JP6992113B2 - Air conditioner - Google Patents

Description

An embodiment of the present invention relates to an air conditioner including, for example, an indoor unit suitable for spot air conditioning.

For example, in a large-scale production factory, an air conditioner that locally cools and heats a plurality of work areas dispersed in the factory building is used. This type of air conditioner is equipped with multiple indoor units that blow temperature- and humidity-controlled air toward the work area. The indoor unit is installed in the work area using, for example, pillars that form the skeleton of the building.

Special Publication No. 61-54137 Special Fair 7-62588 Gazette

Recently, when installing a plurality of indoor units on a pillar, an air conditioner has been developed in which a dedicated frame is used to support the indoor units. The frame is fixed to the outer peripheral portion of the pillar so as to surround the pillar.

However, various devices such as switchboards, lighting fixtures, and fire hydrants are often attached to the pillars located in the work area. Therefore, it is difficult to assemble the frame that supports the indoor unit with the equipment as an obstacle to the pillar to which the equipment is attached.

As a result, the pillars on which the indoor unit can be installed are restricted, and it is undeniable that the degree of freedom in installing the indoor unit is lost.

An object of the present invention is to improve the degree of freedom when installing an indoor unit in a foundation structure and to obtain an air conditioner having excellent versatility.

According to embodiments, the air conditioner includes a support frame, a plurality of interior units, a plurality of exterior panels, a filter, and a cover. The support frame is attached to at least one surface of the basic structure of the space to be air-conditioned. The indoor unit has a heat exchanger and a blower that face the surface of the basic structure and are supported by the support frame along the basic structure to exchange heat between the refrigerant and air. At the same time, a suction port for sucking air for heat exchange is formed. The exterior panel is attached to the support frame and defines an air passage partitioned from the space between the interior unit and the surface of the foundation structure. The filter is provided so as to face the air passage. The cover covers the area of the surface of the foundation structure to which the support frame is attached, is exposed to the air passage, and constitutes a part of the inner wall surface of the air passage. The support frame has a first frame element fixed to the surface of the foundation structure together with the cover, and is arranged parallel to the surface of the foundation structure away from the surface of the foundation structure than the first frame element. The second frame element is provided with a subframe attached to the second frame element by connecting a plurality of the indoor units. When the suction port of the indoor unit is opened in the air passage and the blower of the indoor unit is operated, the air in the space is sucked into the air passage through the filter.

FIG. 1 is a circuit diagram showing a piping system of the air conditioner according to the first embodiment. FIG. 2 is a perspective view of the indoor unit used in the first embodiment as viewed from the front. FIG. 3 is a perspective view of the indoor unit as viewed from the rear. FIG. 4 is a perspective view showing the internal structure of the indoor unit in an exploded manner. FIG. 5 is a front view of the indoor unit. FIG. 6 is a cross-sectional view of the indoor unit showing the flow direction of the air blown out from the indoor unit. FIG. 7 is a perspective view showing a state in which the indoor unit assembly is installed on a pillar in the first embodiment. FIG. 8 is a perspective view showing a state in which the support frame is fixed to the pillar of the building in the first embodiment. FIG. 9 is a cross-sectional view showing a state in which the indoor unit is installed on the pillar of the building via the support frame in the first embodiment. FIG. 10 is a perspective view showing a state in which the lower structure of the first frame element is fixed to the pillar of the building in the first embodiment. FIG. 11 is a perspective view showing a state in which the lower structure and the upper structure of the first frame element are fixed to the pillar of the building in the first embodiment. FIG. 12 is a perspective view showing a state in which the second frame element is coupled to the first frame element of the support frame in the first embodiment. FIG. 13 is a perspective view showing a process of attaching a plurality of indoor units one by one to the superstructure of the second frame element in the first embodiment. FIG. 14 is a perspective view showing a state in which four indoor units are arranged side by side in a row on the superstructure of the second frame element in the first embodiment. FIG. 15 is a perspective view showing a state in which four indoor units are arranged side by side in a row on the superstructure of the second frame element in the second embodiment. FIG. 16 is a perspective view showing a state in which the superstructure of the second frame element to which the four indoor units are attached is assembled to the first frame element fixed to the pillar in the second embodiment. .. FIG. 17 is a perspective view showing a state in which a support frame to which four indoor units and a plurality of side panels are attached is fixed to a pillar in a third embodiment. FIG. 18 is a perspective view showing a state in which a support frame to which four indoor units and a plurality of side panels are attached is fixed to a pillar in a third embodiment. FIG. 19 is a perspective view showing a state in which the indoor unit assembly is installed on a pillar in the third embodiment. FIG. 20 is a perspective view showing a state in which the indoor unit assembly is installed on a pillar in the fourth embodiment. FIG. 21 is a circuit diagram showing a piping system of the air conditioner according to the fifth embodiment. FIG. 22 is a perspective view showing a state in which the first to fourth indoor unit assemblies are installed on the pillars in the fifth embodiment. FIG. 23 is a cross-sectional view showing a state in which the first to fourth indoor unit assemblies are installed on the pillars via support frames in the fifth embodiment.

[First Embodiment]
Hereinafter, the first embodiment will be described with reference to FIGS. 1 to 16.

FIG. 1 is a circuit diagram showing a piping system of an air conditioner 1 used for local cooling / heating of a large-scale space such as a production factory or a vehicle factory. As shown in FIG. 1, the air conditioner 1 includes an outdoor unit 2 and an indoor unit assembly 3 as main elements.

The outdoor unit 2 is installed outside the factory building 4, for example, and houses various refrigeration cycle devices such as a compressor for compressing a refrigerant, a heat exchanger, and an accumulator. The indoor unit assembly 3 is installed in the work area A inside the building 4. The work area A is an example of a space to be air-conditioned. The indoor unit assembly 3 includes, for example, four indoor units 5.

The liquid pipe 7 and the gas pipe 8 are connected to the outdoor unit 2. The liquid pipe 7 and the gas pipe 8 are each guided to the indoor unit assembly 3. The liquid pipe 7 has four liquid pipes 10a, 10b, 10c, 10d branched by three Y-shaped branch joints 9a, 9b, 9c. The liquid tubes 10a, 10b, 10c, and 10d are connected to the indoor unit 5, respectively.

Similarly, the gas pipe 8 has four gas pipes 12a, 12b, 12c, 12d branched by three T-shaped branch joints 11a, 11b, 11c. The gas pipes 12a, 12b, 12c, and 12d are each connected to the indoor unit 5.

Therefore, the refrigerant compressed by the outdoor unit 2 is distributed to the indoor unit 5 of the indoor unit assembly 3, and the refrigerant discharged from the indoor unit 5 is returned to the outdoor unit 2 again.

Further, the indoor unit assembly 3 includes a remote controller 13. In the indoor unit assembly 3, various operations such as operation / stop, temperature setting, and operation switching of the indoor unit 5 can be executed by the remote controller 13.

The four indoor units 5 included in the indoor unit assembly 3 have a common configuration with each other. Therefore, in the present embodiment, one indoor unit 5 will be described as a representative.

