JP2016153709A - Building air conditioning structure and process of manufacture of air conditioning structure - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide a building air conditioning structure and a process of manufacture of air conditioning structure in which a connecting chamber construction work can be facilitated under a constitution where the connecting part between an air conditioner and an air conditioning duct is provided with the connecting chamber.SOLUTION: A certain building unit of buildings is provided with a machine room 33. An air conditioning system comprises an air conditioning device 51 installed on a floor surface 58 of the machine room 33, an air conditioning duct 52 arranged at an attic space 49 for transporting the conditioned air generated by the air conditioning device 51 into an indoor space, and a connecting chamber 70 arranged at the machine room 33 to connect the air conditioning device 51 with the air conditioning duct 52. The connecting chamber 70 has a plurality of plate-like heat insulators 72, 73, 75 to 78 arranged to enclose a chamber inner space 71. The plurality of heat insulators comprise an upper heat insulator 72 arranged at a ceiling surface 56 and a left side heat insulator 73 arranged at wall surfaces 63a, 63c, a right side heat insulator and a rear side heat insulator 75.SELECTED DRAWING: Figure 2

Description

  The present invention relates to an air conditioning structure for a building and a method for manufacturing the air conditioning structure.

  2. Description of the Related Art Conventionally, a unit type building constructed by combining a plurality of building units with each other is known. In a unit type building, each building unit is manufactured in advance in a manufacturing factory, and then transported to a construction site by a truck or the like. And in a construction site, a building is constructed | assembled by those building units being mutually combined.

  In such a unit type building, there is a case in which a whole building air conditioning system that performs whole building air conditioning using a common air conditioner is provided (for example, see Patent Document 1). In a building provided with a whole building air conditioning system, there may be a machine room in which an air conditioner is installed. FIG. 8 shows the configuration around the machine room, and the configuration of the entire building air conditioning system will be described below with reference to FIG.

  As shown in FIG. 8A, the air conditioning system includes an air conditioner 92 installed on the floor surface of the machine room 91, a connection duct 93 connected to the air conditioner 92, and a connection connected to the connection duct 93. A chamber 94 and an air conditioning duct 95 connected to the connection chamber 94 are provided. The connection duct 93 extends upward from the air conditioner 92, and a connection chamber 94 is connected to an upper end portion thereof. The connection chamber 94 is installed near the ceiling in the machine room 91. The connection chamber 94 is supported from below by a pair of brackets 99 protruding from the wall surface of the machine room 91.

  The air conditioning duct 95 is disposed in an attic space 97 above the corridor 96 provided adjacent to the machine room 91. The conditioned air generated by the air conditioner 92 is supplied to the air conditioning duct 95 via the connection duct 93 and the connection chamber 94. Then, the conditioned air is then conveyed through the air conditioning duct 95 to the living room space to be air conditioned.

  The machine room 91 is provided with an air conditioner 92, a connection duct 93, and a connection chamber 94. These members 92 to 94 are installed in the machine room 91 after the building unit is installed at the construction site. Is done. And after these members 92-94 are installed in the machine room 91, the air-conditioning duct 95 is installed in the attic space 97, and the air-conditioning duct 95 and the connection chamber 94 are connected.

  Here, the installation work of the connection chamber 94 in the machine room 91 will be described with reference to FIG. As shown in FIG. 8B, when installing the connection chamber 94, the connection chamber 94 is installed so as to be lifted above the brackets 99 and bridged on the brackets 99. Then, the connection chamber 94 is fixed by being fitted into a fixing portion (not shown) provided on the bracket 99.

JP 2010-181120 A

  However, the above-described operation of lifting the connection chamber 94 and installing the connection chamber 94 on the bracket 99 is an operation of looking up upward, and is considered to have a large work load. In particular, the operation of fitting the connection chamber 94 into the fixed portion while looking upward is an operation in a state in which it is difficult to see, so the work load is considered to be significantly increased. For this reason, it is considered that there is room for improvement regarding the construction of the connection chamber 94 on site.

  The present invention has been made in view of the above circumstances, and has a configuration in which a connection chamber is provided in a connection portion that connects an air conditioner and an air conditioning duct, and the construction work of the connection chamber can be facilitated. The main purpose is to provide an air conditioning structure for a building and a method for manufacturing the air conditioning structure.

  In order to solve the above-mentioned problem, the air conditioning structure of a building of the first invention is constructed by combining a plurality of building units with each other, and one of the building units includes a floor surface and a ceiling surface. Applied to a unit type building provided with a machine room surrounded by a wall surface, installed in the machine room on the floor surface, installed on the back of the ceiling, and generated by the air conditioner An air-conditioning duct that conveys conditioned air to a room to be air-conditioned, and a connection chamber that is provided above the air-conditioning apparatus in the machine room and that constitutes a connection portion that connects the air-conditioning apparatus and the air-conditioning duct. In the air conditioning structure of a building, the connection chamber is provided across the ceiling surface and the wall surface, and a space in the chamber through which the conditioned air flows and A plurality of plate-like heat insulating materials provided surrounding the inner space, and the plurality of heat insulating materials include a ceiling heat insulating material provided on the ceiling surface and a wall provided on the wall surface. Insulating material is included.

  According to the present invention, the connection chamber is formed by including the chamber inner space through which the conditioned air flows and the plurality of plate-like heat insulating materials provided to surround the chamber inner space. Can be suitably secured. In addition, the connection chamber is provided across the ceiling surface and the wall surface in the machine room, and the plurality of heat insulating materials constituting the connection chamber include a ceiling heat insulating material provided on the ceiling surface of the machine room, And a wall insulating material provided on the wall surface of the machine room. In this case, since these heat insulating materials can be previously attached to the ceiling surface and the wall surface of the machine room (within the building unit) at the unit manufacturing factory, a part of the connection chamber is previously stored at the unit manufacturing factory. Manufacturable (can be assembled). Insulation materials that are not installed at the unit manufacturing plant will be assembled at the construction site, but the assembly work is done by lifting the connection chamber onto the bracket and fitting it into the fixed part while looking upward. This can be done more easily than Therefore, in this case, the construction work of the connection chamber on site can be facilitated.

  In the air conditioning structure of a building according to a second aspect of the present invention, in the first aspect, the connection chamber is provided across the wall surfaces provided in three directions of the machine room, and the plurality of heat insulating materials Includes a plurality of the wall heat insulating materials provided on the respective wall surfaces.

  According to the present invention, the connection chamber is provided across the wall surfaces provided on the three sides of the machine room, and the plurality of heat insulating materials constituting the connection chamber are provided on the three wall surfaces, respectively. Wall insulation is included. In this case, since these three wall heat insulating materials can be previously attached to the wall surface at the unit manufacturing factory, the construction work of the connection chamber can be further facilitated.

