JP2021081182A - Method for manufacturing ceiling-suspended air conditioning unit - Google Patents

Abstract

To provide a method for manufacturing a ceiling-suspended air conditioning unit in which an air conditioning device, which shall be installed in a suspended state, is attached to a frame.SOLUTION: The present invention is a method for manufacturing a ceiling-suspended air conditioning unit comprising: a unit assembly step of assembling a plurality of air conditioning units for ceiling suspension to each other; an upper frame attachment step of attaching an upper frame that forms the upper part of a frame for integrally holding the plurality of air conditioning units to the plurality of air conditioning units assembled to each other from above; and a lower frame attachment step of raising the upper frame to which the plurality of air conditioning units are attached, and attaching a lower frame that forms the lower part of the frame from the lower side of the plurality of air conditioning units.SELECTED DRAWING: Figure 11

Description

The present invention relates to a method for manufacturing a ceiling-mounted air conditioning unit.

In recent years, various techniques for facilitating the installation of air-conditioning equipment such as concealed air conditioners and chambers installed behind the ceiling have been proposed (see, for example, Patent Document 1-2).

Japanese Patent No. 5208841 Japanese Unexamined Patent Publication No. 2019-207092 JP-A-2019-207095

Concealed air conditioners installed behind the ceiling are usually attached to bar screws (sometimes called "all screws") that are fixed to the structural material of the building, and are suspended by the bar screws. It can be installed. Therefore, the mounting portion of the commercially available concealed air conditioner has a structure premised on being installed in such a suspended state. Therefore, in order to facilitate the installation of air-conditioning equipment at the site, for example, ancillary parts such as a chamber are integrated in advance with the air-conditioner body or the like by a frame in the factory, and transported from the factory to a remote construction site by vehicle or the like. In order to attach an air conditioner with a structure that is premised on installation in a suspended state to the frame at the factory, even in the case of adopting the form of the above, in order to prevent damage to the attachment part provided in the air conditioner. , It is necessary to handle the air conditioner in a proper posture.

The present invention has been made in view of such circumstances, and an object of the present invention is to provide a method for manufacturing a ceiling-mounted air-conditioning unit in which an air-conditioning device that is premised on installation in a suspended state is attached to a frame.

In order to solve the above problems, in the present invention, after attaching the upper frame from the upper side to a plurality of air conditioners assembled to each other, the upper frame is raised and the lower frame is attached from the lower side of the plurality of air conditioners.

Specifically, the present invention is a method for manufacturing a ceiling-mounted air-conditioning unit, in which a plurality of equipment-assembling steps for assembling a plurality of ceiling-mounted air-conditioning devices to each other and a plurality of air-conditioning devices assembled to each other from above. The upper frame mounting process of mounting the upper frame that forms the upper part of the frame that integrally holds the air conditioner and the upper frame to which multiple air conditioners are mounted are raised, and from the lower side of the multiple air conditioners, the frame It has a lower frame mounting step of mounting the lower frame forming the lower part.

In the above manufacturing method, after attaching the upper frame from the upper side to a plurality of air conditioners assembled to each other, the upper frame is raised and the lower frame is attached from the lower side of the plurality of air conditioners. When attaching an air conditioner with a structure that is supposed to be installed to the frame, it is possible to easily perform the manufacturing work while keeping the air conditioner in an appropriate posture. Therefore, the mounting portion provided on the air conditioner is not damaged. Therefore, it is possible to efficiently manufacture the ceiling-mounted air conditioning unit.

The above manufacturing method includes a preparatory step of preparing a frame member that integrally holds a plurality of air conditioners for ceiling suspension, an upper frame assembly step of assembling the upper frame forming the upper part of the frame, and a frame assembly process. It may further include a lower frame assembly step of assembling the lower frame forming the lower portion. According to this, since the upper frame and the lower frame are assembled, the assembly of the ceiling-mounted air conditioning unit can be started from the state where the upper frame and the lower frame are not present.

Further, in the upper frame assembling step, the upper frame may be assembled upside down and then turned upside down. According to this, even if the upper frame has a form in which a member for attaching the lower frame is projected downward, the upper frame can be assembled in a stable posture.

Further, the above manufacturing method further includes a frame transfer process for transferring the upper frame assembled by the upper frame assembly process and the lower frame assembled by the lower frame assembly process, and further includes an equipment assembly process and an upper frame attachment process. And, in the lower frame attaching step, the upper frame and the lower frame transferred from another place by the frame transfer step may be used. According to this, each step can be performed at an appropriate place.

Further, in the above manufacturing method, when the frame is tilted together with the air conditioner from the posture when the air conditioner is suspended from the ceiling, the air conditioner has a ceiling suspension as a regulating means for restricting the relative movement of the air conditioner with respect to the frame. It may further have a regulatory means mounting step of mounting to the mounting portion for use. According to this, the manufactured ceiling-mounted air-conditioning unit can be transported in a sideways posture.

Further, in the lower frame attaching step, the upper frame to which the plurality of air conditioners are attached may be lifted by a hoisting machine, and the lower frame may be attached from the lower side of the plurality of air conditioners. According to this, the upper frame to which a plurality of air conditioners are attached can be easily raised.

Further, the above-mentioned manufacturing method may further include an auxiliary frame attaching step of attaching an auxiliary frame for supporting the piping provided in the air conditioner to the upper frame. According to this, the piping provided in the air conditioner can be protected by the auxiliary frame during the production of the ceiling-mounted air conditioner unit.

According to the above-mentioned method for manufacturing a ceiling-mounted air-conditioning unit, an air-conditioning device that is premised on being installed in a suspended state can be easily attached to the frame while maintaining an appropriate posture.