As shown in FIGS. 2 to 6, the indoor unit 5 includes a housing 20, an air heat exchanger 21, a blower 22, a control unit 23, and a duct unit 24 as main elements. The housing 20 is a square box-shaped element having a depth dimension D, a width dimension W, and a height dimension H, and is formed of, for example, a thin steel plate. The width dimension W and the height dimension H of the housing 20 are equal to each other, and the depth dimension D is set to be much smaller than the width dimension W and the height dimension H. Therefore, the housing 20 has a flat shape.

The housing 20 has a base 26, a front cover 27, a top cover 28, and a partition plate 29. The base 26 is composed of an upright back panel 30 and a dish-shaped bottom plate 31 fixed to the lower end of the back panel 30. A square suction port 32 is formed in a substantially central portion of the back panel 30. The bottom plate 31 projects horizontally from the lower end of the back panel 30 toward the front of the housing 20. A drain port 33 is formed at the rear end of the bottom plate 31. The drain port 33 projects behind the housing 20.

As shown in FIG. 4, the front cover 27 has a front panel 34 and a pair of side panels 35a and 35b. The front panel 34 is an element constituting the front surface of the housing 20. The front panel 34 faces the back panel 30, and a through hole 36 is formed in a substantially central portion of the front panel 34. Further, the lower end portion of the front panel 34 is fixed to the front end portion of the bottom plate 31 with a plurality of screws.

The side panels 35a and 35b extend from the side edges of the front panel 34 toward the back panel 30 at an angle of 90 °. The rear ends of the side panels 35a and 35b are fixed to both sides of the back panel 30 with a plurality of screws.

The top cover 28 is fixed to the upper end of the front panel 34 and the upper ends of the side panels 35a and 35b with a plurality of screws. The top cover 28 covers the gap between the upper end of the front cover 27 and the upper part of the back panel 30.

As shown in FIG. 6, the partition plate 29 is interposed between the upper portion of the back panel 30 and the upper end portion of the front cover 27. The partition plate 29 divides the inside of the housing 20 into two chambers, a first storage chamber 38 and a second storage chamber 39.

The first storage chamber 38 has a larger volume than the second storage chamber 39, and the suction port 32 and the through hole 36 of the housing 20 are opened in the first storage chamber 38. The bottom plate 31 of the housing 20 constitutes the bottom of the first storage chamber 38, and the bottom plate 31 also functions as a drain pan. The second containment chamber 39 is located above the first containment chamber 38 and is covered with a top cover 28. In other words, the second storage chamber 39 can be exposed to the outside of the housing 20 by loosening the screws and removing only the top cover 28.

Further, brackets 40a and 40b are fixed to both sides of the back panel 30, respectively. The brackets 40a and 40b extend in the height direction of the housing 20 and project to the side of the housing 20.

As shown in FIGS. 4 to 6, the air heat exchanger 21 is housed in the first storage chamber 38. The air heat exchanger 21 has a flat plate shape and includes a plurality of cooling fins 43 and a plurality of heat transfer tubes 44 through which a refrigerant flows. The cooling fins 43 are elongated square plates extending in the height direction of the housing 20, and are arranged in a row at intervals in the width direction of the housing 20. The heat transfer tubes 44 are arranged at intervals in the height direction and the depth direction of the housing 20, and are connected in series with each other to form a plurality of flow paths (paths). Further, the heat transfer tube 44 is thermally connected to the cooling fin 43.

According to the present embodiment, the air heat exchanger 21 stands up along the back panel 30 inside the first accommodation chamber 38. As a result, the air heat exchanger 21 is exposed behind the housing 20 through the suction port 32.

As best shown in FIG. 6, the air heat exchanger 21 has an upper end surface 21a and a lower end surface 21b. The upper end surface 21a faces the partition plate 29 inside the first storage chamber 38. The lower end surface 21b is covered from below with a bottom plate 31 as a drain pan. The upper end surface 21a and the lower end surface 21b of the air heat exchanger 21 are inclined downward as they proceed from the back panel 30 toward the front panel 34, respectively.

As a result, when water droplets are generated on the upper end surface 21a of the air heat exchanger 21 due to dew condensation, the water droplets tend to flow away from the back panel 30 as the upper end surface 21a is inclined. Similarly, when the water droplets generated on the surface of the air heat exchanger 21 become drain water and reach the lower end portion of the air heat exchanger 21, the drain water accompanies the inclination of the lower end surface 21b of the air heat exchanger 21. It becomes easier to flow in the direction away from the back panel 30.

Therefore, it is possible to prevent so-called water leakage, in which drain water flows out of the housing 20 from the suction port 32 of the back panel 30.

As shown in FIG. 4, the refrigerant pipe 45 connected to the air heat exchanger 21 is housed in the first storage chamber 38. In the present embodiment, in order to secure a space for accommodating the refrigerant pipe 45 inside the first accommodation chamber 38, the air heat exchanger 21 is located on the side of one side panel 35a between the side panels 35a and 35b of the front cover 27. It is biased to. As a result, a space is created between the air heat exchanger 21 and the other side panel 35b, and the refrigerant pipes 45 are concentratedly arranged in the space.

As shown in FIG. 3, the indoor unit 5 has a pair of connection ports 46a and 46b connected to the refrigerant pipe 45. The connection ports 46a and 46b penetrate the back panel 30 and project behind the housing 20, so that the liquid pipe 10a and the gas pipe 12a are connected to the connection ports 46a and 46b.

Further, as shown in FIG. 5, as the air heat exchanger 21 is offset to the side of one side panel 35a, the center C1 of the air heat exchanger 21 becomes the center C2 of the front panel 34 of the front cover 27. It is shifted sideways from. The center of the through hole 36 opened in the front panel 34 is located on an extension of the center C1 of the air heat exchanger 21.

As shown in FIGS. 4 and 5, the blower 22 is supported at the center of the front panel 34 of the housing 20. The blower 22 includes a cylindrical casing 50 and an impeller 51 housed inside the casing 50 as main elements.

The casing 50 has a first flange portion 52 and a second flange portion 53. The first flange portion 52 projects outward along the radial direction of the casing 50 at one end of the casing 50. The second flange portion 53 projects outward along the radial direction of the casing 50 at the other end of the casing 50. The first flange portion 52 is fixed to the front panel 34 with a plurality of screws at a position corresponding to the through hole 36.

The impeller 51 is rotatably supported by the casing 50 so as to be coaxially located on the extension line of the center C1 of the air heat exchanger 21. The boss portion 55 of the impeller 51 has a built-in motor 56 that rotates the impeller 51.

The control unit 23 is an element for controlling the air heat exchanger 21 and the blower 22, and is housed in the second storage chamber 39 of the housing 20. The control unit 23 includes various electrical components 58 such as a control board, a reactor and a plurality of terminal blocks. The electrical component 58 is supported on the upper part of the back panel 30.

As shown in FIGS. 4 and 6, a cylindrical attachment 60 is attached to the blower 22. The attachment 60 has a flange portion 61 at one end. The flange portion 61 is fixed to the second flange portion 53 of the blower 22 with a plurality of screws. As a result, the attachment 60 is coaxially projected from the casing 50 of the blower 22 toward the front of the housing 20.

