portion 31 is arranged to overlap at least a portion of the first bent portion 41 in the vertical direction intersecting the first direction A. In the vertical direction intersecting the first direction A, at least a portion of the second bent portion 32 is arranged to overlap at least a portion of the second bent portion 42.

As shown in FIG. 6, the second conduit 4A further includes, for example, a third bent portion 46 and a fourth portion 47. The other end of the first portion 43 is connected to one end of the third bent portion 46 . The other end of the third bent portion 46 is connected to one end of the fourth portion 47 . The other end of the fourth portion 47 is connected to the other end of the second pipe 4 on the side opposite to the second inlet and outlet via the branch portion 4C.

Each pipe diameter of the first bent portion 41, second bent portion 42, first portion 43, second portion 44, and third portion 45 of the second pipe line 4A is, for example, 3.5 mm or more and 6.5 mm or less. . The pipe diameters of the first bent portion 41, the second bent portion 42, the first portion 43, the second portion 44, and the third portion 45 are, for example, constant. Each pipe diameter of the first bent portion 41, second bent portion 42, first portion 43, second portion 44, and third portion 45 of the second conduit 4A is, for example, the first bent portion of the first conduit 3A. 31, the diameters of the second bent portion 32, the first portion 33, the second portion 34, and the third portion 35 are equal to each other.

Each outer diameter of the first bent portion 41 , second bent portion 42 , first portion 43 , second portion 44 , and third portion 45 of the second pipe line 4A is less than the outer diameter of the connect pipe 27 . Each outer diameter of the first bent portion 31, second bent portion 32, first portion 33, second portion 34, and third portion 35 of the first conduit 3A, and the first bent portion 31 of the first conduit 3A , the sum of the outer diameters of the second bent portion 32, the first portion 33, the second portion 34, and the third portion 35 is less than the outer diameter of the connect pipe 27.

As shown in FIGS. 4 and 6, the sum of the lengths (pipe length) of the first bent portion 41, the second portion 44, and the second bent portion 42 of the second pipe line 4A is, for example, It is shorter than each maximum width of the exchanger 2A and the second heat exchanger 2B in the direction intersecting the first direction A.

As shown in FIGS. 3, 4, and 6, the entire third conduit 3B is arranged in the first region R1. The third conduit 3B includes, for example, a fourth bent portion 38, an eighth portion 39, and a ninth portion 40.

One end of the eighth portion 39 is connected to the third port 13B of the second heat exchanger 2B. The other end of the eighth portion 39 is connected to one end of the fourth bent portion 38 . The other end of the fourth bent portion 38 is connected to one end of the ninth portion 40 . The other end of the ninth portion 40 is connected to the other end of the first pipe 3 on the side opposite to the first inlet and outlet via the branch portion 3C. The ninth portion 40, the fourth bent portion 38, and the eighth portion 39 are connected in series in the above described order from the first pipe 3 side toward the second heat exchanger 2B side.

Each pipe diameter of the fourth bent portion 38, the eighth portion 39, and the ninth portion 40 of the third pipe line 3B is, for example, 3.5 mm or more and 6.5 mm or less. The diameters of the fourth bent portion 38, the eighth portion 39, and the ninth portion 40 are, for example, constant. Each outer diameter of the fourth bent portion 38, the eighth portion 39, and the ninth portion 40 of the third pipe line 3B is less than the outer diameter of the connect pipe 27.

As shown in FIGS. 3, 4, and 6, the entire fourth conduit 4B is arranged in the first region R1. The fourth conduit 4B includes, for example, a fourth bent portion 48, an eighth portion 49, and a ninth portion 50.

One end of the eighth portion 49 is connected to the fourth port 14B of the second heat exchanger 2B. The other end of the eighth portion 49 is connected to one end of the fourth bent portion 48 . The other end of the fourth bent portion 48 is connected to one end of the ninth portion 50. The other end of the ninth portion 50 is connected to the other end of the second pipe 4 on the side opposite to the second inlet and outlet via the branch portion 4C. The ninth portion 50, the fourth bent portion 48, and the eighth portion 49 are connected in series in the above described order from the second pipe 4 side toward the second heat exchanger 2B side.