FIG. 1 is a view showing a state in which the ceiling-mounted air conditioning unit is viewed from diagonally above. FIG. 2 is a view showing a state in which the ceiling-mounted air conditioning unit is viewed from the side. FIG. 3 is a diagram showing a frame in the ceiling-mounted air conditioning unit in a completed state. FIG. 4 is a diagram showing an example of an assembly process of the upper frame. FIG. 5 is a diagram showing an example of the work of inverting the top and bottom of the upper frame. FIG. 6 is a first diagram showing an example of an assembly process of the lower frame. FIG. 7 is a second diagram showing an example of the assembly process of the lower frame. FIG. 8 is a first diagram showing an example of a process of assembling the air conditioner. FIG. 9 is a second diagram showing an example of a process of assembling the air conditioner. FIG. 10 is a diagram showing a mounting method in the ceiling-suspended mounting portion of the air conditioner main body. FIG. 11 is a diagram showing an example of a process of attaching the lower frame to the air conditioner. FIG. 12 is a view showing how the lower frame has been attached. FIG. 13 is a diagram showing how the auxiliary frame is attached. FIG. 14 is a diagram showing a method of mounting the ceiling-mounted air conditioning unit on the vehicle. FIG. 15 is a diagram showing members provided in the ceiling-mounted air conditioning unit. FIG. 16 is a diagram showing temporary fixing. FIG. 17 is a diagram showing a state in which the temporary fixing is attached. FIG. 18 is a diagram showing an example of a trolley on which a ceiling-mounted air conditioning unit is mounted. FIG. 19 is a diagram showing how to use the dolly. FIG. 20 is a first modification of the ceiling-mounted air conditioning unit. FIG. 21 is a diagram comparing the outer dimensions of the ceiling-mounted air conditioning unit of the embodiment and the modified example. FIG. 22 is a diagram showing an example of obstacle prevention means provided on the auxiliary frame. FIG. 23 is a diagram showing an example of an obstacle.

Hereinafter, embodiments of the present invention will be described. The embodiments shown below are examples of embodiments of the present invention, and the technical scope of the present invention is not limited to the following embodiments.

FIG. 1 is a view showing a state in which the ceiling-mounted air conditioning unit 1 is viewed from diagonally above. Further, FIG. 2 is a view showing a state in which the ceiling-mounted air conditioning unit 1 is viewed from the side. FIG. 1 shows a state in which the ceiling-mounted air conditioning unit 1 is suspended from the ceiling by suspension bolts K. For convenience of explanation, in the present embodiment, the Z-axis direction is defined as the upward direction of the ceiling-mounted air conditioning unit 1 in FIGS. 1 and 2, and the direction along the XY plane determined by the X-axis and the Y-axis is the ceiling-mounted air conditioning unit. Defined as the lateral direction of unit 1. Further, the suspension bolt K for suspending the ceiling suspension air conditioning unit 1 from the ceiling of the building is usually provided with a steady rest F as shown in FIG. 1, but the steady rest provided for the suspension bolt K is like this. It is not limited to any form. The steady rest provided in the steady rest F may be, for example, a cross type that intersects diagonally in a top view. Further, for the steady rest, for example, when the ceiling-mounted air-conditioning unit 1 is directly attached to the ceiling, or when the hanging bolt K for suspending the ceiling-mounted air-conditioning unit 1 is extremely short, a metal fitting stronger than the suspension bolt K is used. When the suspended air conditioning unit 1 is rigidly connected to the ceiling, it is omitted. Further, the steady rest is not limited to the form of being attached to the upper part and the lower part of the suspension bolt K, and for example, the upper end is embedded in the ceiling and the lower end is connected to the ceiling suspension air conditioning unit 1. Good.

As shown in FIGS. 1 and 2, the ceiling-mounted air conditioning unit 1 is an air conditioning unit in which an air conditioner main body 3, an air supply chamber 4, and a return air chamber 5 are assembled and integrated with a frame 2. The ceiling-mounted air conditioning unit 1 includes a refrigerant pipe, a water pipe, a drain pipe, a drain pump, a damper, an intake / exhaust grill, a filter, and various other air conditioning devices, in addition to the air supply chamber 4 and the return air chamber 5. The ceiling-mounted air-conditioning unit 1 is a narrow space between the floor that constitutes the upper floor or rooftop of the building and the decorative ceiling panel that constitutes the ceiling surface of the floor on which the ceiling-mounted air-conditioning unit 1 is installed. It is installed in the space behind the ceiling. Therefore, as shown in FIG. 1, the ceiling-mounted air conditioning unit 1 basically has a horizontally long external shape in which the horizontal dimension is longer than the vertical dimension.

Further, when the ceiling-mounted air-conditioning unit 1 is installed on the back side of the ceiling panel, the ceiling-mounted air-conditioning unit 1 is in a concealed state. However, the ceiling-mounted air conditioning unit 1 is not limited to such a form in which it is installed in a concealed state. For example, when a decorative ceiling panel is not installed on the ceiling, the ceiling-mounted air conditioning unit 1 is in a state where it can be visually recognized by a person in the living room.

Further, the hanging bolt K may be screwed into a nut for supporting the hanging bolt embedded in the floor concrete constituting the floor, but instead, it is attached to a structural material such as H steel constituting the beam. It may be screwed into various members such as hangers.

As shown in FIGS. 1 and 2, the ceiling-mounted air conditioning unit 1 connects the air supply chamber 4 to the exhaust port side of the air conditioner main body 3 and connects the return air chamber 5 to the intake port side of the air conditioner main body 3. doing. Therefore, the ceiling-mounted air conditioner unit 1 has a form in which the air conditioner main body 3 is arranged at the center of the frame 2 and the air conditioner main body 3 is sandwiched between the air supply chamber 4 and the return air chamber 5. The connecting portion between the air conditioner main body 3 and the air supply chamber 4 and the connecting portion between the return air chamber 5 and the air conditioner main body 3 are connected by screws. The connecting portion between the air conditioner main body 3 and the air supply chamber 4 and the connecting portion between the return air chamber 5 and the air supply chamber 4 are softly connected so that some relative movement is possible. You may. In this case, by making the other opening to be fitted into one opening slightly smaller and filling the gap between the openings with a sealing material such as a flexible sponge packing for airtightness, some relative movement can be achieved. It becomes a possible flexible connection structure.

First, the air conditioner main body 3 will be described. The air conditioner main body 3 is a package unit in which a coil through which a heat medium for temperature adjustment flows flows inside a rectangular housing 31 and an electric fan for blowing air. The pipe 33 is also provided. Examples of the auxiliary machine 32 include a valve for switching the flow path of the heat medium pipe through which the heat medium flowing through the coil passes, a drainage pump for draining the drain pan that receives the water condensed in the coil, and the like. The air conditioner main body 3 may be an air conditioner in which the refrigerant of the refrigerating cycle that repeats evaporation and condensation is supplied through the incidental pipe 33 and causes the coil in the machine to function as a condenser or an evaporator, or through the incidental pipe 33. It may be an air conditioner that cools or heats the air by passing the supplied cold water or hot water through a coil in the machine. Further, the air conditioner main body 3 may have the auxiliary machine 32 omitted.

