JP2021063624A - Switching unit - Google Patents

Abstract

To insulate heat of refrigerant pipes properly.SOLUTION: A switching unit 1 includes refrigerant pipes 30, a first on-off valve 31, a second on-off valve 32, a third on-off valve 33, a fourth on-off valve 34, a case 41, sheet-like heat insulation materials, and foam heat insulation materials. In the refrigerant pipes 30, a refrigerant circulating through outdoor units 3-1 to 3-2 and indoor units 5-1 to 5-4 flows. The first on-off valve 31, the second on-off valve 32, the third on-off valve 33, and the fourth on-off valve 34 open or close the refrigerant pipes 30. The case 41 is formed with a pipe storage space 75 in which the refrigerant pipes 30 are disposed. The sheet-like heat insulation materials are bonded to a part of an inner surface, which faces the pipe storage space 75, of the case 41. The foam heat insulation materials fill the pipe storage space 75.SELECTED DRAWING: Figure 12

Description

The present invention relates to a switching unit.

A switching unit provided in a multi-chamber air conditioner including a plurality of indoor units is known. The switching unit is provided with a plurality of refrigerant pipes and a plurality of on-off valves that form a part of the refrigerant circuit of the multi-chamber air conditioner, and by controlling the plurality of on-off valves, cooling operation and heating are performed for each indoor unit. Cooling / heating free operation that switches between operation can be performed.

Japanese Unexamined Patent Publication No. 2014-163657

The switching unit is further provided with an effervescent heat insulating material that insulates a plurality of refrigerant pipes from the outside air. The foamed heat insulating material is filled in the pipe storage space by expanding the foamed heat insulating material stock solution injected into the pipe storage space in which a plurality of refrigerant pipes are arranged and expanding in the pipe storage space. As the foamed heat insulating material expands and hardens, a gap may be formed in the pipe storage space where the foamed heat insulating material is not filled. When such a gap is formed, the switching unit may have difficulty in ensuring heat insulation of a plurality of refrigerant pipes.

The disclosed technique has been made in view of this point, and an object of the present invention is to provide a switching unit that appropriately insulates a plurality of refrigerant pipes.

The switching unit according to one aspect of the present disclosure is a case in which a plurality of refrigerant pipes through which refrigerant flows, a plurality of on-off valves for opening and closing the plurality of refrigerant pipes, and a storage space in which the plurality of refrigerant pipes are arranged are formed. A heat insulating material attached to a part of the inner surface of the case, and a foamed heat insulating material filled in the storage space.

The disclosed switching unit can adequately insulate a plurality of refrigerant pipes.

FIG. 1 is a schematic view showing a multi-chamber air conditioner provided with the switching unit of the first embodiment. FIG. 2 is a refrigerant circuit diagram showing the switching unit of the first embodiment. FIG. 3 is a perspective view showing the switching unit of the first embodiment. FIG. 4 is a lower perspective view showing the switching unit of the first embodiment. FIG. 5 is a perspective view showing the inside of the case. FIG. 6 is a lower perspective view showing a switching unit from which the lower part of the outer body has been removed. FIG. 7 is a lower perspective view showing the upper part of the outer body, the right partition plate, and the left partition plate. FIG. 8 is a perspective view showing a solenoid valve partition plate. FIG. 9 is a perspective view showing the electric box fixture. FIG. 10 is a side view showing a pipe group. FIG. 11 is a top view showing the switching unit of the first embodiment. FIG. 12 is a cross-sectional view showing the switching unit of the first embodiment.

Hereinafter, the switching unit according to the embodiment disclosed in the present application will be described with reference to the drawings. The following description does not limit the technique of the present disclosure. Further, in the following description, the same components are given the same reference numerals, and duplicate description will be omitted.

As shown in FIG. 1, the switching unit 1 of the first embodiment is provided in the multi-chamber air conditioner 2. FIG. 1 is a schematic view showing a multi-chamber air conditioner 2 provided with the switching unit 1 of the first embodiment. The multi-chamber air conditioner 2 includes a switching unit 1, a plurality of outdoor units 3-1 to 2-3, a plurality of indoor units 5-1 to 5-4, a low pressure gas pipe 6, a high pressure gas pipe 7, and a liquid pipe 8. And have. The outdoor unit 3-1 of the plurality of outdoor units 3-1 to 3-2 is connected to the switching unit 1 via the low pressure gas pipe 6, the high pressure gas pipe 7, and the liquid pipe 8.

The outdoor unit 3-1 includes a compressor (not shown), an outdoor heat exchanger, and a four-way valve. One end of the compressor is connected to the low pressure gas pipe 6, and the other end of the compressor is connected to the high pressure gas pipe 7. The compressor generates a high-pressure gas-phase refrigerant by compressing the low-pressure gas-phase refrigerant supplied to the outdoor unit 3-1 via the low-pressure gas pipe 6, and discharges the high-pressure gas-phase refrigerant into the high-pressure gas pipe 7. One end of the outdoor heat exchanger is connected to the liquid pipe 8, and the other end of the outdoor heat exchanger is connected to the four-way valve. The four-way valve is connected to the high pressure gas pipe 7 and the low pressure gas pipe 6. The four-way valve is switched between a first mode and a second mode. When the four-way valve is switched to the first mode, the high pressure gas pipe 7 is connected to the indoor heat exchanger without connecting the low pressure gas pipe 6 to the high pressure gas pipe 7 or the indoor heat exchanger. When the four-way valve is switched to the second mode, the low pressure gas pipe 6 is connected to the indoor heat exchanger without connecting the high pressure gas pipe 7 to the low pressure gas pipe 6 or the indoor heat exchanger. The outdoor unit 3-2, which is different from the outdoor unit 3-1 of the plurality of outdoor units 3-1 to 2-3, is also formed in the same manner as the outdoor unit 3-1. It is connected to the switching unit 1 via the tube 8.

The multi-chamber air conditioner 2 further includes a plurality of indoor unit liquid pipes 11-1 to 11-4 and a plurality of indoor unit side gas pipes 12-1 to 12-4. The plurality of indoor unit liquid pipes 11-1 to 11-4 correspond to a plurality of indoor units 5-1 to 5-4. The indoor unit 5-1 of the plurality of indoor units 5-1 to 5-4 is the indoor unit liquid pipe 11 corresponding to the indoor unit 5-1 of the plurality of indoor unit liquid pipes 11-1 to 11-4. It is connected to the switching unit 1 via -1. The plurality of indoor unit side gas pipes 12-1 to 12-4 correspond to a plurality of indoor units 5-1 to 5-4. The indoor unit 5-1 is further connected to the switching unit 1 via the indoor unit side gas pipe 12-1 corresponding to the indoor unit 5-1 of the plurality of indoor unit side gas pipes 12-1 to 12-4. Has been done.

The indoor unit 5-1 includes an expansion valve (not shown) and an indoor heat exchanger. One end of the expansion valve is connected to the indoor unit liquid pipe 11-1, and the other end of the expansion valve is connected to one end of the indoor heat exchanger. The other end of the indoor heat exchanger is connected to the gas pipe 12-1 on the indoor unit side. The other indoor units among the plurality of indoor units 5-1 to 5-4 are also formed in the same manner as the indoor unit 5-1 and have one and a plurality of indoor unit liquid pipes 11-1 to 11-4. It is connected to the switching unit 1 via one of the indoor unit side gas pipes 12-1 to 12-4.

The multi-chamber air conditioner 2 may include more than 12 indoor units, and at this time, further includes another switching unit 14, a low pressure gas pipe 15, a high pressure gas pipe 16, and a liquid pipe 17. .. Like the switching unit 1, the switching unit 14 is connected to the 13th and subsequent indoor units, and is connected to the switching unit 1 via the low pressure gas pipe 15, the high pressure gas pipe 16, and the liquid pipe 17. When the multi-chamber air conditioner 2 is provided with 12 or less indoor units, it is not necessary to include the switching unit 14, and the switching unit 14, the low pressure gas pipe 15, the high pressure gas pipe 16, and the liquid pipe 17 are provided. It may be omitted.

