JP7684578B2 - Heat exchanger and ventilation system - Google Patents

Description

This disclosure relates to a heat exchanger and a ventilation device.

Figure 23 of Patent Document 1 discloses a heat exchanger that exchanges heat between air and air. This heat exchanger includes a seat block constructed by stacking multiple heat transfer plates, and a top plate and a bottom plate that cover the end faces of the seat block. The top plate and bottom plate have side covers that rise from their respective peripheries. The side covers extend along the periphery of the top plate or bottom plate. The side covers fit along the side of the seat block, thereby determining the relative position of the top plate or bottom plate to the seat block.

JP 2004-3824 A

In the heat exchanger of Patent Document 1, part of the side of the seat block is covered by a side cover of the top plate or bottom plate. Therefore, the side cover prevents air from flowing into the air flow paths adjacent to the top plate and side plate. As a result, air cannot pass through some of the multiple air flow paths formed in the heat exchanger, and there is a risk of a large loss in air pressure when the air passes through the heat exchanger.

The objective of this disclosure is to reduce the air pressure loss in the heat exchanger.

The first aspect of the present disclosure is a heat exchanger (10) comprising a plurality of flat sheet-like partition members (15) and a plurality of spacing members (25, 55) that are alternately stacked with the partition members (15) to maintain the spacing between adjacent partition members (15), and in which a first flow path (21) and a second flow path (51) are alternately formed with the partition members (15) in between, the spacing members (25, 55) having a frame portion (30, 60) along the periphery of the partition members (15), the frame portion (30, 60) being formed on one surface in the stacking direction of the partition members (15) and the spacing members (25, 55) and the frame portion (30, 60) being formed on one surface in the stacking direction of the partition members (15) and the spacing members (25, 55) and the frame portion (30, 60) being formed on the other surface of the partition members (15) and the spacing members (25, 55). The partition member (15) and the spacing member (25, 55) have a convex rib portion (34, 64) extending in the extension direction of the frame portion (30, 60) and a concave rib portion (35, 65) formed on the other surface and extending in the extension direction of the frame portion (30, 60), and the convex rib portion (34, 64) of one of the adjacent spacing members (25, 55) fits into the concave rib portion (35, 65) of the other. A first end surface member (91) is provided that covers the inner area of the convex rib portion (34, 64) of the spacing member (25, 55) located at the end of the stacking direction of the partition member (15) and the spacing member (25, 55) and contacts the inner part of the convex rib portion (34, 64) of the frame portion (30, 60).

In the first embodiment, the first end surface member (91) covers the inner area of the protruding rib portion (34, 64) of the spacing member (25, 55) and prevents air from leaking from the space surrounded by the frame portion (30, 60) of the spacing member (25, 55). On the other hand, the first end surface member (91) does not cover the side surfaces of the stacked partition members (15) and spacing members (25, 55). Therefore, in this embodiment, the flow of air flowing into the heat exchanger (10) is not obstructed by the first end surface member (91), and the air pressure loss in the heat exchanger (10) is reduced.

In a second aspect of the present disclosure, in the heat exchanger (10) of the first aspect, the surface of the first end member (91) facing the spacing member (25, 55) is a flat surface.

In the second embodiment, the first end surface member (91) does not enter the space surrounded by the frame portion (30, 60) of the spacing member (25, 55). Therefore, the air flow in the space surrounded by the frame portion (30, 60) of the spacing member (25, 55) is not obstructed by the first end surface member (91). As a result, the air pressure loss in the heat exchanger (10) is reduced.

In a third aspect of the present disclosure, in the heat exchanger (10) of the first or second aspect, the plurality of spacing members (25, 55) include a one-end spacing member (81) located at one end of the stacking direction of the partition member (15) and the spacing members (25, 55), and an other-end spacing member (82) located at the other end of the stacking direction, the one-end spacing member (81) is arranged in a position in which the orientation of the convex rib portion (34, 64) is the same as that of the spacing members (25, 55) other than the other-end spacing member (82), and the other-end spacing member (82) is arranged in a position in which the orientation of the convex rib portion (34, 64) is opposite to that of the one-end spacing member (81), and the first end surface member (91) is attached to each of the one-end spacing member (81) and the other-end spacing member (82).

In the third embodiment, the convex rib portion (34, 64) of the one-end spacing member (81) and the convex rib portion (34, 64) of the other-end spacing member (82) each face outward from the heat exchanger (10). A first end surface member (91) is attached to each of the one-end spacing member (81) and the other-end spacing member (82), and one end side and the other end side of the heat exchanger (10) are blocked by the first end surface member (91). Therefore, according to this embodiment, a common member can be used to block one end side and the other end side of the heat exchanger (10).