A cylindrical ventilation register 62 is fitted in the attachment 60. The ventilation register 62 is an element for adjusting the amount of air blown from the blower 22 and arbitrarily changing the blowing direction, and is coaxially projected from the attachment 60 toward the front of the housing 20. ..

As shown in FIGS. 4 and 6, the duct portion 24 has a cylindrical outer cylinder 65. The outer cylinder 65 is an element that continuously covers the blower 22, the attachment 60, and the ventilation register 62, and a flange portion 66 is formed at one end along the axial direction thereof. The flange portion 66 is continuous in the circumferential direction of the outer cylinder 65 and projects outward along the radial direction of the outer cylinder 65. The flange portion 66 is detachably supported by the front panel 34 with a plurality of screws.

The outer cylinder 65 projects horizontally from the front panel 34 toward the front of the housing 20 while surrounding the blower 22, the attachment 60, and the ventilation register 62. As shown in FIG. 6, the axis O1 passing through the center of the outer cylinder 65 penetrates the center C1 of the air heat exchanger 21.

The protruding end of the outer cylinder 65 is located in front of the housing 20 with respect to the ventilation register 62. A guide wall 67 is formed at the protruding end of the outer cylinder 65. The guide wall 67 is continuous in the circumferential direction of the outer cylinder 65 and projects inward along the radial direction of the outer cylinder 65. The guide wall 67 defines a circular outlet 68 at the protruding end of the outer cylinder 65. The outlet 68 faces the blower 22 via the ventilation register 62.

As best shown in FIG. 6, the outer cylinder 65 of the duct portion 24 defines a ventilation passage 70 between the blower 22, the attachment 60 and the ventilation register 62. One end of the ventilation path 70 reaches the front panel 34 of the housing 20. The other end of the ventilation path 70 is closed by the guide wall 67.

A plurality of air return holes 71 are formed in the front panel 34 of the housing 20 facing one end of the ventilation passage 70. The air return hole 71 is located around the blower 22 and is opened in the first storage chamber 38 of the housing 20. Therefore, one end of the ventilation path 70 is communicated with the upstream side of the blower 22. Further, in the present embodiment, the inner surface of the outer cylinder 65 facing the ventilation passage 70 and the inner surface of the guide wall 67 are covered with the heat insulating material 72.

As shown in FIG. 7, the indoor unit assembly 3 having four indoor units 5 is installed on the outer peripheral portion of the existing pillar 80 which is the skeleton of the building 4 by using a dedicated support frame 81.

The pillar 80 is an example of a foundation structure and stands vertically from the floor surface F of the building 4. According to this embodiment, the pillar 80 is a square pillar having first to fourth surfaces 80a, 80b, 80c, 80d. The first to fourth surfaces 80a, 80b, 80c, and 80d face the work area A in the building 4 and are oriented in four different directions. The first to fourth surfaces 80a, 80b, 80c, and 80d are basically flat surfaces without unevenness, but there may be a large number of holes or a large number of dents.

In the present embodiment, the fire hydrant 82 is arranged at the lower part of the second surface 80b of the pillar 80. Further, a switchboard 83 is arranged below the third surface 80c of the pillar 80. The fire hydrant 82 and the switchboard 83 each project around the pillar 80.

As shown in FIGS. 8 and 9, the support frame 81 is selectively attached to the lower part of the first surface 80a of the pillar 80 so as to avoid the fire hydrant 82 and the switchboard 83. The area of the first surface 80a of the pillar 80 to which the support frame 81 is attached is covered with a plurality of covers 84. Each cover 84 is composed of, for example, a square flat metal plate, and is arranged in a row so as to be continuous in the height direction of the pillar 80.

The support frame 81 includes a first frame element 85 and a second frame element 86. The first frame element 85 is divided into a lower structure 87 and an upper structure 88.

The lower structure 87 of the first frame element 85 includes a pair of vertical rails 90a and 90b and a pair of horizontal rails 91a and 91b. The vertical rails 90a and 90b stand up along the pillar 80 at positions corresponding to both sides of the first surface 80a of the pillar 80 along the width direction. In other words, the vertical rails 90a and 90b are arranged parallel to each other with an interval in the width direction of the first surface 80a. The arrangement intervals of the vertical rails 90a and 90b substantially coincide with the width dimension of the first surface 80a.

The vertical rails 90a and 90b are made of angle steel having, for example, an L-shaped cross-sectional shape, and include a first support portion 92a and a second support portion 92b that are orthogonal to each other. The first support portion 92a and the second support portion 92b are elongated flat plate-shaped elements extending in the height direction of the pillar 80.

The first support portion 92a of the one vertical rail 90a stands upright so as to face the cover 84 that covers the first surface 80a of the pillar 80. The second support portion 92b of the one vertical rail 90a stands upright so as to be continuous with the second surface 80b of the pillar 80. Similarly, the first support portion 92a of the other vertical rail 90b stands upright so as to face the cover 84 covering the first surface 80a of the pillar 80. The second support portion 92b of the other vertical rail 90b stands upright so as to be continuous with the fourth surface 80d of the pillar 80.

The cross rails 91a and 91b are made of, for example, channel steel. One horizontal rail 91a is horizontally bridged between the upper ends of the vertical rails 90a and 90b. Both ends of the cross rail 91a along the longitudinal direction are connected to the upper ends of the vertical rails 90a and 90b with, for example, a plurality of screws or bolts.

The other horizontal rail 91b is horizontally bridged between the lower ends of the vertical rails 90a and 90b. Both ends of the cross rail 91b along the longitudinal direction are connected to the lower ends of the vertical rails 90a and 90b with, for example, a plurality of screws or bolts. As a result, the lower structure 87 is assembled in a square frame shape along the height direction of the pillar 80.

The cross rails 91a and 91b of the lower structure 87 are abutted against the cover 84 covering the first surface 80a, respectively, and are fixed to the first surface 80a by using fasteners 93 such as a plurality of screws. .. The fastener 93 penetrates the cross rails 91a and 91b and the cover 84 and is screwed into the pillar 80. Therefore, the cross rails 91a and 91b are connected to the pillar 80 together with the cover 84, and the cover 84 is interposed between the pillar 80 and the cross rails 91a and 91b.

As a result, the lower structure 87 of the first frame element 85 is held in a posture of standing vertically from the floor surface F of the building 4 so as to be along the first surface 80a of the pillar 80.

As shown in FIGS. 8, 9 and 11, the superstructure 88 of the first frame element 85 includes a pair of vertical rails 95a and 95b and one horizontal rail 96. The vertical rails 95a and 95b stand along the pillar 80 at positions corresponding to both sides of the first surface 80a of the pillar 80 along the width direction. In other words, the vertical rails 95a and 95b are arranged parallel to each other with an interval in the width direction of the first surface 80a of the pillar 80. The arrangement intervals of the vertical rails 95a and 95b substantially coincide with the width dimension of the first surface 80a.