  In the air conditioning structure of a building according to a third aspect of the present invention, in the second aspect of the invention, the machine room has an opening that leads to an adjacent room on a side surface that is different from the three sides. The space between the wall surfaces is substantially the same as the width of the opening.

  In a building such as a house, the machine room may be formed as a small room having a width substantially the same as the width of the opening, for example, for securing a large living space. Therefore, in the present invention, the second invention is applied to such a machine room. In this case, since it is easy to install the connection chamber in a state of straddling the three walls, it can be said that this is a preferable configuration for realizing the second invention.

  In the air conditioning structure of a building according to a fourth aspect of the present invention, in any one of the first to third aspects of the invention, a storage shelf is installed in the machine room adjacent to the connection chamber. Is characterized in that a storage shelf heat insulating material is provided as the heat insulating material.

  According to the present invention, since the storage shelf is provided in the machine room, the machine room is used not only as an installation space for an air conditioner or the like but also as a storage space. For this reason, effective use of the space in the machine room is attempted. Further, the storage shelf is provided adjacent to the connection chamber, and some of the heat insulating materials (storage shelf heat insulating materials) among the plurality of heat insulating materials constituting the connection chamber are provided on the outer surface of the storage shelf. In this case, since the storage shelf heat insulating material can be attached to the storage shelf in advance at the manufacturing factory, the storage shelf heat insulating material can be disposed simply by installing the storage shelf in the machine room at the construction site. . Thereby, the construction work of the connection chamber on site can be made easier.

  A building air conditioning structure according to a fifth aspect of the present invention includes the connection duct that connects the air conditioner and the connection chamber in any one of the first to fourth aspects, and the connection chamber has the connection at the bottom thereof. A plate-like connection member having a connection port connected to the duct, the connection member is provided between the wall surfaces facing each other across the machine room, and on the upper surface of the connection member A bottom heat insulating material as the heat insulating material is provided.

  According to the present invention, the air conditioner and the connection chamber are connected via the connection duct, and the connection duct is connected to the connection port of the connection member provided at the bottom of the connection chamber. The connection member is provided so as to be bridged between the wall surfaces facing each other with the machine room interposed therebetween, and a bottom heat insulating material constituting the connection chamber is provided on the upper surface of the connection member. In this case, since the connection member for connecting the connection duct can also be used as the base of the bottom heat insulating material, the connection member can be made multifunctional.

  The air conditioning structure for a building of a sixth invention is the air conditioning structure for a building according to the fifth invention, wherein a storage shelf is installed adjacent to the connection chamber in the machine room, and the storage shelf is fixed to the connection member. It is characterized by being.

  According to the present invention, since the storage shelf is fixed to the connection member, the connection member can be used as a base for fixing the storage shelf. Thereby, further multifunctionalization of the connection member can be achieved.

  The air conditioning structure of a building according to a seventh aspect of the invention is the invention according to any one of the first to sixth aspects, wherein the heat insulating material includes a duct side heat insulating material connected to the air conditioning duct, and the duct side heat insulating material is A duct connecting part inserted into the air conditioning duct and connected to the air conditioning duct, and the duct side heat insulating material including the duct connecting part penetrates the air conditioning duct and the space in the chamber. And a communication hole.

  According to this invention, the duct connection part provided in the duct side heat insulating material is inserted in the duct of an air conditioning duct, and is connected with the air conditioning duct. In this case, the connection chamber and the air conditioning duct can be connected by a relatively simple operation of inserting and connecting the duct connecting portion into the air conditioning duct.

  The air conditioning structure for a building according to an eighth aspect of the present invention is characterized in that, in any one of the first to seventh aspects, an airtight sheet is provided on the plate surface of each of the heat insulating materials.

  According to the present invention, since the airtight sheet is provided on the plate surface of each heat insulating material constituting the connection chamber, the air-conditioned air flowing through the space in the chamber is prevented from leaking outside through the heat insulating material. can do. Thereby, the airtight performance of the connection chamber can be enhanced.

  A manufacturing method of an air conditioning structure of a ninth invention is a manufacturing method of manufacturing the air conditioning structure of a building described in the first invention, and in the unit manufacturing factory, the ceiling heat insulating material is attached to the ceiling surface, The wall heat insulating material is attached to the wall surface.

  According to the present invention, among the plurality of heat insulating materials constituting the connection chamber, the ceiling heat insulating material and the wall heat insulating material are respectively attached to the ceiling surface and the wall surface of the machine room in the unit manufacturing factory. In this case, since a part of the connection chamber can be assembled in the building unit at the unit manufacturing factory, the construction work of the connection chamber on site can be facilitated.

The longitudinal cross-sectional view which shows the structure of the second floor part. The longitudinal cross-sectional view which shows the structure around a machine room. The cross-sectional view which shows the structure around a machine room. The perspective view which shows the outline | summary of a unit type building. The perspective view of a building unit. Explanatory drawing for demonstrating the work procedure in the case of installing an air conditioning system. Explanatory drawing for demonstrating the work procedure in the case of installing an air conditioning system. Explanatory drawing for demonstrating the structure around a machine room in the past.

  Hereinafter, an embodiment embodying the present invention will be described with reference to the drawings. In the present embodiment, the present invention is embodied in a two-story unit type building having a steel frame ramen structure. FIG. 4 is a perspective view showing an outline of a unit type building.

  As shown in FIG. 4, a building 10 such as a house includes a building body 12 provided on a foundation 11 and a roof portion 13 provided above the building body 12. The building body 12 is a two-story building having a first floor portion 14 as a lower floor portion and a second floor portion 15 as an upper floor portion, and is configured by connecting a plurality of building units 20 to each other. The building unit 20 is manufactured in advance in a manufacturing factory, and then transported to a construction site by a truck or the like. Moreover, the roof part 13 is comprised as a flat roof (flat roof).

  FIG. 5 shows a perspective view of the building unit 20. As shown in FIG. 5, the building unit 20 includes four columns 21 disposed at the four corners thereof, and four ceiling beams 22 and floor beams 23 that connect the upper end portion and the lower end portion of each column 21, respectively. And. A rectangular frame (frame) is formed by the pillars 21, the ceiling beams 22 and the floor beams 23. The column 21 is made of a square tube-shaped square steel. The ceiling girder 22 and the floor girder 23 are made of channel steel having a U-shaped cross section, and are installed so that their openings face each other.