At least a portion of the fourth duct 4B is arranged in line with at least a portion of the third duct 3B in a direction intersecting the first direction A. At least a portion of the fourth duct 4B is arranged to overlap with at least a portion of the third duct 3B in the direction intersecting the first direction A.

Each pipe diameter of the fourth bent portion 48, the eighth portion 49, and the ninth portion 50 of the fourth pipe line 4B is, for example, 3.5 mm or more and 6.5 mm or less. The diameters of the fourth bent portion 48, the eighth portion 49, and the ninth portion 50 are, for example, constant. Each outer diameter of the fourth bent portion 48, the eighth portion 49, and the ninth portion 50 of the fourth pipe line 4B is less than the outer diameter of the connect pipe 27.

Each outer diameter of the first pipe 3 and the second pipe 4 is less than the outer diameter of the connect pipe 27. The sum of the outer diameters of the first pipe 3 and the second pipe 4 is less than or equal to the outer diameter of the connect pipe 27, for example, less than the outer diameter of the connect pipe 27.

<Effect>
The indoor unit 1 includes a first inflow port and a second outflow port through which refrigerant flows in or out, a first heat exchanger 2A connected between the first outflow port and the second outflow port, and a first heat exchanger 2A connected between the first outflow port and the second outflow port. A second heat exchanger 2B is provided which is connected in parallel to the first heat exchanger 2A to the inlet and the second inlet and outlet. The first heat exchanger 2A and the second heat exchanger 2B are provided so that the refrigerant flowing in the first direction A and the gas flowing in the direction intersecting the first direction A exchange heat. The first inflow port, the second outflow port, and the first heat exchanger 2A are arranged so as to sandwich the second heat exchanger 2B in the first direction A.

The indoor unit 1 includes a first pipe line 3A that connects the first inlet and the first heat exchanger 2A, a second pipe line 4A that connects the second inlet and the first heat exchanger 2A, and a second pipe line 4A that connects the second inlet and the first heat exchanger 2A. It further includes a third pipe line 3B that connects the first inlet and the second heat exchanger 2B, and a fourth pipe line 4B that connects the second outlet and the second heat exchanger 2B. Each of the third pipe line 3B and the fourth pipe line 4B is arranged in a first region R1 located on the opposite side of the first heat exchanger 2A with respect to the second heat exchanger 2B in the first direction A. There is.

When the indoor unit described in Patent Document 1 is used as an indoor unit of a household air conditioner, the first inlet and the second inlet are connected to the first heat exchanger and the second heat exchanger. At least four conduits need to be arranged not only in the first region but also in the second region. Therefore, a space is required for arranging the at least four pipes both in the second region and around the second heat exchanger located between the second region and the first region.

On the other hand, in the indoor unit 1, since the third conduit 3B and the fourth conduit 4B are arranged in the first region R1, the second conduit 3B and the fourth conduit 4B are arranged in the second region R2 and in the direction intersecting the first direction A. There is no need for space for the third pipe line 3B and the fourth pipe line 4B to be arranged in the area adjacent to the heat exchanger 2B.

If the unnecessary space is removed from the indoor unit 1 as described above, the indoor unit 1 can be downsized without reducing its performance. On the other hand, if the first heat exchanger 2A and the second heat exchanger 2B are increased in size by the amount of space that is deemed unnecessary as described above, the increase in size of the indoor unit 1 can be suppressed, and the size of the indoor unit 1 can be reduced. performance improvement is realized. That is, even when the indoor unit 1 is used as an indoor unit of a domestic air conditioner, the increase in size is suppressed and the deterioration in performance is suppressed compared to the above-mentioned outdoor unit.