FIG. 2 is a refrigerant circuit diagram showing the switching unit 1 of the first embodiment. The switching unit 1 includes an outdoor unit side low pressure gas pipe 21, an outdoor unit side high pressure gas pipe 22, an outdoor unit side liquid pipe 23, a plurality of pipe groups 24-1 to 24-12, and a plurality of indoor unit side gas pipes 25-1. It is provided with ~ 25-12 and a plurality of indoor unit side liquid pipes 26-1 to 26-12. The low pressure gas pipe 21 on the outdoor unit side is connected to the low pressure gas pipe 6. The outdoor unit side high pressure gas pipe 22 is connected to the high pressure gas pipe 7. The outdoor unit side liquid pipe 23 is connected to the liquid pipe 8. The plurality of indoor unit side gas pipes 25-1 to 25-12 correspond to a plurality of pipe groups 24-1 to 24-12. The plurality of indoor unit side liquid pipes 26-1 to 26-12 correspond to a plurality of pipe groups 24-1 to 24-12.

The pipe group 24-1 of the plurality of pipe groups 24-1 to 24-12 includes a plurality of refrigerant pipes 30, a plurality of on-off valves 31 to 34, and a plurality of capillary tubes 35 to 36. The plurality of on-off valves 31 to 34 and the plurality of capillary tubes 35 to 36 are connected to each other via a plurality of refrigerant pipes 30. That is, one end of the first on-off valve 31 of the plurality of on-off valves 31 to 34 is connected to the low-pressure gas pipe 21 on the outdoor unit side, and the other end of the first on-off valve 31 is connected to the plurality of gas pipes 25 on the indoor unit side. It is connected to the indoor unit side gas pipe 25-1 corresponding to the pipe group 24-1 of -1 to 25-12. One end of the second on-off valve 32 of the plurality of on-off valves 31 to 34 is connected to the outdoor unit side high-pressure gas pipe 22, and the other end of the second on-off valve 32 is connected to the indoor unit side gas pipe 25-1. Has been done. One end of the third on-off valve 33 of the plurality of on-off valves 31 to 34 is connected to the low-pressure gas pipe 21 on the outdoor unit side, and the other end of the third on-off valve 33 is connected to one end of the first capillary tube 35. ing. One end of the fourth on-off valve 34 of the plurality of on-off valves 31 to 34 is connected to the high-pressure gas pipe 22 on the outdoor unit side, and the other end of the fourth on-off valve 34 is connected to one end of the first capillary tube 35. ing. The other end of the first capillary tube 35 is connected to the gas pipe 25-1 on the indoor unit side. One end of the second capillary tube 36 is connected to one end of the first on-off valve 31, and the other end of the second capillary tube 36 is connected to the other end of the first on-off valve 31.

Of the plurality of pipe groups 24-1 to 24-12, other pipe groups different from the pipe group 24-1 are formed in the same manner as the pipe group 24-1. For example, the pipe group 24-12 of the plurality of pipe groups 24-1 to 24-12 includes a plurality of on-off valves 31 to 34 and a plurality of capillary tubes 35 to 36. The pipe group 24-12 is connected to the indoor unit side gas pipe 25-12 corresponding to the pipe group 24-12 among the plurality of indoor unit side gas pipes 25-1 to 25-12.

The plurality of indoor unit side gas pipes 25-1 to 25-12 correspond to the plurality of indoor units 5-1 to 5-4. For example, the indoor unit side gas pipe 25-1 corresponding to the indoor unit 5-1 of the plurality of indoor unit side gas pipes 25-1 to 25-12 is connected to the indoor unit side gas pipe 12-1 and is indoors. It is connected to the indoor unit 5-1 via the machine side gas pipe 12-1. The indoor unit side gas pipe 25-2 corresponding to the indoor unit 5-2 of the plurality of indoor unit side gas pipes 25-1 to 25-12 is connected to the indoor unit side gas pipe 12-2 and is connected to the indoor unit side gas pipe 12-2. It is connected to the indoor unit 5-2 via the gas pipe 12-2. The indoor unit side gas pipe 25-3 corresponding to the indoor unit 5-3 among the plurality of indoor unit side gas pipes 25-1 to 25-12 is connected to the indoor unit side gas pipe 12-3 and is connected to the indoor unit side gas pipe 12-3. It is connected to the indoor unit 5-3 via the gas pipe 12-3. The indoor unit side gas pipe 25-4 corresponding to the indoor unit 5-4 of the plurality of indoor unit side gas pipes 25-1 to 25-12 is connected to the indoor unit side gas pipe 12-4 and is connected to the indoor unit side gas pipe 12-4. It is connected to the indoor unit 5-4 via the gas pipe 12-4.

The plurality of indoor unit side liquid pipes 26-1 to 26-12 are connected to the outdoor unit side liquid pipe 23, respectively. The plurality of indoor unit side liquid pipes 26-1 to 26-12 correspond to the plurality of indoor units 5-1 to 5-4. For example, the indoor unit side liquid pipe 26-1 corresponding to the indoor unit 5-1 of the plurality of indoor unit side liquid pipes 26-1 to 26-12 is connected to the indoor unit liquid pipe 11-1 and is connected to the indoor unit. It is connected to the indoor unit 5-1 via the liquid pipe 11-1. The indoor unit side liquid pipe 26-2 corresponding to the indoor unit 5-2 of the plurality of indoor unit side liquid pipes 26-1 to 26-12 is connected to the indoor unit liquid pipe 11-2 and is connected to the indoor unit liquid pipe 11-2. It is connected to the indoor unit 5-2 via 11-2. Of the plurality of indoor unit side liquid pipes 26-1 to 26-12, the indoor unit side liquid pipe 26-3 corresponding to the indoor unit 5-3 is connected to the indoor unit liquid pipe 11-3 and is connected to the indoor unit liquid pipe 11-3. It is connected to the indoor unit 5-3 via 11-3. Of the plurality of indoor unit side liquid pipes 26-1 to 26-12, the indoor unit side liquid pipe 26-4 corresponding to the indoor unit 5-4 is connected to the indoor unit liquid pipe 11-4 and is connected to the indoor unit liquid pipe 11-4. It is connected to the indoor unit 5-4 via 11-4.

The low-pressure gas pipe 21 on the outdoor unit side of the switching unit 1 is connected to the low-pressure gas pipe 15 when the multi-chamber air conditioner 2 is provided with another switching unit, and the switching unit 14 is connected via the low-pressure gas pipe 15. It is connected to the low pressure gas pipe 21 on the outdoor unit side of the above. At this time, the outdoor unit side high pressure gas pipe 22 of the switching unit 1 is connected to the high pressure gas pipe 16 and is connected to the outdoor unit side high pressure gas pipe 22 of the switching unit 14 via the high pressure gas pipe 16. The outdoor unit side liquid pipe 23 of the switching unit 1 is connected to the liquid pipe 17, and is connected to the outdoor unit side liquid pipe 23 of the switching unit 14 via the liquid pipe 17. That is, the outdoor unit side low pressure gas pipe 21, the outdoor unit side high pressure gas pipe 22, and the outdoor unit side liquid pipe 23 of the switching unit 14 are connected to the low pressure gas pipe 6, the high pressure gas pipe 7, and the liquid pipe via the switching unit 1. It is connected to 8 respectively. Similarly to the switching unit 1, the switching unit 14 is the thirteenth unit via the plurality of indoor unit side gas pipes 25-1 to 25-12 and the plurality of indoor unit side liquid pipes 26-1 to 26-12. It is connected to the subsequent indoor unit.

FIG. 3 is a perspective view showing the switching unit 1 of the first embodiment. FIG. 4 is a lower perspective view showing the switching unit 1 of the first embodiment. The switching unit 1 is generally formed in a rectangular columnar shape having a rectangular bottom surface, and further includes a case 41 and an electrical component box 42. The case 41 includes an outer body upper 43 and an outer body lower 44. The outer body upper 43 includes a top plate 45, a front plate 46, a right side plate 47, and a left side plate 48. The outer body lower 44 includes a lower surface plate 49. The case 41 is formed so that the upper surface plate 45 and the lower surface plate 49 are respectively aligned with the two bottom surfaces of the rectangular prism of the switching unit 1. In the case 41, the front plate 46, the right side plate 47, and the left side plate 48 are further aligned with the three side surfaces of the rectangular prism of the switching unit 1, and the surface of the right side plate 47 is opposite to the surface of the left side plate 48. It is formed so as to form a side surface.