The air conditioner main body 3 is supported by attaching the ceiling suspension mounting portion 34 provided on the outer surface of the housing 31 to the hanging metal fitting 26 provided on the frame 2. Since the air conditioner main body 3 is an off-the-shelf device that is supposed to be used in a suspended state by a hanging bracket such as a hanging bolt K provided in a building, the ceiling suspension mounting portion 34 is also a hanging bolt K. It is designed on the assumption that it can be attached to such a hanging bracket. Therefore, in the ceiling-mounted air conditioner unit 1 of the present embodiment, the air conditioner main body 3 is suspended in the frame 2 by making the hanging metal fitting 26 provided on the frame 2 look like such a hanging metal fitting. It is designed to be in the lowered state. Further, since the air conditioner main body 3 has a built-in electric fan, a vibration-proof rubber 35 is provided on the ceiling-suspended mounting portion 34, and the vibration transmitted from the air conditioner main body 3 to the frame 2 is vibration-proof rubber. Block at 35. As a result, the generation of abnormal noise or the like due to the resonance of the frame 2 due to the vibration generated by the air conditioner main body 3 is suppressed as much as possible. Since the anti-vibration rubber 35 has a vibration-proof permissible direction that allows movement for vibration-proof, the vibration-proof permissible direction is defined when the rubber is transported under a load. It is desirable that the direction of load (direction of gravity) is almost the same. The means for blocking the vibration of the air conditioner main body 3 is not limited to the form in which the anti-vibration rubber 35 is interposed between the frame 2 and the air conditioner main body 3 in this way. For example, a spring or rubber may be provided at the connecting portion between the frame 2 and the suspension bolt K. However, in this case, since the frame 2 can move relative to the hanging bolt K, the frame 2 itself does not have earthquake resistance. Therefore, from the viewpoint of ensuring the seismic resistance of the entire ceiling-mounted air conditioning unit 1, in the present embodiment, the frame 2 itself has an seismic structure by rigidly connecting the connecting portion between the frame 2 and the hanging bolt K, instead of the frame 2. A vibration-proof rubber 35 is interposed between the frame 2 and the air conditioner main body 3.

Next, the air supply chamber 4 will be described. The air supply chamber 4 is a chamber for dividing the air-conditioned air blown out from the air conditioner main body 3 into a plurality of air supply ducts stretched around various parts of the building. Therefore, the rectangular housing 41 forming the internal space of the chamber is provided with a plurality of connecting openings 42 for connecting the air supply ducts. In FIGS. 1 and 2, six connecting openings 42 are provided in the housing 41, but the number of connecting openings 42 depends on the size of the housing 41, the diameter of the connecting openings 42, and the like. Will be changed as appropriate. Further, the air supply chamber 4 is not limited to a form in which an air supply duct is connected to all six connecting openings 42. The number of air supply ducts actually connected to the air supply chamber 4 depends on the number of air supply ducts provided at the location where the ceiling-mounted air conditioning unit 1 is installed. Therefore, if there are, for example, two air supply ducts provided at the location where the ceiling-mounted air conditioning unit 1 is installed, the openings of four of the six connecting openings 42 in the air supply chamber 4 are closed. It is used in the state where it is used. Therefore, the connecting opening 42 in which the opening is closed in this way may be omitted in advance, and an air supply chamber 4 provided with only the required number of connecting openings 42 may be manufactured and incorporated into the ceiling-mounted air conditioning unit 1. However, in the present embodiment, in order to improve the construction efficiency and shorten the manufacturing period of the members, it is proposed to prepare a large number of common ceiling-mounted air-conditioning units 1 that can be applied to various installation locations. However, the ceiling-mounted air-conditioning unit 1 disclosed in the present application is not limited to a form that can be commonly applied in various places as described above. The ceiling-mounted air conditioning unit 1 may include an air supply chamber 4 having a number of connecting openings 42 according to the installation location.

Next, the return air chamber 5 will be described. The return air chamber 5 is a chamber for merging the air flowing from a plurality of return air ducts stretched around the building. Therefore, the return air chamber 5 is also provided with a plurality of connection openings for connecting the return air ducts, similarly to the air supply chamber 4. Like the air supply chamber 4, the return air chamber 5 also adopts a form in which a large number of connecting openings are provided so that it can be applied to various installation locations, but the ceiling-mounted air conditioning unit 1 is installed at the same installation location as described above. It may be provided with a return air chamber 5 having a corresponding number of connecting openings. The return air chamber 5 may be omitted depending on the building.

Since the air supply chamber 4 and the return air chamber 5 do not have a built-in drive unit such as an electric fan like the air conditioner main body 3, they basically do not generate vibration. Therefore, in the present embodiment, the air supply chamber 4 and the return air chamber 5 are attached to the frame 2 without using a component such as a vibration isolator that blocks vibration transmission. However, the ceiling-mounted air conditioning unit 1 is not limited to such a form. The ceiling-mounted air conditioning unit 1 may have, for example, an air supply chamber 4 and a return air chamber 5 attached to the frame 2 via anti-vibration rubber. Further, the ceiling-suspended air-conditioning unit 1 may have, for example, a form in which the air supply chamber 4 and the return air chamber 5 are attached to the frame 2 by a member having a suspended structure like the air conditioner main body 3.

In this way, the ceiling-mounted air conditioning unit 1 in which the air conditioner main body 3, the air supply chamber 4, and the return air chamber 5 are integrated is compared with each of the air conditioner main body 3, the air supply chamber 4, and the return air chamber 5. Naturally, the weight is large. Therefore, weight reduction is required in order to lift it with an indoor aerial work platform and attach it near the ceiling of the building. Therefore, in the ceiling-mounted air conditioning unit 1 of the present embodiment, the frame 2 is made of an aluminum member. Therefore, even in the portion where the angle members 21 constituting the frame 2 are fastened to each other, by fastening the rib plates 22 and 23 with bolts, sufficient strength is exhibited as compared with the case where the angle members 21 are welded to each other. I have to. Further, in order to strengthen the strength near the end portion of the frame 2, a bar screw 25 is provided to fasten the end portions of the angle member 21 to each other at a portion corresponding to the corner of the frame 2. Further, among the fastening portions of the plurality of angle members 21 on the frame 2, one rib is provided for each portion (the portion of reference numeral 23) where the load is applied in the direction (plane direction) along the plate surface of the rib plate. While the plate 23 is provided, as for the portion where the load in the bending direction of the rib plate is applied (the portion of reference numeral 22), the number of rib plates 22 capable of satisfying the thickness required for ensuring the strength is provided. It is provided. If the number of sheets that can satisfy the thickness required to secure the strength is, for example, two, by fastening the angle members 21 to each other in a state where the angle members 21 are sandwiched between the two rib plates 22. , The rib plate 22 is prevented from being deformed or damaged due to a load. For example, as can be seen from FIG. 1, the hanging portion 24 provided on the frame 2 for attaching the ceiling-mounted air conditioning unit 1 to the hanging bolt K is in the middle of the angle member 21 extending in the lateral direction. When the ceiling-suspended air-conditioning unit 1 is suspended by the suspension bolt K, the load of the entire ceiling-suspended air-conditioning unit 1 is applied to the end of the angle member 21. Therefore, providing a plurality of rib plates 22 at such locations is effective in ensuring the strength of the frame 2.

