JP2024024317A - Ventilation device - Google Patents

Abstract

PROBLEM TO BE SOLVED: To facilitate the maintenance of components in a casing via an opening part for taking in/out a heat exchange element.

SOLUTION: A ventilation device includes: fans 42, 43 for producing an airflow; a heat exchange element 41 through which air produced by the fans 42, 43 passes; a casing 13 storing the fans 42, 43 and the heat exchange element 41, and having an opening part 24a for taking in/out the heat exchange element 41 formed therein; and a flow path member 50 forming a flow path through which the airflow passes in the casing 13, and having a rail 55 for guiding the taking-in/out of the heat exchange element 41. The flow path member 50 includes: a fixed part 61 fixed to the casing 13 and having a portion 55a of the rail 55; and a movable part 62 provided movably to a storage space S side of the heat exchange element 41 with respect to the casing 13 and having another portion 55b of the rail 55.

SELECTED DRAWING: Figure 6

COPYRIGHT: (C)2024,JPO&INPIT

Description

TECHNICAL FIELD This disclosure relates to ventilation devices.

Patent Document 1 discloses a ventilation device. This ventilation device includes an air supply fan, an exhaust fan, a total heat exchanger, and a casing that houses these. This ventilation system uses a total heat exchanger to exchange heat between the air taken into the casing by an air supply fan and the air taken into the casing by an exhaust fan, and then exhausts the air after heat exchange to the outdoors and indoors. It is configured as follows.

In the ventilation device of Patent Document 1, an opening for maintenance is formed in the side plate of the casing facing the longitudinal end surface of the total heat exchanger. The total heat exchanger is supported so as to be movable in the longitudinal direction by a guide rail provided within the casing, and is taken out of the casing through the opening by this movement. Further, Patent Document 1 describes that maintenance such as cleaning and replacement of each component housed in the casing is performed through the opening.

Japanese Patent Application Publication No. 2022-16965

The total heat exchanger is provided in a range that occupies most of the casing in its longitudinal direction. Similarly, guide rails for guiding total heat exchangers are also widely available. Therefore, even if you take the total heat exchanger out of the casing through the opening and attempt to perform maintenance on parts inside the casing, such as replacing the fan, through the opening, the guide rails will get in the way and prevent you from doing the work properly. There is a possibility that there is no.

An object of the present disclosure is to facilitate maintenance of components within the casing through an opening for inserting and removing a heat exchange element.

(1) The ventilation device of the present disclosure includes:
a fan that generates airflow;
a heat exchange element through which air generated by the fan passes;
a casing in which the fan and the heat exchange element are housed, and an opening through which the heat exchange element is taken in and taken out is formed;
a flow path member that forms a flow path through which the air flow passes within the casing and has a rail that guides the insertion and removal of the heat exchange element;
The flow path member includes a fixing part that is fixed to the casing and has a part of the rail, and another part of the rail that is movable toward the housing space of the heat exchange element with respect to the casing. A movable part having a.

According to the ventilation device having the above configuration, by moving the movable part of the flow path member to the accommodation space side together with a part of the rail, it becomes possible to expose the parts inside the casing to the accommodation space side, and the opening And maintenance of the component can be facilitated through the accommodation space.

(2) In the ventilation device of (1) above, preferably, the movable part is arranged closer to the accommodation space than the fan,
By moving the movable part toward the accommodation space, the fan is exposed to the accommodation space.

According to this configuration, by moving the movable part of the flow path member together with a part of the rail toward the accommodation space side and removing it, the fan can be exposed to the accommodation space side, and the fan can be exposed through the opening and the accommodation space. maintenance can be made easier.

(3) In the ventilation system of (2) above, preferably the fan includes a motor,
By moving the movable part toward the accommodation space, the motor is exposed to the accommodation space.

According to this configuration, the fan motor can be easily maintained through the opening and the housing space.

(4) In the ventilation device according to any one of (1) to (3) above, preferably, the fan includes an air supply fan that takes outdoor air into the casing and supplies it indoors; It includes an exhaust fan that takes indoor air into the casing and exhausts it outside.
the heat exchange element is disposed between the supply air fan and the exhaust fan;
The flow path member includes a first flow path member having the rail for guiding the heat exchange element on the air supply fan side, and a second flow path having the rail for guiding the heat exchange element on the exhaust fan side. and members.

