JP6115782B2 - Air conditioner - Google Patents

Description

  The present invention relates to a built-in type air conditioner including an indoor unit installed on a ceiling of a building.

  2. Description of the Related Art Conventionally, a built-in type air conditioner including an indoor unit installed in a ceiling portion such as a ceiling space of a building and an outdoor unit connected to the indoor unit via a refrigerant pipe is known. In this type of built-in air conditioner, a compressor and an outdoor heat exchanger are accommodated in the outdoor unit, and an indoor heat exchanger and a blower are accommodated in the indoor unit. And a compressor, an outdoor heat exchanger, and an indoor heat exchanger are connected by refrigerant piping, and the refrigerant circuit is constituted. The conditioned air that is blown to the indoor heat exchanger by the drive of the blower and exchanges heat with the refrigerant flowing in the indoor heat exchanger is blown out into the conditioned room through the blowout duct (see, for example, Patent Document 1).

JP 2002-162064 A

  By the way, a filter is attached to the suction port of the indoor unit so that dust and the like are not sucked into the indoor unit together with air. This filter needs to be periodically cleaned or replaced in order to prevent a reduction in the amount of air sucked due to clogging or the like. However, cleaning or replacement of the filter of the indoor unit installed in a narrow ceiling space may not be easily performed depending on the position and size of the inspection port on the ceiling, and workability is poor.

In addition, the indoor unit is partitioned by a partition plate into a heat exchange chamber that houses the heat exchanger and a blower chamber that houses the blower. The blower chamber is provided with an electrical unit together with the blower. The electrical unit is configured by accommodating electrical components inside an electrical box. The electrical box is provided with a plurality of wiring holes for drawing wiring into the blower chamber and the heat exchange chamber, and a plurality of fixing holes for fixing electrical components such as an electrical board to the electrical box. However, dust or the like drawn into the blower chamber by the blower may flow into the electrical box through these holes. When dust or the like flows into the electrical box, the dust may adhere to the electrical components in the electrical box and cause a failure.
An object of the present invention is to provide a built-in type air conditioner that solves the problems of the conventional techniques described above and improves the maintainability of the filter. It is another object of the present invention to provide a built-in type air conditioner that solves the above-described problems of the prior art and prevents dust from flowing into the electrical box.

In order to achieve the above object, the present invention divides the inside of a unit main body into a heat exchange chamber that houses a heat exchanger and a blower chamber that houses a blower fan by a partition plate, and the blower fan sucks the inlet In the built-in type air conditioner that sucks air from the air and blows out the air by exchanging heat with the heat exchanger, the unit main body is installed in a ceiling space, and is mounted on a ceiling plate near the side plate of the unit main body. Is provided with an inspection port, the suction port is formed in the suction side panel of the unit body, the suction port is provided with a filter unit that covers the entire suction port,
The filter unit has a plurality of filter parts with mesh-like filter materials attached to the inner opening of the outer frame material, and is provided with a plurality of filter parts connected in the lateral direction of the suction port. Are connected to each other, and one of the adjacent filter parts is folded to the front side or the rear side of the other filter part, and the folded filter part is then connected to the rear side or the front side of the next filter part. The unit main body includes a pair of rails provided parallel to each other above and below the suction port, the rail has an opening on the inspection port side, and the filter unit The filter unit is detachably provided by sliding horizontally between the rails from the open end of the rail. Slide the filter body in the horizontal direction and fold one filter part near the side plate to the front side or the rear side of the other filter part. It can be folded to the side or front side, and can be pulled out from the inspection port .

  In the built-in type air conditioner according to the present invention, the filter unit includes the filter portion detachably attached to the connecting portion.

  Further, in the built-in type air conditioner according to the present invention, the connecting portion includes a shaft portion provided at one of the edge portions of the adjacent filter portions facing each other, and a holding portion provided at the other. When the shaft portion is held and connected by the holding portion, the holding portion is configured to be rotatable around the shaft portion.

  According to the present invention, the suction port is provided with a filter unit that covers the entire suction port, and the filter unit is provided with a plurality of filter portions connected in a lateral direction of the suction port, and the filter portions are connected to each other. Since the filter unit is detachably attached at the connecting part to be connected and the filter unit is detachably attached, the filter unit can be connected while sliding the filter unit in the lateral direction when attaching or detaching the filter unit. The filter unit can be made compact by folding the filter unit, and the filter unit can be easily attached and detached even in a narrow ceiling space, and the maintainability of the filter unit can be improved. Further, according to the present invention, an electrical box is provided adjacent to the blower chamber, and a fixing hole for fixing an electrical component to the electrical box is opened on the surface facing the blower chamber. Since the second partition plate is provided between the electrical box and the blower chamber so as to close the fixing hole, the fixing hole for fixing the electrical component to the electrical box is closed with the second partition plate, It is possible to prevent dust and the like from flowing into the electrical box from the blower chamber.