A fourth aspect of the present disclosure is a heat exchanger (10) according to any one of the first to third aspects, which includes a second end surface member (92) that covers the first end surface member (91) and the convex rib portion (34, 64) of the spacing member (25, 55) to which the first end surface member (91) is attached, and that contacts the protruding end surface of the convex rib portion (34, 64).

In the fourth aspect, a second end surface member (92) is provided at the end of the heat exchanger (10) in the stacking direction of the partition member (15) and the spacing member (25, 55). The second end surface member (92) covers the first end surface member (91) and contacts the protruding end surface of the protruding rib portion (34, 64). As a result, the airtightness of the heat exchanger (10) is improved.

In a fifth aspect of the present disclosure, in the heat exchanger (10) of the fourth aspect, the first end surface member (91) and the second end surface member (92) are each a flat plate-shaped member.

In the fifth aspect, the shapes of the first end surface member (91) and the second end surface member (92) can be simplified.

In a sixth aspect of the present disclosure, in the heat exchanger (10) of the fourth or fifth aspect, a fixing member (95) is provided so as to penetrate all of the stacked partition members (15) and spacing members (25, 55), the first end face member (91), and the second end face member (92), and fixes the partition members (15), the spacing members (25, 55), the first end face member (91), and the second end face member (92).

In the sixth aspect, all of the stacked partition members (15) and spacing members (25, 55), the first end surface member (91), and the second end surface member (92) are fixed to each other by the fixing member (95).

The seventh aspect of the present disclosure is a heat exchanger (10) according to any one of the first to fifth aspects, which includes a fixing member (95) that is provided so as to penetrate all of the stacked partition members (15) and spacing members (25, 55) and the first end surface member (91) and fixes the partition members (15), spacing members (25, 55), and first end surface member (91).

In the seventh aspect, all of the stacked partition members (15) and spacing members (25, 55) and the first end surface member (91) are fixed to each other by the fixing member (95).

The eighth aspect of the present disclosure is a ventilation device (100) that includes any one of the first to eighth heat exchangers (10) described above, and exchanges heat in the heat exchanger (10) between supply air that is supplied from the outside to the inside of a room and exhaust air that is discharged from the inside of a room to the outside of the room.

In the eighth aspect, the supply air and the exhaust air exchange heat with each other in a heat exchanger (10) provided in the ventilation device (100).

FIG. 1 is a schematic diagram of a ventilation device. FIG. 2 is a perspective view of the heat exchanger. FIG. 3 is a plan view of the heat exchanger. FIG. 4 is a plan view of the first frame of the heat exchanger. FIG. 5 is a perspective view of a portion of the first frame. FIG. 6 is a plan view of the second frame of the heat exchanger. FIG. 7 is a perspective view of a portion of the second frame. FIG. 8 is a cross-sectional view of the heat exchanger showing a part of the cross section VIII-VIII of FIG. FIG. 9 is a cross-sectional view of the heat exchanger taken along line IX-IX of FIG. FIG. 10 is a cross-sectional view showing a cross section of the heat exchanger of the first modified example, which corresponds to FIG.

An embodiment will be described. The ventilation device (100) of this embodiment includes a heat exchanger (10) and supplies air to an indoor space and exhausts air from the indoor space.

- Ventilation equipment -
As shown in Fig. 1, the ventilation device (100) includes a casing (110) that houses a heat exchanger (10). The casing (110) is provided with an outside air inlet (111), an air supply port (112), an inside air inlet (113), and an exhaust port (114). In addition, an air supply side passage (121) and an exhaust side passage (122) are formed in the internal space of the casing (110).

The air supply side passage (121) has one end connected to the outside air intake port (111) and the other end connected to the air supply port (112). The air exhaust side passage (122) has one end connected to the inside air intake port (113) and the other end connected to the air exhaust port (114). In the ventilation device (100), outside air flows through the air supply side passage (121) toward the room, and indoor air flows through the air exhaust side passage (122) toward the outside.

The heat exchanger (10) is disposed so as to cross the intake side passage (121) and the exhaust side passage (122). The heat exchanger (10) is installed in the casing (110) with the first air flow path (36) communicating with the intake side passage (121) and the second air flow path (37) communicating with the exhaust side passage (122).

The ventilation device (100) further includes an intake fan (131) and an exhaust fan (132). The intake fan (131) is disposed downstream of the heat exchanger (10) in the intake side passage (121). The exhaust fan (132) is disposed downstream of the heat exchanger (10) in the exhaust side passage (122).