With this configuration, parts of the rails can be removed to expose parts inside the casing on both the air supply fan side and the exhaust fan side.

(5) In the ventilation device according to any one of (1) to (4) above, preferably the fixed part and the movable part are arranged adjacent to each other,
The movable part is pressed against the fixed part by the heat exchange element arranged in the accommodation space.

According to this configuration, the movable part can be brought into close contact with the fixed part using the heat exchange element, and leakage of air from between the two can be suppressed.

(6) In the ventilation device according to any one of (1) to (5) above, preferably, a part of the rail and another part of the rail are arranged so that the part of the rail and the other part of the rail are arranged adjacent to each other in the direction in which the heat exchange element is taken in and taken out;
One of the part of the rail and the other part of the rail, which is closer to the opening, is located closer to the accommodation space than the other part.

According to this configuration, when inserting the heat exchange element into the accommodation space, it is possible to suppress the heat exchange element from being caught on the other rail that is away from the opening.

FIG. 1 is a perspective view of a ventilation device according to a first embodiment of the present disclosure. FIG. 2 is a plan view schematically showing the inside of the ventilation device. 3 is a schematic cross-sectional view taken along line AA in FIG. 2. FIG. 3 is a schematic cross-sectional view taken along line BB in FIG. 2. FIG. FIG. 3 is a schematic plan view of a flow path member and a heat exchange element. FIG. 3 is a schematic plan view of the flow path member showing a state in which the movable portion of the flow path member is removed. It is a perspective view of a flow path member. FIG. 3 is a perspective view of a fixed portion of the flow path member. It is a perspective view of the movable part of a flow path member. It is a sectional view of a guide rail of a flow path member. 8 is a schematic cross-sectional view taken along line CC in FIG. 7. FIG. 12 is an enlarged view of section D in FIG. 11. FIG. FIG. 12 is an enlarged view of section D in FIG. 11 showing a modification of the flow path member. It is a schematic plan view of the flow path member of the ventilation device based on 2nd Embodiment. It is a top view which expands and shows a part of a flow path member and a heat exchange element. It is a top view which expands and shows a part of flow path member and heat exchange element of the ventilation apparatus based on 3rd Embodiment.

Embodiments of the present disclosure will be described in detail below with reference to the accompanying drawings.
[First embodiment]
FIG. 1 is a perspective view of a ventilation device according to a first embodiment of the present disclosure. FIG. 2 is a plan view schematically showing the inside of the ventilation device. FIG. 3 is a schematic cross-sectional view taken along line AA in FIG. 2. FIG. 4 is a schematic cross-sectional view taken along line BB in FIG. 2. In addition, in this embodiment, the direction of the ventilation device 10 will be explained according to arrows X, Y, and Z shown in FIG. 1 and the like. In this embodiment, as an example, the third direction indicated by arrow Z is the up-down direction.

The ventilation device 10 ventilates the indoor space by exchanging outdoor air with indoor air. The ventilation device 10 is connected to an outdoor space and an indoor space via a duct. The ventilation system 10 is mainly installed in the ceiling of a room. However, the ventilation device 10 may be installed on the lower surface of the ceiling, a wall, etc. indoors, or may be installed outdoors.

The ventilation device 10 has a box-shaped casing 13 formed in the shape of a rectangular parallelepiped. Inside the casing 13, a total heat exchanger (heat exchanger) 41, an air supply fan 42, and an exhaust fan 43, which will be described later, are housed. The casing 13 is provided with a return air intake 14, an exhaust outlet 15, an outside air intake 16, and a supply air outlet 17. A duct connected to the indoor space or the outdoor space is connected to the return air intake 14, the exhaust outlet 15, the outside air intake 16, and the supply air outlet 17.

The return air intake port 14 is used to take air (return air) RA from the indoor space into the casing 13. The exhaust outlet 15 is used to discharge the return air RA taken into the casing 13 to the outside as exhaust EA. The outside air intake port 16 is used to take in air (outside air) OA from outside into the casing 13. The air supply outlet 17 is used to supply outside air OA taken into the casing 13 into the room as air supply SA.