The vertical rails 95a and 95b are made of angle steel having, for example, an L-shaped cross-sectional shape, and include a third support portion 98a and a fourth support portion 98b that are orthogonal to each other. The third support portion 98a and the fourth support portion 98b are flat plate-shaped elements extending in the height direction of the pillar 80.

The third support portion 98a of the one vertical rail 95a stands upright so as to face the cover 84 covering the first surface 80a. The fourth support portion 98b of the one vertical rail 95a stands upright so as to be continuous with the second surface 80b of the pillar 80. Similarly, the third support portion 98a of the other vertical rail 95b stands upright so as to face the cover 84 covering the first surface 80a. The fourth support portion 98b of the other vertical rail 95b stands upright so as to be continuous with the fourth surface 80d of the pillar 80.

The cross rail 96 is made of, for example, channel steel. The horizontal rail 96 is horizontally bridged between the upper ends of the vertical rails 95a and 95b. Both ends of the cross rail 96 along the longitudinal direction are connected to the upper ends of the vertical rails 95a and 95b with, for example, a plurality of screws or bolts.

The cross rail 96 of the upper structure 88 is abutted against the cover 84 covering the first surface 80a, and is fixed to the first surface 80a by using a plurality of fasteners 93 like the lower structure 87. .. The fastener 93 penetrates the cross rail 96 and the cover 84 and is screwed into the pillar 80. Therefore, the cross rail 96 is connected to the pillar 80 together with the cover 84, and the cover 84 is interposed between the pillar 80 and the cross rail 96.

As a result, the upper structure 88 of the first frame element 85 is held in a posture of standing vertically from the upper end of the lower structure 87 so as to be along the first surface 80a of the pillar 80.

Further, in the present embodiment, the lower ends of the vertical bars 95a and 95b of the upper structure 88 are fitted inside the upper ends of the vertical bars 90a and 90b of the lower structure 87, and for example, with a plurality of screws or bolts. It is connected to the vertical rails 90a and 90b. As a result, the lower structure 87 and the upper structure 88 are assembled as an integral structure.

As shown in FIGS. 8 and 12, the second frame element 86 is divided into a lower structure 100 and an upper structure 101. The lower structure 100 of the second frame element 86 includes a pair of vertical rails 102a and 102b, a pair of horizontal rails 103a and 103b, and two sets of support stays 111a and 111b. The vertical rails 102a and 102b stand up along the height direction of the pillar 80 at positions facing the vertical rails 90a and 90b constituting the lower structure 87 of the first frame element 85. Therefore, the vertical rails 102a and 102b are arranged in parallel with a distance from each other.

The vertical rails 102a and 102b are made of angle steel having, for example, an L-shaped cross-sectional shape, and include a fifth support portion 104a and a sixth support portion 104b that are orthogonal to each other. The fifth support portion 104a and the sixth support portion 104b are flat plate-shaped elements extending in the height direction of the pillar 80.

The fifth support portion 104a of the one vertical rail 102a stands upright so as to face the first support portion 92a of the vertical rail 90a. The sixth support portion 104b of the one vertical rail 102a stands at a position away from the second support portion 92b of the vertical rail 90a. Similarly, the fifth support portion 104a of the other vertical rail 102b stands upright so as to face the first support portion 92a of the vertical rail 90b. The sixth support portion 104b of the other vertical rail 102b stands at a position away from the second support portion 92b of the vertical rail 90b.

The cross rails 103a and 103b are made of, for example, channel steel. One horizontal rail 103a is horizontally bridged between the upper ends of the vertical rails 102a and 102b. Both ends of the cross rail 103a along the longitudinal direction are connected to the upper ends of the vertical rails 102a and 102b with, for example, a plurality of screws or bolts.

The other horizontal rail 103b is horizontally bridged between the lower ends of the vertical rails 102a and 102b. Both ends of the cross rail 103b along the longitudinal direction are connected to the lower ends of the vertical rails 102a and 102b with, for example, a plurality of screws or bolts. Therefore, the lower structure 100 is assembled in a square frame shape along the height direction of the pillar 80.

As shown in FIG. 12, the support stays 111a and 111b are each made of angle steel having an L-shaped cross-sectional shape, for example. One support stay 111a is bridged between the cross rail 103a and the cross rail 91a constituting the lower structure 87 of the first frame element 85. Both ends of the support stay 111a along the longitudinal direction are connected to the upper surface portions of the cross rails 103a and 91a by, for example, a plurality of screws or bolts.

The other support stay 111b is bridged between the cross rail 103b and the cross rail 91b constituting the lower structure 87 of the first frame element 85. Both ends of the support stay 111b along the longitudinal direction are connected to the upper surface portions of the cross rails 103b and 91b with, for example, a plurality of screws or bolts. Therefore, the lower structure 100 of the second frame element 86 is fixed to the lower structure 87 of the first frame element 85.

As shown in FIGS. 8, 9 and 12, the superstructure 101 of the second frame element 86 has a pair of front vertical rails 106a and 106b, a pair of rear vertical rails 106c and 106d, and a pair of horizontal rails. It is provided with crosspieces 107a and 107b and a set of support stays 111c.

The rear vertical rails 106c and 106d stand up along the height direction of the pillar 80 at positions facing the vertical rails 95a and 95b constituting the superstructure 87 of the first frame element 85. Therefore, the rear vertical rails 106c and 106d are arranged in parallel with a distance from each other.

The rear vertical rails 106c and 106d are made of angle steel having, for example, an L-shaped cross-sectional shape, and include a seventh support portion 110a and an eighth support portion 110b that are orthogonal to each other. The seventh support portion 110a and the eighth support portion 110b are flat plate-shaped elements extending in the height direction of the pillar 80.

On the other hand, the seventh support portion 110a of the rear vertical rail 106c stands upright facing the third support portion 98a of the vertical rail 95a. On the other hand, the eighth support portion 110b of the rear vertical rail 106c stands so as to be aligned with the fourth support portion 98b of the vertical rail 95a. Similarly, the seventh support portion 110a of the other rear vertical rail 106d stands upright facing the third support portion 98a of the vertical rail 95b. The eighth support portion 110b of the other rear vertical rail 106d stands so as to be aligned with the fourth support portion 98b of the vertical rail 95b.

The rear vertical rails 106c and 106d are respectively connected to the vertical rails 95a and 95b constituting the superstructure 87 of the first frame element 85 by, for example, a plurality of screws or bolts.

The front vertical rails 106a and 106b stand upright along the height direction of the pillar 80 at positions facing the rear vertical rails 106c and 106d. Therefore, the front vertical rails 106a and 106b are arranged in parallel with a distance from each other.

Like the rear vertical rails 106c and 106d, the front vertical rails 106a and 106b are made of angle steel having, for example, an L-shaped cross-sectional shape, and the seventh support portion 110a and the eighth support portion 110b are orthogonal to each other. Includes. The seventh support portion 110a and the eighth support portion 110b are flat plate-shaped elements extending in the height direction of the pillar 80.