The above-mentioned ceiling-mounted air-conditioning unit 1 is manufactured at a factory and then transported to a construction site using a transportation vehicle such as a truck. Hereinafter, a method of manufacturing the ceiling-mounted air conditioning unit 1 will be described.

FIG. 3 is a diagram showing a frame 2 in the ceiling-mounted air conditioning unit 1 in a completed state. In FIG. 3, for ease of understanding, a diagram showing only the frame 2 is shown side by side with a completed drawing of the ceiling-mounted air conditioning unit 1.

As can be seen from FIG. 3, the frame 2 has a three-dimensional structure, and has a portion forming the upper portion of the ceiling-mounted air conditioning unit 1 and a portion forming the lower portion of the ceiling-mounted air conditioning unit 1. There is. The method for manufacturing the ceiling-mounted air-conditioning unit 1 in the present embodiment includes a step of manufacturing a portion of the frame 2 that forms the upper portion of the ceiling-mounted air-conditioning unit 1 and a method of forming the lower portion of the frame 2 that forms the lower portion of the ceiling-mounted air conditioning unit 1. It has several steps, such as the process of manufacturing the part to be used. Therefore, for convenience of explanation, the portion of the frame 2 that forms the upper part of the ceiling-mounted air conditioning unit 1 will be referred to as the upper frame 2U, and the portion of the frame 2 that forms the lower portion of the ceiling-mounted air conditioning unit 1 will be referred to as the lower frame 2B.

In the method of manufacturing the ceiling-mounted air conditioning unit 1 in the present embodiment, the upper frame 2U and the lower frame 2B are assembled separately. FIG. 4 is a diagram showing an example of an assembly process of the upper frame 2U. As shown in FIG. 4, the upper frame 2U is a structure in which a plurality of angle members 21 are fastened to each other with bolts and nuts. In the manufacturing process of the upper frame 2U, a plurality of angle members 21 prepared by using a material processing machine or the like are butted against each other, and in this state, they are fastened with bolts and nuts to form a structure. The rib plate 22 is appropriately used in combination with the portion where the angle members 21 are fastened at a right angle. As a result, the overall strength of the upper frame 2U formed by fastening the angle members 21 to each other is ensured.

As described above, in each part of the frame 2, the number of rib plates 22 capable of satisfying the thickness required for ensuring the strength is provided at the portion where the load of the entire ceiling-mounted air conditioning unit 1 is applied. As described above, the strength of the frame 2 is ensured. When, for example, two rib plates 22 are provided at such a location, the two rib plates 22 are arranged so as to sandwich the two rib plates 22 from both sides with respect to the fastening portion of the angle member 21. Then, a bolt is inserted into a screw hole on one of the two rib plates 22. The bolt inserted into the screw hole passes through the screw hole of the first rib plate 22, the screw hole of the angle member 21, and the screw hole of the second rib plate 22. Then, the tip of the bolt protrudes from the screw hole of the second rib plate 22. By screwing the nut into the tip of the bolt, the fastening portion of the angle member 21 is sandwiched between the two rib plates 22 from both sides.

Of the upper frame 2U shown in FIG. 4, the square frame (the central frame of the three frames formed on the upper frame 2U) whose four sides are all surrounded by the angle member 21 is the suspension position of the air conditioner main body 3. Corresponds to. Then, in the upper frame 2U, two square frames (two outer frames of the three frames formed in the upper frame 2U) whose four sides are surrounded by three angle members 21 and one bar screw 25 are supplied. Corresponds to the air chamber 4 and the return air chamber 5. Therefore, the outer square frame formed by the entire upper frame 2U forms the exoskeleton of the frame 2. The same applies to the lower frame 2B. Therefore, the air conditioner main body 3, the air supply chamber 4, and the return air chamber 5 are the exoskeleton of the frame 2 formed by the square frame forming the outermost part of the upper frame 2U and the outermost part of the lower frame 2B. It fits inside the chamber and is protected by the exoskeleton even during transportation of the ceiling-mounted air conditioning unit 1. The bar screw 25 has a configuration that is not particularly necessary for holding the air conditioner main body 3, the air supply chamber 4, and the return air chamber 5 on the frame 2, but can withstand the impact force of an object that collides with the end of the angle member 21. , The frame 2 functions as a configuration necessary for exhibiting structural strength as an exoskeleton.

During the production of the upper frame 2U, the work is performed with the upper frame 2U turned upside down. Then, when the production of the upper frame 2U is completed, the work of inverting the top and bottom of the upper frame 2U is performed so that the top and bottom of the upper frame 2U face in the correct direction. FIG. 5 is a diagram showing an example of the work of inverting the upper frame 2U upside down. When the production of the upper frame 2U is completed, for example, as shown in FIG. 5, the work of inverting the upper frame 2U upside down is performed.

FIG. 6 is a first diagram showing an example of an assembly process of the lower frame 2B. Further, FIG. 7 is a second diagram showing an example of an assembly process of the lower frame 2B. As shown in FIGS. 6 and 7, the lower frame 2B is a structure in which a plurality of angle members 21 are fastened to each other with bolts and nuts, similarly to the upper frame 2U. In the manufacturing process of the lower frame 2B, a plurality of angle members 21 prepared by using a material processing machine or the like are butted against each other, and in this state, they are fastened with bolts and nuts to form a structure. Further, the angle member 21 and the rib plate 23 are fastened so that the rib plate 23 for connecting the upper frame 2U protrudes upward. In the lower frame 2B, not only the rib plate 22 and the rib plate 23 but also the L-shaped metal fitting 29 is used for the fastening portion between the angle members 21. Further, as shown in FIG. 7, a support member 27, which will be described later, and a vibration-proof steady rest 2A for preventing the air-conditioning equipment attached to the frame 2 from swinging with respect to the frame 2 are also attached to the lower frame 2B.