FIG. 1 is a side view showing a built-in type air conditioner according to an embodiment of the present invention. FIG. 2 is a side view showing a built-in type air conditioner. FIG. 3 is a sectional view of the indoor unit. FIG. 4 is an external perspective view of the indoor unit. FIG. 5 is a perspective view of the filter unit. FIG. 6 is a perspective view of the filter portion. FIG. 7 is a diagram illustrating the configuration of the coupling portion, FIG. 7A is a diagram illustrating a state before coupling, and FIG. 7B is a diagram illustrating the coupled state. FIG. 8 is a view showing a mounting structure for attaching the filter unit to the unit main body. FIG. 9 is a diagram showing a state in which the filter unit is pulled out from the unit main body. FIG. 10 is a view showing filter units of indoor units of different sizes, (A) is a view showing triple filter units, and (B) is a view showing double filter units. FIG. 11 is an external perspective view of the indoor unit from which the bottom plate on the blower chamber side is removed as viewed from the lower surface side. FIG. 12 is a partially exploded perspective view of the indoor unit. FIG. 13 is a view showing an attached state of the second partition plate. FIG. 14 is a front view of the electrical unit. FIG. 15 is a diagram illustrating a wiring state of the communication line that passes from the second partition plate to the heat exchange chamber. FIG. 16 is a diagram illustrating the configuration of the second partition plate and the sealing member.

Hereinafter, embodiments of the present invention will be described with reference to the drawings.
A built-in type air conditioner 1 according to an embodiment to which the present invention is applied includes an outdoor unit (not shown) and an indoor unit 5 connected to the outdoor unit through a refrigerant pipe. Although not shown, the outdoor unit is installed outdoors such as on the rooftop of a building, exchanges heat with outdoor air, condenses the refrigerant during cooling operation and releases heat to the outside air, and evaporates the refrigerant during heating operation. Heat is taken from outside air. The built-in type air conditioning apparatus 1 circulates this refrigerant between the outdoor unit and the indoor heat exchanger (heat exchanger) 60 of the indoor unit 5 to perform air conditioning of the conditioned room 2.

  As shown in FIG. 1, the indoor unit 5 is suspended in a ceiling space 34 between the ceiling 32 and the ceiling plate 33 of the building 31. The indoor unit 5 includes an indoor heat exchanger (heat exchanger) 60, a unit main body 10 configured to accommodate a blower fan 50 that blows air to the indoor heat exchanger 60, and a suction extending from the unit main body 10 to the ceiling plate 33. A duct 53 and a blowout duct 54 are included.

  The unit case 11 of the unit body 10 includes a top plate 12, a bottom plate 13, a side plate 14, a suction side panel 15, and a blowout side panel 16, and is formed in a substantially rectangular shape. The unit body 10 is provided with a plurality of suspension fittings 41 fixed to the side plate 14 of the unit case 11. The unit main body 10 is suspended in the ceiling back space 34 by attaching these suspension fittings 41 to suspension bolts 42 suspended from the ceiling 32. A detachable ceiling panel (inspection port) 35 is attached to the ceiling plate 33 at an appropriate position, and various maintenance of the indoor unit 5 can be performed from the conditioned room 2 side by removing the ceiling panel 35. Can do.

  The unit case 11 includes a suction side panel 15 disposed on a pair of opposed side surfaces and a blowout side panel 16, and a suction port 17 formed on the suction side panel 15 disposed on the upstream side of the blower fan 50. And an outlet 18 formed in the outlet side panel 16 disposed on the downstream side of the indoor heat exchanger 60. At an appropriate position of the ceiling plate 33, an air inlet 51 and an air supply port 52 are provided that allow the interior of the conditioned room 2 to communicate with the ceiling space 34. The suction port 17 of the unit case 11 and the suction port 51 of the ceiling plate 33 are connected by a suction duct 53. A filter unit 20 is provided on the air inlet side of the suction port 17. Further, the air outlet 18 of the unit case 11 and the air supply port 52 of the ceiling plate 33 are connected by an air outlet duct 54.

  The indoor unit 5 sucks the air in the conditioned room 2 into the unit main body 10 through the intake port 51, the suction duct 53, the filter unit 20, and the suction port 17 by driving the blower fan 50. The indoor unit 5 sends the sucked air to the indoor heat exchanger 60 to exchange heat with the refrigerant flowing in the indoor heat exchanger 60. The indoor unit 5 then supplies conditioned air into the conditioned room 2 via the air outlet 18, the air outlet duct 54, and the air supply port 52. That is, the indoor unit 5 sucks the air in the conditioned room 2 and blows the conditioned air heat-exchanged with the refrigerant flowing in the indoor heat exchanger 60 to the conditioned room 2 again.

  As shown in FIG. 2, the indoor unit 5 includes the filter unit 20 in the suction port 17, and the air in the ceiling space 34 is driven through the filter unit 20 and the suction port 17 by driving the blower fan 50. 10, the sucked air is blown to the indoor heat exchanger 60 to exchange heat with the refrigerant flowing through the indoor heat exchanger 60, and conditioned air is blown through the outlet 18, the outlet duct 54, and the air inlet 52. Therefore, the configuration may be such that the conditioned room 2 is supplied. That is, the indoor unit 5 may be configured to suck in the air in the ceiling back space 34 and blow out conditioned air heat-exchanged with the refrigerant flowing in the indoor heat exchanger 60 to the conditioned room 2.

  As shown in FIG. 3, the inside of the unit case 11 is a partition plate 55 provided substantially perpendicular to the top plate 12 and the bottom plate 13, and a blower chamber R <b> 1 that houses the blower fan 50 and an indoor heat exchanger 60. And a heat exchange chamber R2 that accommodates The partition plate 55 is formed of a metal plate or the like, and blocks the air flow between the air blowing chamber R1 and the heat exchange chamber R2. 3, 4, and 5 are diagrams illustrating the indoor unit 5 including the filter unit 20 in the suction port 17 illustrated in FIG. 2.