  A plurality of small ceiling beams 25 are bridged between the large ceiling beams 22 on the long sides of the building unit 20 at predetermined intervals. Similarly, a plurality of floor beams 26 are bridged between the large floor beams 23 on the long sides of the building unit 20 at predetermined intervals. The ceiling beam 25 and the floor beam 26 are provided at the same interval and at positions corresponding to the upper and lower sides, respectively. For example, the ceiling beam 25 is made of lip groove steel, and the floor beam 26 is made of square steel. The ceiling member 27 is supported by the ceiling beam 25 and the floor member 28 is supported by the floor beam 26.

  Next, the configuration of the second floor portion 15 of the building 10 will be described with reference to FIG. FIG. 1 is a longitudinal sectional view showing the configuration of the second floor portion 15.

  As shown in FIG. 1, the second floor portion 15 of the building 10 is provided with a living room 31, a corridor 32, and a machine room 33 as indoor spaces. The corridor 32 connects the living room 31 and the machine room 33. The hallway 32 is partitioned from the living room 31 by a partition wall 35, and an entrance 37 for entering and exiting the living room 31 from the hallway 32 is provided in the partition wall 35. The door 37 is provided with a door 38, and the door 37 is opened and closed by the door 38. The hallway 32 corresponds to the “neighboring room”.

  A machine room 33 is provided on the opposite side of the living room 31 with the corridor 32 interposed therebetween. The machine room 33 is surrounded on three sides by a partition wall 39, and an opening 41 opened toward the corridor 32 is provided on one side surface thereof. The opening portion 41 is provided with a pair of upper and lower door portions 42 and 43, and the opening portion 41 is opened and closed by the door portions 42 and 43. The machine room 33 is formed using the internal space of one building unit 20.

  A ceiling member 27 is provided on the ceiling of the second floor portion 15. The ceiling surface material 27 is configured to have a gypsum board, and is supported from above by a field edge 48 provided on the lower surfaces of the ceiling beam 22 and the ceiling beam 25. A ceiling back space 44 is formed above the ceiling surface material 27. The ceiling back space 44 is a space between the ceiling surface material 27 and the roof portion 13 thereabove.

  Of the ceiling portion of the second floor portion 15, a ceiling surface material 45 is further provided below the ceiling surface material 27 at the ceiling portion of the hallway 32. That is, a so-called falling ceiling is formed by the ceiling surface material 45 in the ceiling portion of the hallway 32. Similarly to the ceiling surface material 27, the ceiling surface material 45 has a gypsum board. The ceiling surface material 45 is provided between the partition walls 46 facing each other with the corridor 32 interposed therebetween. A ceiling back space 49 is formed between the ceiling surface material 45 and the ceiling surface material 27 thereabove. In this case, in the ceiling portion of the corridor 32, two layers of ceiling back spaces 44 and 49 that are partitioned vertically by the ceiling surface material 27 are formed.

  A ceiling surface 55 is formed by the ceiling surface material 45 in the ceiling portion of the hallway 32, while a ceiling surface 56 is formed by the ceiling surface material 27 in the ceiling portions of the living room 31 and the machine room 33. In this case, the ceiling height of the hallway 32 is lower than the ceiling height of the living room 31 and the machine room 33. For this reason, the hallway 32 is a low ceiling space whose ceiling height is lower than the living room 31 and the machine room 33 (and other indoor spaces).

  A joist 57 is provided on the floor beam 23 in the floor portion of the second floor portion 15. Floor material 28 is provided on each joist 57 and each floor beam 26. The floor material 28 has a particle board. A floor surface 58 of the indoor spaces 31 to 33 is formed by the floor material 28.

  By the way, the main building 10 is provided with an air conditioning system on the first floor portion 14 and the second floor portion 15 respectively. The air conditioning system is a so-called entire building air conditioning system that air-conditions a plurality of indoor spaces using a common air conditioner. Below, the structure of the air conditioning system 50 provided in the second floor part 15 is demonstrated.

  The air conditioning system 50 includes an air conditioner 51 that generates conditioned air (warm air and cold air) and an air conditioner duct 52 that is connected to the air conditioner 51 via a connection duct 59 and the like. The air conditioner 51 is configured as an indoor unit installed in the machine room 33. The air conditioner 51 takes in air flowing into the machine room 33 from the corridor 32 as return air, and generates conditioned air based on the return air. The air conditioner 51 supplies the generated conditioned air to the air conditioning duct 52.

  The air conditioning duct 52 is installed in a ceiling space 49 above the hallway 32 and is disposed so as to extend in the horizontal direction in the space 49. The air conditioning duct 52 has a plurality of duct portions 54 divided in the longitudinal direction of the duct 52. The air conditioning duct 52 is configured by connecting the duct portions 54 to each other. Each duct portion 54 is formed in a square cylinder shape from a resin material such as styrene foam having excellent heat insulation performance, and has an internal passage 54a (see FIG. 2) through which conditioned air flows. The internal passages 54a of the duct portions 54 communicate with each other, and the internal passages 54a of the air conditioning duct 52 are formed by the internal passages 54a that communicate with each other.

  The air conditioning duct 52 does not necessarily need to be configured by a plurality of duct portions 54 (duct members), and may be configured by a long duct member.

  A blowout chamber 53 is connected to the air conditioning duct 52. The blowing chamber 53 is connected to a plurality of locations in the air conditioning duct 52. The conditioned air flowing through the air conditioning duct 52 is supplied to each of the blowout chambers 53, and the supplied conditioned air is blown out (supplied) from each of the blowout chambers 53 toward the indoor space. In FIG. 1, the blowout chamber 53 that blows conditioned air toward the living room 31 among the blowout chambers 53 is shown. The blowout chamber 53 is inserted through an insertion hole 67 formed in the partition wall 35.

  Next, the configuration around the machine room 33 will be described with reference to FIGS. FIG. 2 is a longitudinal sectional view showing the configuration around the machine room 33. FIG. 3 is a cross-sectional view showing a configuration around the machine room 33, and corresponds to a cross section taken along line AA of FIG.

  As shown in FIGS. 2 and 3, the machine room 33 is located at the end of the hallway 32 and is formed as a space on the extension of the hallway 32. The machine room 33 is formed so that three sides thereof are surrounded by partition walls 39 (39a to 39c). Among these partition walls 39a to 39c, the partition wall 39a and the partition wall 39b are opposed to each other with the machine chamber 33 interposed therebetween, and the partition wall 39c is provided so as to connect the partition walls 39a and 39b. In this case, the interval between the opposing partition walls 39a and 39b and the interval between the opposing partition walls 46 across the corridor 32 are the same. Therefore, the machine room 33 is formed as a small room (small room) surrounded by the floor surface 58 and the ceiling surface 56 that are vertically opposed to each other and the wall surfaces 63a to 63c of the partition walls 39a to 39b.