The casing 13 has a top plate 21, a bottom plate 22, and four side plates 23-26. The top plate 21 and the bottom plate 22 are formed into a rectangle or a square. The four side plates 23 to 26 connect the four sides of the top plate 21 and the bottom plate 22. The four side plates 23 to 26 are formed in a rectangular shape.

The side plate 23 of the casing 13 disposed on one side in the second direction Y is provided with an outside air intake port 16 and an exhaust outlet 15. The side plate 26 disposed on the other side in the second direction Y is provided with a return air intake 14 and a supply air outlet 17. The outside air intake port 16 and the exhaust outlet 15 are arranged in a direction along the long side of the side plate 23 (first direction X). The return air intake port 14 and the supply air outlet 17 are arranged in a direction along the long side of the side plate 26 (first direction X).

The side plate 24 disposed on one side in the first direction X has an opening 24a for maintenance. The total heat exchanger 41 housed in the casing 13 can be inserted into or taken out from the casing 13 in the first direction X through the maintenance opening 24a. By taking out the total heat exchanger 41 from the casing 13, the opening 24a can be used to inspect or replace parts inside the casing 13. In the side plate 24, an electrical component box 27 is provided at a position adjacent to the opening 24a. The electrical component box 27 houses a control board for controlling the ventilation system 10 and the like.

A total heat exchanger 41, an air supply fan 42, and an exhaust fan 43 are arranged inside the casing 13. Inside the casing 13, the return air RA taken in from the return air intake port 14 passes through the total heat exchanger 41, and is discharged outside from the exhaust outlet 15 as exhaust EA. Hereinafter, this air flow will also be referred to as "first air flow F1." The outside air OA taken in from the outside air intake port 16 passes through the total heat exchanger 41, and is supplied into the room from the supply air outlet 17 as supply air SA. Hereinafter, this air flow will also be referred to as "second air flow F2."

The total heat exchanger 41 in this embodiment is a known orthogonal type total heat exchanger configured so that the first air flow F1 and the second air flow F2 pass almost orthogonally. The total heat exchanger 41 is constructed by alternately stacking a plurality of partition plates formed in a flat plate shape and having heat conductivity and moisture permeability, and partition plates formed in a corrugated plate shape. . The total heat exchanger 41 is generally formed into a rectangular column shape as a whole. The total heat exchanger 41 exchanges sensible heat and latent heat between the air flowing in the first air flow F1 and the air flowing in the second air flow F2.

As shown in FIGS. 2 to 4, the inside of the casing 13 is divided into two regions, an indoor side and an outdoor side, by a total heat exchanger 41. As shown in FIGS. 2 and 4, an upstream exhaust flow path 46a is formed in the casing 13 on the upstream side of the first air flow F1 rather than the total heat exchanger 41. A downstream exhaust flow path 46b is formed on the downstream side of the first air flow F1. The upstream exhaust flow path 46a and the downstream exhaust flow path 46b constitute an exhaust flow path 46 that communicates the indoor and outdoor areas via the total heat exchanger 41.

As shown in FIGS. 2 and 3, an upstream air supply flow path 47a is formed in the casing 13 on the upstream side of the second air flow F2 rather than the total heat exchanger 41. A downstream air supply flow path 47b is formed on the downstream side of the second air flow F2. The upstream air supply passage 47a and the downstream air supply passage 47b constitute an air supply passage 47 that communicates the indoor and outdoor areas via the total heat exchanger 41.

As shown in FIG. 2, a guide flow path 48 for guiding the air flow from the downstream side air supply flow path 47b to the air supply outlet 17 is provided in a region of the casing 13 on the indoor side of the total heat exchanger 41. It is being A guide flow path 49 for guiding air flow from the downstream exhaust flow path 46b to the exhaust outlet 15 is provided in a region outside the total heat exchanger 41 outdoors.