- Overall configuration of heat exchanger -
The heat exchanger (10) of the present embodiment is a so-called total heat exchanger. The heat exchanger (10) is provided in a ventilation system and exchanges sensible heat and latent heat (moisture) between outdoor air (supply air) supplied into the room and indoor air (exhaust air) exhausted to the outside.

As shown in Figures 2 and 3, the heat exchanger (10) is formed in a columnar shape with polygonal end faces. In this embodiment, the end faces of the heat exchanger (10) are horizontally long and octagonal. The heat exchanger (10) is formed with one main heat exchange section (11) and two auxiliary heat exchange sections (12a, 12b). In the following description, "upper", "lower", "right", "left", "front" and "rear" refer to the directions shown in Figure 2 unless otherwise specified.

The main heat exchange section (11) is located at the center of the heat exchanger (10) in the left-right direction. In the plan view of the heat exchanger (10) shown in FIG. 3, the main heat exchange section (11) is a horizontally long rectangular section. The auxiliary heat exchange sections (12a, 12b) are located to the sides of the main heat exchange section (11) in the left-right direction of the heat exchanger (10). In the heat exchanger (10), one auxiliary heat exchange section (12a, 12b) is disposed on each side of the main heat exchange section (11) in the left-right direction. In the plan view of the heat exchanger (10) shown in FIG. 3, each auxiliary heat exchange section (12a, 12b) is a trapezoidal section.

The heat exchanger (10) includes a plurality of first elements (20) and a plurality of second elements (50). In the heat exchanger (10), the first elements (20) and the second elements (50) are alternately stacked on top of each other. The first elements (20) form a first flow path (21). The first flow path (21) is an air flow path through which the supply air flows. The second elements (50) form a second flow path (51). The second flow path (51) is an air flow path through which the exhaust air flows. In the heat exchanger (10), the first flow paths (21) and the second flow paths (51) are alternately formed in the stacking direction of the first elements (20) and the second elements (50).

A first inlet (22a), a first outlet (22b), a second inlet (52a), and a second outlet (52b) are formed on a side surface of the heat exchanger (10) (a surface along the stacking direction of the first element (20) and the second element (50)). The first inlet (22a) and the first outlet (22b) are formed in the first element (20) and communicate with the first flow path (21). The second inlet (52a) and the second outlet (52b) are formed in the second element (50) and communicate with the second flow path (51).

The first inlet (22a), the first outlet (22b), the second inlet (52a), and the second outlet (52b) are formed on different side surfaces of the heat exchanger (10). In one of the sub-heat exchange sections (12a) of the heat exchanger (10), the first inlet (22a) opens on one side surface, and the second outlet (52b) opens on the other side surface. In the other of the sub-heat exchange sections (12b) of the heat exchanger (10), the first outlet (22b) opens on one side surface, and the second inlet (52a) opens on the other side surface.

The side surface of the heat exchanger (10) is formed by the outer peripheral surfaces of the stacked first element (20) and second element (50). The side surface of the heat exchanger (10) is substantially flat.

As described below, in the heat exchanger (10) of this embodiment, a first end surface member (91) and a second end surface member (92) are provided at one end and the other end in the stacking direction of the first element (20) and the second element (50). All of the first elements (20) and second elements (50) and the first end surface members (91) and second end surface members (92) are fixed to each other by eight fixing members (95). Note that the number of fixing members (95) is merely an example.

As described below, six notches (38, 68) are formed in each of the first element (20) and the second element (50) constituting the heat exchanger (10). In each element (20, 50), the notches (38, 68) open to the outer peripheral surface of the element (20, 50).

Each cutout portion (38, 68) formed in one element (20, 50) corresponds to a cutout portion (38, 68) formed in the other element (20, 50). In the heat exchanger (10), the corresponding cutout portions (38, 68) of each element (20, 50) are aligned in a row in the stacking direction of the elements (20, 50).

In the heat exchanger (10) of this embodiment, a sealing member (17) is provided to fill the aligned cutouts (38, 68). The sealing member (17) is formed by filling the aligned cutouts (38, 68) with a filler such as a silicone sealant and allowing it to solidify.

-Heat exchange function of heat exchanger-
As shown in Fig. 1, in the heat exchanger (10), the outdoor air OA flows into the first inlet (22a), and the room air RA flows into the second inlet (52a). The outdoor air OA that flows into the first inlet (22a) flows as supply air through the first flow path (21), passes through one of the sub-heat exchange sections (12a), the main heat exchange section (11), and the other of the sub-heat exchange sections (12b) in this order, and then flows out through the first outlet (22b) to be supplied to the room. The room air RA that flows into the second inlet (52a) flows as exhaust air through the second flow path (51), passes through the other of the sub-heat exchange sections (12b), the main heat exchange section (11), and one of the sub-heat exchange sections (12a) in this order, and then flows out through the second outlet (52b) to be discharged to the outside of the room.