  An opening 41 that opens the machine room 33 toward the corridor 32 is provided on the opposite side of the machine room 33 from the partition wall 39c. The opening width of the opening 41 is substantially the same as the width of the machine room 33 (interval between the partition walls 39a and 39b), and the opening height is the ceiling height of the hallway 32 (from the floor surface 58 to the ceiling surface) (Distance up to 55). A door frame 61 is provided on the peripheral edge of the opening 41. The door frame 61 has an upper frame 61 a provided along the upper edge of the opening 41 and a pair of vertical frames 61 b provided along each side edge of the opening 41. The upper frame 61 a is fixed to a long base material 62 spanned between the partition walls 46 above the opening 41, and the vertical frames 61 b are respectively connected to the partition walls 39 a and 39 b of the machine chamber 33. Each is fixed. In addition, a communication portion 69 that communicates the machine room 33 and the ceiling space 49 is provided above the opening 41. The communication portion 69 is formed between the base material 62 and the ceiling surface 56.

  In the following description, in the machine room 33, the opening 41 side in the depth direction is referred to as the front side (front side), and the partition wall 39c side opposite to the opening 41 side is the back side (rear side). That's it. The left and right in the machine room 33 means the left and right when the machine room 33 is viewed from the front side (the corridor 32 side). Therefore, in the machine room 33, the partition wall 39a side is the left side, and the partition wall 39b side is the right side.

  Inside the door frame 61, two upper and lower door portions 42 and 43 for opening and closing the opening 41 are provided. Among these door portions 42 and 43, a storage shelf 64 is provided on the back side (machine room 33 side) of the upper door portion 43. The storage shelf 64 is provided in the upper part of the machine room 33, and more specifically, is provided across the upper half of the machine room 33. The upper door 43 is an open / close door that opens and closes the storage shelf 64.

  A portion of the opening 41 below the storage shelf 64 is a maintenance opening 65. The maintenance opening 65 is an opening used when maintaining the air conditioner 51. The lower door portion 42 is an open / close door that opens and closes the maintenance opening 65. A vent 66 is formed between the lower end of the door 42 and the floor 58 to communicate the machine room 33 and the corridor 32, and the air in the corridor 32 enters the machine room 33 through the vent 66. It comes to be taken in.

  The storage shelf 64 includes a bottom plate portion 64a, a top plate portion 64b, and a back plate portion 64c, and a U-shaped shelf body is formed by each of the plate portions 64a to 64c. The storage shelf 64 is installed with the open side of the shelf body facing the hallway 32 side. In this case, the top plate portion 64b is disposed at the same height as the ceiling surface material 45 above the hallway 32, and the back plate portion 64c is disposed to face the partition wall 39c. A plurality of upper and lower shelf boards 64d are provided inside the shelf body. These shelf boards 64d are being fixed to the back board part 64c in the rear-end part.

  The storage shelf 64 is provided so as to straddle the opposing partition walls 39a and 39b, and both end portions in the width direction are fixed to the partition walls 39a and 39b via fixing brackets (not shown), respectively. ing. The storage shelf 64 is arranged on the corridor 32 side (front side) in the depth direction in the machine room 33. As a result, a first space S <b> 1 is formed behind the storage shelf 64 in the machine room 33. In the machine room 33, a second space S2 is formed above the storage shelf 64, and a third space S3 is formed between the second space S2 and the first space S1. The third space S3 is a space surrounded by the first space S1, the second space S2, the ceiling surface 56, and the wall surface 63c.

  Incidentally, as described above, the storage shelf 64 is provided in the upper part of the machine room 33, so that the space in the upper part of the machine room 33 that tends to become a dead space is effectively used.

  In the machine room 33, the air conditioner 51 is installed as described above. The air conditioner 51 is installed on the floor 58 in the machine room 33, and is disposed on the back side with respect to the storage shelf 64. A connection duct 59 is connected to the upper end of the air conditioner 51. The connection duct 59 is composed of a flexible pipe having a silencing function, and extends upward from the air conditioner 51. The connection duct 59 is disposed in the first space S1 in the machine room 33, and extends in the vertical direction in the space S1. Further, the upper end of the connection duct 59 is located in the middle in the height direction of the first space S1 (in other words, the storage shelf 64), more specifically, above the center in the height direction.

  A connection chamber 70 is connected to the upper end of the connection duct 59. The connection chamber 70 is a chamber that connects the connection duct 59 and the air conditioning duct 52. The air conditioning system 50 has a feature in the configuration of the connection chamber 70, and the configuration of the connection chamber 70 will be described in detail below.

  The connection chamber 70 is provided on the ceiling side in the machine room 33. The connection chamber 70 is provided in the second space S2 extending from the first portion 70a to the front side (forward), and a first portion 70a extending up and down across the upper portion of the first space S1 and the third space S3. Second portion 70b. Of these portions 70 a and 70 b, the first portion 70 a is connected to the connection duct 59, and the second portion 70 b is connected to the air conditioning duct 52. The connection chamber 70 is L-shaped as a whole by these portions 70a and 70b, and is disposed so as to fill the upper portion of the first space S1, the second space S2, and the third space S3, respectively. Yes.

  The connection chamber 70 has the same width (horizontal width) as the width of the machine room 33, and is provided across the partition walls 39a and 39b (the wall surfaces 63a and 63b of the machine room 33). Further, the connection chamber 70 further straddles the wall surface 63 c and the ceiling surface 56 of the machine room 33 and the outer surface of the storage shelf 64. A portion of the first portion 70a of the connection chamber 70 that is disposed in the first space S1 is formed between the back surface 64e of the storage shelf 64 (back plate portion 64c) and the wall surface 63c of the machine room 33 that are opposed to each other with the space S1 interposed therebetween. It is provided across. In addition, the second portion 70b is provided across the top surface 64f of the storage shelf 64 (top plate portion 64b) and the top surface 64f of the machine room 33 facing each other up and down across the second space S2. . The back surface 64e and the top surface 64f of the storage shelf 64 correspond to the outer surface of the storage shelf 64, respectively.

  The connection chamber 70 has a chamber internal space 71 therein. The chamber internal space 71 is a flow path through which conditioned air flows, and the connection duct 59 and the air conditioning duct 52 communicate with each other. The connection chamber 70 includes a plurality of plate-like heat insulating materials 72 to 78 provided so as to surround the chamber inner space 71. The connection chamber 70 is formed in a box shape by combining the plurality of heat insulating materials 72 to 78 with each other. These heat insulating materials 72 to 78 are all made of a foam heat insulating material, and specifically made of foamed urethane foam.