As shown in FIGS. 3 and 4, a partition wall 51 is provided in the casing 13 to partition the upstream exhaust flow path 46a and the downstream air supply flow path 47b. A partition wall 52 is provided within the casing 13 to partition the downstream exhaust flow path 46b and the upstream air supply flow path 47a. As shown in FIG. 2, a partition wall 53 forming a guide channel 48 is provided inside the casing 13. As shown in FIG. Similarly, a partition wall 54 that forms a guide flow path 49 is provided within the casing 13 .

As shown in FIG. 2, an exhaust fan 43 is disposed in a region outside the total heat exchanger 41 inside the casing 13. By driving this exhaust fan 43, a first air flow F1 is generated, and return air RA from the room passes through the exhaust flow path 46 and the guide flow path 49 and is discharged to the outside as exhaust air EA. An air supply fan 42 is arranged in a region of the casing 13 on the indoor side of the total heat exchanger 41 . By driving this air supply fan 42, a second air flow F2 is generated, and outside air OA from outside the room passes through the air supply flow path 47 and the guide flow path 48 and is supplied into the room as air supply SA.

The air supply fan 42 is disposed at an intermediate portion in the first direction X within the casing 13. Specifically, the air supply fan 42 is arranged between the return air intake port 14 and the air supply outlet 17 in the first direction X. The air supply fan 42 has a fan rotor 42a and a motor 42b. The air supply fan 42 is arranged such that the rotational axis of the fan rotor 42a is along the second direction Y. In the second direction Y, the motor 42b of the air supply fan 42 is arranged closer to the total heat exchanger 41 than the fan rotor 42a. A fan rotor 42a of the air supply fan 42 is disposed within the guide passage 48, and a motor 42b is disposed in the downstream air supply passage 47b. The air supply fan 42 is fixed to the casing 13 via a support member (not shown).

The exhaust fan 43 is disposed at an intermediate portion in the first direction X within the casing 13. Specifically, the exhaust fan 43 is arranged between the exhaust outlet 15 and the outside air intake port 16 in the first direction X. The exhaust fan 43 has a fan rotor 43a and a motor 43b. The exhaust fan 43 is arranged such that the rotation axis of the fan rotor 43a is along the second direction Y. The motor 43b of the exhaust fan 43 is arranged closer to the total heat exchanger 41 than the fan rotor 43a. A fan rotor 43a of the exhaust fan 43 is arranged within the guide passage 49, and a motor 43b is arranged in the downstream exhaust passage 46b. The exhaust fan 43 is fixed to the casing 13 via a support member (not shown).

As shown in FIGS. 3 and 4, the total heat exchanger 41 is supported movably in the first direction X by guide rails 55, 56, and 57. The total heat exchanger 41 is formed in a rectangular parallelepiped shape that is long in the first direction X (see FIG. 1), and has four corners along the first direction It is placed in a position where it is positioned. The guide rails 55, 56, and 57 extend in the first direction X and guide the total heat exchanger 41 at four corners of the total heat exchanger 41. By moving along the guide rails 55, 56, 57, the total heat exchanger 41 is taken out to the outside through the opening 24a formed in the side plate 24 of the casing 13, and inserted into the inside of the casing 13 from the outside. be done.

A guide rail 55 arranged on one side in the second direction Y is provided on the partition wall 51. A guide rail 55 disposed on the other side in the second direction Y is provided on the partition wall 52. The guide rail 56 arranged on one side (upper side) in the third direction Z is provided on the lower surface of the top plate (specifically, a heat insulating material fixed to the lower surface of the top plate). The guide rail 57 arranged on the other side (lower side) in the third direction is provided on the upper surface of the bottom plate (specifically, the heat insulating material fixed to the upper surface of the bottom plate).

FIG. 5 is a schematic plan view of the flow path member and the heat exchange element.
A flow path member 50 is provided within the casing 13 . This flow path member 50 constitutes partition walls 51 to 54 that form the above-mentioned air supply flow path 47, exhaust flow path 46, and guide flow paths 48, 49. In the second direction Y, the flow path member 50 of this embodiment is arranged in a region on one side and a region on the other side of the total heat exchanger 41 in the casing 13. Since both flow path members 50 have the same configuration, the flow path member 50 on one side, particularly the flow path member 50 on the air supply fan 42 side, will be described below.