After assembling the upper frame 2U and the lower frame 2B, the air conditioner is assembled. FIG. 8 is a first diagram showing an example of a process of assembling the air conditioner. Further, FIG. 9 is a second diagram showing an example of a process of assembling the air conditioner. An air conditioner main body 3, an air supply chamber 4, and a return air chamber 5 are prepared at the site where the ceiling-mounted air conditioning unit 1 is manufactured. Then, the air conditioner main body 3 is placed on a work table or the like with the top and bottom facing the correct direction. Therefore, when assembling the air conditioner, first, as shown in FIG. 8, the upper frame 2U with the top and bottom facing the correct direction is arranged so as to cover from the upper side of the air conditioner main body 3, and the air conditioner main body 3 is attached. Attach the part to the upper frame 2U. Next, as shown in FIG. 9, the air supply chamber 4 and the return air chamber 5 are assembled. The air supply chamber 4 is connected to the air outlet of the air conditioner main body 3. Further, the return air chamber 5 is connected to the suction port of the air conditioner main body 3. The air conditioner main body 3, the air supply chamber 4, and the return air chamber 5 are all connected to each other by screws with their top and bottom facing the correct direction.

As described above, the air conditioner main body 3, the air supply chamber 4, and the return air chamber 5 are designed on the assumption that they are suspended from the ceiling. For example, the air conditioner main body 3 is supported by the ceiling suspension mounting portion 34 provided on the outer surface of the housing 31 being attached to the hanging metal fitting 26 of the frame 2. The partially enlarged view of FIG. 9 shows the ceiling-mounted mounting portion 34 provided on the air conditioner main body 3 and its surroundings. FIG. 10 is a diagram showing a mounting method of the ceiling-mounted mounting portion 34 of the air conditioner main body 3. As shown in FIG. 10, the ceiling mount mounting portion 34 is inserted into a screw hole provided in the angle member 21 of the upper frame 2U, and a bar screw-shaped hanging bracket 26 fixed with a nut is inserted. It is fixed in a state of being sandwiched by a nut screwed into the hanging metal fitting 26 via the anti-vibration rubber 35 and the temporary fixing 6. The temporary fixing 6 is removed after the ceiling-mounted air conditioning unit 1 is transferred to the site where it is installed. The air conditioner main body 3 was connected to the air supply chamber 4 and the return air chamber 5 with screws and was in a state like temporary fixing, but is fixed to the hanging metal fitting 26 by the ceiling suspension mounting portion 34 in this way. As a result, the air conditioners attached to the frame 2 are firmly fixed to each other.

FIG. 11 is a diagram showing an example of a process of attaching the lower frame 2B to the air conditioner. As described above, the air conditioner main body 3, the air supply chamber 4, and the return air chamber 5 are attached to the upper frame 2U. Therefore, when the lower frame 2B is attached to the upper frame 2U to complete the frame 2, the upper frame 2U is lifted by a hoist (also referred to as a "hoist") as shown in FIG. As described above, the air conditioner main body 3, the air supply chamber 4, and the return air chamber 5 are attached to the upper frame 2U by using the attachment portions provided in each air conditioner for suspending from the ceiling. Therefore, when the upper frame 2U is lifted by the hoisting machine, the air conditioner main body 3, the air supply chamber 4, and the return air chamber 5 are lifted together with the upper frame 2U in a state of being suspended from the upper frame 2U. After the upper frame 2U is lifted by the hoisting machine, the lower frame 2B is attached to the upper frame 2U from the lower side of the air conditioner main body 3, the air supply chamber 4, and the return air chamber 5 suspended from the upper frame 2U. When arranging the lower frame 2B below the air conditioner main body 3, the air supply chamber 4, and the return air chamber 5, the hoisting machine that suspends the upper frame 2U is moved onto the lower frame 2B, or the upper part. The lower frame 2B is moved to the lower side of the air conditioner main body 3, the air supply chamber 4, and the return air chamber 5 suspended from the frame 2U. When moving, the air conditioner main body 3, the air supply chamber 4, and the return air chamber 5 suspended from the upper frame 2U do not interfere with the support member 27 and the steady rest 2A provided on the lower frame 2B, for example, air conditioning. The moving operation is performed so that the machine body 3 is located between the two support members 27. Then, by fastening the rib plate 23 of the lower frame 2B to the angle member 21 of the upper frame 2U with bolts and nuts, the lower frame 2B is attached to the upper frame 2U, and the frame 2 is formed.

FIG. 12 is a view showing how the lower frame 2B has been attached. After attaching the lower frame 2B to the upper frame 2U, the hoisting machine that suspends the upper frame 2U is lowered, and the lifting wire attached to the upper frame 2U is removed from the upper frame 2U. Then, the parts for which the installation work remains are attached and cured so that the ceiling-mounted air conditioning unit 1 can be transported to the construction site.

FIG. 13 is a diagram showing a state in which the auxiliary frame 103 is attached. As described above, the air conditioner main body 3 is provided with various pipes. Therefore, in assembling the ceiling-mounted air conditioning unit 1, an auxiliary frame 103 for supporting these pipes is attached to the upper frame 2U. The auxiliary frame 103 may be performed after the lower frame 2B is attached to the upper frame 2U, but in order to protect the piping of the air conditioner main body 3 while assembling the ceiling-mounted air conditioning unit 1, for example, the upper frame 103. It may be attached to the upper frame 2U when assembling the 2U.

The ceiling-mounted air conditioning unit 1 is completed by the above manufacturing method. According to the above manufacturing method, when an air conditioner having a structure that is premised on being installed in a suspended state, such as a commercially available concealed air conditioner, is attached to the frame 2 at a factory, the air conditioner is attached. Since it can be easily mounted while being maintained in an appropriate posture, the mounting portion provided in the air conditioner is not damaged. Therefore, the ceiling-mounted air conditioning unit 1 can be efficiently manufactured.

The ceiling-mounted air conditioning unit 1 can be transported from the factory to the construction site by, for example, the following method. FIG. 14 is a diagram showing a method of mounting the ceiling-mounted air conditioning unit 1 on a vehicle. As described above, the ceiling-mounted air-conditioning unit 1 has a horizontally long external shape in which the horizontal dimension is longer than the vertical dimension in order to install it in the narrow space behind the ceiling between the floor and the ceiling panel. It has become. The air conditioner main body 3 is suspended in the frame 2 by a hanging metal fitting 26 provided on the frame 2. Therefore, for example, when the ceiling-mounted air-conditioning unit 1 assembled at the factory is transported to the construction site, normally, as shown in FIG. 14A, the vehicle V without tilting the ceiling-mounted air-conditioning unit 1 sideways. It will be stacked flat on the loading platform as it is. However, in this case, the space above the loading platform of the ceiling-mounted air-conditioning unit 1 is not effectively utilized, and the ceiling-mounted air-conditioning unit 1 cannot be efficiently transported. Therefore, for example, as shown in FIG. 14B, it is conceivable that the ceiling-mounted air conditioning unit 1 is loaded on the loading platform of the vehicle V in a state of being laid on its side. If the ceiling-mounted air-conditioning unit 1 is laid on its side and loaded on the loading platform of the ceiling-mounted air-conditioning unit 1, the upper space of the loading platform of the vehicle V can be effectively utilized.