  The plurality of heat insulating materials 72 to 78 include an upper heat insulating material 72 provided above the chamber internal space 71, a left heat insulating material 73 provided to the left of the chamber internal space 71, and a right side of the chamber internal space 71. A right heat insulating material 74 provided in the inner space 71, a rear heat insulating material 75 provided behind the chamber inner space 71, a storage shelf heat insulating material 76 provided between the chamber inner space 71 and the storage shelf 64, and a chamber. There are a lower heat insulating material 77 provided below the inner space 71 and a front heat insulating material 78 provided in front of the chamber inner space 71.

  The upper heat insulating material 72 is formed in a rectangular plate shape (flat plate shape), and is provided in a state where the plate surface is superimposed on the ceiling surface 56. The upper heat insulating material 72 is fixed to the ceiling surface 56 using an adhesive. The upper heat insulating material 72 extends across the second space S2 and the third space S3, and the rear end thereof is in contact with the wall surface 63c. The upper heat insulating material 72 is provided across the wall surfaces 63 a and 63 b of the machine room 33. The upper heat insulating material 72 corresponds to a ceiling heat insulating material.

  The left heat insulating material 73 has a flat plate shape, and has a shape in which a part of the rectangular shape is cut out into a rectangular shape so as to avoid interference with the storage shelf 64. The left heat insulating material 73 is provided in a state where its plate surface is overlapped with the wall surface 63a of the machine room 33, and is fixed to the wall surface 63a with an adhesive. Specifically, the left-side heat insulating material 73 is disposed in the second space S2 extending from the portion 73a to the front side and extending to the front side over the first space S1 and the third space S3. Part 73b.

  The left heat insulating material 73 has the same length in the front-rear direction as the upper heat insulating material 72. The left heat insulating material 73 has the same front end position as that of the upper heat insulating material 72 in the same direction, and the rear end is in contact with the wall surface 63 c of the machine room 33. The left heat insulating material 73 has an upper end in contact with the upper heat insulating material 72 and is provided continuously with the upper heat insulating material 72. In the left heat insulating material 73, the lower end portion of the portion 73 b is in contact with the top surface 64 f of the storage shelf 64.

  The right heat insulating material 74 has the same shape and the same size as the left heat insulating material 73. That is, the right side heat insulating material 74 and the left side heat insulating material 73 have the same configuration, and the common use of the members is achieved. The right heat insulating material 74 is provided in a state where its plate surface is overlapped with the wall surface 63b of the machine room 33, and is fixed to the wall surface 63b with an adhesive. The right heat insulating material 74 has the same installation configuration as the left heat insulating material 73 except that the right heat insulating material 74 is provided on the wall surface 63 b of the machine room 33. That is, the right heat insulating material 74 is disposed so as to be symmetric with the left heat insulating material 73 with respect to the center in the width direction (left-right direction) of the machine room 33. Therefore, the description of the installation configuration of the right heat insulating material 74 is omitted here.

  The rear heat insulating material 75 is formed in a rectangular plate shape (flat plate shape), and is provided in a state where the plate surface is overlapped with the wall surface 63 c of the machine chamber 33. The rear heat insulating material 75 is fixed to the wall surface 63c with an adhesive. The rear heat insulating material 75 is provided across the left heat insulating material 73 and the right heat insulating material 74. Therefore, the rear heat insulating material 75 is provided continuously with the heat insulating materials 73 and 74. Further, the rear heat insulating material 75 is in contact with the upper heat insulating material 72 at the upper end portion thereof, and is provided continuously with the upper heat insulating material 72. The lower end portion of the rear heat insulating material 75 is at the same height as the lower end portions of the left and right heat insulating materials 73 and 74.

  The left and right heat insulating materials 73 and 74 and the rear heat insulating material 75 correspond to wall heat insulating materials, respectively.

  The storage shelf heat insulating material 76 is formed to have an L-shaped cross section, and a top surface portion 76 a provided on the top surface 64 f of the storage shelf 64 and a back surface portion 76 b provided on the back surface 64 e of the storage shelf 64. And have. The top surface portion 76a is fixed to the top surface 64f of the storage shelf 64 using an adhesive, and the back surface portion 76b is fixed to the back surface 64e of the storage shelf 64 using an adhesive. In this embodiment, the storage shelf heat insulating material 76 is integrally formed including the top surface portion 76a and the back surface portion 76b. However, the top surface portion 76a and the back surface portion 76b may be formed as separate bodies.

  The storage shelf heat insulating material 76 is provided across the left heat insulating material 73 and the right heat insulating material 74. Therefore, the storage shelf heat insulating material 76 is provided continuously with these heat insulating materials 73 and 74. The front end portion of the storage shelf heat insulating material 76 (top surface portion 76a) is located at the same position as the front end portion of the upper heat insulating material 72 (and both the left and right heat insulating materials 73 and 74) in the front-rear direction. Moreover, the lower end part of the storage shelf heat insulating material 76 (back surface part 76b) exists in the same position as the lower end part of the left and right heat insulating materials 73 and 74 (and the rear heat insulating material 75) in the vertical direction.

  The lower heat insulating material 77 is formed in a rectangular plate shape (flat plate shape), and is provided to face the upper heat insulating material 72 with the chamber inner space 71 interposed therebetween in the first space S1. The lower heat insulating material 77 is provided across the lower ends of the left and right heat insulating materials 73, 74, the rear heat insulating material 75, and the storage shelf heat insulating material 76 (specifically, the back surface portion 76b). In this case, the lower heat insulating material 77 is provided continuously with each of the heat insulating materials 73 to 76. The lower heat insulating material 77 corresponds to the bottom heat insulating material.

  A connection member 81 connected to the connection duct 59 is provided on the lower surface of the lower heat insulating material 77. The connection member 81 is formed of a steel plate and has a flat plate portion 82 on which the lower surface of the lower heat insulating material 77 is overlapped. The flat plate portion 82 has the same size in plan view as the lower heat insulating material 77, and the lower heat insulating material 77 is fixed to the upper surface of the flat plate portion 82 using an adhesive.

  The connection member 81 has a plurality (specifically, four) flange portions 83 extending downward from the respective end sides of the flat plate portion 82. Of the flange portions 83 (83 a to 83 c), the front flange portion 83 a is fixed to the back surface 64 e of the storage shelf 64 by screws 84. The screws 84 penetrate the back plate portion 64c of the storage shelf 64 from the front side and are screwed into the flange portion 83a. The rear flange portion 83b is fixed to the wall surface 63c of the machine chamber 33 with screws 84, and the left and right flange portions 83c are fixed to the wall surfaces 63a and 63b of the machine chamber 33 with screws 84, respectively. The screws 84 are made of resin.