The seventh support portion 110a of the one front vertical rail 106a stands so as to face the seventh support portion 110a of the rear vertical rail 106c. The eighth support portion 110b of the one front vertical rail 106a stands at a position away from the eighth support portion 110b of the rear vertical rail 106c. Similarly, the seventh support portion 110a of the other front vertical rail 106b stands upright so as to face the seventh support portion 110a of the rear vertical rail 106d. The eighth support portion 110b of the other front vertical rail 106b stands at a position away from the eighth support portion 110b of the rear vertical rail 106d.

The cross rails 107a and 107b are made of, for example, channel steel. One horizontal rail 107a is horizontally bridged between the upper ends of the front vertical rails 106a and 106b. Both ends of the cross rail 107a along the longitudinal direction are connected to the upper ends of the front vertical rails 106a and 106b with, for example, a plurality of screws or bolts.

The other vertical rail 107b is horizontally bridged between the intermediate portions of the front vertical rails 106a and 106b. Both ends of the cross rail 107b along the longitudinal direction are connected to the intermediate portions of the front vertical rails 106a and 106b with, for example, a plurality of screws or bolts. As a result, the superstructure 101 is assembled in a square frame shape along the height direction of the pillar 80.

As shown in FIG. 8, the lower end portions of the front vertical rails 106a and 106b of the upper structure 101 are fitted inside the upper end portions of the vertical rails 102a and 102b of the lower structure 100, and for example, a plurality of screws or It is connected to the vertical rails 102a and 102b with bolts.

As shown in FIG. 12, the support stay 111c is made of angle steel having an L-shaped cross-sectional shape, for example, like the support stays 111a and 111b. The support stay 111c is bridged between the cross rail 107a and the cross rail 96 constituting the superstructure 88 of the first frame element 85. Both ends of the support stay 111c along the longitudinal direction are connected to the upper surface portions of the cross rails 107a and 96 by a plurality of screws or bolts.

As shown in FIGS. 8 and 9, the front vertical rails 106a and 106b each include a pair of support stays 112. The support stay 112 is made of, for example, channel steel. The support stays 112 are separated from each other in the longitudinal direction of the front vertical rails 106a and 106b, and are connected to the vertical rails 106a and 106b with, for example, a plurality of screws or bolts.

The support stay 112 is horizontally projected from the front vertical rails 106a and 106b toward the rear vertical rails 106c and 106d. The protruding end of the support stay 112 is connected to the rear vertical rails 106c, 106d by, for example, a plurality of screws or bolts.

As a result, the second frame element 86 is separated from the first frame element 85 by a distance corresponding to the length of the support stay 112, and the fifth support portion 104a and the front vertical rail of the vertical rails 102a and 102b. The seventh support portion 110a of the 106a and 106b is arranged in parallel with the first surface 80a of the pillar 80.

As shown in FIGS. 8, 9 and 12, a pair of fixing members 120a and 120b for receiving the brackets 40a and 40b of the indoor unit 5 are attached to the seventh support portion 110a of the front vertical rails 106a and 106b. ing. The fixing members 120a and 120b are made of angle steel having, for example, an L-shaped cross-sectional shape, and each has a ninth support portion 121a. The ninth support portion 121a is a flat plate-shaped element extending in the height direction of the pillar 80, and is located on the front side of the front vertical rails 106a and 106b.

As shown in FIG. 7, the indoor unit assembly 3 having the four indoor units 5 is detachably supported by the superstructure 101 of the second frame element 86. Specifically, the brackets 40a and 40b of each indoor unit 5 are fixed to the ninth support portion 121a of the fixing members 120a and 120b with, for example, a plurality of screws or bolts. As a result, the four indoor units 5 are lined up in a row along the height direction of the pillar 80, and the back panel 30 of the housing 20 of each indoor unit 5 covers the first surface 80a of the pillar 80. Facing the cover 84.

As shown in FIG. 9, when the indoor unit 5 is fixed to the superstructure 101 of the second frame element 86, the duct portion 24 of the indoor unit 5 is horizontal in the direction away from the first surface 80a of the pillar 80. Is protruding to.

At the same time, the housing 20 of the four indoor units 5 is separated from the first surface 80a of the pillar 80, and there is a gap between the back panel 30 of the housing 20 and the cover 84 covering the first surface 80a. G is formed. The gap G has an elongated shape extending in the height direction of the pillar 80.

As shown in FIG. 7, a plurality of side panels 131, one front panel 132, one top cover 133, and one filter 134 are attached to the support frame 81. The side panel 131, the front panel 132, the top cover 133, and the filter 134 are examples of exterior panels, respectively.

The side panel 131 is provided between the second support portion 92b of the vertical rails 90a and 90b of the first frame element 85 and the sixth support portion 104b of the vertical rails 102a and 102b of the second frame element 86, as well as the first. A plurality of screws so as to straddle between the fourth support portion 98b of the vertical rails 95a and 95b of the frame element 85 and the eighth support portion 110b of the front vertical rails 106a and 106b of the second frame element 86. Alternatively, it is attached to the support frame 81 with bolts. The side panels 131 are lined up in a row along the height direction of the pillar 80 and face each other with a gap G in between.

The front panel 132 is a square plate-shaped element, and is a front surface of a fifth support portion 104a of the vertical rails 102a, 102b so as to straddle between the vertical rails 102a, 102b constituting the second frame element 86. For example, it is attached with multiple screws or bolts. Therefore, the front panel 132 is located below the indoor unit assembly 3. The gap between the indoor unit assembly 3 and the front panel 132 is closed by the cross rail 103a of the second frame element 86.

The top cover 133 is straddled between the upper end of the upper structure 88 of the first frame element 85 and the upper end of the upper structure 101 of the second frame element 86, for example, using a plurality of screws or bolts. It is attached to the support frame 81. The top cover 133 is continuous with the upper end of the side panel 131 located at the uppermost position and the housing 20 of the uppermost indoor unit 5 without a gap.

The filter 134 is compatible with the front panel 132. The filter 134 includes a square outer frame 135 and a filter element 136 for filtering air. The outer frame 135 is attached to the front surface of the fifth support portion 104a of the vertical rails 102a, 102b so as to straddle between the vertical rails 102a, 102b constituting the second frame element 86, for example, with a plurality of screws or bolts. Has been done. The upper edge of the outer frame 135 is abutted tightly against the lower edge of the front panel 132. The gap between the lower edge of the outer frame 135 and the floor surface F of the building 4 is closed by a baseboard 137.

The filter element 136 is a square plate-shaped element, which is detachably supported by the outer frame 135.

The side panel 131, the front panel 132, the top cover 133, and the filter 134 surround the gap G to define an air passage 200 as shown in FIG. 9 with the pillar 80. The air passage 200 stands up along the pillar 80. The air passage 200 is partitioned from the work area A inside the building 4 and leads to the work area A via the filter 134.

The cover 84 that covers the first surface 80a of the pillar 80 is exposed to the air passage 200 and constitutes a part of the inner wall surface of the air passage 200. Further, the suction ports 32 of all the indoor units 5 are opened in the air passage 200.