In the indoor unit 1, each of the first pipe line 3A and the second pipe line 4A is arranged in a second region R2 located between the first heat exchanger 2A and the second heat exchanger 2B in the first direction A. It includes a first bent part 31 and a second bent part 32 which are bent, and a first part 33 arranged in line with the second heat exchanger 2B in the direction intersecting the first direction A. At least a portion of the first bent portion 31 of the first conduit 3A is arranged to overlap with at least a portion of the second bent portion 32 of the first conduit 3A in a direction intersecting the first direction A. . The width in the first direction A of the second region R2 required for arranging the first pipe line 3A is as follows: The width in the first direction A of the second region R2 is narrower than the width in the first direction A required for arranging the first conduit 3A, which is arranged so as not to overlap with the second region R2. As a result, even when the indoor unit 1 is used as an indoor unit of a household air conditioner, it is possible to achieve further miniaturization compared to the outdoor unit.

In the indoor unit 1, the first bent portions 31, 41 and the second bent portions 32, 42 are arranged in the second region R2. The centers of curvature of the first bent portions 31 and 41 are located on the second heat exchanger 2B side with respect to the first bent portions 31 and 41. The centers of curvature of the second bent portions 32, 42 are located on the first heat exchanger 2A side with respect to the second bent portions 32, 42. Even in this case, even when the indoor unit 1 is used as an indoor unit of a home air conditioner, the increase in size is suppressed and the deterioration in performance is suppressed compared to the above-mentioned outdoor unit.

Embodiment 2.
As shown in FIG. 7, the indoor unit 1 according to the second embodiment basically has the same configuration as the indoor unit 1 according to the first embodiment, but the first bent portions 31, 41 and the second bent portion The indoor unit 1 differs from the indoor unit 1 according to the first embodiment in that the sections 32 and 42 are arranged in the third region R3.

The first port 13A and the second port 14A of the first heat exchanger 2A are provided on the other side of the first heat exchanger 2A in the first direction A (on the left side of the paper in FIG. 7). That is, the first port 13A and the second port 14A are provided at one end of the first heat exchanger 2A facing the first pipe 3 and the second pipe 4 in the first direction A. The first port 13A and the second port 14A face the third region R3.

The third port 13B and the fourth port 14B are provided on one side of the second heat exchanger 2B in the first direction A (on the right side of the paper in each figure). That is, the third port 13B and the fourth port 14B are provided at one end of the second heat exchanger 2B facing the first pipe 3 and the second pipe 4 in the first direction A. The third port 13B and the fourth port 14B face the first region R1.

As shown in FIG. 7, the first conduit 3A has a first bent portion 31, a second bent portion 32, a first portion 33, a second portion 34, and a third portion 35. The entire first bent portion 31, second bent portion 32, second portion 34, and third portion 35, as well as a portion including one end of the first portion 33, are arranged in the third region R3. The other part including the other end of the first portion 33 is arranged in the first region R1. The remainder of the first portion 33 includes a portion disposed in line with the second heat exchanger 2B in the direction intersecting the first direction A, a portion disposed in the second region R2, and a portion disposed in the direction intersecting the first direction A. It has a portion arranged in line with the first heat exchanger 2A in the intersecting direction. Of the remaining portion of the first portion 33, the portion disposed alongside the second heat exchanger 2B in the direction intersecting the first direction A is disposed outside the fins of the second heat exchanger 2B. and is not connected to the fin. Similarly, of the remaining portion of the first portion 33, the portion disposed side by side with the first heat exchanger 2A in the direction intersecting the first direction A is located outside the fins of the first heat exchanger 2A. fins and not connected to the fins.