As the blower fan 50, a sirocco fan that is a centrifugal blower fan is used. In the blower fan 50, a cylindrical fan body 50A having a large number of blades is accommodated in a fan case 50B, and a motor shaft 50C extending in the axial direction of the fan body 50A is connected to a fan motor 30 described later. The fan body 50A is rotated by driving the motor. The partition plate 55 is provided with an opening 55A, and the air blowing port 50D of the blower fan 50 is connected to the opening 55A and exposed to the heat exchange chamber R2.
In addition, the filter unit 20 is detachably attached to the air inlet side of the suction port 17 through which the air from the conditioned room 2 is guided into the indoor unit 5 by driving the blower fan 50.

  The indoor heat exchanger 60 includes a flat plate-like upper heat exchange unit 61 and a lower heat exchange unit 62, and the upper heat exchange unit 61 and the lower heat exchange unit 62 are abbreviated in a side view. It is connected in combination in the shape of According to this configuration, the indoor heat exchanger 60 is configured by connecting the two plate-shaped heat exchange parts 61 and 62 in a substantially square shape in a side view. The height of the heat exchanger can be kept low and the heat exchange area can be increased compared to the case where the heat exchanger is arranged vertically. The upper heat exchanging portion 61 and the lower heat exchanging portion 62 are both fin-and-tube heat exchangers, and are spaced from each other between a pair of tube plates extending in the ventilation direction and the tube plates. A plurality of fin plates to be arranged and a plurality of tubes penetrating these fin plates are provided.

  A drain pan 70 that receives drain water from the indoor heat exchanger 60 is disposed below the indoor heat exchanger 60. The indoor heat exchanger 60 has an upper end extending to the side of the lower surface of the top plate 12 and a lower end placed on the drain pan 70, whereby the heat exchange chamber R <b> 2 is moved by the indoor heat exchanger 60. Are divided into a primary chamber 65A on the upstream side and a secondary chamber 65B on the downstream side of the indoor heat exchanger 60.

  The drain pan 70 covers the entire bottom surface of the heat exchange chamber R2 and is supported by the bottom plate 13. The drain pan 70 is made of foamed polystyrene, and the inside of the indoor heat exchanger 60 that receives the drain water is covered with a resin sheet or the like for waterproofing and mold prevention. Thereby, the drain pan 70 can be reduced in weight. The drain pan 70 is formed with a drain pool 70A whose bottom is lowered by one step, and a drain pump suction port is disposed in the drain pool 70A, although not shown. The drain pan 70 is detachably provided from the unit case 11 by removing the heat exchange chamber side bottom plate 13A. The drain pan 70 is formed in a box shape with four side surfaces rising from the bottom surface.

  Drain water such as condensed water generated in the indoor heat exchanger 60 flows along the surface of the indoor heat exchanger 60 and is collected in the drain pan 70 by its own weight. A step 60 </ b> C is formed between the air outflow side surface 61 </ b> B of the upper heat exchange unit 61 and the upper end part 62 </ b> B of the lower heat exchange unit 62. Drain water, such as condensed water, generated in the upper heat exchange section 61 and flowing along the outflow side surface 61 </ b> B under its own weight, is received by the step 60 </ b> C and flows along the surface of the lower heat exchange section 62. Thereby, it is possible to prevent the drain water generated in the upper heat exchange part 61 from being scattered from the connecting part 60 </ b> B between the upper heat exchange part 61 and the lower heat exchange part 62.

The blower fan 50 is arranged so that the blower port 50D is provided obliquely downward so that the blowing direction from the blower port 50D is directed to the connecting part 60B between the upper heat exchange unit 61 and the lower heat exchange unit 62. . According to this configuration, the amount of air passing through the upper heat exchange unit 61 and the lower heat exchange unit 62 can be made substantially the same, and the upper heat exchange unit 61 and the lower heat exchange unit 62 The temperature difference in the heat exchange surface can be reduced, and the heat exchange efficiency in the indoor heat exchanger 60 can be made uniform.
The indoor heat exchanger 60 may have a configuration in which the open side of the character is arranged in a direction facing the air outlet 50D of the blower fan 50, or the top of the character is omitted from illustration. The structure arrange | positioned in the direction which the air outlet 50D of the ventilation fan 50 opposes may be sufficient. The heat exchanger 60 is arranged such that the inclination α of the lower heat exchange part 62 with respect to the horizontal direction does not become smaller than a predetermined angle, for example, 37 degrees. By setting the inclination angle of the lower heat exchange part 62 with respect to the horizontal direction to 37 degrees or more, it is possible to prevent the drain water from flowing through the lower heat exchange part 62 and the heat of the heat exchanger 60. It is possible to prevent the exchange capacity from being lowered due to adhesion of drain water.