The air passage 200 is a harness electrically connected to a liquid pipe 7 and a gas pipe 8 connected to the indoor unit 5, a drain pipe 123 connected to the drain port 33 of the indoor unit 5, and a control unit 23 of the indoor unit 5. It also functions as a space for passing the 124. The liquid pipe 7, the gas pipe 8, the drain pipe 123, and the harness 124 are routed from the air passage 200 through the upper wall of the top cover 133 to the upper part of the pillar 80.

Next, a procedure for installing the indoor unit assembly 3 on the pillar 80 using the support frame 81 will be described.

First, as shown in FIG. 10, the lower structure 87 of the first frame element 85 is fixed to the lower part of the first surface 80a of the pillar 80 together with the plurality of covers 84. Subsequently, as shown in FIG. 11, the lower end of the upper structure 88 of the first frame element 85 is connected to the upper end of the lower structure 87, and the upper structure 88 is connected to the first of the pillar 80 together with the plurality of covers 84. It is fixed to the surface 80a of. As a result, the first frame element 85 of the support frame 81 is directly attached to the first surface 80a of the pillar 80 in a form of standing up along the pillar 80.

After that, as shown in FIG. 12, the lower structure 100 of the second frame element 86 and the lower structure 87 of the first frame element 85 are connected by the support stays 111a and 111b.

Subsequently, the rear vertical rails 106c and 106d constituting the superstructure 101 of the second frame element 86 are fixed to the vertical rails 95a and 95b constituting the superstructure 88 of the first frame element 85.

After that, the front vertical rails 106a, 106b constituting the upper structure 101 of the second frame element 86 are placed on the rear vertical rails 106c, via a plurality of support stays 112 protruding from the front vertical rails 106a, 106b. Combine with 106d.

After that, the fixing members 120a and 120b are fixed to the front vertical rails 106a and 106b constituting the upper structure 101 of the second frame element 86.

As a result, the second frame element 86 is directly attached to the pillar 80 in a form protruding from the first surface 80a of the pillar 80, and the assembly of the support frame 81 to the pillar 80 is completed.

After that, as shown in FIG. 13, a plurality of indoor units 5 are attached to the superstructure 101 of the second frame element 86 one by one. Specifically, the brackets 40a and 40b of the indoor unit 5 are attached to the ninth support portion 121a of the fixing members 120a and 120b with, for example, a plurality of screws or bolts.

FIG. 14 shows a state in which the four indoor units 5 are attached to the superstructure 101 of the second frame element 86. The four indoor units 5 are arranged in a row along the height direction of the pillar 80.

After the attachment of the four indoor units 5 to the superstructure 101 is completed, the side panel 131, the front panel 132, the top cover 133, and the filter 134 are attached to the support frame 81.

As a result, as shown in FIG. 7, the installation work of the indoor unit assembly 3 on the pillar 80 is completed.

In such a first embodiment, when the indoor unit 5 of the indoor unit assembly 3 starts operating, the blower 22 of the indoor unit 5 sucks the air in the first accommodation chamber 38 of the housing 20 through the through hole 36. .. As a result, a negative pressure acts on the suction port 32 of the housing 20.

Since the suction port 32 is opened in the air passage 200 partitioned between the pillar 80 and the housing 20, the air inside the building 4 is sucked into the air passage 200 through the filter 134. The filter 134 is attached to the lower structure 100 of the second frame element 86 so as to be located below the indoor unit assembly 3. Therefore, the air near the floor surface F of the work area A is sucked into the air passage 200.

The air sucked into the blower 22 from the air passage 200 passes through the air heat exchanger 21. The air heat exchanger 21 converts the air toward the blower 22 into cold or warm air by exchanging heat between the air toward the blower 22 and the refrigerant flowing through the heat transfer tube 44. After passing through the ventilation register 62, the heat-exchanged air is blown out horizontally from the outlet 68 of the duct portion 24 toward the work area A.

As a result, the heat-exchanged air can be sent to the work area A from the side of the first surface 80a of the pillar 80, and local air conditioning of the work area A or stratified air conditioning using the pillar 80 becomes possible. ..

According to the present embodiment, a part of the air passing through the ventilation register 62 and heading toward the outlet 68 is guided to the ventilation passage 70 by the guide wall 67 defining the outlet 68, as shown by the broken line arrow in FIG. Will be done. The ventilation passage 70 leads to the upstream side of the blower 21 through the air return hole 71 opened in the front surface of the housing 20. Therefore, the air guided to the ventilation passage 70 is sucked into the blower 22 from the air return hole 71 via the first accommodation chamber 38.

As a result, a part of the air that has passed through the ventilation register 62 returns to the direction of the housing 20 through the ventilation passage 70. In other words, the outer peripheral surface of the ventilation register 62 is directly exposed to the flow of air exchanged by the air heat exchanger 21, and the temperature difference between the outer peripheral surface and the inner peripheral surface of the ventilation register 62 is small. Become.

As a result, for example, under high temperature and high humidity conditions, even if the cold air accompanying the cooling operation passes through the ventilation register 62, dew condensation is less likely to occur on the outer peripheral surface of the ventilation register 62. In addition, since the inner surface of the outer cylinder 65 facing the ventilation passage 70 and the inner surface of the guide wall 67 are covered with the heat insulating material 72, it is possible to prevent dew condensation from forming on the outer peripheral surface of the outer cylinder 65.

Therefore, it is possible to prevent so-called water droplets from being blown out from the outlet 68 of the duct portion 24 during the cooling operation, and to avoid the phenomenon that water droplets are dropped from the outer cylinder 65.

According to the first embodiment, the support frame 81 for fixing the four indoor units 5 to the pillar 80 is directly attached to the first surface 80a of the pillar 80 together with the cover 84. Therefore, even when the fire hydrant 82 is arranged on the second surface 80b of the pillar 80 or the switchboard 83 is arranged on the third surface 80c, the indoor unit 5 can be installed on the pillar 80.

In other words, the first surface 80a of the pillar 80 detached from the fire hydrant 82 or the switchboard 83 can be selected as the installation surface of the support frame 81, and the fire hydrant 82 or the switchboard 83 interferes with the assembly of the support frame 81 to the pillar 80. It doesn't have to be. Therefore, the degree of freedom in installing the indoor unit 5 on the pillar 80 is improved, and the air conditioner 1 having excellent versatility can be provided.

Moreover, in the present embodiment, the support frame 81 is directly attached to the first surface 80a of the pillar 80 together with the plurality of covers 84, and the cover 84 constitutes a part of the inner wall surface of the air passage 200. ..

According to this configuration, for example, the pillar 80 adopts a truss structure, or a hollow structure having a large number of holes in the first to fourth surfaces 80a, 80b, 80c, 80d of the pillar 80. Even if it is, the space inside the pillar 80 and the air passage 200 can be partitioned by the cover 84.

As a result, it is possible to prevent the air inside the pillar 80 from directly flowing into the air passage 200 without passing through the filter 134 when the indoor unit 5 is in operation. As a result, the indoor unit 5 sucks in the air purified by the filter 134, so that it becomes difficult for dust to adhere to the air heat exchanger 21 of the indoor unit 5.