  A connection port 86 to which the connection duct 59 is connected is formed in the flat plate portion 82 of the connection member 81. The connection port 86 includes a burring hole formed in the flat plate portion 82. The upper end of the connection duct 59 is inserted into the connection port 86, and the connection duct 59 and the connection port 86 are bonded and fixed in an airtight state in the inserted state. As a result, the connection duct 59 is connected to the connection member 81, and thus connected to the connection chamber 70. Further, a hole 77 a is formed in the lower heat insulating material 77 at a position corresponding to the connection port 86. The connection duct 59 (connection port 86) and the chamber internal space 71 communicate with each other through the hole 77a.

  The front heat insulating material 78 is formed in a rectangular plate shape, and is provided in the second space S2 so as to face the rear heat insulating material 75 with the inner space 71 interposed therebetween. The front heat insulating material 78 is provided across the front end portions of the upper heat insulating material 72, the left and right heat insulating materials 73 and 74, and the storage shelf heat insulating material 76 (the top surface portion 76a), and these heat insulating materials 72 to 74 and 76 are provided. It is fixed to the front end of each using an adhesive. In this case, the front heat insulating material 78 is provided continuously with these heat insulating materials 72 to 74 and 76. The front heat insulating material 78 corresponds to the duct heat insulating material.

  The front heat insulating material 78 has a protruding portion 87 protruding toward the ceiling back space 49 side on the front surface thereof. The projecting portion 87 has a rectangular shape. The protrusion 87 is inserted into (inserted into) the internal passage 54a of the duct portion 54 (the duct internal passage 52a of the air conditioning duct 52) and connected to the duct portion 54 (air conditioning duct 52). As a result, the front heat insulating material 78 is connected to the duct portion 54, and the connection chamber 70 is connected to the air conditioning duct 52. Moreover, the protrusion part 87 is being fixed to the duct part 54 using the adhesive agent in the state inserted in the internal channel | path 54a. In detail, the protrusion part 87 and the duct part 54 are being fixed in the state by which the airtight state between both was ensured. In this case, the protruding portion 87 corresponds to the duct connecting portion.

  A hole 88 that penetrates in the thickness direction including the protruding portion 87 is formed in the front heat insulating material 78. The internal passage 54 a and the chamber internal space 71 are communicated with each other through the hole 88. The hole 88 corresponds to a communication hole.

  Airtight sheets 89 are attached to the inner side surfaces of the respective heat insulating materials 72 to 78 (that is, the surface on the chamber inner space 71 side) using an adhesive. The airtight sheet 89 is made of a resin material having airtightness, and is made of, for example, polyethylene resin. The airtight sheet 89 is affixed over the entire range of the inner surfaces of the heat insulating materials 72 to 78 facing the chamber inner space 71. However, a hole 89 a is formed in the airtight sheet 89 of the lower heat insulating material 77 so as to correspond to the hole 88 of the heat insulating material 77, and the heat insulating material 78 of the airtight sheet 89 of the front heat insulating material 78 is formed. A hole portion 89 a is formed corresponding to the hole portion 88.

  Next, an operation procedure when the air conditioning system 50 is installed in the building 10 will be described. 6 and 7 are explanatory diagrams for explaining the work procedure.

  In the unit manufacturing factory, first, each building unit 20 constituting the building 10 is manufactured. Thereby, the machine room 33 is formed in the predetermined building unit 20. Note that the door units 42 and 43 are not attached to the building unit 20. Also, the ceiling face material 45 above the hallway 32 is not attached.

  When installing the air conditioning system 50, first, as shown in FIG. 6A, the upper heat insulating material 72 is attached to the ceiling surface 56 of the machine room 33 using an adhesive. Further, the left heat insulating material 73, the right heat insulating material 74, and the rear heat insulating material 75 are attached to the respective wall surfaces 63a to 63c of the machine room 33 using an adhesive. Then, the airtight sheet | seat 89 is affixed on the inner surface of each of these heat insulating materials 72-75, respectively using an adhesive agent.

  In addition, after attaching the heat insulating materials 72-75 to the ceiling surface 56 and each wall surface 63a-63c of the machine room 33, respectively, you may make it affix the airtight sheet | seat 89 on these heat insulating materials 72-75.

  Next, as shown in FIG. 6B, the connection member 81 is fixed to the wall surfaces 63 a to 63 c of the machine chamber 33 with screws 84. In this case, the flange portion 83b of the connecting member 81 is fixed to the wall surface 63c with screws 84, and the flange portions 83c on both sides are fixed to the wall surfaces 63a and 63b with screws 84, respectively. Prior to this fixing operation, a lower heat insulating material 77 is previously attached to the connecting member 81 using an adhesive, and an airtight sheet 89 is attached to the lower heat insulating material 77 using an adhesive. deep. Thereby, installation of the lower heat insulating material 77 and the airtight sheet 89 is completed by performing the fixing operation of the connecting member 81 to the wall surfaces 63a to 63b.

  Instead of the above procedure, first, only the connection member 81 may be fixed to the wall surfaces 63a to 63c, and then the lower heat insulating material 77 and the airtight sheet 89 may be attached to the connection member 81.

  Thereafter, each building unit 20 manufactured at the unit manufacturing factory is transported to the construction site by a truck.

  At the construction site, each building unit 20 is first installed at a predetermined position. Thereafter, as shown in FIG. 6C, the air conditioner 51 is installed on the floor 58 of the machine room 33 formed in the predetermined building unit 20. Then, the connection duct 59 is connected to the air conditioner 51, and the connection duct 59 is connected to the connection port 86 of the connection member 81.

  Next, as shown in FIG. 7A, the storage shelf 64 is installed in the machine room 33. In this case, the storage shelf 64 is fixed to each of the wall surfaces 63 a and 63 b of the machine room 33 with screws or the like, and is fixed to the flange portion 83 a of the connection member 81 with screws 84. Prior to the installation operation of the storage shelf 64, a storage shelf heat insulating material 76 is attached to the storage shelf 64 in advance using an adhesive, and an airtight sheet 89 is used for the storage shelf heat insulating material 76 using an adhesive. Paste it. Thereby, the installation work of the storage shelf 64 and the airtight sheet 89 are completed by performing the installation work of the storage shelf 64.

  Next, as shown in FIG. 7B, the front heat insulating material 78 is fixed to the upper heat insulating material 72, the left and right heat insulating materials 73 and 74, and the storage shelf heat insulating material 76, respectively, using an adhesive. Prior to this fixing operation, an airtight sheet 89 is previously attached to the front heat insulating material 78 using an adhesive. Thereby, installation (manufacture) of the connection chamber 70 is completed.