  As shown in FIG. 4, the unit case 11 includes a maintenance panel 56, a pump unit 75, and a lid (pipe presser) 68 detachably provided on one side plate 14 </ b> A. The maintenance panel 56 is attached to the one side plate 14 </ b> A so as to close a maintenance opening provided in the one side plate 14 </ b> A in order to perform maintenance of an electrical unit 80 described later housed in the unit case 11. The pump unit 75 includes a drain pump 78 that draws drain water from the drain pan 70 and a fixture 79 of the drain pump 78. One side plate 14A is provided with a pump mounting opening, and the pump unit 75 accommodates the drain pump 78 in the unit case 11, and the fixing plate 79 closes the pump mounting opening. It is attached to 14A. The lid 68 is connected to the indoor heat exchanger 60 and is disposed to hold down the auxiliary refrigerant pipe 67 that penetrates one side plate 14A. Further, when the lid body 68 is attached to one side plate 14A, the opening 66B formed in the one side plate 14A is closed.

  The inspection port 35 is provided in the vicinity of one side plate 14A of the unit case 11 in which the maintenance panel 56, the pump unit 75, and the lid body 68 are collectively formed. As described above, since the maintenance openings are collectively formed on one side plate 14A of the unit case 11 and the inspection port 35 is provided in the vicinity of the one side plate 14A, the maintainability of the unit body 10 can be improved. . By the way, although the size of the inspection port 35 is slightly different depending on the place where the indoor unit 5 is installed, it is generally formed in a substantially rectangular shape within 450 cm × 450 cm. Occasionally, an operator reaches into the ceiling space 34 through the inspection port 35, and work is performed from the conditioned room 2 side.

  A plurality of blower fans 50 are arranged side by side in the width W1 direction (lateral direction) of the suction port 17 inside the blower chamber R1. The blower fan 50 is connected to the fan motor 30 by a motor shaft 50 </ b> C extending in the axial direction, and the fan body 50 </ b> A of each blower fan 50 is configured to rotate by driving the fan motor 30. The number of the blower fans 50 accommodated in the blower chamber R1 can be appropriately changed according to the width dimension of the unit case 11 (the output capacity / capacity of the indoor unit 5). In the present embodiment, the blower chamber R1 is provided with a plurality of blower fans 50 connected by a single motor shaft 50C, and the plurality of blower fans 50 are similarly rotated by the single fan motor 30. However, the present invention is not limited to this, and each of the plurality of blower fans 50 may include the fan motor 30. The filter unit 20 is provided so as to cover the entire suction port 17 having the width W <b> 1 along the arrangement direction of the blower fans 50. A width W1 of the suction port 17 is formed to be smaller than a lateral width W of the unit body 10 in the lateral direction, and is arranged close to the other side plate 14B facing the one side plate 14A.

As shown in FIG. 5, the filter unit 20 is divided into a plurality of filter parts 21, 21..., And each filter part 21 is made of a flexible synthetic resin and formed by resin molding or the like. Formed equally. The filter unit 21 includes an outer frame body 25A formed in a substantially rectangular frame shape, and a partition member 25B that partitions the openings 25 inside the outer frame body 25A into a lattice shape. According to this configuration, when the inner opening 25 of the outer frame body 25A is partitioned in a lattice shape by the partition member 25B, the filter portion 21 formed using a flexible synthetic resin is pulled in the outer peripheral direction. The amount of deformation can be reduced, and the tensile strength of the filter portion 21 can be increased.
A mesh-like filter material made of a nonwoven fabric or the like covering the opening 25 is attached to the opening 25 of the filter portion 21 by, for example, adhesion or heat welding. In addition, the filter unit 21 includes a handle portion 26 that can be used as a handle when the filter unit 20 is attached to and detached from the outer frame body 25 </ b> A along the lower edge of the opening 25.

  The filter part 21 is integrally provided with a connecting part 24 for connecting adjacent filter parts 21 and 21 side by side. The connecting portion 24 includes a shaft portion 22 formed on one edge 21 </ b> C of a pair of adjacent edges of the adjacent filter portions 21, 21, and a holding formed on the other edge 21 </ b> D so as to hold the shaft portion 22. The holding part 23 is comprised. That is, in each filter part 21 single-piece | unit, as shown in FIG. 6, the shaft part 22 is provided in one edge 21C of the both edges of the width direction, and the holding part 23 is provided in the other edge 21D. The shaft portion 22 and the holding portion 23 are provided in two vertically arranged, and each shaft portion 22 and the holding portion 23 are provided close to the end portion side in the height direction of the filter portion 21.

  The filter unit 20 is fitted and connected so as to hold the shaft part 22 of the filter parts 21 and 21 by the holding part 23, and each filter part 21, 21,... . In the connecting portion 24 in which the shaft portion 22 and the holding portion 23 are connected, the adjacent filter portions 21 are folded (folded) on either the front side or the rear side of the shaft portion 22 as a rotation axis. Connected freely. That is, as shown in FIG. 5, the filter portion 21A can rotate in either the rotation direction X1 or the rotation direction X2 with respect to the filter portion 21B around the connecting portion 24, and the filter portion 21A. Is folded to the rear side of the filter portion 21B when rotated in the rotational direction X1, or folded to the front side of the filter portion 21B when rotated in the rotational direction X2.