In addition, since the metal cover 84 interposed between the support frame 81 and the pillar 80 functions as a kind of strength member, both the pillar 80 and the support frame 81 can be used by using the cover 84. Can be reinforced. Therefore, the indoor unit assembly 3 having the four indoor units 5 can be firmly fixed to the pillar 80, and sufficient vibration resistance can be secured.

The indoor unit assembly 3 is not limited to being attached to the superstructure 101 of the second frame element 86. For example, the indoor unit assembly 3 may be attached to the lower structure 100 of the second frame element 86, and the front panel 132 and the filter 134 may be attached to the upper structure 101 of the second frame element 86.

According to this configuration, the four indoor units 5 are arranged in a row from the floor surface F of the building 4 along the height direction of the pillar 80, so that the air conditioned by the indoor unit 5 is used in the work area A. It can be blown out in parallel with the floor surface F from a low position. As a result, stratified air conditioning that pushes up the air accumulated in the vicinity of the floor surface F toward the upper side of the building 4 becomes possible, and the temperature difference in the entire work area A can be suppressed to a small extent.

In the first embodiment, the indoor unit assembly 3 is installed on the first surface 80a of the pillar 80 via the support frame 81, but the present invention is not limited thereto.

For example, when the fourth surface 80d of the pillar 80 detached from the fire hydrant 82 or the switchboard 83 faces the work area A, the indoor unit assembly 3 is installed on the fourth surface 80d using another support frame 81. You may. That is, the air conditioned in two directions may be blown out around the pillar 80, and the air blowing direction is not particularly limited.

Further, there are no particular restrictions on the positions of the indoor unit 5, the front panel 132, and the filter 134 with respect to the pillar 80, and the indoor unit 5 is, for example, depending on the position of the fire hydrant 82 attached to the pillar 80 or the environment of the work area A to be air-conditioned. , The positions of the front panel 132 and the filter 134 can be appropriately changed in the height direction of the pillar 80.

[Second Embodiment]
15 and 16 disclose a second embodiment.

The second embodiment is different from the first embodiment in that the outdoor unit assembly 3 having the four indoor units 5 is pre-assembled as an integral structure before being installed on the pillar 80. Other than this, the configuration of the outdoor unit assembly 3 is the same as that of the first embodiment.

As shown in FIG. 15, in the four indoor units 5, the brackets 40a and 40b projecting from both side portions of the respective housings 20 form the fixing members 120a and 120b of the upper structure 101 of the second frame element 86. It is fixed with multiple screws or bolts.

At this time, it is in a state of being separated from the fixing members 120a and 120b and the superstructure 101, and exhibits a function as a kind of subframe for connecting the four indoor units 5.

Therefore, the four indoor units 5 are supported by the fixing members 120a and 120b in a state of being arranged in a row in the longitudinal direction of the fixing members 120a and 120b, and are assembled as one sub-assembly 300.

As shown in FIG. 16, the sub-assembly 300 in which the four indoor units 5 are fixed to the fixing members 120a and 120b is assembled to the support frame 81 previously attached to the pillar 80.

According to the second embodiment, in the stage before incorporating the four indoor units 5 into the pillar 80, the four indoor units 5 are assembled as an integral structure using the fixing members 120a and 120b. Therefore, in comparison with the case where the four indoor units 5 are assembled to the support frame 81 one by one, the positions of the indoor units 5 can be easily adjusted to each other, and the four indoor units 5 whose positions have been adjusted can be easily adjusted. Can be installed on the pillar 80 at a time.

Therefore, workability when installing the four indoor units 5 on the pillar 80 is improved.

[Third Embodiment]
17 to 19 disclose a third embodiment.

The third embodiment is different from the first embodiment in that four indoor units 5 are fixed to the support frame 81 before the support frame 81 is attached to the first surface 80a of the pillar 80. is doing.

As shown in FIG. 17, the four indoor units 5 are fixed to the superstructure 101 of the second frame element 86 in a row. At the time when the indoor unit 5 is fixed to the superstructure 101, the second frame element 86 is coupled to the first frame element 85 via the support stay 112.

In the present embodiment, the plurality of side panels 131 are previously placed between the vertical bars 90a and 90b of the first frame element 85 and the vertical bars 102a and 102b of the second frame element 86, and the vertical bars of the first frame element 85. A plurality of screws or bolts are attached to the support frame 81 so as to straddle between the rails 95a and 95b and the front vertical rails 106a and 106b of the second frame element 86.

Further, the plurality of covers 84 are also temporarily fixed to the first frame element 85 of the support frame 81.

As shown in FIG. 18, the support frame 81 to which the four indoor units 5, the plurality of covers 84, and the plurality of side panels 131 are attached is in an upright posture along the first surface 80a of the pillar 80. It is abutted against the surface 80a of 1. In this state, the cross rails 91a and 91b constituting the lower structure 87 of the first frame element 85 are between the vertical rails 102a and 102b constituting the lower structure 100 of the second frame element 86 of the pillar 80. It is exposed to the surroundings.

Similarly, the cross rail 96 constituting the superstructure 88 of the first frame element 85 is connected to the pillar 80 from between the upper ends of the front vertical rails 106a and 106b constituting the superstructure 101 of the second frame element 86. Is exposed to the surroundings. Therefore, the cross rails 91a, 91b, 96 are fixed to the first surface 80a of the pillar 80 together with the cover 84 by using a plurality of screws or bolts, respectively.

After that, as shown in FIG. 19, the front panel 132, the top cover 133, and the filter 134 are attached to the support frame 81 standing upright along the pillar 80. This completes the installation work of the indoor unit assembly 3 having the four indoor units 5.

According to the third embodiment, the support frame 81 itself can be assembled in a place different from the work space A, and four indoor units 5 can be attached to the support frame 81.

Therefore, the assembly work of the support frame 81 and the attachment work of the indoor unit 5 to the support frame 81 can be easily performed. Further, the support frame 81 and the indoor unit 5 can be collectively incorporated into the pillar 80, and the workability is improved.

[Fourth Embodiment]
FIG. 20 discloses a fourth embodiment.

In the fourth embodiment, the indoor unit assembly 3 includes two indoor units 5. The two indoor units 5 are attached to the fixing members 120a and 120b of the second frame element 86. The indoor unit 5 is arranged in the height direction of the pillar 80 in the lower half region along the height direction of the superstructure 101 of the second frame element 86.

In the present embodiment, since the two indoor units 5 are offset to the lower half region along the height direction of the upper structure 101, the other indoor units 5 are located in the upper half region along the height direction of the fixing members 120a and 120b. The front panel 150 is attached. The front panel 150 is attached to the fixing members 120a and 120b so as to be located between the upper indoor unit 5 and the top cover 133.

In the fourth embodiment, the other front panel 150 is attached to the upper half region along the height direction of the superstructure 101, but the filter 134 may be attached instead of the front panel 150.

[Fifth Embodiment]
21 to 23 disclose a fifth embodiment.

In the air conditioner 1 according to the fifth embodiment, the first to fourth indoor unit assemblies 3a, 3b, 3c, 3d are installed on the first to fourth surfaces 80a, 80b, 80c, 80d of the pillar 80. The point is different from the first embodiment.