In each of the auxiliary heat exchange sections (12a, 12b) of the heat exchanger (10), the supply air flowing through the first flow path (21) and the exhaust air flowing through the second flow path (51) flow in directions that cross each other. In the main heat exchange section (11) of the heat exchanger (10), the supply air flowing through the first flow path (21) and the exhaust air flowing through the second flow path (51) flow in opposite directions.

In the heat exchanger (10), sensible heat and latent heat (moisture) are exchanged between the supply air flowing through the first flow path (21) and the exhaust air flowing through the second flow path (51). In the heat exchanger (10), heat moves from the supply air or the exhaust air, whichever has a higher temperature, to the one with a lower temperature. In addition, in the heat exchanger (10), moisture moves from the supply air or the exhaust air, whichever has a higher humidity, to the one with a lower humidity.

--First element, second element--
As shown in Figures 8 and 9, the first element (20) includes a first frame (25) and a partition sheet (15), and the second element (50) includes a second frame (55) and a partition sheet (15).

The first frame (25) and the second frame (55) are each a flat member made of resin formed by injection molding. In the following description, the surface shown in FIG. 4 is referred to as the "front surface" of the first frame (25), and the surface opposite this front surface is referred to as the "reverse surface." Additionally, the surface shown in FIG. 6 is referred to as the "front surface" of the second frame (55), and the surface opposite this front surface is referred to as the "reverse surface."

The partition sheet (15) is a sheet-like member that has high moisture permeability and low air permeability. This partition sheet (15) is a partition member that separates the first flow path (21) and the second flow path (51). The material of the partition sheet (15) is a polymer material (e.g., polyurethane) that contains hydrophilic and hydrophobic groups. The thickness of the partition sheet (15) is, for example, about 1 to 30 μm.

The partition sheet (15) may be made of paper, nonwoven fabric, or the like. Examples of the material of the paper or nonwoven fabric that constitutes the partition sheet (15) include fibrous resin, fibrous metal, glass fiber, and pulp.

In the first element (20), the partition sheet (15) is adhered to the rear surface of the first frame (25) by an adhesive. The partition sheet (15) covers almost the entire rear surface of the first frame (25). In the second element (50), the partition sheet (15) is adhered to the rear surface of the second frame (55) by an adhesive. The partition sheet (15) covers almost the entire rear surface of the second frame (55). In each element (20, 50), the partition sheet (15) may be fixed to the frame (25, 55) by, for example, heat fusion without using an adhesive. In each element (20, 50), the partition sheet (15) does not have to be fixed to the frame (25, 55).

--First frame--
As shown in Fig. 4, the first frame (25) is formed in a horizontally elongated octagonal shape in a plan view. The outer shape of the first frame (25) in a plan view is substantially the same as the shape of the end face of the heat exchanger (10). The first frame (25) is a first spacing member that maintains the spacing between adjacent partition sheets (15).

The first frame (25) is formed with one central area (26) and two end areas (27a, 27b). The central area (26) is a horizontally long rectangular area and is located in the center in the left-right direction of FIG. 4. In the first frame (25), the end areas (27a, 27b) are formed on both sides of the central area (26). The end areas (27a, 27b) are trapezoidal areas located to the sides of the central area (26) in the left-right direction of FIG. 4.

<Frame>
The first frame (25) includes a frame portion (30). The frame portion (30) is a portion that extends along the outer periphery of the first frame (25) and is formed over the entire circumference of the first frame (25). In other words, the frame portion (30) is formed in a horizontally elongated octagonal frame shape. The frame portion (30) surrounds the periphery of the air flow path formed by the first frame (25). The frame portion (30) also fits along the peripheral edge of the partition sheet (15).

Two first communication openings (22) are formed in the frame portion (30) of the first frame (25). The frame portion (30) of the first frame (25) is divided into a first communication portion (30a) in which the first communication openings (22) are formed, and a first partition portion (30b) that separates the air flow path from the outside of the frame portion (30). The first partition portion (30b) is a portion of the frame portion (30) in which the first communication openings (22) are not formed.