  Next, as shown in FIG. 7C, the duct portion 54 is connected to the front heat insulating material 78. In this case, the duct portion 54 is connected while inserting the protruding portion 87 of the front heat insulating material 78 into the internal passage 54a. Thereafter, the remaining duct portions 54 are sequentially connected to configure (manufacture) the air conditioning duct 52. Then, a ceiling member 45 is attached above the hallway 32. Thereby, the installation of the air conditioning duct 52 in the ceiling space 49 is completed.

  Thereafter, a series of operations are completed by connecting the blowout chamber 53 to the air conditioning duct 52.

  As mentioned above, according to the structure of this embodiment explained in full detail, the following outstanding effects are acquired.

  The connection chamber 70 includes a chamber inner space 71 through which conditioned air flows and a plurality of plate-like heat insulating materials 72 to 78 provided so as to surround the chamber inner space 71. In this case, the heat insulation performance of the connection chamber 70 can be suitably ensured. Among the plurality of heat insulating materials 72 to 78, the upper heat insulating material 72 is provided on the ceiling surface 56 of the machine room 33, and the left heat insulating material 73, the right heat insulating material 74, and the rear heat insulating material 75 are respectively machine room 33. The wall surfaces 63a to 63c are provided. In this case, each of the heat insulating materials 72 to 75 can be attached to the ceiling surface 56 and the wall surfaces 63a to 63c of the machine room 33 (in the building unit 20) in advance in the unit manufacturing factory. Part of 70 can be manufactured (assembled) in advance at the unit manufacturing factory. Further, the heat insulating materials 77 and 78 that are not attached at the unit manufacturing factory are assembled at the construction site. In the assembling operation, the connection chamber is lifted up onto the bracket and fitted into the fixing portion while looking upward. Compared to the above work, it can be performed easily. Therefore, in this case, the construction work of the connection chamber 70 on site can be facilitated.

  In addition, since it is difficult to see the work such as fitting the connection chamber into the fixing portion of the bracket while looking upward, it is difficult to ensure the quality, but the construction of the connection chamber 70 as described above is difficult. If so, the work can be performed in a relatively easy-to-see state, and the quality can be easily ensured.

  The connection chamber 70 is provided so as to straddle the three wall surfaces 63a to 63c of the machine room 33, and the wall heat insulating materials 73 to 75 (the left heat insulating material 73, A right heat insulating material 74 and a rear heat insulating material 75) were provided. In this case, since these three wall heat insulating materials 73 to 75 can be attached to the wall surfaces 63a to 63c in advance at the unit manufacturing factory, the construction work of the connection chamber 70 can be further facilitated.

  Further, in the main building 10, the machine room 33 is formed as a small chamber having substantially the same width as the width of the opening 41, so that the connection chamber 70 extends over the three wall surfaces 63a to 63c as described above. Easy to install. Therefore, it can be said that this is a preferable configuration in applying the above-described configuration in which the wall heat insulating materials 73 to 75 are provided on the respective wall surfaces 63a to 63c.

  A storage shelf 64 is installed in the machine room 33 adjacent to the connection chamber 70, and a storage shelf heat insulating material 76 that constitutes the connection chamber 70 in a state of straddling the top surface 64 f and the back surface 64 e (outer surface) of the storage shelf 64. Provided. In this case, since the storage shelf heat insulating material 76 can be previously attached to the storage shelf 64 at the manufacturing factory, the storage shelf heat insulating material 76 is disposed only by installing the storage shelf 64 in the machine room 33 at the construction site. Can be set. Thereby, the construction work of the connection chamber 70 on the site can be further facilitated.

  A plate-like connection member 81 having a connection port 86 connected to the connection duct 59 is provided at the bottom of the connection chamber 70, and the connection member 81 is provided across the wall surfaces 63 a and 63 b of the machine room 33. A lower heat insulating material 77 constituting the connection chamber 70 was provided on the upper surface of the connection member 81. In this case, since the connection member 81 that connects the connection duct 59 can be used as the base of the lower heat insulating material 77, the connection member 81 can be multi-functional.

  Since the storage shelf 64 is fixed to the connection member 81 (flange portion 83a) with the screws 84, the connection member 81 can be used as a base for fixing the storage shelf 64. Thereby, further multifunctionalization of the connection member 81 can be achieved.

  Further, since the screws 84 are made of resin, it is possible to suppress heat from being transmitted to the connection chamber 70 (chamber inner space 71) via the screws 84, and as a result, it is possible to suppress deterioration of the heat insulating performance of the chamber 70.

  A protrusion 87 connected to the air conditioning duct 52 by being inserted into the duct internal passage 52a (the internal passage 54a of the duct portion 54) of the air conditioning duct 52 in the front heat insulating material 78 connected to the air conditioning duct 52 (duct portion 54). In addition to the provision of the protrusion 87, a hole 88 that penetrates through the front heat insulating material 78 and communicates the chamber inner space 71 and the duct inner passage 52a is provided. In this case, the connection chamber 70 and the air conditioning duct 52 can be connected by a relatively simple operation such as inserting and connecting the protrusion 87 into the duct passage 52 a of the air conditioning duct 52.

  Since the airtight sheets 89 are provided on the inner side surfaces of the heat insulating materials 72 to 78 constituting the connection chamber 70, the conditioned air flowing through the chamber inner space 71 permeates the heat insulating materials 72 to 78 and leaks to the outside. Can be suppressed. Thereby, the airtight performance of the connection chamber 70 can be improved.

  The present invention is not limited to the above embodiment, and may be implemented as follows, for example.

  (1) In the above embodiment, the connection chamber 70 is provided so as to straddle the three wall surfaces 63 a to 63 c in the machine room 33. You may provide so that it may straddle only the wall surface 63a, 63b. In that case, since the rear heat insulating material 75 is disposed apart from the wall surface 63c, the rear heat insulating material 75 is, for example, the upper heat insulating material 72, the left and right heat insulating materials 73 and 74, and the lower heat insulating material 77. It is conceivable to fix using an adhesive.

  Further, the connection chamber 70 may be provided so as to straddle only the two wall surfaces 63 a and 63 c of the machine room 33. In that case, since the right heat insulating material 74 is disposed away from the wall surface 63b, the right heat insulating material 74 is, for example, the upper heat insulating material 72, the rear heat insulating material 75, the storage shelf heat insulating material 76, and the lower heat insulating material. It is conceivable to fix to 77 using an adhesive.