As shown in FIG. 7, the second conduit 4A has a first bent portion 41, a second bent portion 42, a first portion 43, a second portion 44, and a third portion 45. The entire first bent portion 41, second bent portion 42, second portion 44, and third portion 45, as well as a portion including one end of the first portion 43, are arranged in the third region R3. The other part including the other end of the first portion 43 is arranged in the first region R1. The remainder of the first portion 43 includes a portion disposed in parallel with the second heat exchanger 2B in the direction intersecting the first direction A, a portion disposed in the second region R2, and a portion disposed in the direction intersecting the first direction A. It has a portion arranged in line with the first heat exchanger 2A in the intersecting direction. Of the remaining portion of the first portion 43, the portion disposed alongside the second heat exchanger 2B in the direction intersecting the first direction A is disposed outside the fins of the second heat exchanger 2B. and is not connected to the fin. Similarly, of the remaining portion of the first portion 43, the portion arranged in line with the first heat exchanger 2A in the direction intersecting the first direction A is located outside the fins of the first heat exchanger 2A. fins and not connected to the fins.

Each center of curvature of the first bent portions 31, 41 is arranged on the first heat exchanger 2A side with respect to the first bent portions 31, 41. The centers of curvature of the second bent portions 32, 42 are located on the first heat exchanger 2A side with respect to the second bent portions 32, 42.

The first bent portion 31, the second bent portion 32, the first portion 33, the second portion 34, and the third portion 35 have a C-shape in the third region R3. The first bent portion 41, the second bent portion 42, the first portion 43, the second portion 44, and the third portion 45 have a C-shape in the third region R3. The first bent portion 31 is arranged to overlap with the second bent portion 32 in a direction intersecting the first direction A. The portion of the first bent portion 31 that is connected to the first portion 33 overlaps the portion of the second bent portion 32 that is connected to the third portion 35 in the direction intersecting the first direction A. It is located. The first bent portion 41 is arranged to overlap with the second bent portion 42 in a direction intersecting the first direction A. The portion of the first bent portion 41 that is connected to the first portion 43 overlaps the portion of the second bent portion 42 that is connected to the third portion 45 in the direction intersecting the first direction A. It is located.

The first bent portion 31 and the second bent portion 32 are provided symmetrically with respect to the second portion 34, for example. The first bent portion 41 and the second bent portion 42 are provided symmetrically with respect to the second portion 44, for example.

Each panel member PA of the first heat exchanger 2A and the second heat exchanger 2B has an insertion hole for inserting, for example, the first portion 33 of the first pipe line 3A and the first portion 43 of the second pipe line 4A. A hole is provided. Thereby, the first portion 33 of the first conduit 3A and the first portion 43 of the second conduit 4A are positioned with respect to the first heat exchanger 2A and the second heat exchanger 2B.

Since the indoor unit 1 according to the second embodiment has basically the same configuration as the indoor unit 1 according to the first embodiment, it can achieve the same effects as the indoor unit 1 according to the first embodiment. can.

Furthermore, in the indoor unit 1 according to the second embodiment, the centers of curvature of the first bent portions 31, 41 and the second bent portions 32, 42 are on the side of the first heat exchanger 2A with respect to the second bent portions 32, 42. Therefore, each of the first conduit 3A and the second conduit 4A has a C-shape in the third region R3. Therefore, in the indoor unit 1 according to the second embodiment, the part of the first bent part 31 that is connected to the first part 33 is the part of the second bent part 32 that is connected to the first part 33 in the direction intersecting the first direction A. It is arranged so as to overlap the part connected to the third part 35.

For example, if the distance between the outer circumferential surface located on the curvature center side of each of the first bent part 31 and the second bent part 32 and the center of curvature is the radius of curvature, then the first bent part 31 and the second bent part 32 of the first embodiment The distance L1 (see FIG. 6) in the first direction A between the connecting portion with the first portion 33 and the connecting portion between the second bent portion 32 and the third portion 35 is determined by the outer diameter of the second portion 34, the first It is equal to the sum of the radius of curvature of the bent portion 31 and the radius of curvature of the second bent portion 32. On the other hand, in the second embodiment, the distance L2 ( (see FIG. 7) is equal to the sum of the outer diameter of the second portion 34 and the larger value of the radius of curvature of the first bent portion 31 and the radius of curvature of the second bent portion 32. Therefore, the distance L2 in the second embodiment is shorter than the distance L1 in the first embodiment.