  As shown in FIG. 7A, the shaft portion 22 and the holding portion 23 constituting the connecting portion 24 are configured to face each other when two filter portions 21 are arranged. The shaft portion 22 includes a shaft body 22A and a holding body 22B that holds the shaft body 22A integrally with the filter portion 21 with a predetermined gap S1 between the shaft portion 22A and the filter portion 21. The holding part 23 protrudes from the front surface side of the filter part 21, and protrudes from the rear surface side of the first holding body 23 </ b> A having a circular arc shape surrounding a part of the circumference of the shaft body 22 </ b> A and the filter part 21. And a second holding body 23B having a circular arc shape surrounding a part of the circumference of the shaft body 22A. The first holding body 23A and the second holding body 23B are alternately arranged at positions where they do not overlap each other when viewed from the front. A gap S2 is formed between the first holding body 23A and the second holding body 23B. In the gap S2, as shown in FIG. 7B, when the shaft portion 22 and the holding portion 23 are connected, the holding body 22B of the shaft portion 22 is disposed.

  The first holding body 23A and the second holding body 23B are formed so that their end portions 23C do not overlap in plan view. That is, the first holding body 23A and the second holding body 23B are provided with a predetermined gap in a side view between the end portions 23C, and this gap is formed between the shaft body 22A and the shaft body 22A. It is set smaller than the diameter. According to this configuration, the connecting portion 24 pushes the shaft body 22A from the gap between the first holding body 23A and the second holding body 23B, so that the holding body 23A and the holding body 23B have the shaft body 22A. , And the shaft portion 22 and the holding portion 23 can be easily connected. Further, the filter part 21 can be easily divided by pulling the shaft part 22 of the connecting part 24 in one direction and the holding part 23 in the other direction opposite to the one direction.

  The thickness T of the first holding body 23A and the second holding body 23B is formed to be thinner than the gap S1 between the shaft body 22A and the filter part 21, and the filter part 21 is pivoted about the shaft body 22A. When rotating to the center, the first holding body 23A or the second holding body 23B slides between the gaps S1, and the first holding body 23A and the second holding body 23B are shaft bodies 22A. Rotate around. Thereby, the filter part 21 is configured to be foldable (bendable) by the connecting part 24 on either the front side or the rear side of the adjacent filter part 21. Further, the adjacent filter parts 21 are configured to be bendable while being connected to each other by the connecting part 24.

  As shown in FIG. 8, the suction side panel 15 includes a pair of rails 45 above and below the suction port 17. The rail 45 includes an upper rail 45 </ b> A provided on the upper side of the suction port 17 and a lower rail 45 </ b> B provided on the lower side of the suction port 17. The rails 45A and 45B are provided substantially parallel to each other, and the upper and lower ends 20A and 20B of the filter unit 20 are supported on the rails 45A and 45B, respectively. Each of the rails 45A and 45B is formed by bending a single metal plate or the like a plurality of times, and arranging a support part 47 for supporting the filter unit 20 and the support part 47 at a position spaced apart from the suction side panel 15 by a predetermined distance S3. The gap forming portion 48 and the fixing portion 49 fixed to the suction side panel 15 with the screw 38 are integrally formed. The lower rail 45 </ b> B is provided with a placement portion 47 </ b> A on which the edge portion is bent in the horizontal direction and the handle portion 26 of the filter unit 20 is placed on the upper surface.

  The end portion 45C on the side plate 14A side of the rail 45 is opened, and the filter unit 20 is inserted into / removed from the side plate 14A side through the opened end portion 45C to be detachable. It is configured. Alternatively, the rail 45 is attached to the suction side panel 15 at the end 45D on the other side plate 14B side opposite to the one side plate 14A, and includes a stopper 46 that extends between the rails 45A and 45B. The stopper 46 prevents the filter unit 20 inserted into the rail 45 from the one side plate 14A side from being pushed out to the other side plate 14B side.

  At the time of maintenance of the indoor unit 5 and the like, the filter unit 20 is pulled out in the X direction in the figure by an unillustrated worker reaching out from the inspection port 35 into the ceiling space 34 as shown in FIG. The unit case 11 is removed. The filter unit 20 is provided by being divided into a plurality of filter parts 21, and each filter part 21 can be folded to either the front side or the rear side with respect to the adjacent filter part 21 at the connecting part 24. It is configured as follows. Thereby, the filter unit 20 is pulled out to the side plate 14 </ b> A side along the rail 45, and is pulled out to the conditioned room 2 through the inspection port 35 while folding the filter unit 21 at the connecting portion 24. Since the filter unit 20 is long with respect to the size of the inspection port 35, it is difficult to draw out the filter unit 20 to the conditioned room 2 side through the inspection port 35 as it is. Since it can be pulled out while being folded at the connecting portion 24, it can be easily taken out from the small inspection port 35 to the conditioned room 2 side, and the maintainability is improved.

  By the way, as shown in FIG. 10, the indoor unit 5 changes the number of the ventilation fans 50 accommodated in the unit case 11, and the magnitude | size of the indoor heat exchanger 60 according to required output capacity. However, the size of the unit case 11 changes accordingly. Since the filter unit 20 is configured by connecting a plurality of filter parts 21, and each filter part 21 is detachable from each other by a connecting part 24, for example, as shown in FIG. 10 (A) or FIG. 10 (B). As described above, an arbitrary number of filter parts 21 can be connected and used according to the number of blower fans provided and the size of the suction port 17. FIG. 10A shows a triple filter unit 20 in which three filter parts 21 are connected, and FIG. 10B shows a double filter unit in which two filter parts 21 are connected. Thus, the filter unit 20 can be used by connecting any number of filter units. As a result, the filter unit 20 can be made into a common part among the indoor units 5 having different output capacities and / or different sizes of the unit case 11, facilitating parts management and reducing production costs. Reduction can be achieved.