The first to fourth indoor unit assemblies 3a, 3b, 3c, and 3d each include four indoor units 5. Further, the first to fourth indoor unit assemblies 3a, 3b, 3c, 3d each use the same support frame 81 as in the first embodiment, and the first to fourth surfaces 80a, 80b, 80c of the pillar 80 are used. , 80d is supported. Since the configuration in which the support frame 81 is attached to the pillar 80 is the same as that in the first embodiment, the same reference numerals as those in the first embodiment are added, and the description thereof will be omitted.

FIG. 21 shows the piping system of the air conditioner 1 provided with the first to fourth indoor unit assemblies 3a, 3b, 3c, 3d. The liquid pipe 7 connected to the outdoor unit 2 is branched into the first to fourth liquid component pipes 7a, 7b, 7c, 7d via the first branch header 400. The gas pipe 8 connected to the outdoor unit 2 is branched into the first to fourth gas distribution pipes 8a, 8b, 8c, 8d via the second branch header 401. The first to fourth liquid component pipes 7a, 7b, 7c, 7d and the first to fourth gas component pipes 8a, 8b, 8c, 8d are individually the first to fourth indoor unit assemblies 3a, 3b, It is guided to 3c and 3d.

The first to fourth liquid distribution pipes 7a, 7b, 7c, 7d each have four liquid pipes 10a, 10b, 10c, 10d branched by three Y-shaped branch joints 9a, 9b, 9c. There is. The liquid tubes 10a, 10b, 10c, and 10d are connected to the indoor unit 5, respectively.

Similarly, the first to fourth gas distribution pipes 8a, 8b, 8c, 8d have four gas pipes 12a, 12b, 12c, 12d branched by three T-shaped branch joints 11a, 11b, 11c, respectively. Have. The gas pipes 12a, 12b, 12c, and 12d are each connected to the indoor unit 5.

Therefore, the refrigerant compressed by the outdoor unit 2 is distributed to the indoor units 5 of the first to fourth indoor unit assemblies 3a, 3b, 3c, and 3d, and the refrigerant discharged from the indoor unit 5 is again outdoors. It is designed to be returned to Machine 2.

Further, the first to fourth indoor unit assemblies 3a, 3b, 3c, 3d each include remote controllers 13a, 13b, 13c, 13d. In the first to fourth indoor unit assemblies 3a, 3b, 3c, 3d, various operations such as operation / stop, temperature setting, and operation switching of the indoor unit 5 are performed by the remote controllers 13a, 13b, 13c, 13d for each assembly. Is feasible.

As shown in FIGS. 22 and 23, the first indoor unit assembly 3a is installed on the first surface 80a of the pillar 80 via the support frame 81. The four indoor units 5 included in the first indoor unit assembly 3a are arranged in a row in the height direction of the pillar 80 along the first surface 80a. Further, a plurality of side panels 131, a front panel 132, a top cover 133, a filter 134, and a skirting board 137 are attached to the support frame 81 corresponding to the first indoor unit assembly 3a.

The second indoor unit assembly 3b is installed on the second surface 80b of the pillar 80 via the support frame 81. The four indoor units 5 included in the second indoor unit assembly 3b are arranged in a row in the height direction of the pillar 80 along the second surface 80b. Further, a plurality of side panels 131, a front panel 132, a top cover 133, a filter 134, and a skirting board 137 are attached to the support frame 81 corresponding to the second indoor unit assembly 3b.

The third indoor unit assembly 3c is installed on the third surface 80c of the pillar 80 via the support frame 81. The four indoor units 5 included in the third indoor unit assembly 3c are arranged in a row in the height direction of the pillar 80 along the third surface 80c. Further, a plurality of side panels 131, a front panel 132, a top cover 133, a filter 134, and a skirting board 137 are attached to the support frame 81 corresponding to the third indoor unit assembly 3c.

The fourth indoor unit assembly 3d is installed on the fourth surface 80d of the pillar 80 via the support frame 81. The four indoor units 5 included in the fourth indoor unit assembly 3d are arranged in a row in the height direction of the pillar 80 along the fourth surface 80d. Further, a plurality of side panels 131, a front panel 132, a top cover 133, a filter 134, and a skirting board 137 are attached to the support frame 81 corresponding to the fourth indoor unit assembly 3d.

Therefore, when the first to fourth indoor unit assemblies 3a, 3b, 3c, and 3d are installed on the pillar 80, the duct portions 24 of the 16 indoor units 5 are directed in four directions centered on the pillar 80. It is projected radially.

Although some embodiments of the present invention have been described, these embodiments are presented as examples and are not intended to limit the scope of the invention. These novel embodiments can be implemented in various other embodiments, and various omissions, replacements, and changes can be made without departing from the gist of the invention. These embodiments and variations thereof are included in the scope and gist of the invention, and are also included in the scope of the invention described in the claims and the equivalent scope thereof.

For example, the foundation structure is not limited to the pillars of the building, and may be beams or braces straddling between adjacent pillars.

Furthermore, the foundation structure is not specified by the columns and beams that form the skeleton of the building, but stands up from the dedicated columns or the floor of the building that are erected from the floor of the building to support the indoor unit assembly. It may be a wall surface.

At the same time, the pillar, which is an example of the foundation structure, is not limited to a square pillar, and may be composed of, for example, H-shaped steel or I-shaped steel, or may be configured by combining a plurality of shaped steels.

1 ... Air conditioner, 5 ... Indoor unit, 21 ... Air heat exchanger, 22 ... Blower, 32 ... Suction port, 80 ... Basic structure (pillar), 80a, 80b, 80c, 80d ... First to fourth Surface, 81 ... Support frame, 131, 132, 133, 134 ... Exterior panel (side panel, front panel, top cover, filter), 200 ... Air passage, A ... Space to be air-conditioned (work area).

Claims (2)

A support frame attached to at least one surface of the foundation structure of the space to be air-conditioned,
It has a heat exchanger and a blower that face the surface of the basic structure and are supported by the support frame along the basic structure to exchange heat between the refrigerant and air, and for heat exchange. Multiple indoor units with suction ports for sucking in air, and
A plurality of exterior panels attached to the support frame and defining an air passage partitioned from the space between the indoor unit and the surface of the foundation structure.
A filter provided so as to face the air passage and
A cover that covers the area of the surface of the foundation structure to which the support frame is attached, is exposed to the air passage, and forms a part of the inner wall surface of the air passage.
Including
The support frame has a first frame element fixed to the surface of the foundation structure together with the cover, and is arranged parallel to the surface of the foundation structure away from the surface of the foundation structure than the first frame element. A second frame element is provided, and a subframe in which a plurality of the indoor units are connected and attached to the second frame element is provided.
An air conditioner in which the air in the space is sucked into the air passage through the filter when the suction port of the indoor unit is opened in the air passage and the blower of the indoor unit is operated. The air according to claim 1, wherein the support frame extends along the height direction of the foundation structure, and a plurality of the indoor units are supported in a row in the height direction on the support frame. Harmonizer.

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