Each first communication opening (22) formed in the frame (30) connects the air flow path surrounded by the frame (30) to the outside of the frame (30). In the frame (30) shown in FIG. 4, one first communication opening (22) is formed over almost the entire downward oblique side located in the left end area (27a) and the lower part of the short side located at the left end of the end area (27a), forming a first inlet (22a). In the frame (30) shown in FIG. 4, the other first communication opening (22) is formed over almost the entire upward oblique side located in the right end area (27b) and the upper part of the short side located at the right end of the end area (27b), forming a first outlet (22b).

As shown in Figures 4 and 5, the frame portion (30) of the first frame (25) has a closing portion (31), an outer rib (33), and an auxiliary rib (32). A part of the outer rib (33) forms a convex portion (34). The closing portion (31) is formed with a concave portion (35).

The blocking portion (31) constitutes the first partition wall portion (30b) of the frame portion (30). As shown in FIG. 8, the cross-sectional shape of the blocking portion (31) is a rectangle with one corner cut out. The blocking portion (31) separates the first flow path (21) surrounded by the frame portion (30) from the outside of the frame portion (30). The thickness of the blocking portion (31) is substantially equal to the thickness of the first flow path (21).

As shown in FIG. 4, the outer rib (33) is a portion that extends along the outer periphery of the frame portion (30) and is formed around the entire circumference of the frame portion (30). The outer rib (33) is formed along all eight sides of the frame portion (30). The outer rib (33) is disposed on the front surface side of the closing portion (31) and is formed integrally with the closing portion (31).

As shown in FIG. 8, the portion of the outer rib (33) adjacent to the blocking portion (31) forms a convex rib portion (34). The convex rib portion (34) extends along the outermost edge of the blocking portion (31) and protrudes from the front surface of the blocking portion (31). The outer peripheral surface of the convex rib portion (34) forms a single plane together with the outer peripheral surface of the blocking portion (31). In addition, the convex rib portion (34) forms the first partition portion (30b) together with the blocking portion (31).

As shown in FIG. 8, the groove (35) is a groove that opens to the back surface of the blocking portion (31). The groove (35) is formed along the outermost edge of the blocking portion (31) over the entire length of the blocking portion (31). The groove (35) also opens to the outer peripheral surface of the blocking portion (31). The cross-sectional shape of the groove (35) corresponds to the cross-sectional shape of the protruding portion (64) of the second frame (55) described later. The outer rib (63) of the second frame (55) fits into the groove (35) of the first frame (25). Therefore, the protruding portion (64), which is part of the outer rib (63) of the second frame (55), fits into the groove (35) of the first frame (25).

As shown in Figures 4 and 5, the auxiliary rib (32) is a portion that extends along the first communication opening (22). The auxiliary rib (32) is disposed on the back surface side of the frame portion (30). The cross-sectional shape of the auxiliary rib (32) is a flattened rectangle. The front surface of the auxiliary rib (32) is located on the same plane as the tip end surface of the convex portion (64) of the adjacent second frame (55). The back surface of the auxiliary rib (32) is located on the same plane as the back surface of the blocking portion (31).

As shown in FIG. 4, six first cutouts (38) are formed in the frame portion (30) of the first frame (25). Each first cutout (38) is a cutout that opens to the outer peripheral surface of the frame portion (30) and extends toward the inside of the frame portion (30).

<First inner rib, first retaining rib, first support portion>
4 and 5, the first frame (25) includes a first inner rib (40), a first retaining rib (41), and a first support portion (42). The first inner rib (40), the first retaining rib (41), and the first support portion (42) are provided in each end area (27a, 27b) of the first frame (25).

The first inner rib (40) is formed in a straight rod shape and extends in a direction intersecting with the first communication opening (22). In this embodiment, the first inner rib (40) is formed integrally with the outer rib (33) and the auxiliary rib (32) that extend along the first communication opening (22). The height of the first inner rib (40) is substantially equal to the thickness of the first flow path (21). In this embodiment, five first inner ribs (40) are arranged in parallel with each other and at approximately regular intervals in each end area (27a, 27b) of the first frame (25).

The first retaining rib (41) is formed in a straight rod shape and extends in a direction substantially perpendicular to the first inner rib (40). The first retaining rib (41) is formed from one of the adjacent first inner ribs (40) to the other. In other words, the first retaining rib (41) crosses the portion of the first flow path (21) between the adjacent first inner ribs (40). The thickness of each first retaining rib (41) is less than half the thickness of the first inner rib (40).

The first support pillars (42) are plate-shaped portions extending in the width direction of the auxiliary ribs (32) of the frame portion (30). The first support pillars (42) connect the outer ribs (33) and the auxiliary ribs (32). The first support pillars (42) are provided between adjacent first inner ribs (40) in the longitudinal direction of the auxiliary ribs (32).