The electrical component box 42 is generally formed in a rectangular parallelepiped shape. A control circuit (not shown) is arranged inside the electrical component box 42. The control circuit controls each part provided in the multi-chamber air conditioner 2. The electrical component box 42 is arranged so as to form a side surface opposite to the side surface formed by the front plate 46 of the square pillars of the switching unit 1, and is fixed to the case 41.

As shown in FIG. 3, the top plate 45 has a right side inlet 51, a plurality of right air vent holes 52, a central inlet 53, a plurality of central air vent holes 54, a left side inlet 55, and a plurality of left air vent holes. 56 and are formed. A plurality of upper surface heat radiating holes 61 are further formed in the upper surface plate 45. The plurality of upper surface heat radiating holes 61 are formed in a region of the upper surface plate 45 on the side closer to the electrical component box 42. A plurality of right side heat dissipation holes 62 are formed in the right side plate 47. The plurality of right-side heat-dissipating holes 62 are formed in a region of the right-side plate 47 that is closer to the electrical component box 42.

Similar to the right side plate 47, the left side plate 48 of the outer body 43 is formed with a plurality of left side heat dissipation holes 63 as shown in FIG. The plurality of left side heat dissipation holes 63 are formed in a region of the left side plate 48 on the side closer to the electrical component box 42. A plurality of lower surface heat radiating holes 64 are formed in the lower surface plate 49 of the outer body lower 44. The plurality of lower surface heat radiating holes 64 are formed in a region of the lower surface plate 49 on the side closer to the electrical component box 42. The switching unit 1 is arranged so that the upper surface plate 45 and the lower surface plate 49 are arranged along the horizontal plane and the upper surface plate 45 is arranged vertically above the lower surface plate 49 at the time of use.

FIG. 5 is a perspective view showing the inside of the case 41. A plurality of piping groups 24-1 to 24-12 are arranged inside the case 41. The low pressure gas pipe 21 on the outdoor unit side is formed in a rod shape. Both ends of the outdoor unit side low pressure gas pipe 21 are arranged outside the case 41, and the center of the outdoor unit side low pressure gas pipe 21 is arranged inside the case 41. The outdoor unit side high pressure gas pipe 22 is formed in a rod shape. Both ends of the outdoor unit side high pressure gas pipe 22 are arranged outside the case 41, and the center of the outdoor unit side high pressure gas pipe 22 is arranged inside the case 41. The outdoor unit side liquid pipe 23 is formed in a rod shape. Both ends of the outdoor unit side liquid pipe 23 are arranged outside the case 41, and the center of the outdoor unit side liquid pipe 23 is arranged inside the case 41.

FIG. 6 is a lower perspective view showing the switching unit 1 from which the outer body lower 44 has been removed. The switching unit 1 further includes a solenoid valve partition plate 71, a right-side partition plate 72, and a left-side partition plate 73. The solenoid valve partition plate 71 is formed in a plate shape, is arranged so as to be along another plane parallel to the plane along which the front plate 46 is, and is fixed to the case 41. The solenoid valve partition plate 71 divides the inside of the case 41 into a coil portion storage space 74 and a pipe storage space 75. The coil portion storage space 74 is surrounded by a top plate 45, a right side plate 47, a left side plate 48, a solenoid valve partition plate 71, and an electrical component box 42. The pipe storage space 75 is surrounded by a top plate 45, a front plate 46, a right side plate 47, a left side plate 48, a bottom plate 49, and a solenoid valve partition plate 71. That is, the solenoid valve partition plate 71 separates the coil portion storage space 74 and the pipe storage space 75.

In the outdoor unit side low pressure gas pipe 21, both ends of the outdoor unit side low pressure gas pipe 21 are arranged outside the case 41 so that the center of the outdoor unit side low pressure gas pipe 21 is arranged in the pipe storage space 75. As described above, the right side plate 47 and the left side plate 48 are penetrated. In the outdoor unit side high pressure gas pipe 22, both ends of the outdoor unit side high pressure gas pipe 22 are arranged outside the case 41 so that the center of the outdoor unit side high pressure gas pipe 22 is arranged in the pipe storage space 75. As described above, the right side plate 47 and the left side plate 48 are penetrated. In the outdoor unit side liquid pipe 23, the center of the outdoor unit side liquid pipe 23 is arranged in the pipe storage space 75, and both ends of the outdoor unit side liquid pipe 23 are arranged outside the case 41. It penetrates the right side plate 47 and the left side plate 48.

FIG. 7 is a lower perspective view showing the outer body upper 43, the right partition plate 72, and the left partition plate 73. The right partition plate 72 is arranged along another plane parallel to the plane along which the right side plate 47 or the left side plate 48 is, and is fixed to the case 41. The left partition plate 73 is arranged along yet another plane parallel to the plane along which the right side plate 47 or the left side plate 48 is, and is fixed to the case 41. The right side partition plate 72 and the left side partition plate 73 divide the pipe storage space 75 into a right side pipe storage space 76, a central pipe storage space 77, and a left side pipe storage space 78. The right side pipe storage space 76 is surrounded by an upper surface plate 45, a front surface plate 46, a right side surface plate 47, a lower surface plate 49, a solenoid valve partition plate 71, and a right side partition plate 72. The central pipe storage space 77 is surrounded by an upper surface plate 45, a front surface plate 46, a lower surface plate 49, a solenoid valve partition plate 71, a right side partition plate 72, and a left side partition plate 73. The left pipe storage space 78 is surrounded by an upper surface plate 45, a front surface plate 46, a left side surface plate 48, a lower surface plate 49, a solenoid valve partition plate 71, and a left side partition plate 73. That is, the right partition plate 72 separates the right pipe storage space 76 and the central pipe storage space 77. The left partition plate 73 separates the central pipe storage space 77 and the left pipe storage space 78.

As shown in FIG. 6, four pipe groups 24-1 to 24-4 out of a plurality of pipe groups 24-1 to 24-12 are arranged in the right-hand pipe storage space 76. Each of the four indoor unit side gas pipes 25-1 to 25-4 out of the plurality of indoor unit side gas pipes 25-1 to 25-12 is arranged so that one end is arranged outside the pipe storage space 75. Moreover, it penetrates the front plate 46 so that the other end is arranged in the pipe storage space 75. Each of the four indoor unit side liquid pipes 26-1 to 26-4 out of the plurality of indoor unit side liquid pipes 26-1 to 26-12 is arranged so that one end is arranged outside the pipe storage space 75. Moreover, it penetrates the front plate 46 so that the other end is arranged in the pipe storage space 75.

In the central pipe storage space 77, four pipe groups 24-5 to 24-8 out of a plurality of pipe groups 24-1 to 24-12 are arranged. Each of the four indoor unit side gas pipes 25-5 to 25-8 out of the plurality of indoor unit side gas pipes 25-1 to 25-12 is arranged so that one end is arranged outside the pipe storage space 75. Moreover, it penetrates the front plate 46 so that the other end is arranged in the pipe storage space 75. Each of the four indoor unit side liquid pipes 26-5 to 26-8 out of the plurality of indoor unit side liquid pipes 26-1 to 26-12 is arranged so that one end is arranged outside the pipe storage space 75. Moreover, it penetrates the front plate 46 so that the other end is arranged in the pipe storage space 75.

In the left pipe storage space 78, four pipe groups 24-9 to 24-12 out of a plurality of pipe groups 24-1 to 24-12 are arranged. Each of the four indoor unit side gas pipes 25-9 to 25-12 out of the plurality of indoor unit side gas pipes 25-1 to 25-12 is arranged so that one end is arranged outside the pipe storage space 75. Moreover, it penetrates the front plate 46 so that the other end is arranged in the pipe storage space 75. Each of the four indoor unit side liquid pipes 26-9 to 26-12 out of the plurality of indoor unit side liquid pipes 26-1 to 26-12 is arranged so that one end is arranged outside the pipe storage space 75. Moreover, it penetrates the front plate 46 so that the other end is arranged in the pipe storage space 75.