As a result, the space for arranging the first conduit 3A and the second conduit 4A in the third region R3 of the indoor unit 1 according to the second embodiment is the same as that in the second region R3 of the indoor unit 1 according to the first embodiment. The space is reduced compared to the space for arranging the first pipe line 3A and the second pipe line 4A in R2.

Note that also in the indoor unit 1 according to the second embodiment, the first port 13A may be arranged to overlap with the third port 13B in the first direction A. Similarly, the second port 14A may be arranged to overlap in the first direction A with the fourth port 14B.

Embodiment 3.
As shown in FIG. 8, the indoor unit 1 according to the third embodiment has basically the same configuration as the indoor unit 1 according to the second embodiment, but the length L _A of the first pipe line 3A, The pipe diameter D _A of the first pipe line 3A, the length L _B of the third pipe line 3B, and the pipe diameter D _B of the third pipe line 3B simultaneously satisfy the following relational expressions (1) and (2). It is different from the indoor unit 1 according to the second embodiment in that it satisfies the requirements.

The above relational expressions (1) and relational expressions (2) are based on the relationship between the length of the first pipe line 3A and the third pipe line 3B during cooling operation in which liquid phase refrigerant flows in the first pipe line 3A and the third pipe line 3B. It was designed to reduce the pressure loss difference caused by the difference in length.

First, relational expression (1) will be explained. Relational expression (3) between the pressure loss ΔP _A of the gas-liquid two-phase refrigerant flowing through the first pipe line 3A during cooling operation, the pipe diameter D _A of the first pipe line 3A, and the length L _A of the first pipe line 3A is expressed as ΔP _A =A×L _A /D _A ⁿ . Similarly, the relational expression between the pressure loss ΔP _B of the gas-liquid two-phase refrigerant flowing through the third pipe line 3B during cooling operation, the pipe diameter D _B of the third pipe line 3B, and the length L _B of the third pipe line 3B (4) is expressed as ΔP _B =A×L _B /D _B ⁿ . Note that A is a value determined from each density, each viscosity, each refrigerant circulation amount, etc. of a gas phase refrigerant and a liquid phase refrigerant when the specific refrigerant is at a specific pressure and temperature.

The pressure loss ΔP _A of the gas-liquid two-phase refrigerant flowing into the first heat exchanger 2A via the first pipe line 3A is If it is set equal to the pressure loss ΔP _B , the flow rate of the gas-liquid two-phase refrigerant flowing into the first heat exchanger 2A becomes equal to the flow rate of the gas-liquid two-phase refrigerant flowing into the second heat exchanger 2B. In this case, each heat exchange performance of the first heat exchanger 2A and the second heat exchanger 2B during cooling operation becomes equal to each other.

In this way, the above relational expression (1) is determined from the above relational expressions (3) and (4) by adjusting the pipe diameter D _A of the first pipe line 3A and the first pipe diameter D so that ΔP _A and ΔP _B are equal. This figure was derived to show the relationship among the length L _A of the line 3A, the pipe diameter D _B of the third pipe line 3B, and the length L _B of the third pipe line 3B.

Next, relational expression (2) will be explained. Relational expression (2) specifies the numerical range of n in relational expression (1). Although n in relational expression (1) may be a constant, the value of n may vary depending on the size of the pipe diameter. Therefore, the optimal n value that can make the pressure loss difference zero within the range where the pipe diameter is 3.5 mm or more and 6.5 mm or less, and the The optimal n value that can make the pressure loss difference zero was derived by the following fitting.