<First flow passage inner rib, first support rib>
4 and 5, the first frame (25) includes a first flow passage inner rib (45) and a first support rib (46). The first flow passage inner rib (45) and the first support rib (46) are provided in the central area (26) of the first frame (25).

The first flow path rib (45) is formed in a straight rod shape and extends in a direction parallel to the long side of the central area (26). In other words, the first flow path rib (45) extends from one end area (27a) to the other end area (27b). The height of the first flow path rib (45) is substantially equal to the thickness of the first flow path (21) (see FIG. 8). In this embodiment, eleven first flow path ribs (45) are arranged in the central area (26) of the first frame (25) in a parallel orientation and at approximately regular intervals from one another.

The first support rib (46) is formed in a straight rod shape and extends in a direction substantially perpendicular to the first flow path rib (45). The first support rib (46) is formed from one of the adjacent first flow path ribs (45) to the other. In other words, the first support rib (46) crosses the portion of the first flow path (21) between the adjacent first flow path ribs (45). The first support rib (46) is formed integrally with the first flow path rib (45) and maintains the distance between the adjacent first flow path ribs (45).

<Inner protrusion>
4 and 5, the first frame (25) has eight inner protrusions (48). The inner protrusions (48) are portions for connecting the stacked elements (20, 50).

Each inner protrusion (48) is formed integrally with the closing portion (31) of the frame portion (30). In the first frame (25), six inner protrusions (48) are provided in the central area (26), and one inner protrusion (48) is provided in each end area (27a, 27b).

In the central area (26), three inner protrusions (48) are provided in each of the two blocking sections (31) located in the central area (26). In each blocking section (31) in the central area (26), the inner protrusions (48) are arranged near the left end, near the right end, and near the center in the left-right direction. In each end area (27a, 27b), the inner protrusions (48) are arranged at positions corresponding to the upper base of the trapezoid.

Each inner protrusion (48) is a tab-shaped portion that protrudes from the blocking portion (31) toward the inside of the frame portion (30). The thickness of the inner protrusion (48) is substantially equal to the thickness of the blocking portion (31). Each inner protrusion (48) has one insertion hole (48a) formed therein. The insertion hole (48a) is a hole that penetrates the inner protrusion (48) in the thickness direction.

- Second frame -
As shown in Fig. 6, the second frame (55) is formed in a horizontally elongated octagonal shape in a plan view. The outer shape of the second frame (55) in a plan view is substantially the same as the shape of the end face of the heat exchanger (10). The second frame (55) is a second spacing member that maintains the spacing between adjacent partition sheets (15).

The second frame (55) is formed with one central area (56) and two end areas (57a, 57b). The central area (56) is a horizontally long rectangular area and is located in the center in the left-right direction of FIG. 6. In the second frame (55), the end areas (57a, 57b) are formed on both sides of the central area (56). The end areas (57a, 57b) are trapezoidal areas located to the sides of the central area (56) in the left-right direction of FIG. 6.

<Frame>
The second frame (55) includes a frame portion (60). The frame portion (60) is a portion that extends along the outer periphery of the second frame (55) and is formed over the entire circumference of the second frame (55). In other words, the frame portion (60) is formed in a horizontally elongated octagonal frame shape. The frame portion (60) surrounds the periphery of the air flow path formed by the second frame (55). The frame portion (60) also fits along the peripheral edge of the partition sheet (15).

Two second communication openings (52) are formed in the frame portion (60) of the second frame (55). The frame portion (60) of the second frame (55) is divided into a second communication portion (60a) in which the second communication openings (52) are formed, and a second partition portion (60b) that separates the air flow path from the outside of the frame portion (60). The second partition portion (60b) is a portion of the frame portion (60) in which the second communication openings (52) are not formed.

Each second communication opening (52) formed in the frame (60) connects the second flow path (51) surrounded by the frame (60) to the outside of the frame (60). In the frame (60) shown in FIG. 6, one second communication opening (52) is formed over almost the entire upward oblique side located in the left end area (57a) and the upper part of the short side located at the left end of the end area (57a), forming a second outlet (52b). In the frame (60) shown in FIG. 6, the other second communication opening (52) is formed over almost the entire downward oblique side located in the right end area (57b) and the lower part of the short side located at the right end of the end area (57a), forming a second inlet (52a).

As shown in Figures 6 and 7, the frame portion (60) of the second frame (55) has a blocking portion (61), an outer rib (63), and an auxiliary rib (62). A part of the outer rib (63) forms a convex portion (64). The blocking portion (61) is formed with a concave portion (65).