At this time, the right side pipe storage space 76 is connected to the outside of the case 41 via the right side injection port 51 of the upper surface plate 45 and the plurality of right side air vent holes 52. The plurality of right air vent holes 52 are arranged at the four corners of the square region of the upper surface plate 45 exposed to the right pipe storage space 76. That is, the plurality of right air vent holes 52 are formed in the vicinity of the corner where the three planes along the upper surface plate 45, the front plate 46, and the right side plate 47 intersect, and in the upper surface plate 45, the front plate 46, and the right partition plate 72. It is formed near the corner where three planes along each intersect. The plurality of right air vent holes 52 are further provided in the vicinity of the corners where the three planes intersecting the upper surface plate 45, the right side plate 47, and the solenoid valve partition plate 71, respectively, and the upper surface plate 45, the solenoid valve partition plate 71, and the right partition. It is formed near the corner where three planes along the plate 72 intersect.

The central pipe storage space 77 is connected to the outside of the case 41 via the central injection port 53 and the plurality of central air vent holes 54. The plurality of central air vent holes 54 are arranged at the four corners of the square region of the upper surface plate 45 exposed to the central pipe storage space 77. That is, the plurality of central air vent holes 54 are formed in the vicinity of the corner where the three planes along the upper surface plate 45, the front plate 46, and the right partition plate 72 intersect, and the upper surface plate 45, the front plate 46, and the left partition plate 73. It is formed in the vicinity of the corner where the three planes along each intersect. The plurality of central air vent holes 54 are further provided in the vicinity of the corners where the three planes intersecting the upper surface plate 45, the solenoid valve partition plate 71, and the right side partition plate 72, respectively, and the upper surface plate 45, the solenoid valve partition plate 71, and the left side. It is formed in the vicinity of a corner where three planes along the partition plate 73 intersect.

The left pipe storage space 78 is connected to the outside of the case 41 via the left injection port 55 and the plurality of left air vent holes 56. The plurality of left air vent holes 56 are arranged at the four corners of the square region of the upper surface plate 45 exposed to the left pipe storage space 78. That is, the plurality of left air vent holes 56 are formed in the vicinity of the corner where the three planes along the upper surface plate 45, the front plate 46, and the left side plate 48 intersect, and in the upper surface plate 45, the front plate 46, and the left partition plate 73. It is formed near the corner where three planes along each intersect. The plurality of left air vent holes 56 are further provided in the vicinity of the corners where the three planes intersecting the top plate 45, the left side plate 48, and the solenoid valve partition plate 71, respectively, and the top plate 45, the solenoid valve partition plate 71, and the left partition. It is formed near the corner where three planes along the plate 73 intersect.

FIG. 8 is a perspective view showing the solenoid valve partition plate 71. The solenoid valve partition plate 71 is formed with a plurality of solenoid valve through holes 81. The switching unit 1 further includes a plurality of electric box fixtures 82-1 to 82-3. Of the plurality of electric box fixtures 82-1 to 82-3, the electric box fixture 82-1 is formed in a bent band shape. The electric box fixture 82-1 is arranged in the area of the coil portion storage space 74 on the side closer to the lower surface plate 49, and is arranged on the side of the area closer to the lower surface plate 49 on the side closer to the right side plate 47. There is. Of the plurality of electric box fixtures 82-1 to 82-3, the electric box fixing tool 82-2 and the electric box fixing tool 82-3 have a bent strip shape, respectively, similarly to the electric box fixing tool 82-1. Is formed in. The electric box fixture 82-2 is arranged in the area near the lower surface plate 49 in the coil portion storage space 74, and is arranged on the side closer to the left side surface plate 48 in the area closer to the lower surface plate 49. There is. The electric box fixing tool 82-3 is arranged in the area of the coil portion storage space 74 near the lower surface plate 49, and is arranged between the electric box fixing tool 82-1 and the electric box fixing tool 82-2. ing.

FIG. 9 is a perspective view showing the electric box fixture 82-1. One end of the electric box fixing tool 82-1 is fixed to the solenoid valve partition plate 71 via a plurality of bolts 83. The other end of the electric box fixing tool 82-1 is fixed to the outer body lower 44 via a plurality of bolts 84. Of the plurality of electric box fixtures 82-1 to 82-3, the electric box fixture different from the electric box fixture 82-1 is also fixed to the solenoid valve partition plate 71 in the same manner as the electric box fixture 82-1. , It is fixed to the outer body lower 44.

The bottom plate 49 includes a plurality of heat dissipation hole non-formed portions 85-1 to 85-3. The plurality of heat dissipation hole non-formed portions 85-1 to 85-3 correspond to a plurality of electric box fixtures 82-1 to 82-3. The heat dissipation hole non-formed portion 85-1 corresponding to the electric box fixture 82-1 of the plurality of heat dissipation hole non-formed portions 85-1 to 85-3 is the electric box fixture 82-1 of the bottom plate 49. It forms an area underneath. That is, the figure in which the heat radiation hole non-formed portion 85-1 is normally projected onto the horizontal plane overlaps with the figure in which the electric box fixture 82-1 is normally projected on the horizontal plane. At this time, the lower surface plate 49 is formed so that a plurality of lower surface heat radiating holes 64 are not formed in the heat radiating hole non-formed portion 85-1. The heat radiation hole non-formed portion 85-1 is sufficiently separated from the intermediate portion 113 so that air flows in the space sandwiched between the heat radiation hole non-formed portion 85-1 and the intermediate portion 113. That is, the electric box fixture 82-1 is arranged so that air flows in the space sandwiched between the heat dissipation hole non-formed portion 85-1 and the intermediate portion 113, and is fixed to the case 41.

Of the plurality of heat dissipation hole non-formed portions 85-1 to 85-3, the heat radiation hole non-formed portion 85-2 corresponding to the electric box fixture 82-2 is also electric like the heat radiation hole non-formed portion 85-1. It is located below the box fixture 82-2. Of the plurality of heat dissipation hole non-formed portions 85-1 to 85-3, the heat radiation hole non-formed portion 85-3 corresponding to the electric box fixture 82-3 is also electric like the heat radiation hole non-formed portion 85-1. It is located below the box fixture 82-3. At this time, the lower surface plate 49 is formed so that the plurality of lower surface heat radiating holes 64 are not formed in the plurality of heat radiating hole non-formed portions 85-1 to 85-3. That is, the lower surface plate 49 is formed so that the figure obtained by projecting the plurality of lower surface heat dissipation holes 64 onto the horizontal plane does not overlap with the figure obtained by projecting the plurality of electric box fixtures 82-1 to 82-3 onto the horizontal plane. Has been done.

The electrical component box 42 is fixed to a plurality of electrical box fixtures 82-1 to 82-3 via a plurality of bolts (not shown). That is, the electrical component box 42 is fixed to the solenoid valve partition plate 71 via a plurality of solenoid valve fixtures 82-1 to 82-3, and is fixed to the case 41 via the solenoid valve partition plate 71. The electrical component box 42 is further fixed to the upper surface plate 45, the right side surface plate 47, and the left side surface plate 48 of the outer body upper 43.

The end of the outer body 43 on the side closer to the electrical component box 42 is formed by forming a plurality of upper surface heat radiating holes 61, a plurality of right side heat radiating holes 62, and a plurality of left side heat radiating holes 63. Compared to other parts of the body 43, the strength is weak and it is easily deformed. The end of the outer body lower 44 on the side closer to the electrical component box 42 is weaker in strength than the other part of the outer body lower 44 due to the formation of a plurality of lower surface heat radiating holes 64. Easy to deform. In the switching unit 1, the electrical component box 42 is fixed to the case 41 via a plurality of electrical box fixtures 82-1 to 82-3, so that the end of the case 41 on the side closer to the electrical component box 42. Can be prevented from being deformed by the electrical component box 42.