FIG. 7 is a perspective view of the flow path member. FIG. 8 is a perspective view of the fixing portion of the flow path member. FIG. 9 is a perspective view of the movable part of the flow path member.
The flow path member 50 is mainly formed of a member having heat insulating properties. The flow path member 50 is formed of a foamed resin material such as expanded polystyrene, for example. The flow path member 50 has a guide rail 55. For example, as shown in FIG. 10, only the guide rail 55 of the flow path member 50 is formed of a metal member. The guide rail 55 has a groove having a substantially C-shaped cross section, into which the corner 41a of the total heat exchanger 41 is inserted.

As shown in FIG. 7, the channel member 50 has a first wall 64, a second wall 65, and a third wall 66 that are arranged parallel to each other. The first to third walls 64 to 66 are arranged side by side at intervals in the third direction Z and are connected by a plurality of connecting walls 67. A downstream air supply flow path 47b is formed between the first wall 64 and the second wall 65. An upstream exhaust flow path 46a is formed between the second wall 65 and the third wall 66. The second wall 65 substantially constitutes the partition wall 51. In the case of the flow path member 50 on the exhaust fan 43 side, a downstream exhaust flow path 46b is formed between the first wall 64 and the second wall 65, and the second wall 65 and the third wall 66 are connected to each other. An upstream air supply flow path 47a is formed therebetween, and the second wall 65 substantially constitutes the partition wall 52.

As shown in FIGS. 8 and 9, the flow path member 50 has a fixed part 61 and a movable part 62. The fixed part 61 is a part fixed to the casing 13. The movable part 62 is a part that is movable with respect to the casing 13. The fixed part 61 and the movable part 62 are adjacent to each other.

As shown in FIG. 8, the fixed portion 61 of the flow path member 50 includes substantially the entire first wall 64 and the third wall 66, and a portion of the second wall 65. A partition wall 53 that forms a guide flow path 48 (see FIG. 2) is formed in the fixed portion 61. A fan rotor 42a of the air supply fan 42 is disposed within this guide flow path 48.

On the other hand, as shown in FIG. 9, the movable part 62 of the flow path member 50 has a part of the second wall 65. As shown in FIG. 5, the movable part 62 is arranged around the motor 42b of the air supply fan 42. The movable portion 62 is formed with a recess 62a in which the motor 42b is placed.

FIG. 11 is a schematic cross-sectional view taken along line CC in FIG. 7. FIG. 12 is an enlarged view of section D in FIG. 11.
In the flow path member 50, a mating portion between the fixed portion 61 and the movable portion 62 has a fitting structure using projections and depressions. Specifically, the convex portion 61c formed on the fixed portion 61 and the concave portion 62c formed on the movable portion 62 fit together, and the convex portion 61d formed on the fixed portion 61 and the convex portion formed on the movable portion 62 fit together. 62d are fitted. By adopting such a fitting structure, leakage of air from the boundary between the fixed part 61 and the movable part 62 can be suppressed.

FIG. 13 is an enlarged view of section D in FIG. 11 showing a modification of the flow path member.
In the channel member 50, a fitting structure according to a modified example shown in FIG. 13 may be adopted at the abutting portion between the fixed part 61 and the movable part 62. In this modification, two convex parts 61c formed in the fixed part 61 and two concave parts 62c formed in the movable part 62 fit together, and one concave part 61d formed in the fixed part 61 and the two concave parts 62c formed in the movable part 62 fit together. One convex portion 62d formed in is fitted. According to this modification, the contact area between the fixed part 61 and the movable part 62 can be expanded compared to the example shown in FIG. 12, and leakage of air from the boundary between the two can be further suppressed.

As shown in FIGS. 5 and 7, the guide rail 55 is provided on the second wall 65 (partition wall 51) of the flow path member 50. The guide rail 55 is divided into a fixed rail part 55a provided on the fixed part 61 and a movable rail part 55b provided on the movable part 62. The fixed rail portions 55a are provided on both sides of the guide rail 55 in the longitudinal direction (first direction X), and the movable rail portion 55b is provided at an intermediate portion of the guide rail 55 in the longitudinal direction.