FIG. 9 is a graph showing the relationship between the pipe diameter (inner diameter) of the refrigerant pipe through which the gas-liquid two-phase refrigerant flows and the pressure loss gradient per unit length. The horizontal axis in FIG. 9 indicates the pipe diameter (unit: mm) of the refrigerant pipe through which the gas-liquid two-phase refrigerant flows, and the vertical axis in FIG. The pressure loss gradient ΔP/ΔL (unit: kPa/m) is shown.

The plurality of circular plots shown in FIG. 9 indicate the relationship between the pipe diameter D and the pressure loss gradient ΔP/ΔL per unit length, which is calculated from the above relational expression (3) or the above relational expression (4). .

The solid line shown in FIG. 9 is the formula ΔP obtained by fitting the above-mentioned plurality of plots in which the pipe diameter D is 3.5 mm or more and 6.5 mm or less using the formula ΔP/ΔL=B/D ⁿ . /ΔL=B/D ^4.9 . B is a value determined from each density, each viscosity, each refrigerant circulation amount, etc. of a gas phase refrigerant and a liquid phase refrigerant when the specific refrigerant is at a specific pressure and temperature. Since the pipe diameter of the heat transfer tube of the indoor unit of a general household air purifier is 3.5 mm or more and 6.5 mm or less, this formula is The pressure loss gradient is shown when the pipe diameter is equal to the heat transfer tube diameter of the indoor unit of a typical household air purifier.

The dotted line shown in FIG. 9 is the formula ΔP obtained by fitting the above-mentioned plurality of plots in which the pipe diameter D is 9.5 mm or more and 13.0 mm or less using the formula ΔP/ΔL=C/D ⁿ . /ΔL=C/D ^5.1 is shown. C is a value determined from each density, each viscosity, each refrigerant circulation amount, etc. of a gas phase refrigerant and a liquid phase refrigerant when the particular refrigerant is at a particular pressure and temperature. Since the pipe diameter of the extension pipe of a general household air purifier is 9.5 mm or more and 13.0 mm or less, the above formula is based on the general pipe diameter of the first pipe line 3A and the third pipe line 3B. Shows the pressure loss gradient when the pipe diameter is equal to the extension pipe diameter of a household air purifier.

The length L _A of the first pipe line 3A, the pipe diameter D _A of the first pipe line 3A, the length L _B of the third pipe line 3B, and the pipe diameter D _B of the third pipe line 3B are as described above. By setting the derived relational expressions (1) and (2) to be satisfied at the same time, the flow rate of the gas-liquid two-phase refrigerant flowing into the first heat exchanger 2A is equal to the flow rate of the gas flowing into the second heat exchanger 2B. It becomes equal to the flow rate of the liquid two-phase refrigerant, and each heat exchange performance of the first heat exchanger 2A and the second heat exchanger 2B becomes equal to each other.

For example, if the length L _A of the first pipe line 3A is 0.8 m, the length L _B of the third pipe line 3B is 0.03 m, and the pipe diameter D _B of the third pipe line 3B is 5 mm, the above relational expression ( The pipe diameter D _A of the first pipe line 3A that satisfies (1) and (2) is 9.65 mm. In other words, the length L _A of the first pipe line 3A is 0.8 m, the pipe diameter D _A of the first pipe line 3A is 9.65 mm, the length L B of the third pipe line 3B is 0.03 m, and the length L _B of the third pipe line 3A is 0.03 m. When the pipe diameter D _B of the passage 3B is 5 mm, the heat exchange performances of the first heat exchanger 2A and the second heat exchanger 2B during cooling operation are equal to each other.

That is, in the indoor unit 1 according to the third embodiment, compared to the indoor unit 1 according to the second embodiment, the gas-liquid two-phase gas is supplied to each of the first heat exchanger 2A and the second heat exchanger 2B during cooling operation. Since variations in the amount of refrigerant flowing in are suppressed, deterioration in heat exchange performance is suppressed even when the air volumes of the first blower 5A and the second blower 5B are equal to each other.