As shown in FIG. 10, the switching unit 1 further includes a plurality of shafts 86-1 to 86-4 and a plurality of coil portions 87-1 to 87-4 with respect to the piping group 24-1. ing. FIG. 10 is a side view showing the piping group 24-1. The plurality of shafts 86-1 to 86-4 correspond to a plurality of on-off valves 31 to 34. The plurality of coil portions 87-1 to 87-4 correspond to a plurality of on-off valves 31 to 34. The first shaft 86-1 of the plurality of shafts 86-1 to 86-4 is formed in a rod shape and penetrates and moves through one of the plurality of solenoid valve through holes 81 of the solenoid valve partition plate 71. It is possible to be supported by the first on-off valve 31. The first coil portion 87-1 of the plurality of coil portions 87-1 to 87-4 is arranged in the coil portion storage space 74 and is fixed to the solenoid valve partition plate 71. The first coil portion 87-1 moves the first shaft 86-1 by being energized by the control circuit. The first on-off valve 31 connects or shuts off between the outdoor unit side low-pressure gas pipe 21 and the indoor unit side gas pipe 25-2 according to the movement of the first shaft 86-1.

The second shaft 86-2 of the plurality of shafts 86-1 to 86-4 is formed in a rod shape and penetrates and moves through one of the plurality of solenoid valve through holes 81 of the solenoid valve partition plate 71. It is possible to be supported by the second on-off valve 32. The second coil portion 87-2 of the plurality of coil portions 87-1 to 87-4 is arranged in the coil portion storage space 74 and is fixed to the solenoid valve partition plate 71. The second coil portion 87-2 moves the second shaft 86-2 by being energized by the control circuit. The second on-off valve 32 connects or shuts off between the outdoor unit side high pressure gas pipe 22 and the indoor unit side gas pipe 25-3 according to the movement of the second shaft 86-2.

The third shaft 86-3 of the plurality of shafts 86-1 to 86-4 is formed in a rod shape and penetrates and moves through one of the plurality of solenoid valve through holes 81 of the solenoid valve partition plate 71. It is possible to be supported by the third on-off valve 33. The third coil portion 87-3 of the plurality of coil portions 87-1 to 87-4 is arranged in the coil portion storage space 74 and is fixed to the solenoid valve partition plate 71. The third coil portion 87-3 moves the third shaft 86-3 by being energized by the control circuit. The third on-off valve 33 connects or shuts off between the outdoor unit side low-pressure gas pipe 21 and the first capillary tube 35 in response to the movement of the third shaft 86-3.

The fourth shaft 86-4 of the plurality of shafts 86-1 to 86-4 is formed in a rod shape and penetrates and moves through one of the plurality of solenoid valve through holes 81 of the solenoid valve partition plate 71. It is possible to be supported by the fourth on-off valve 34. The fourth coil portion 87-4 of the plurality of coil portions 87-1 to 87-4 is arranged in the coil portion storage space 74 and is fixed to the solenoid valve partition plate 71. The fourth coil portion 87-4 moves the fourth shaft 86-4 by being energized by the control circuit. The fourth on-off valve 34 connects or shuts off between the outdoor unit side high-pressure gas pipe 22 and the first capillary tube 35 in response to the movement of the fourth shaft 86-4.

That is, the plurality of coil portions 87-1 to 87-4 are opened and closed by a plurality of shafts 86-1 to 86-4 so that the plurality of on-off valves 31 to 34 of the piping group 24-1 are opened and closed. Drive the valves 31 to 34 respectively. The switching unit 1 has a plurality of shafts 86-1 to 86-4 and a plurality of coil portions for other piping groups different from the piping group 24-1 among the plurality of piping groups 24-1 to 24-12. 87-1 to 87-4 are further provided. That is, the switching unit 1 further includes a plurality of shafts 86-1 to 86-4 and a plurality of coil portions 87-1 to 87-4 for each of the plurality of piping groups 24-1 to 24-12.

FIG. 11 is a top view showing the switching unit 1 of the first embodiment. The switching unit 1 further includes a plurality of sheet-shaped heat insulating materials. Each of the plurality of sheet-shaped heat insulating materials is formed of a material having a very small heat conduction as compared with the material on which the case 41 is formed, and is formed in a sheet shape. The plurality of sheet-shaped heat insulating materials include a right side heat insulating material 91 for the front plate, a central heat insulating material 92 for the front plate, a left heat insulating material 93 for the front plate, a heat insulating material 94 for the right side plate, and a heat insulating material 95 for the left side plate. .. The right heat insulating material 91 for the front plate is attached to a part of the area of the front plate 46 facing the right pipe storage space 76. The central heat insulating material 92 for the front plate is attached to a part of the front plate 46 facing the central pipe storage space 77. The left heat insulating material 93 for the front plate is attached to a part of the area of the front plate 46 facing the left pipe storage space 78.

FIG. 12 is a cross-sectional view showing the switching unit 1 of the first embodiment. The heat insulating material 94 for the right side plate is close to the upper surface plate 45 of the right side plate 47 so that the lower region of the half of the right side plate 47 closer to the lower surface plate 49 is not covered with the heat insulating material 94 for the right side plate. It is affixed to the upper part of the side. Similar to the heat insulating material 94 for the right side plate, the heat insulating material 95 for the left side plate also has a left side so that the lower portion of the left side plate 48 on the side closer to the lower surface plate 49 is not covered with the heat insulating material 95 for the left side plate. It is attached to the upper portion of the face plate 48 on the side closer to the upper surface plate 45. Similar to the heat insulating material 94 for the right side plate, the right heat insulating material 91 for the front plate also has a lower portion of the front plate 46 on the side closer to the lower surface plate 49 so that the lower portion is not covered with the right heat insulating material 91 for the front plate. , Is attached to the upper portion of the front plate 46 on the side closer to the upper surface plate 45. Similar to the heat insulating material 94 for the right side plate, the central heat insulating material 92 for the front plate also has a lower portion of the front plate 46 on the side closer to the lower surface plate 49 so that the lower portion is not covered with the central heat insulating material 92 for the front plate. , Is attached to the upper portion of the front plate 46 on the side closer to the upper surface plate 45. Similar to the heat insulating material 94 for the right side plate, the left heat insulating material 93 for the front plate is also so that the lower portion of the front half of the front plate 46 near the lower surface plate 49 is not covered with the left heat insulating material 93 for the front plate. , Is attached to the upper portion of the front plate 46 on the side closer to the upper surface plate 45.

The plurality of sheet-shaped heat insulating materials further include a right side heat insulating material 97 for the upper surface plate, a central heat insulating material 98 for the upper surface plate, and a left side heat insulating material 99 for the upper surface plate. The right heat insulating material 97 for the top plate is attached to a part of the area of the top plate 45 facing the right pipe storage space 76 so that the right injection port 51 and the plurality of right air vent holes 52 are not blocked. ing. The central heat insulating material 98 for the upper surface plate is attached to a part of the upper surface plate 45 facing the central pipe storage space 77 so that the central injection port 53 and the plurality of central air vent holes 54 are not blocked. ing. The left heat insulating material 99 for the top plate is attached to a part of the area of the top plate 45 facing the left pipe storage space 78 so that the left injection port 55 and the plurality of left air vent holes 56 are not blocked. ing. At this time, the plurality of sheet-shaped heat insulating materials are not attached to both sides of the right partition plate 72 and both sides of the left partition plate 73.

The switching unit 1 further includes a plurality of foam insulation materials. The plurality of foam insulation includes the right foam insulation 101, the central foam insulation 102, and the left foam insulation 103. The right foam heat insulating material 101 is filled in the right pipe storage space 76. The central foam heat insulating material 102 is filled in the central pipe storage space 77. The left foam heat insulating material 103 is filled in the left pipe storage space 78.