FIG. 6 is a schematic plan view of the flow path member with the movable portion of the flow path member removed.
The movable part 62 of the flow path member 50 moves in the second direction Y toward the space S after the total heat exchanger 41 is taken out from the opening 24a of the casing 13, in other words, toward the housing space S of the total heat exchanger 41. can be done. Furthermore, the movable part 62 can be taken out from the housing space S to the outside of the casing 13 via the opening 24a. When the movable part 62 is moved, the air supply fan 42 is exposed to the accommodation space S side. Therefore, the air supply fan 42 can be inspected from the accommodation space S without the guide rail 55 getting in the way. In particular, since the motor 42b of the air supply fan 42 is disposed closer to the storage space S than the fan rotor 42a, inspection of the motor 42b can be easily performed from the storage space S.

The air supply fan 42 can be moved to the accommodation space S side by removing it from the casing 13. Furthermore, the air supply fan 42 can be taken out from the housing space S to the outside of the casing 13 via the opening 24a. This allows the air supply fan 42 to be replaced or repaired easily.

In FIGS. 5 to 9, the air supply fan 42 and the flow path member (first flow path member) 50 around it have been described, but the exhaust fan 43 and the flow path member (second flow path member) 50 around it have been described. also has a similar configuration. Therefore, the movable part 62 of the flow path member 50 is moved to the accommodation space S side and taken out from the opening 24a, and the exhaust fan 43 is exposed to the accommodation space S side or taken out to the outside of the casing 13 through the opening 24a. You can

[Second embodiment]
FIG. 14 is a schematic plan view of a flow path member of a ventilation device according to a second embodiment. FIG. 15 is an enlarged plan view of a part of the flow path member and the heat exchange element.
In this embodiment, the configuration of the flow path member 50 is different from that in the first embodiment. In the movable portion 62 of the flow path member 50, end sides 62e on both sides in the first direction X are inclined with respect to the second direction Y. Specifically, both end sides 62e of the movable part 62 are inclined so that the distance between them becomes narrower as the distance from the accommodation space S increases. The end side 62f of the movable part 62 that is farthest from the accommodation space S in the second direction Y is arranged along the first direction X.

In the fixed part 61, the two opposing sides 61e that butt against both end sides 62e of the movable part 62 are also inclined with respect to the second direction Y so that the distance between them becomes narrower as the distance from the storage space S increases. In the fixed part 61, an opposing side 61f that butts against the end side 62f of the movable part 62 is arranged along the first direction X. Elastically deformable seal members 71 are provided on opposing sides 61e and 61f of the fixed portion 61. The seal member 71 may be provided on the end sides 62e and 62f of the movable portion 62.

When the total heat exchanger 41 is not accommodated in the accommodation space S, as shown in FIG. 15, the movable rail portion 55b projects toward the accommodation space S by a distance t with respect to the fixed rail portion 55a. Therefore, when the total heat exchanger 41 is inserted into the storage space S, the movable part 62 is pushed by the total heat exchanger 41 and moves toward the fixed part 61, and each end side 62e, 62f of the movable part 62 is moved to the fixed part. 61 (substantially the sealing member 71). Thereby, the seal member 71 is compressed, the degree of close contact between the fixed part 61 and the movable part 62 is increased, and leakage of air from the boundary between the two can be further suppressed.

In this embodiment, the end of the movable rail section 55b adjacent to the end of the fixed rail section 55a is inclined in a direction farther away from the accommodation space S than the fixed rail section 55a. Thereby, the total heat exchanger 41 inserted into the accommodation space S can be prevented from being caught on the movable rail portion 55b.

In the present embodiment, the end sides 62e and 62f of the movable part 62 may be formed into an arcuate shape as a whole, and the opposing sides 61e and 61f of the fixed part 61 that are opposite thereto are also curved into an arcuate shape. It may be formed into a shape. In this case, one seal member 71 can be easily provided along all the opposing sides 61e, 61f without any gaps.