Note that the indoor unit 1 according to the third embodiment has a length L _A of the first pipe line 3A, a pipe diameter D _A of the first pipe line 3A, a length L _B of the third pipe line 3B, and a third pipe line 3A. The indoor unit 1 may have the same configuration as the indoor unit 1 according to the first embodiment, except that the pipe diameter D _B of the channel 3B satisfies the following relational expressions (1) and (2) at the same time.

Although the embodiments of the present invention have been described above, the embodiments described above can be modified in various ways. Further, the scope of the present invention is not limited to the above-described embodiments. The scope of the present invention is indicated by the scope of the claims, and is intended to include meanings equivalent to the scope of the claims and all changes within the scope.

1 Indoor unit, 2A first heat exchanger, 2B second heat exchanger, 3 first pipe, 3A first pipe, 3B third pipe, 3C, 4C branch, 4 second pipe, 4A second pipe channel, 4B fourth pipe, 5A first blower, 5B second blower, 7A first connection, 7B second connection, 13A first port, 13B third port, 14A second port, 14B fourth port, 20 outdoor unit, 21 compressor, 22 outdoor heat exchanger, 23 pressure reducing device, 24 four-way valve, 25, 26 extension pipe, 27, 28 connect pipe, 31, 32, 36, 38, 41, 42, 46, 48 bending Part, 33, 43 First part, 34, 44 Second part, 35, 45 Third part, 37, 47 Fourth part, 39, 49 Eighth part, 40, 50 Ninth part, 100 Air conditioner.

Claims (5)

An indoor unit,
a first pipe and a second pipe through which a refrigerant flows into or out of the indoor unit;
A first heat exchanger that is connected in parallel to each other between the first pipe and the second pipe, and in which a refrigerant flowing in a first direction and a gas flowing in a direction crossing the first direction exchange heat. and a second heat exchanger;
a first pipe line connecting the first pipe and the first heat exchanger;
a second pipe line connecting the second pipe and the first heat exchanger;
a third pipe line connecting the first pipe and the second heat exchanger;
a fourth pipe line connecting the second pipe and the second heat exchanger,
The first piping, the second piping, and the first heat exchanger are arranged so as to sandwich the second heat exchanger in the first direction,
Each of the third pipe line and the fourth pipe line is provided with the first pipe line and the second pipe line, and is arranged so that the first heat exchanger is connected to the second heat exchanger in the first direction. It is located in the first area located on the opposite side of the
Each of the first conduit and the second conduit has a first bend disposed in a second region located between the first heat exchanger and the second heat exchanger in the first direction. and a second bent part,
In the first conduit, the first bent portion is disposed on one side of the second bent portion in a direction intersecting the first direction,
In the second conduit, the first bent portion is disposed on the one side in a direction intersecting the first direction with respect to the second bent portion ,
The center of curvature of the first bent portion is located on the second heat exchanger side with respect to the first bent portion,
In the indoor unit, the center of curvature of the second bent portion is located on the first heat exchanger side with respect to the second bent portion. At least a portion of the first bent portion of the first conduit is arranged to overlap with at least a portion of the second bent portion of the first conduit in a direction intersecting the first direction. , The indoor unit according to claim 1. The length LA of the first pipe line, the pipe diameter DA of the first pipe line, the length LB of the third pipe line, and the pipe diameter DB of the third pipe line are expressed by the following relational expression (1) and The indoor unit according to claim 1 or 2, which satisfies (2) at the same time.

a first blower that sends the gas to the first heat exchanger;
further comprising a second blower that sends the gas to the second heat exchanger,
The indoor unit according to any one of claims 1 to 3, wherein the air volume of the first fan is controlled independently of the air volume of the second fan. The indoor unit according to any one of claims 1 to 4,
An air conditioner comprising an outdoor unit connected to the indoor unit and including a compressor, a pressure reducing device, and an outdoor heat exchanger.

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