The right foam heat insulating material 101 fills the right pipe storage space 76 to cover a plurality of refrigerant pipes 30 included in the four pipe groups 24-1 to 24-4, and the plurality of refrigerant pipes 30 come into contact with air. Prevent it from happening. The central foam heat insulating material 102 covers the plurality of refrigerant pipes 30 included in the four pipe groups 24-5 to 24-8 by filling the central pipe storage space 77, and the plurality of refrigerant pipes 30 come into contact with air. Prevent it from happening. The left foam heat insulating material 103 covers the plurality of refrigerant pipes 30 included in the four pipe groups 24-9 to 24-12 by filling the left pipe storage space 78, and the plurality of refrigerant pipes 30 come into contact with air. Prevent it from happening. Further, in the switching unit 1, since the plurality of sheet-shaped heat insulating materials are not attached to the lower half of the inner side surface of the case 41, the amount of the plurality of sheet-shaped heat insulating materials can be reduced, and the case 41 can be reduced. It is possible to reduce the man-hours for attaching a plurality of sheet-shaped heat insulating materials to the inner surface of the. The plurality of foam insulation materials are filled under the pipe storage space 75 and appropriately filled under the pipe storage space 75. In the switching unit 1, a plurality of sheet-shaped heat insulating materials are appropriately filled on the lower side of the pipe storage space 75, so that the plurality of sheet-shaped heat insulating materials are attached to the lower half of the inner side surface of the case 41. Even if it is not present, the plurality of refrigerant pipes 30 can be appropriately insulated.

[Manufacturing method of switching unit 1]
In the method of manufacturing the switching unit 1, first, an intermediate product is prepared. The intermediate product is in the process of manufacturing the switching unit 1, and a plurality of foamed heat insulating materials have not yet been provided. In the intermediate product, the foam insulation stock solution is injected into the right pipe storage space 76 via the right injection port 51, the foam insulation stock solution is injected into the central pipe storage space 77 via the central injection port 53, and the foam insulation material stock solution is injected into the central pipe storage space 77. The foamed heat insulating material stock solution is injected into the left pipe storage space 78 via the above.

The foamed heat insulating material stock solution injected into the right side pipe storage space 76, the central pipe storage space 77, and the left side pipe storage space 78 is stored on the lower surface plate 49 and foams. The foamed heat insulating material stock solution expands by foaming and spreads over the right side pipe storage space 76, the central pipe storage space 77, and the left side pipe storage space 78. The air existing in the right pipe storage space 76 flows out to the outside of the case 41 through the plurality of right air vent holes 52 when the foamed heat insulating material stock solution injected into the right pipe storage space 76 expands. By allowing air to flow out through the plurality of right air vent holes 52, the foamed heat insulating material stock solution can appropriately enter the corners of the right pipe storage space 76 in the vicinity of the plurality of right air vent holes 52, and the right side can be appropriately entered. It can be appropriately distributed to the corners of the pipe storage space 76. The air existing in the central pipe storage space 77 flows out to the outside of the case 41 through the plurality of central air vent holes 54 when the foamed heat insulating material stock solution injected into the central pipe storage space 77 expands. The foamed heat insulating material stock solution can appropriately enter the corners of the central pipe storage space 77 in the vicinity of the plurality of central air vent holes 54 by allowing air to flow out through the plurality of central air vent holes 54, and is central. It can be appropriately distributed to the corners of the pipe storage space 77. The air existing in the left pipe storage space 78 flows out to the outside of the case 41 through the plurality of left air vent holes 56 when the foamed heat insulating material stock solution injected into the left pipe storage space 78 expands. By allowing air to flow out through the plurality of left air vent holes 56, the foamed heat insulating material stock solution can appropriately enter the corners of the left pipe storage space 78 in the vicinity of the plurality of left air vent holes 56, and the left side can be appropriately entered. It can be appropriately distributed to the corners of the pipe storage space 78.

The foamed insulation stock solution also adheres to the surface of the object it comes into contact with when inflated. For example, the foamed heat insulating material stock solution comes into close contact with the inner surface of the case 41 by contacting the inner surface of the case 41 when it is expanding. The foamed heat insulating material stock solution adheres to the plurality of sheet-shaped heat insulating materials by coming into contact with the plurality of sheet-shaped heat insulating materials attached to the inside of the case 41 when it is expanding. When the foamed heat insulating material stock solution is inflated, it comes into contact with the plurality of refrigerant pipes 30 to come into close contact with the surfaces of the plurality of refrigerant pipes 30 and cover the surfaces of the plurality of refrigerant pipes 30.

The foamed insulation stock solution further cures gradually over time, and even when it expands, it gradually cures while expanding. The undiluted solution of foamed heat insulating material becomes difficult to adhere to the surface of an object in contact with it by curing. Therefore, the foamed heat insulating material stock solution adheres to the lower portion of the inner surface of the case 41 on the side closer to the lower surface plate 49, but does not adhere to the upper portion on the side far from the lower surface plate 49, and does not adhere to the upper portion. A gap may be formed between the foam insulation and the foam insulation. The switching unit 1 has a plurality of sheet-shaped heat insulating materials attached to the upper portion of the inner surface of the case 41 away from the lower surface plate 49, thereby reducing the volume of the gap and reducing the volume of the gap, and the piping storage space 75. The area away from the bottom plate 49 can be appropriately insulated.

The effervescent insulation stock solution does not expand as it hardens. The right inlet 51, the plurality of right air vents 52, the central inlet 53, the plurality of central air vents 54, the left inlet 55, and the plurality of left air vents 56 are shown after the foamed heat insulating material stock solution has stopped expanding. It is blocked by an uncovered lid. In the intermediate product, the switching unit 1 is formed by closing the right side inlet 51, the plurality of right side air vent holes 52, the central inlet 53, the plurality of central air vent holes 54, the left side inlet 55, and the plurality of left side air vent holes 56. Is formed in.

[Operation of multi-chamber air conditioner 2]
When the indoor unit 5-1 is allowed to perform the cooling operation, the switching unit 1 opens the first on-off valve 31 of the pipe group 24-1 corresponding to the indoor unit 5-1 and opens the second on-off valve 31 of the pipe group 24-1-1. By closing the on-off valve 32, the low-pressure gas pipe 6 is connected to the indoor unit side gas pipe 12-1. At this time, the high-pressure liquid-phase refrigerant flowing through the liquid pipe 8 is supplied to the indoor unit 5-1 via the indoor unit liquid pipe 11-1, and is supplied from the indoor unit 5-1 via the indoor unit side gas pipe 12-1. The low-pressure gas phase refrigerant that flows out is supplied to the low-pressure gas pipe 6. The switching unit 1 closes the first on-off valve 31 of the pipe group 24-1 and opens the second on-off valve 32 of the pipe group 24-1 when the indoor unit 5-1 is allowed to perform the heating operation. , The high pressure gas pipe 7 is connected to the indoor unit side gas pipe 12-1. At this time, the high-pressure gas phase refrigerant flowing through the high-pressure gas pipe 7 is supplied to the indoor unit 5-1 via the indoor unit side gas pipe 12-1, and from the indoor unit 5-1 via the indoor unit liquid pipe 11-1. The low-pressure two-phase refrigerant that flows out is supplied to the liquid pipe 8.

In the third on-off valve 33 and the fourth on-off valve 34 of the piping group 24-1, the pressure of the refrigerant flowing through the piping group 24-1 is equalized when the first on-off valve 31 and the second on-off valve 32 open and close. That is, the first on-off valve 31 and the second on-off valve 32 are opened and closed appropriately. The switching unit 1 is the same as the piping group 24-1 when the other indoor unit different from the indoor unit 5-1 of the plurality of indoor units 5-1 to 5-4 is allowed to perform the cooling operation or the heating operation. , Operate a plurality of piping groups 24-1 to 24-12.

The indoor unit 5-1 is cooled by supplying a high-pressure liquid-phase refrigerant from the switching unit 1 via the indoor unit liquid pipe 11-1. At this time, the expansion valve of the indoor unit 5-1 expands the high-pressure liquid-phase refrigerant supplied via the indoor unit liquid pipe 11-1, and generates a liquid-rich low-pressure two-phase refrigerant from the high-pressure liquid-phase refrigerant. .. The indoor heat exchanger of the indoor unit 5-1 functions as a condenser. That is, the indoor heat exchanger cools the indoor air by exchanging heat between the low-pressure two-phase refrigerant and the indoor air, and raises the dryness of the low-pressure two-phase refrigerant while keeping the pressure of the low-pressure two-phase refrigerant constant. , A low-pressure gas-phase refrigerant in an overheated state is generated from the low-pressure two-phase refrigerant.