  In the above embodiment, the machine chamber 33 is formed as a small chamber having a width substantially the same as the width of the opening 41. However, the machine chamber 33 may be formed with a width larger than the width of the opening 41. Conceivable. In such a machine room 33, it is desirable to employ the above-described configuration in which the connection chamber 70 is provided so as to straddle only the two wall surfaces 63a and 63b.

  (2) In the above embodiment, the storage shelf heat insulating material 76 is provided in the storage shelf 64 installed in the machine room 33, but the storage shelf 64 may not be provided in the machine room 33. In such a case, since the storage shelf heat insulating material 76 cannot be provided, it extends over the front heat insulating material 78 and the rear heat insulating material 75 (for example, formed with the same size as the front heat insulating material 78). It is conceivable to provide a side heat insulating material.

  (3) In the above embodiment, the air conditioner 51 and the connection chamber 70 are connected via the connection duct 59. However, the air conditioner 51 and the connection chamber 70 may be directly connected without using the connection duct 59. In that case, it is conceivable that the connection chamber 70 is formed to extend downward to reach the upper end of the air conditioner 51, and the connecting member 81 at the bottom is directly connected to the air conditioner 51.

  (4) In the above embodiment, the connecting member 81 (including the lower heat insulating material 77) is fixed to the wall surfaces 63a to 63c of the machine room 33 at the unit manufacturing plant. You may fix to 63a-63c. Even in such a case, since the connection member 81 is disposed at the bottom of the connection chamber 70, the fixing operation does not need to be performed while looking upward, and the fixing operation can be performed relatively easily.

  (5) In the said embodiment, although the airtight sheet 89 was provided in the inner surface of each heat insulating material 72-78, it replaces with or adds to this, and the outer surface (the chamber inner space 71 side is the side surface) An airtight sheet 89 may be provided on the opposite surface. Moreover, you may make it not provide the airtight sheet | seat 89 in both the inner surface and the outer surface of the heat insulating materials 72-78. However, in order to improve the airtight performance of the connection chamber 70, it is desirable to provide the airtight sheet 89.

  (6) In the said embodiment, although the foam type heat insulating material was used as the heat insulating materials 72-78, this may be changed and fiber type heat insulating materials, such as glass wool, may be used. However, in that case, a plurality of plate materials made of resin or metal are provided so as to surround the chamber inner space 71, and a fiber-based heat insulating material is provided on the plate surface of the plate material.

  (7) When the roof part 13 is a roof-type or gable-type roof, an attic space (in other words, an overhead space above the ceiling member 27) is formed below the roof part 13, The air conditioning duct 52 can be installed in the attic space. Therefore, in such a case, the connection chamber 70 may be connected to the air conditioning duct 52. In that case, the connection chamber 70 is connected to an air-conditioning duct, for example, at its upper end.

  DESCRIPTION OF SYMBOLS 10 ... Building, 20 ... Building unit, 32 ... Corridor as next room, 33 ... Machine room, 41 ... Opening, 50 ... Air conditioning system, 51 ... Air conditioning apparatus, 52 ... Air conditioning duct, 52a ... Duct passage, 58 ... Floor Surface, 56 ... Ceiling surface, 63a to 63c ... Wall surface, 64 ... Storage shelf, 64e ... Back surface as outer surface, 64f ... Top surface as outer surface, 70 ... Connection chamber, 71 ... Space in chamber, 72 ... As ceiling heat insulating material 73 ... left side heat insulating material as wall heat insulating material, 74 ... right side heat insulating material as wall heat insulating material, 75 ... rear side heat insulating material as wall heat insulating material, 76 ... storage shelf heat insulating material, 77 ... bottom heat insulating material A lower heat insulating material as a material, 78... A front heat insulating material as a duct side heat insulating material, 81... Connecting member, 86 .. connection port, 87 ... a projecting portion as a duct connecting portion, 88. ... an airtight sheet.

Claims (9)

Built by combining multiple building units with each other,
One of these building units is applied to a unit type building in which a machine room surrounded by a floor surface, a ceiling surface and a wall surface is provided.
An air conditioner installed on the floor in the machine room;
An air conditioning duct that is installed behind the ceiling and conveys conditioned air generated by the air conditioner to a room to be air conditioned;
A building air conditioning structure comprising a connection chamber provided above the air conditioner in the machine room and constituting a connection portion for connecting the air conditioner and the air conditioning duct,
The connection chamber is provided across the ceiling surface and the wall surface, and includes a space in the chamber through which the conditioned air flows and a plurality of plate-like heat insulating materials provided to surround the space in the chamber And
The air conditioning structure of a building, wherein the plurality of heat insulating materials include a ceiling heat insulating material provided on the ceiling surface and a wall heat insulating material provided on the wall surface. The connection chamber is provided across the wall surfaces provided in three sides of the machine room,
The air conditioning structure for a building according to claim 1, wherein the plurality of heat insulating materials include a plurality of the wall heat insulating materials provided on the respective wall surfaces. In the machine room, an opening leading to the adjacent room is formed on the side surface on the side different from the three sides,
The building air conditioning structure according to claim 2, wherein a distance between the wall surfaces on both sides of the opening is substantially the same as a width of the opening. In the machine room, a storage shelf is installed adjacent to the connection chamber,
The building air conditioning structure according to any one of claims 1 to 3, wherein a storage shelf heat insulating material as the heat insulating material is provided on an outer surface of the storage shelf. A connection duct connecting the air conditioner and the connection chamber;
The connection chamber includes a plate-like connection member having a connection port connected to the connection duct at the bottom thereof,
The connecting member is provided between the wall surfaces facing each other across the machine room,
The building air conditioning structure according to any one of claims 1 to 4, wherein a bottom heat insulating material as the heat insulating material is provided on an upper surface of the connection member. In the machine room, a storage shelf is installed adjacent to the connection chamber,
The building air conditioning structure according to claim 5, wherein the storage shelf is fixed to the connection member. As the heat insulating material, having a duct side heat insulating material connected to the air conditioning duct,
The duct side heat insulating material is
A duct connection part inserted into the air conditioning duct and connected to the air conditioning duct;
It has a communicating hole which connects the inside of the said air-conditioning duct and the said space in a chamber by penetrating the said duct side heat insulating material including the said duct connection part, The any one of Claim 1 thru | or 6 characterized by the above-mentioned. The air conditioning structure of the building described in 1.   The air conditioning structure of a building according to any one of claims 1 to 7, wherein an airtight sheet is provided on a plate surface of each of the heat insulating materials. A manufacturing method for manufacturing an air conditioning structure of a building according to claim 1,
In a unit manufacturing factory, the ceiling heat insulating material is attached to the ceiling surface, and the wall heat insulating material is attached to the wall surface.

Images