  FIG. 11 is a view of the unit body 10 as viewed from the bottom side. The bottom plate 13 is divided into a blower chamber side bottom plate (not shown) and a heat exchange chamber side bottom plate 13B. In FIG. 11, for convenience of explanation, the blower chamber side bottom plate and the filter unit 20 are provided. The unit main body 10 in a state where is removed is shown. An electrical unit 80 is provided inside the unit main body 10 so as to be adjacent to the blower chamber R1. As shown in FIGS. 12, 13, and 14, the electrical unit 80 accommodates electrical components such as an electrical board 82 inside an electrical box 81. The electrical box 81 is formed in a substantially rectangular box shape, and includes an opening 80 </ b> A that faces one side plate 14. The opening 80A is sealed by the maintenance panel 56, and during maintenance of the electrical unit 80, the maintenance panel 56 is removed from the one side plate 14A so that the electrical components housed in the electrical box 81 can be maintained. It is configured.

  A plurality of fixing holes 82 </ b> A for fixing an electrical component such as the electrical board 82 to the electrical box 81 are provided on the surface 81 </ b> A facing the blower chamber R <b> 1 of the electrical box 81. The configuration of the electrical components housed in the electrical box 81 varies depending on the output capacity and model of the indoor unit, but since the electrical box 81 is used as a common component, the surface 81A of the electrical box 81 facing the blower chamber R1, in particular, A plurality of fixing holes 82A are opened on the back surface 81C, and a plurality of fixing holes 82A are provided in these fixing holes 82A. A second partition plate 90 is provided between the blower chamber R1 and the electrical equipment box 81 so as to close the fixing holes 82A. The second partition plate 90 is formed by bending a single metal member into a substantially L shape.

Inside the unit body 10, a third chamber R3 partitioned from the air blowing chamber R1 and the heat exchange chamber R2 by the partition plate 55 and the second partition plate 90 is provided. Housed in the third chamber R3. A bracket 85 formed in a substantially U shape along the top plate 12, the suction side panel 15, and the partition plate 55 is provided in the blower chamber R <b> 1. The bracket 85 is provided with an opening 85A that allows the third chamber R3 to communicate with the blower chamber R1. The second partition plate 90 is detachably provided along the bracket 85 from the bottom surface side of the blower chamber R1 from which the bottom plate 13 is removed so as to close the opening 85A.
An extended portion 92 extending from the second partition plate 90 is provided on the upper edge of the second partition plate 90. The bracket 85 is provided with a pocket-shaped receiving portion 85B into which the extending portion 92 is inserted on the surface on the third chamber R3 side (see FIG. 16). The second partition plate 90 is held in a state in which the extending portion 92 at the upper edge is inserted into the receiving portion 85B. Therefore, the gap between the upper edge of the second partition plate 90 and the bracket 85 is closed by this insertion structure.

As shown in FIG. 13, the second partition plate 90 has a bottom surface 90 </ b> B that covers the bottom surface side of the third chamber R <b> 3 after the extension portion 92 is inserted into the receiving portion 85 </ b> B of the bracket 85. The suction side panel 15 and the bottom plate 13 are fixed to the frame 15A fixed with screws 91A, and the partition plate 55 and the bottom plate 13 are fixed to the frame 55A fixed with screws 91B. . When the second partition plate 90 is fixed with screws 91A and 91B, the surface of the bracket 85 on the third chamber R3 side is closed so that the gap between the second partition plate 90 and the bracket 85 is closed. It is fixed so that it can be pressed against.
A predetermined gap is provided between the second partition plate 90 and the back surface 81C of the electrical box 81, and the power line 84B or the communication line 84A drawn out from the back surface 81 of the electrical box 81 has the first Wiring is performed in the vicinity of the partition plate 55 through a gap between the two partition plates 90 and the back surface 81 </ b> C of the electrical box 81.

  Of the surface 81A facing the blower chamber R1 of the electrical box 81, on the side surface 81B facing the partition plate 55, the communication line wiring hole 87A for drawing the communication line 84A from the inside of the electrical box 81 into the third chamber R3. And a power line wiring hole 87B for drawing the power line 84B from the inside of the electrical equipment box 81 into the third chamber R3. The communication line wiring hole 87 </ b> A and the power supply line wiring hole 87 </ b> B are provided at positions separated from the upper part and the lower part of the electrical equipment box 81. Accordingly, since the power supply line 84B and the communication line 84A can be separated from each other, it is possible to prevent the noise flowing on the signal flowing through the communication line 84A due to the current flowing through the power supply line 84B.

  The bracket 85 includes two holes 93 </ b> A and 93 </ b> B provided in the vicinity of the partition plate 55 so as to be separated from each other in the vertical direction. A hole 93A formed in the lower portion of the bracket 85 is a communication line hole 93A for drawing out the communication line 84A from the third chamber R3 to connect it to the fan motor 30 and the like housed in the blower chamber R1. The hole 93B formed in the upper part of the bracket 85 is a power supply line hole 93B for drawing out the power supply line 84B from the third chamber R3 to connect to the fan motor 30 or the like. In each of the holes 93A and 94B, a rubber plug 94B having a notch (hole) having a size enough to allow the communication line 83A or the power supply line 84B to pass therethrough is fitted. The rubber plug 94 prevents dust and the like from flowing from the blower chamber R1 to the third chamber R3 via the communication line hole 93A or the power line hole 93B.