The indoor unit 5-1 is heated by supplying a high-pressure gas phase refrigerant from the switching unit 1 via the gas pipe 12-1 on the indoor unit side. At this time, the indoor heat exchanger of the indoor unit 5-1 functions as a condenser. That is, the indoor heat exchanger heats the indoor air by exchanging heat between the high-pressure vapor phase refrigerant and the indoor air, cools the high-pressure vapor phase refrigerant while keeping the pressure of the high-pressure vapor phase refrigerant constant, and performs high pressure. It lowers the dryness of the gas phase refrigerant and produces a high pressure liquid phase refrigerant. The expansion valve of the indoor unit 5-1 expands the high-pressure liquid-phase refrigerant to generate a liquid-rich low-pressure two-phase refrigerant from the high-pressure liquid-phase refrigerant.

Of the plurality of indoor units 5-1 to 5-4, other indoor units different from the indoor unit 5-1 are also subjected to cooling operation and heating operation in the same manner as the indoor unit 5-1. ..

Of the plurality of outdoor units 3-1 to 2-3, the four-way valve of the outdoor unit 3-1 uses the amount of refrigerant used in the indoor unit in which the cooling operation is performed, and is used in the indoor unit in which the heating operation is performed. When the amount of refrigerant is greater than the amount of refrigerant, the mode is switched to the first mode. At this time, the low-pressure gas-phase refrigerant flowing through the low-pressure gas pipe 6 is supplied to the compressor, and the high-pressure gas-phase refrigerant compressed by the compressor of the outdoor unit 3-1 is supplied to the high-pressure gas pipe 7 to open the four-way valve. It is supplied to the outdoor heat exchanger via. The outdoor heat exchanger of the outdoor unit 3-1 operates as a condenser. That is, the outdoor heat exchanger exchanges heat between the high-pressure vapor-phase refrigerant supplied from the compressor of the outdoor unit 3-1 via the four-way valve and the outside air, so that the pressure of the high-pressure vapor refrigerant remains constant and high pressure. It cools the gas-phase refrigerant, lowers the dryness of the high-pressure vapor-phase refrigerant, and produces a high-pressure liquid-phase refrigerant. The high-pressure liquid-phase refrigerant is supplied to the liquid pipe 8. The compressor compresses the low-pressure gas-phase refrigerant flowing through the low-pressure gas pipe 6 to generate an overheated high-pressure gas-phase refrigerant from the low-pressure gas-phase refrigerant.

Of the plurality of outdoor units 3-1 to 2-3, the four-way valve of the outdoor unit 3-1 uses the amount of refrigerant used in the indoor unit in which the heating operation is performed, and is used in the indoor unit in which the cooling operation is performed. When the amount of refrigerant is greater than the amount of refrigerant, the mode is switched to the second mode. At this time, the low-pressure gas-phase refrigerant flowing through the low-pressure gas pipe 6 and the low-pressure gas-phase refrigerant generated by the outdoor heat exchanger are supplied to the compressor and compressed by the compressor of the outdoor unit 3-1. The phase refrigerant is supplied to the outdoor heat exchanger via the four-way valve. The outdoor heat exchanger of the outdoor unit 3-1 operates as an evaporator. That is, the outdoor heat exchanger raises the dryness of the low-pressure two-phase refrigerant while keeping the pressure of the low-pressure two-phase refrigerant constant by exchanging heat between the low-pressure two-phase refrigerant flowing through the liquid pipe 8 and the indoor air, and lower pressure. A superheated low-pressure vapor-phase refrigerant is generated from the two-phase refrigerant. The compressor compresses the low-pressure gas-phase refrigerant supplied from the four-way valve and the low-pressure gas-phase refrigerant flowing through the low-pressure gas pipe 6 to generate an overheated high-pressure gas-phase refrigerant from the low-pressure gas-phase refrigerant, and produces a superheated high-pressure vapor refrigerant. Is supplied to the high-pressure gas pipe 7.

Of the plurality of outdoor units 3-1 to 2-3, other outdoor units different from the outdoor unit 3-1 also operate in the same manner as the outdoor unit 3-1.

The first coil portion 87-1, the second coil portion 87-2, the third coil portion 87-3, and the fourth coil portion 87-4 generate heat when energized. The switching unit 1 may malfunction due to the heat of the first coil portion 87-1, the second coil portion 87-2, the third coil portion 87-3, and the fourth coil portion 87-4. Examples of the defects include that the plurality of on-off valves 31 to 34 do not operate properly, that the plurality of refrigerant pipes 30 are heated, and that the control circuit inside the electrical component box 42 is heated.

The switching unit 1 is formed on the case 41 by forming a plurality of upper surface heat radiating holes 61, a plurality of right side heat radiating holes 62, a plurality of left side heat radiating holes 63, and a plurality of lower surface heat radiating holes 64, thereby forming the outside of the case 41. More air can flow into the coil storage space 74. In the switching unit 1, the first coil portion 87-1, the second coil portion 87-2, the third coil portion 87-3, and the fourth coil portion 87- are generated by the inflow of external air into the coil portion storage space 74. 4 and can be appropriately dissipated. The switching unit 1 causes a problem when the first coil portion 87-1, the second coil portion 87-2, the third coil portion 87-3, and the fourth coil portion 87-4 appropriately dissipate heat. Can be prevented.

The plurality of electric box fixtures 82-1 to 82-3 are arranged so as to vertically overlap the plurality of heat dissipation hole non-formed portions 85-1 to 85-3, so that the plurality of electric box fixtures 82-1 to 82-3 are arranged from the plurality of lower surface heat radiation holes 64. It does not prevent the inflow of outside air. In the switching unit 1, more air can flow into the coil portion storage space 74 because the plurality of electric box fixtures 82-1 to 82-3 do not block the inflow of outside air. In the switching unit 1, a large amount of air flows into the coil portion storage space 74, so that the first coil portion 87-1, the second coil portion 87-2, the third coil portion 87-3, and the fourth coil portion 87- 4 and can be appropriately dissipated.

[Effect of switching unit 1 of Example 1]
The switching unit 1 of the first embodiment includes a plurality of refrigerant pipes 30, a first on-off valve 31, a second on-off valve 32, a third on-off valve 33, a fourth on-off valve 34, a case 41, a plurality of sheet-shaped heat insulating materials, and foaming. It is equipped with heat insulating material. In the plurality of refrigerant pipes 30, the refrigerant circulating through the plurality of outdoor units 3-1 to 3-2 and the plurality of indoor units 5-1 to 5-4 flows. The first on-off valve 31, the second on-off valve 32, the third on-off valve 33, and the fourth on-off valve 34 open and close a plurality of refrigerant pipes 30. In the case 41, a pipe storage space 75 in which a plurality of refrigerant pipes 30 are arranged is formed. The plurality of sheet-shaped heat insulating materials are attached to a part of the inner side surface of the case 41 facing the pipe storage space 75. The foam insulation material fills the pipe storage space 75. In the switching unit 1, a sheet-shaped heat insulating material is attached to a part of the inner side surface of the case 41 so that the sheet-shaped heat insulating material is arranged in a gap where the foamed heat insulating material is difficult to be filled. By doing so, it is possible to appropriately insulate the plurality of refrigerant pipes 30.

Further, the case 41 of the switching unit 1 of the first embodiment includes a front plate 46, a right side plate 47, and a left side plate 48 arranged in the horizontal direction of the pipe storage space 75. The plurality of sheet-shaped heat insulating materials are not attached to the lower portion of the front plate 46, the right side plate 47, and the left side plate 48 near the lower surface plate 49, but are attached to the upper portion arranged above the lower portion. ing. The foamed heat insulating material stock solution expands after being injected into the pipe storage space 75, diffuses from the bottom to the top, and fills the pipe storage space 75. The effervescent heat insulating material stock solution hardens while expanding, so that it adheres to the lower portion, but may not adhere appropriately to the upper portion. Since the sheet-shaped heat insulating material is attached to the upper portion of the switching unit 1, the gap in which the foamed heat insulating material is not filled can be reduced, and the plurality of refrigerant pipes 30 can be appropriately heat-insulated.