The blocking portion (61) constitutes the second partition wall portion (60b) of the frame portion (60). As shown in FIG. 8, the cross-sectional shape of the blocking portion (61) is a rectangle with one corner cut out. The blocking portion (61) separates the second flow path (51) surrounded by the frame portion (60) from the outside of the frame portion (60). The thickness of the blocking portion (61) is substantially equal to the thickness of the second flow path (51).

As shown in FIG. 6, the outer rib (63) is a portion that extends along the outer periphery of the frame portion (60) and is formed around the entire circumference of the frame portion (60). The outer rib (63) is formed along all eight sides of the frame portion (60). The outer rib (63) is disposed on the front surface side of the closing portion (61) and is formed integrally with the closing portion (61).

As shown in FIG. 8, the portion of the outer rib (63) adjacent to the blocking portion (61) forms a convex rib portion (64). The convex rib portion (64) extends along the outermost edge of the blocking portion (61) and protrudes from the front surface of the blocking portion (61). The outer peripheral surface of the convex rib portion (64) forms a single plane together with the outer peripheral surface of the blocking portion (61). In addition, the convex rib portion (64) forms the second partition wall portion (60b) together with the blocking portion (61).

As shown in FIG. 8, the groove (65) is a groove that opens to the back surface of the blocking portion (61). The groove (65) is formed along the outermost edge of the blocking portion (61) over the entire length of the blocking portion (61). The groove (65) also opens to the outer circumferential surface of the blocking portion (61). The cross-sectional shape of the groove (65) corresponds to the cross-sectional shape of the protruding portion (34) of the first frame (25). The outer rib (33) of the first frame (25) fits into the groove (65) of the second frame (55). Therefore, the protruding portion (34), which is part of the outer rib (33) of the first frame (25), fits into the groove (65) of the second frame (55).

As shown in Figures 6 and 7, the auxiliary rib (62) is a portion that extends along the second communication opening (52). The auxiliary rib (62) is disposed on the back surface side of the frame portion (60). The cross-sectional shape of the auxiliary rib (62) is a flattened rectangle. The front surface of the auxiliary rib (62) is located on the same plane as the tip end surface of the convex portion (34) of the adjacent first frame (25). The back surface of the auxiliary rib (62) is located on the same plane as the back surface of the blocking portion (61).

As shown in FIG. 6, six second cutouts (68) are formed in the frame portion (60) of the second frame (55). Each second cutout (68) is a cutout that opens to the outer circumferential surface of the frame portion (60) and extends toward the inside of the frame portion (60).

<Second inner rib, second retaining rib, second support portion>
6 and 7, the second frame (55) includes a second inner rib (70), a second retaining rib (71), and a second support portion (72). The second inner rib (70), the second retaining rib (71), and the second support portion (72) are provided in each end area (57a, 57b) of the second frame (55).

The second inner rib (70) is formed in a straight rod shape and extends in a direction intersecting with the second communication opening (52). In this embodiment, the second inner rib (70) is formed integrally with the outer rib (63) and the auxiliary rib (62) that extend along the second communication opening (52). The height of the second inner rib (70) is substantially equal to the thickness of the second flow path (51). In this embodiment, five second inner ribs (70) are arranged in parallel with each other and at approximately regular intervals in each end area (57a, 57b) of the second frame (55).

The second retaining rib (71) is formed in a straight rod shape and extends in a direction substantially perpendicular to the second inner rib (70). The second retaining rib (71) is formed from one of the adjacent second inner ribs (70) to the other. In other words, the second retaining rib (71) crosses the portion of the second flow path (51) between the adjacent second inner ribs (70). The thickness of each second retaining rib (71) is less than half the thickness of the second inner rib (70).

The second support pillars (72) are plate-shaped portions extending in the width direction of the auxiliary ribs (62) of the frame portion (60). The second support pillars (72) connect the outer ribs (63) and the auxiliary ribs (62). The second support pillars (72) are provided between adjacent second inner ribs (70) in the longitudinal direction of the auxiliary ribs (62).

<Second flow passage inner rib, second support rib>
6 and 7, the second frame (55) includes a second flow path inner rib (75) and a second support rib (76). The second flow path inner rib (75) and the second support rib (76) are provided in the central area (56) of the second frame (55).

The second flow path rib (75) is formed in a straight rod shape and extends in a direction parallel to the long side of the central area (56). In other words, the second flow path rib (75) extends from one end area (57a) to the other end area (57b). The height of the second flow path rib (75) is substantially equal to the thickness of the second flow path (51) (see FIG. 8). In this embodiment, eleven second flow path ribs (75) are arranged in the central area (56) of the second frame (55) in a parallel orientation and at approximately regular intervals from one another.