However, when the ceiling-mounted air conditioner unit 1 is transported on its side as described above, the air conditioner main body 3 may move relative to the frame 2 in the lateral direction with respect to the hanging direction of the hanging metal fitting 26. When the air conditioner main body 3 moves relative to the hanging direction of the hanging metal fitting 26 in the lateral direction, the hanging metal fitting 26 connecting the frame 2 and the air conditioner main body 3 is deformed or mounted for ceiling suspension. The anti-vibration rubber 35 between the portion 34 and the hanging metal fitting 26 may be damaged.

Therefore, when transporting the ceiling-mounted air-conditioning unit 1 of the present embodiment, the following measures are taken to prevent such a problem. FIG. 15 is a diagram showing a member provided in the ceiling-mounted air conditioning unit 1. As shown in FIG. 15, in the ceiling-mounted air-conditioning unit 1 of the present embodiment, a temporary fixing 6 is provided on the ceiling-mounted mounting portion 34. Further, the frame 2 is provided with a support member 27 that limits the relative movement of the air conditioner main body 3 with respect to the frame 2 within a predetermined range. Since the support member 27 limits the relative movement of the air conditioner main body 3 with respect to the frame 2 within a predetermined range, the support member 27 does not come into contact with the frame 2 when the ceiling-mounted air conditioning unit 1 is in a normal posture. Then, when the ceiling-mounted air conditioner unit 1 is laid on its side and the air conditioner main body 3 moves by its own weight in the direction of gravity, the air conditioner main body 3 comes into contact with the support member 27 provided on the frame 2, and the air conditioner main body 3 is moved. It is in a state of being supported from below by the support member 27. Further, regarding the anti-vibration rubber 35, the temporary fixing 6 regulates the relative movement between the hanging metal fitting 26 and the ceiling-mounted mounting portion 34 so that the lateral load of the air conditioner main body 3 is not applied to the frame 2. ing. The temporary fixing 6 and the support member 27 are attached to the frame 2 at an appropriate timing in the manufacturing process of the ceiling-mounted air conditioning unit 1 described above. Then, the temporary fixing 6 is removed after the transportation of the ceiling-mounted air conditioning unit 1 is completed.

FIG. 16 is a diagram showing a temporary fixing 6. The temporary fixing 6 is a U-shaped metal fitting in a cross-sectional view, and has a flat and rectangular top plate portion 61 and side wall portions 62 provided along two long sides of the top plate portion 61, respectively. The top plate portion 61 is provided with a notch portion 63 slightly larger than the outer diameter of the hanging metal fitting 26. The temporary fixing 6 is a temporary fixing for transportation that is attached when the ceiling-mounted air conditioning unit 1 is transported. Such a temporary fixing 6 is attached to the ceiling suspension mounting portion 34 in the following state.

FIG. 17 is a diagram showing an attached state of the temporary fixing 6. In the temporary fixing 6, the upper surface of the top plate portion 61 is pressed by the nut screwed into the hanging metal fitting 26. Then, the lower ends of the two side wall portions 62 along the long sides of the top plate portion 61 press the ceiling suspension mounting portion 34 with the pressing force of the nut that presses the upper surface of the top plate portion 61, thereby causing the hanging metal fittings. It prevents the 26 and the ceiling mount mounting portion 34 from moving relative to each other due to the deformation of the anti-vibration rubber 35. Further, the pressing force applied by the side wall portion 62 of the temporary fixing 6 to the ceiling suspension mounting portion 34 matches the direction of the load assumed in the design of the anti-vibration rubber 35. Therefore, unless the nut that presses the upper surface of the top plate portion 61 is excessively tightened, it is extremely unlikely that the pressing force will destroy the anti-vibration rubber 35.

As described above, since the ceiling-suspended air-conditioning unit 1 is provided with the temporary fixing 6 and the support member 27, even if the ceiling-suspended air-conditioning unit 1 is turned sideways to be mounted on the loading platform of the vehicle V, the ceiling-mounted air conditioning unit 1 is attached to the frame 2. The relative movement of the air conditioner body 3 is restricted. Therefore, even if the air conditioner main body 3 is attached to the frame 2 in a suspended state, the hanging metal fitting 26, the ceiling-mounted attachment portion 34, and the anti-vibration rubber 35 are not damaged by the weight of the air conditioner main body 3. Therefore, the ceiling-mounted air-conditioning unit 1 of the present embodiment can be efficiently mounted in the limited space of the loading platform of the vehicle V. As a matter of course, the regulation means such as the temporary fixing 6 and the support member 27 may be omitted when the ceiling-mounted air conditioning unit 1 is not transported in a sideways posture. Further, in FIG. 14A, the ceiling-mounted air-conditioning unit 1 is shown in a non-stackable form, but the ceiling-mounted air-conditioning unit 1 of the present embodiment is not limited to those that cannot be stacked. The ceiling-mounted air conditioning unit 1 of the present embodiment may be stacked in a plurality of stages in a flat stacking state.

FIG. 18 is a diagram showing an example of a trolley on which the ceiling-mounted air conditioning unit 1 is mounted. The ceiling-mounted air conditioning unit 1 can be transported by, for example, a trolley 112 as shown in FIG. The carriage 112 includes a bottom 112A forming the bottom of the carriage 112, a side 112B surrounding the ceiling-mounted air conditioning unit 1 from the side, and a hinge 112C and a bottom 112A for rotatably connecting the side 112B to the bottom 112A in the lateral direction. A wheel 112D provided on the lower side is provided. Since the side portion 112B that supports the ceiling-mounted air conditioning unit 1 from the side of the trolley 112 can rotate in a direction in which the side portion 112B is laid down with respect to the bottom portion 112A, for example, the following transportation is possible.