FIG. 16 is an enlarged plan view showing a part of the flow path member and heat exchange element of the ventilation device according to the third embodiment.
In this embodiment, the fixed rail portion 55a and the movable rail portion 55b of the divided guide rail 55 are arranged such that the closer to the opening 24a of the casing 13 the closer to the storage space S side in the second direction Y the fixed rail portion 55a and the movable rail portion 55b are. There is. Specifically, the fixed rail section 55a closest to the opening 24a is arranged closer to the accommodation space S than the adjacent movable rail section 55b, and this movable rail section 55b is arranged closer to the fixed rail section 55a farthest from the opening 24a. It is arranged closer to the storage space S than the storage space S. In this embodiment, when the total heat exchanger 41 is inserted into the storage space S, it is possible to prevent the total heat exchanger 41 from getting caught on the end of each rail portion 55b, 55a on the opening 24a side, and to smoothly insert the total heat exchanger 41 into the storage space S. The total heat exchanger 41 can then be inserted into the accommodation space S.

[Operations and effects of embodiment]
(1) The ventilation device 10 of the above embodiment includes fans (supply air fan 42 and exhaust fan 43) that generate airflow, and a heat exchange element (total heat exchanger) through which the air generated by the fans 42 and 43 passes. ) 41, a casing 13 in which the fans 42, 43 and the heat exchange element 41 are housed, and an opening 24a through which the heat exchange element 41 is taken in and out, forming a flow path through which air flows within the casing 13. It also includes a flow path member 50 having a rail 55 for guiding the heat exchange element 41 in and out. The flow path member 50 includes a fixing portion 61 that is fixed to the casing 13 and has a portion 55a of the rail 55, and a fixing portion 61 that is movable toward the accommodation space S of the heat exchange element 41 with respect to the casing 13 and includes the rail 55 and the other portion. A movable portion 62 having a portion 55b. With such a configuration, the parts inside the casing 13 are exposed to the storage space S side by moving the movable part 62 of the flow path member 50 together with the part (movable rail part) 55b of the rail 55 toward the storage space S side. This makes it possible to easily perform maintenance of the component through the opening 24a and the accommodation space S.

(2) In the above embodiment, the movable part 62 of the ventilation device 10 is arranged closer to the accommodation space S than the fans 42 and 43. By moving this movable part 62 toward the accommodation space S side, the fans 42 and 43 are exposed to the accommodation space S side. Therefore, by moving the movable part 62 of the flow path member 50 to the accommodation space S side together with the part 55b of the rail 55 and removing it, the fans 42 and 43 can be exposed to the accommodation space S side, and the openings 24a and Maintenance of the fans 42 and 43 can be facilitated through the accommodation space S.

(3) In the above embodiment, the fans 42 and 43 include motors 42b and 43b, and by moving the movable part 62 toward the storage space S side, the motors 42b and 43b are exposed to the storage space S side. . Therefore, the motors 42b and 43b of the fans 42 and 43 can be easily maintained through the opening 24a and the accommodation space S.

(4) In the above embodiment, the fans 42 and 43 include an air supply fan 42 that takes outdoor air into the casing 13 and supplies it indoors, and an exhaust fan that takes indoor air into the casing 13 and exhausts it to the outdoors. 43. The heat exchange element 41 is disposed between the air supply fan 42 and the exhaust fan 43, and the flow path member 50 includes a first flow path member 50 having a rail 55 that guides the heat exchange element 41 on the air supply fan 42 side. and a second flow path member 50 having a rail 55 for guiding the heat exchange element 41 on the exhaust fan 43 side. Therefore, the parts 55b of the rail 55 can be removed to expose the parts inside the casing 13 on both the air supply fan 42 side and the exhaust fan 43 side.

(5) In the second embodiment, the fixed part 61 and the movable part 62 are arranged adjacent to each other, and the movable part 62 is pressed against the fixed part 61 by the heat exchange element 41 arranged in the accommodation space S. . Therefore, it is possible to bring the movable part 62 into close contact with the fixed part 61 using the heat exchange element 41, and to suppress leakage of air from between the two.