  As shown in FIGS. 12 and 13, the partition plate 55 is provided with a communication line drawing hole 91 that communicates with the third chamber R3 and the heat exchange chamber R2. From the electrical board 82, the communication line 84A is connected to the heat exchanger 60 accommodated in the heat exchange chamber R2 or a sensor such as the drain pump 78. As shown in FIG. 14, the communication line 84A wired to the heat exchange chamber R2 passes through the communication line lead hole (wiring hole) 91 provided in the partition plate 55 from the third chamber R3. Pulled out. As shown in FIG. 15, a sealing member 92 is provided through the communication line drawing hole 91. The sealing member 92 is provided so as to cover the communication line 84 </ b> A passing through the communication line lead hole 91, and closes the gap between the communication line 84 </ b> A and the communication line lead hole 91. Thereby, it is possible to prevent dust and the like from flowing into the third chamber R3 from the heat exchange chamber R2 through the communication line drawing hole 91 formed in the partition plate 55.

  As described above, according to the embodiment to which the present invention is applied, the inside of the unit main body 10 is divided by the partition plate 55 into the heat exchange chamber R2 that houses the heat exchanger 60 and the blower chamber that houses the blower fan 50. In the built-in type air conditioner 1 that is partitioned into R1 and sucks air from the suction port 17 by the blower fan 50 and heat-exchanges the air by the heat exchanger 60, the suction port 17 includes the suction port 17 A filter unit 20 is provided to cover the whole, and the filter unit 20 is provided with a plurality of filter parts 21 connected in the lateral direction of the suction port, and the filter parts 21 are formed to be bendable by connecting parts 24 that connect the filter parts 21 to each other. The filter unit 20 was detachably attached by sliding in the lateral direction of the unit body 10. Thus, when the filter unit 20 is attached or detached, the filter unit 20 can be made compact by folding the filter unit 20 at the connecting portion 24 of each filter portion 21 while sliding the filter unit 20 in the lateral direction of the unit body 10. In addition, since the filter unit 20 can be easily attached and detached even in the narrow ceiling space 34, the maintainability of the filter unit 20 is improved.

  In addition, according to the embodiment to which the present invention is applied, the filter unit 20 is provided with the filter part 21 so as to be detachable from each other by the connecting part 24. Therefore, by changing the number of the filter parts 21 to be connected, The present invention can be widely applied to the unit body 10. Thereby, the filter part 21 can be made into a common part with respect to the indoor unit 5 of different output capacity, and simplification of parts management and reduction of production cost can be aimed at.

  Further, according to the embodiment to which the present invention is applied, the unit body 10 includes a pair of rails 45 provided in parallel to each other above and below the suction port 17, and the filter unit is supported between the rails 45. The end 45C was opened to the side surface 14A side of the unit main body 10, and the filter unit 20 was slidably attached from the opened end 45C in a detachable manner. As a result, the filter unit 20 can be easily attached and detached simply by sliding the filter unit 20 laterally along the rail 45 in a state where a plurality of filter parts 21 are connected, and the maintainability of the filter unit 20 is improved. improves.

  In addition, according to the embodiment to which the present invention is applied, the filter unit 20 includes the connection part 24 of the filter part 21, the one filter part 21 </ b> A of the adjacent filter part 21 as the front side of the other filter part 21 </ b> B, or It is configured to be foldable on either side of the rear surface side. As a result, when the filter unit 20 is folded at the connecting portion 24 of each filter portion 21, for example, the filter unit 20 can be folded with alternating ridges and valleys. As a result, the filter unit 20 can be prevented from being bulky when the connecting portion 24 is bent, and the filter unit 20 can be folded compactly. Therefore, the filter unit 20 can be attached to and detached from the narrow ceiling space 34. The maintenance property of the filter unit 20 can be improved.

  Further, according to the embodiment to which the present invention is applied, the connecting portion 24 is provided on the shaft portion 22 provided on one edge 21C of the edge portions of the adjacent filter portions 21A and 21B facing each other and on the other edge 21D. The holding portion 23 is configured to be rotatable around the shaft portion 22 when the holding portion 23 holds and connects the shaft portion 22. As a result, the filter unit 21 can be coupled with a simple structure without the need for tools and jigs, and the coupling unit 24 can be bent in both directions. Assembling workability and maintainability can be improved.

  Further, according to the embodiment to which the present invention is applied, the unit main body 10 is provided in the ceiling space 34 that communicates with the conditioned room 2 via the inspection port 35, and the rail 45 is an end portion on the inspection port 35 side. 45C is opened, and the filter unit 20 can be inserted and removed between the rails 45 from the open end 45C of the rail 45. Thereby, when removing the filter unit 20, the hand is extended into the ceiling space 34 through the inspection port 35, and the filter unit 21 is connected to each other while sliding the filter unit 20 in the lateral direction of the unit body 10. In addition, the filter unit 20 can be folded at the portion 24 to be compact, and the filter unit 20 can be taken out from the inspection port 35 to the conditioned room 2. When the filter unit 20 is attached, the filter unit 20 can be put into the ceiling back space 34 through the inspection port 35 in a folded state, and the connecting unit 24 is widened while being expanded in the lateral direction. Can be installed by sliding. Therefore, even in the narrow ceiling space 34, the filter unit 20 can be easily attached and detached, and the maintainability of the filter unit 20 can be improved.