FIG. 19 is a diagram showing how to use the dolly 112. As shown in FIG. 19A, for example, the carriage 112 can be equipped with a plurality of ceiling-mounted air conditioning units 1. Further, the side portion 112B that supports the ceiling-mounted air conditioning unit 1 from the side can be rotated in a direction in which the side portion 112B is laid down with respect to the bottom portion 112A. Therefore, for example, in a factory where a ceiling-mounted air-conditioning unit 1 is manufactured, a trolley 112 equipped with the ceiling-mounted air-conditioning unit 1 is mounted on a ceiling-mounted air conditioner by using a truck for transportation, a temporary or permanent elevator at a construction site, or the like. After transferring to the vicinity of the installation location of the unit 1, the ceiling-mounted air conditioning unit 1 can be unloaded from the carriage 112 as follows. That is, after the trolley 112 on which the ceiling-mounted air-conditioning unit 1 is mounted is transferred to the vicinity of the installation location of the ceiling-mounted air-conditioning unit 1, the side portion 112B is laterally extended together with the ceiling-mounted air-conditioning unit 1 as shown in FIG. 19 (B). Put it in a state. When the ceiling-mounted air-conditioning unit 1 is mounted on the trolley 112, the ceiling-mounted air-conditioning unit 1 is mounted so that the posture of the ceiling-mounted air-conditioning unit 1 is correctly vertically oriented when the ceiling-mounted air-conditioning unit 1 is laid on its side together with the side 112B. Then, in the state of FIG. 19B, the upper surface of the ceiling-mounted air conditioning unit 1 faces upward. Therefore, the operator lifts the ceiling-mounted air-conditioning unit 1 to the ceiling while still mounted on a part of the frame constituting the side portion 112B and fixes it to the suspension bolt K, or mounts it on the side portion 112B. By directly lifting the ceiling-mounted air-conditioning unit 1 in the state of being up to the ceiling with an elevator or the like provided with a fork-shaped lifting portion, the ceiling-mounted air-conditioning unit 1 can be easily installed on the ceiling. After attaching the ceiling-mounted air-conditioning unit 1 to the ceiling, a part of the frame constituting the side portion 112B is removed from the ceiling-mounted air-conditioning unit 1 and reassembled to the carriage 112.

The ceiling-mounted air conditioning unit 1 can be transported in this way. The ceiling-mounted air conditioning unit 1 is assembled at the construction site in an extremely short time as compared with the case where the air conditioner main body 3, the air supply chamber 4, and the return air chamber 5 are carried into the construction site in separate states and assembled. Since the work can be completed, the construction period at the construction site can be significantly shortened. Further, since the ceiling-mounted air-conditioning unit 1 can be assembled at the factory, efficient assembly is possible in an environment suitable for assembling the ceiling-mounted air-conditioning unit 1. Therefore, it is possible to shorten the total man-hours as compared with the case where the air conditioner main body 3, the air supply chamber 4, and the return air chamber 5 are carried into the construction site in separate states and the assembly work is performed. However, the ceiling-mounted air conditioning unit 1 is not limited to the form completed at the factory. For example, the frame 2 is manufactured as a semi-finished product, the frame 2 is transferred to a place different from the manufacturing place of the frame 2, the air conditioner main body 3 and the like are attached to the frame 2, and then the frame 2 is installed at the construction site. There may be.

Further, the ceiling-mounted air conditioning unit 1 of the above embodiment may be deformed as follows. FIG. 20 is a first modification of the ceiling-mounted air conditioning unit 1. In the ceiling-mounted air conditioning unit 1 of the first modification, a duct connecting portion 101 is provided instead of the connecting opening 42 provided in the air supply chamber 4. Further, the frame 2 is provided with an auxiliary frame 103 for supporting the cold / hot water pipe connecting portion 102 attached to the air conditioner main body 3.

The duct connecting portion 101 hardly protrudes from the outer surface of the air supply chamber 4. Further, the cold / hot water pipe connection portion 102 is a portion for connecting the cold / hot water pipe passing through the coil provided inside the air conditioner main body 3, and can be connected with one touch without using a pipe, a solenoid valve, or a tool. It consists of a coupler for connecting pipes. A heat insulating material is appropriately provided on the piping. Since the cold / hot water pipe connection portion 102 is a portion that protrudes from the housing of the air conditioner main body 3, when various external forces such as a pipe load are applied to the cold / hot water pipe connection portion 102, the cold / hot water pipe connection portion 102 The base of 102 may be damaged. Therefore, when such a cold / hot water pipe connecting portion 102 is provided in the ceiling-mounted air conditioning unit 1, it is preferable to provide an auxiliary frame 103 for supporting the cold / hot water pipe connecting portion 102 in the frame 2. The auxiliary frame 103 is formed of an angle member 104 similar to the angle member 21 of the frame 2, bolts, nuts, and various other structural members.

Since the air supply chamber 4 of the first modification is provided with such a duct connecting portion 101, the ceiling-mounted air conditioning unit 1 can be made smaller than the case where the connecting opening 42 is provided. FIG. 21 is a diagram comparing the outer dimensions of the ceiling-mounted air conditioning unit 1 of the above embodiment and this modified example. Since the duct connecting portion 101 hardly protrudes from the outer surface of the air supply chamber 4 as compared with the connecting opening 42, as can be seen from FIG. 21, the ceiling-mounted air conditioning unit 1 of the modified example is the embodiment. It is possible to make the outer dimension smaller by the distance L1 than that of the ceiling-mounted air conditioning unit 1. Since the protruding amount of the connecting opening 42 is the length of the connecting portion of a general duct (about 5 to 15 cm), the distance L1 corresponds to this length. Therefore, the ceiling-mounted air-conditioning unit 1 of this modified example in which the duct connecting portion 101 is used instead of the connecting opening 42 facilitates transportation and installation at the site, and further, an object comes into contact with the connecting opening 42. The risk of damage such as deformation of the connecting opening 42 due to this can be suppressed as much as possible. Therefore, this modified example using the duct connecting portion 101 has extremely high workability.

By the way, as described above, the auxiliary frame 103 plays a role of protecting the piping provided in the air conditioner main body 3 at the time of assembling or transporting the ceiling-mounted air conditioning unit 1. The purpose of the auxiliary frame 103 is to prevent an obstacle to the maintenance of the ceiling-mounted air-conditioning unit 1 from being accidentally installed around the ceiling-mounted air-conditioning unit 1 in the ceiling portion where the ceiling-mounted air-conditioning unit 1 is installed. It can also be used for. FIG. 22 is a diagram showing an example of obstacle prevention means provided on the auxiliary frame 103. The auxiliary frame 103 can be provided with, for example, a plate-shaped member such as an obstacle prevention cover 107, or an obstacle prevention means such as a box. The obstacle prevention cover 107 may be completely fixed to the auxiliary frame 103 by a fixing means such as a bolt, may be fixed in a movable state by a fixing means having a movable part such as a hinge, or may be fixed. , May be provided in a detachable state. Further, the obstacle prevention cover 107 can be attached at an arbitrary timing in the manufacturing process of the ceiling-mounted air conditioning unit 1. If the obstacle prevention cover 107 is removable or movable by a hinge or the like, it is possible to prevent the obstacle prevention cover 107 from interfering with the transportation of the ceiling-mounted air conditioning unit 1.