(6) In the third embodiment, the part 55a of the rail 55 and the other part 55b of the rail 55 are arranged adjacent to each other in the direction in which the heat exchange element 41 is taken in and out of the accommodation space S, One of the part 55a of the rail 55 and the other part 55b of the rail 55, which is closer to the opening 24a, is located closer to the accommodation space S than the other. Therefore, when inserting the heat exchange element 41 into the housing space S, it is possible to prevent the heat exchange element 41 from getting caught on the other rail that is away from the opening 24a.

Note that the present disclosure is not limited to the above examples, but is indicated by the scope of the claims, and is intended to include all changes within the meaning and scope equivalent to the scope of the claims.
For example, the flow path member 50 having the fixed part 61 and the movable part 62 may be provided on at least one side of the air supply fan 42 side and the exhaust fan 43 side. It is only necessary that one side be exposed to or taken out from the accommodation space S side. The supply air fan 42 and the exhaust fan 43 were both arranged approximately at the center of the casing 13 in the first direction Good too.

The position of the movable part 62 (movable rail part 55b) in the flow path member 50 in the first direction X can be changed as appropriate depending on the positions of the air supply fan 42 and the exhaust fan 43. The position and number of the movable parts 62 may be set to expose components other than the air supply fan 42 and the exhaust fan 43 to the accommodation space S side. The guide rail 55 provided in the flow path member 50 is not limited to three parts, but may be divided into two or four or more parts depending on the position and number of the movable parts 62.

10: Ventilation device 13: Casing 24a: Opening 41: Total heat exchanger (heat exchange element)
42 : Air supply fan 42b : Motor 43 : Exhaust fan 43b : Motor 50 : Channel member 55 : Guide rail 55a : Fixed rail part 55b : Movable rail part 61 : Fixed part 62 : Movable part S : Accommodation space

Claims (6)

a fan (42, 43) for generating airflow;
a heat exchange element (41) through which air generated by the fan (42, 43) passes;
a casing (13) in which the fans (42, 43) and the heat exchange element (41) are housed, and an opening (24a) through which the heat exchange element (41) is inserted and taken out;
A flow path member (50) having a rail (55) that forms a flow path through which the air flow passes within the casing (13) and guides the insertion and removal of the heat exchange element (41),
The flow path member (50) includes a fixing part (61) fixed to the casing (13) and having a part (55a) of the rail (55), and a fixing part (61) that is fixed to the casing (13) and the heat exchange element to the casing (13). (41) A ventilation device including a movable part (62) that is movable toward the accommodation space (S) side and has another part (55b) of the rail (55). The movable part (62) is arranged closer to the accommodation space (S) than the fans (42, 43),
The ventilation device according to claim 1, wherein the fans (42, 43) are exposed to the accommodation space (S) side by moving the movable part (62) towards the accommodation space (S). The fan (42, 43) includes a motor (42b, 43b),
The ventilation device according to claim 2, wherein the motors (42b, 43b) are exposed to the accommodation space (S) side by moving the movable part (62) to the accommodation space (S) side. The fans (42, 43) are an air supply fan (42) that takes outdoor air into the casing (13) and supplies it indoors, and an air supply fan (42) that takes indoor air into the casing (13) and exhausts it outdoors. an exhaust fan (43);
The heat exchange element (41) is arranged between the supply air fan (42) and the exhaust fan (43),
The flow path member (50) includes a first flow path member (50) having the rail (55) that guides the heat exchange element (41) on the air supply fan (42) side, and the exhaust fan (43). ) A second flow path member (50) having the rail (55) guiding the heat exchange element (41) on the side. The fixed part (61) and the movable part (62) are arranged adjacent to each other,
Ventilation according to any one of claims 1 to 3, wherein the movable part (62) is pressed against the fixed part (61) by the heat exchange element (41) arranged in the accommodation space (S). Device. A part (55a) of the rail (55) and another part (55b) of the rail (55) are arranged in a direction in which the heat exchange element (41) is taken in and out of the accommodation space (S). placed adjacent to
One of the part (55a) of the rail (55) and the other part (55b) of the rail (55), which is closer to the opening (24a), is located closer to the accommodation space (S) than the other. The ventilation device according to any one of claims 1 to 3.

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