  Moreover, according to the embodiment to which the present invention is applied, the inside of the unit body 10 is partitioned by the partition plate 55 into the heat exchange chamber R2 that houses the heat exchanger 60 and the blower chamber R1 that houses the blower fan 50. In the built-in type air conditioner 1 that sucks air from the suction port 17 with the blower fan 50 and exchanges heat with the heat exchanger 60, the electrical box 81 is provided adjacent to the blower chamber R1. In the electrical box 81, a fixing hole 82A for fixing the electrical component 82 to the electrical box 81 is opened on the surface 81A facing the blower chamber R1, and the electrical box 81 and the blower chamber are closed so as to close the fixed hole 82A. A second partition plate 90 was provided between R1. As a result, the fixing hole 82A for fixing the electrical component 82 opening in the electrical box 81 can be closed by the second partition plate 90 provided between the electrical box 81 and the blower chamber R1, and thus the fixing hole 82A is sealed. It is possible to prevent dust and the like from flowing from the blower chamber R1 into the electrical box 81 through the fixing hole 82A without being blocked by a material or the like.

  Further, according to the embodiment to which the present invention is applied, the third partition partitioned from the heat exchange chamber R2 and the blower chamber R1 by the partition plate 55 and the second partition plate 90 inside the unit body 10. The chamber R3 is provided, the electrical box 81 is accommodated in the third chamber R3, the wiring hole 91 communicating with the third chamber R3 and the heat exchange chamber R2 is provided in the partition plate 55, and the electrical equipment is connected via the wiring hole 91. Wirings 84A and 84B from the box 81 were passed through the heat exchange chamber R2. Thereby, since it is possible to wire directly from the third chamber R3 to the heat exchange chamber R2 without passing through the blower chamber R1, dust or the like flows from the blower chamber R1 to the electrical box 81 through the wiring hole. Can be prevented.

  In addition, according to the embodiment to which the present invention is applied, the electrical component box 81 is used as a common component among a plurality of models, and includes a plurality of fixing holes 82A. Therefore, the type of electrical component 82 accommodated inside the electrical component box 81 Even if the dimensions are different for each model, the corresponding fixing hole 82A can be arbitrarily used and fixed, and the fixing hole 82A that remains open without the electrical component 82 being fixed is the second It can be blocked by the partition plate 90, and dust or the like can be prevented from flowing into the electrical equipment box 81 from the blower chamber R1 with a simple configuration without individually closing the open fixing holes 82A with a sealing material or the like.

  Further, according to the embodiment to which the present invention is applied, the second partition plate 90 is configured so that it can be attached to and removed from the blower chamber R1 from the bottom plate 13 side of the unit body 10, so that maintenance can be performed during maintenance. When carrying out maintenance work of the air blowing chamber R1 from the maintenance opening from which the panel 56 has been removed, the second partition plate 90 can be easily attached and detached by inserting and removing it from the bottom side of the unit body 10 from which the bottom plate 13 has been removed. Maintenance workability can be improved.

1 Built-in type air conditioner R1 Blower chamber R2 Heat exchange chamber R3 Third chamber 10 Unit body 13 Bottom plate 35 Ceiling panel (inspection port)
50 Blower fan 55 Partition plate 56 Maintenance panel 60 Indoor heat exchanger (heat exchanger)
80 Electrical unit 81 Electrical box 81A Surface 82 Electrical board (Electrical component)
82 fixing hole 82A fixing hole

Claims (3)

The inside of the unit main body is partitioned by a partition plate into a heat exchange chamber that houses a heat exchanger and a blower chamber that houses a blower fan. Air is sucked in from the suction port by the blower fan, and the air is In a built-in type air conditioner that heats and blows out with an exchanger,
The unit body is installed in a ceiling space, and an inspection port is provided in the ceiling plate near the side plate of the unit body,
The suction port is formed in the suction side panel of the unit body, and the suction port is provided with a filter unit that covers the entire suction port,
The filter unit has a plurality of filter parts with mesh-like filter materials attached to the inner opening of the outer frame material, and is provided with a plurality of filter parts connected in the lateral direction of the suction port ,
In the connecting part that connects the filter parts to each other, one of the adjacent filter parts is folded to the front side or the rear side of the other filter part, and the rear side of the filter part that follows this folded filter part, Alternatively, it can be folded to the front side,
The unit body includes a pair of rails provided parallel to each other above and below the suction port,
The rail has an opening on the inspection port side, and the filter unit is detachably provided by sliding laterally between the rails from the open end of the rail.
The filter unit is slid in the lateral direction of the unit main body, and one filter part is folded to the front side or the rear side of the other filter part in the vicinity of the side plate, and then the other filter part is folded. A built-in type air conditioner that can be folded to the rear side or front side of the subsequent filter section and drawn out from the inspection port.   The built-in type air conditioner according to claim 1, wherein the filter unit includes the filter part detachably attached to the connecting part. The connecting portion integrally includes a shaft portion provided on one of the edge portions of the adjacent filter portions facing each other and a holding portion provided on the other, and the holding portion holds the shaft portion. The built-in type air conditioner according to claim 1 or 2 , wherein the holding portion is configured to be rotatable around the shaft portion when held and connected.

Images