Normally, the air conditioner main body 3 has a built-in filter for preventing the coil and the like from being contaminated by suspended matter in the air. The filter requires regular maintenance such as replacement. Therefore, for example, as shown in FIG. 22A, the air conditioner main body 3 is provided with a filter replacement port 108 for taking in and out the filter. In a ceiling-embedded type air conditioner, when the filter replacement port 108 is provided on the side surface of the housing of the air conditioner main body 3 as in the air conditioner main body 3 shown in FIG. 22 (A), the filter replacement work is usually performed indoors. This is done through an inspection port provided on the ceiling panel that forms the ceiling. Then, as shown in FIG. 22B, the filter 109 is pulled out from the filter exchange port 108. Then, as shown in FIG. 22C, the filter 109 is removed from the air conditioner main body 3. When the replacement work is completed, the inspection port is closed and the periphery of the filter replacement port 108 is hidden by the ceiling panel.

In addition to the ceiling-mounted air-conditioning unit 1, for example, lighting equipment, communication equipment, and various other equipment are installed in the attic space formed by the ceiling panel and covered from the occupants in the room. The equipment installed in the space behind the ceiling is basically hung by hanging bolts or the like hanging from the ceiling slab. Therefore, an obstacle prevention means such as the obstacle prevention cover 107 that hinders the attachment of the hanging bolts suspended from the ceiling slab is provided in the vicinity of the filter replacement port 108 and other work spaces during maintenance work of the ceiling-mounted air conditioning unit 1. By providing the parts that need to be secured so as to cover at least from the upper side, it is possible to prevent such various devices from being installed in places that interfere with the maintenance work of the ceiling-mounted air conditioning unit 1. it can.

FIG. 23 is a diagram showing an example of an obstacle. If there is no obstacle prevention cover 107, a workpiece such as an obstacle 110 may be installed near the filter replacement port 108. A contractor who installs various devices behind the ceiling may not know that the ceiling-mounted air conditioning unit 1 needs a work space for maintenance, so the contractor may install the obstacle 110. possible. In this regard, if an obstacle prevention cover 107 for preventing the installation of the obstacle 110 is installed near the filter replacement port 108, the hanging bolt for installing the obstacle 110 can be hung from the ceiling slab. Since the obstacle prevention cover 107 interferes, the possibility that the obstacle 110 is erroneously installed can be suppressed as much as possible.

K ・ ・ Suspension bolt F ・ ・ Steering V ・ ・ Vehicle 1 ・ ・ Ceiling-suspended air conditioning unit 2 ・ ・ Frame 3 ・ ・ Air conditioner body 4 ・ ・ Air supply chamber 5 ・ ・ Return air chamber 6 ・ ・ Temporary fixing 2U ・・ Upper frame 2B ・ ・ Lower frame 21 ・ ・ Angle material 22 ・ ・ Rib plate 23 ・ ・ Rib plate 24 ・ ・ Hanging part 25 ・ ・ Bar screw 26 ・ ・ Hanging metal fittings 27, 28 ・ ・ Support member 29 ・ ・L-shaped metal fittings 2A ・ ・ Anti-sway 31 ・ ・ Housing 32 ・ ・ Auxiliary equipment 33 ・ ・ Auxiliary piping 34 ・ ・ Ceiling mount mounting part 35 ・ ・ Anti-vibration rubber 41 ・ ・ Housing 42 ・ ・ Connection opening 61・ ・ Top plate part 62 ・ ・ Side wall part 63 ・ ・ Notch part 101 ・ ・ Duct connection part 102 ・ ・ Cold / hot water pipe connection part 103 ・ ・ Auxiliary frame 104 ・ ・ Angle material 107 ・ ・ Obstacle prevention cover 108 ・ ・Filter replacement port 109 ... Filter 110 ... Obstacle 112 ... Cart 112A ... Bottom 112B ... Side 112C ... Hinge 112D ... Wheels

Claims (7)

The equipment assembly process for assembling multiple air conditioners for ceiling suspension to each other,
An upper frame attachment step of attaching an upper frame that forms an upper portion of a frame that integrally holds the plurality of air conditioners to the plurality of air conditioners assembled to each other from above.
It has a lower frame attachment step of raising the upper frame to which the plurality of air conditioners are attached and attaching a lower frame forming a lower portion of the frame from the lower side of the plurality of air conditioners.
How to make a ceiling-mounted air conditioning unit. The preparatory process to prepare the frame members that integrally hold multiple air conditioners for ceiling suspension,
The upper frame assembly process of assembling the upper frame forming the upper part of the frame, and
Further comprising a lower frame assembly step of assembling the lower frame forming the lower portion of the frame.
The method for manufacturing a ceiling-mounted air conditioning unit according to claim 1. In the upper frame assembly step, after assembling the upper frame upside down, the upper frame is turned upside down.
The method for manufacturing a ceiling-mounted air conditioning unit according to claim 2. Further comprising a frame transfer step of transferring the upper frame assembled by the upper frame assembly step and the lower frame assembled by the lower frame assembly step.
The equipment assembly step, the upper frame mounting step, and the lower frame mounting step use the upper frame and the lower frame transferred from other places by the frame transfer step.
The method for manufacturing a ceiling-mounted air conditioning unit according to claim 3 or 4. When the frame is tilted together with the air conditioner from the position when the air conditioner is suspended from the ceiling, the air conditioner has a regulating means for restricting the relative movement of the air conditioner with respect to the frame. It also has a regulatory means mounting process to attach to the mounting part,
The method for manufacturing a ceiling-mounted air conditioning unit according to any one of claims 1 to 4. In the lower frame attaching step, the upper frame to which the plurality of air conditioners are attached is lifted by a hoisting machine, and the lower frame is attached from the lower side of the plurality of air conditioners.
The method for manufacturing a ceiling-mounted air conditioning unit according to any one of claims 1 to 5. The auxiliary frame attaching step of attaching the auxiliary frame for supporting the piping provided in the air conditioner to the upper frame is further provided.
The method for manufacturing a ceiling-mounted air conditioning unit according to any one of claims 1 to 6.

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