Further, the sheet-shaped heat insulating material of the switching unit 1 of the first embodiment is attached to the upper surface plate 45 arranged on the upper side of the pipe storage space 75 in the case 41. The effervescent heat insulating material stock solution hardens while expanding, so that it is difficult to adhere to the top plate 45. Since the sheet-shaped heat insulating material is attached to the upper surface plate 45 of the switching unit 1, the gap in which the foamed heat insulating material is not filled can be reduced, and the plurality of refrigerant pipes 30 can be appropriately heat-insulated.

By the way, in the switching unit 1 of the first embodiment described above, a plurality of sheet-shaped heat insulating materials are attached to the upper surface plate 45, but a plurality of sheet-shaped heat insulating materials may not be attached to the upper surface plate 45. The switching unit 1 reduces the gap formed in the pipe storage space 75 by not attaching the sheet-shaped heat insulating material to the lower portion of the case 41 even when a plurality of sheet-shaped heat insulating materials are not attached to the upper surface plate 45. It is possible to appropriately insulate a plurality of refrigerant pipes 30.

Further, the switching unit 1 of the first embodiment further includes a right partition plate 72 and a left partition plate 73 that separate the pipe storage space 75 into the right pipe storage space 76, the central pipe storage space 77, and the left pipe storage space 78. ing. The right partition plate 72 and the left partition plate 73 do not separate the outside of the case 41 from the pipe storage space 75. Therefore, the switching unit 1 can appropriately insulate the plurality of refrigerant pipes 30 even when the plurality of sheet-shaped heat insulating materials are not attached to the right side partition plate 72 and the left side partition plate 73. The switching unit 1 can reduce the amount of the plurality of sheet-shaped heat insulating materials by preventing the plurality of sheet-shaped heat insulating materials from being attached to the right-side partition plate 72 and the left-side partition plate 73, and can reduce the amount of the plurality of sheet-shaped heat insulating materials. The man-hours for pasting can be reduced.

By the way, in the switching unit 1 of the first embodiment described above, a plurality of sheet-shaped heat insulating materials are not attached to the right partition plate 72 and the left partition plate 73, but a plurality of sheet-shaped heat insulating materials may be attached. .. The switching unit 1 can reduce the gap formed on the upper side of the pipe storage space 75 even when a plurality of sheet-shaped heat insulating materials are attached to the right partition plate 72 and the left partition plate 73, and the plurality of refrigerants can be reduced. The pipe 30 can be appropriately insulated.

Further, the case 41 of the switching unit 1 of the first embodiment has a plurality of right air vent holes 52 and a plurality of right air vent holes 52 in the vicinity of the plurality of upper corners of the right side pipe storage space 76, the central pipe storage space 77, and the left side pipe storage space 78. A central air vent hole 54 and a plurality of left air vent holes 56 are formed. The effervescent insulation stock solution can appropriately enter a plurality of corners by allowing air to flow out through the plurality of air vent holes. Therefore, the switching unit 1 can appropriately fill the right side pipe storage space 76, the central pipe storage space 77, and the left side pipe storage space 78 with the foamed heat insulating material.

By the way, in the switching unit 1 of the above-described first embodiment, a plurality of right air vent holes 52, a plurality of central air vent holes 54, and a plurality of left left air vent holes 56 are formed in the upper surface plate 45, but they are not formed. May be good. The switching unit 1 can reduce the gap formed in the pipe storage space 75 by not attaching the plurality of sheet-shaped heat insulating materials to the lower portion of the case 41 even when the air vent hole is not formed. The plurality of refrigerant pipes 30 can be appropriately insulated.

By the way, in the switching unit 1 of the above-described first embodiment, a plurality of sheet-shaped heat insulating materials are not attached to the lower portion of the front plate 46, the right side plate 47, and the left side plate 48 near the lower surface plate 49. , A plurality of sheet-shaped heat insulating materials may be attached to the lower portion. The switching unit 1 can reduce the gap formed in the pipe storage space 75 even when a plurality of sheet-shaped heat insulating materials are attached to the lower portion, and can appropriately insulate the plurality of refrigerant pipes 30. it can.

The switching unit 1 of the first embodiment described above is provided in the multi-chamber air conditioner 2 provided with a plurality of outdoor units 3-1 to 2-3, but the multi-chamber type including one outdoor unit. It may be provided in an air conditioner. Even when the switching unit 1 is provided in a multi-chamber air conditioner including one outdoor unit, it is possible to appropriately insulate a plurality of refrigerant pipes 30.

Although the examples have been described above, the examples are not limited by the contents described above. Further, the above-mentioned components include those that can be easily assumed by those skilled in the art, those that are substantially the same, that is, those having a so-called equal range. Furthermore, the components described above can be combined as appropriate. Further, at least one of various omissions, substitutions and changes of components may be made without departing from the gist of the embodiment.

1: Switching unit 2: Multi-chamber air conditioner 3-1 to 2-3: Multiple outdoor units 5-1 to 5-4: Multiple indoor units 24-1 to 24-12: Multiple piping groups 30: Multiple refrigerant pipes 31-34: Multiple on-off valves 41: Case 42: Electrical component box 45: Top plate 46: Front plate 47: Right side plate 48: Left side plate 49: Bottom plate 51: Right injection port 52: Multiple right sides Air vent 53: Central inlet 54: Multiple central air vents 55: Left inlet 56: Multiple left air vents 61: Multiple upper surface heat insulating holes 62: Multiple right side heat insulating holes 63: Multiple left side heat insulating holes 64 : Multiple lower surface heat insulating holes 71: Electromagnetic valve partition plate 72: Right partition plate 73: Left partition plate 74: Coil storage space 75: Piping storage space 76: Right pipe storage space 77: Central pipe storage space 78: Left pipe storage Space 82-1 to 82-3: Multiple electric box fixtures 85-1 to 85-3: Multiple heat dissipation hole non-formed parts 87-1 to 87-4: Multiple coil parts 91: Right heat insulating material for front plate 92: Central insulation material for front plate 93: Left insulation material for front plate 94: Insulation material for right side plate 95: Insulation material for left side plate 97: Right insulation material for top plate 98: Central insulation material for top plate 99: Insulation material for top plate Left side insulation material 101: Right side foam insulation material 102: Central foam insulation material 103: Left side foam insulation material

Claims (5)

Multiple refrigerant pipes through which refrigerant flows and
A plurality of on-off valves for opening and closing the plurality of refrigerant pipes,
A case where a storage space in which the plurality of refrigerant pipes are arranged is formed, and a case where the storage space is formed.
A heat insulating material attached to a part of the inner surface of the case and
A switching unit including a foam insulation material filled in the storage space. The case has a side plate that separates the storage space from the outside of the case.
The switching unit according to claim 1, wherein the heat insulating material is not attached to the lower portion of the side plate, but is attached to the upper portion of the side plate which is arranged above the lower portion. The switching unit according to claim 1 or 2, wherein the heat insulating material is attached to a top plate of the case. A partition plate for separating the storage space into a first storage space and a second storage space is further provided.
The plurality of refrigerant pipes
A plurality of first refrigerant pipes arranged in the first storage space,
Including a plurality of second refrigerant pipes arranged in the second storage space,
The switching unit according to claim 1 or 2, wherein the heat insulating material is not attached to the partition plate. The case is
A top plate along the first plane arranged above the storage space,
A first plate along a second plane that is not parallel to the first plane,
Includes a second plate along a third plane that is not parallel to the first plane and the second plane.
The switching according to claim 1 or 2, wherein an air vent hole through which air passes is formed in the vicinity of a corner where the first plane, the second plane, and the third plane intersect in the case. unit.

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