The second support rib (76) is formed in a straight rod shape and extends in a direction substantially perpendicular to the second flow path rib (75). The second support rib (76) is formed from one of the adjacent second flow path ribs (75) to the other. In other words, the second support rib (76) crosses the portion of the second flow path (51) between the adjacent second flow path ribs (75). The second support rib (76) is formed integrally with the second flow path rib (75) and maintains the distance between the adjacent second flow path ribs (75).

<Inner protrusion>
6 and 7, the second frame (55) has eight inner protrusions (78). The inner protrusions (78) are portions for connecting the stacked elements (20, 50).

Each inner protrusion (78) is formed integrally with the closing portion (61) of the frame portion (60). In the second frame (55), six inner protrusions (78) are provided in the central area (56), and one inner protrusion (78) is provided in each end area (57a, 57b).

In the central area (56), three inner protrusions (78) are provided in each of the two blocking portions (61) located in the central area (56). In each blocking portion (61) in the central area (56), the inner protrusions (78) are arranged near the left end, near the right end, and near the center in the left-right direction. In each end area (57a, 57b), the inner protrusions (78) are arranged at positions corresponding to the upper base of the trapezoid. Each inner protrusion (78) of the second frame (55) is arranged at a position that corresponds one-to-one to the inner protrusions (48) of the first frame (25).

Each inner protrusion (78) is a tab-shaped portion that protrudes from the blocking portion (61) toward the inside of the frame portion (60). The thickness of the inner protrusion (78) is substantially equal to the thickness of the blocking portion (61). Each inner protrusion (78) has one insertion hole (78a) formed therein. The insertion hole (78a) is a hole that penetrates the inner protrusion (78) in the thickness direction.

-Layered structure of heat exchanger-
8 and 9, in the heat exchanger (10), the first elements (20) and the second elements (50) are stacked alternately. The first elements (20) and the second elements (50) are stacked with the front surfaces of their respective frames (25, 55) facing upward.

In the heat exchanger (10) of this embodiment, the number of first elements (20) is two more than the number of second elements (50). In the heat exchanger (10) of this embodiment, the first elements (20) are disposed at each of one end and the other end of the stacking direction of the elements (20, 50) (in other words, the vertical direction of the heat exchanger (10)).

The first frame (25) of the first element (20) located at the top of the heat exchanger (10) constitutes the one-end frame (81). This one-end frame (81) is a one-end spacing member. The orientation of the convex rib portion (34) of the one-end frame (81) faces upward, similar to the orientation of the convex rib portions (34, 64) of the frames (25, 55) constituting the other elements (20, 50).

In the heat exchanger (10) of this embodiment, the first frame (25) constituting the other end frame (82) is disposed below the first element (20) located at the bottom. This other end frame (82) is an other end spacing member. The other end frame (82) is disposed with its front surface facing downward. The ridges (34) of the other end frame (82) face downward. Therefore, the ridges (34) of the other end frame (82) face opposite to the ridges (34) of the one end frame (81) (see FIG. 8).

The first frame (25) constituting the other end frame (82) is arranged with its front surface facing downward. Therefore, the first communication portion (30a) of the first frame (25) constituting the other end frame (82) is located on the side of the heat exchanger (10) where the second communication opening (52) of the second element (50) is located (see FIG. 9).

As described below, the upper surface of the one-end frame (81) is covered by the first end member (91) and the second end member (92), and the lower surface of the other-end frame (82) is covered by the first end member (91) and the second end member (92). The first element (20) including the one-end frame (81) forms a first flow path (21). On the other hand, the other-end frame forms a second flow path (51) because the first communication portion (30a) is located on the same side of the heat exchanger (10) as the second communication opening (52) of the second element (50). Therefore, in the heat exchanger (10) of this embodiment, the same number of first flow paths (21) and second flow paths (51) are formed.

--First end surface member, second end surface member--
As described above, the heat exchanger (10) of this embodiment includes the first end surface member (91) and the second end surface member (92). The first end surface member (91) and the second end surface member (92) are provided at the upper end and the lower end of the heat exchanger (10), respectively. The first end surface member (91) and the second end surface member (92) are members constituting the upper surface and the lower surface, respectively, of the heat exchanger (10).

The first end surface member (91) and the second end surface member (92) are each a flat metal member. Both sides of the first end surface member (91) are flat surfaces. Also, both sides of the second end surface member (92) are flat surfaces.

The thickness of the first end surface member (91) is substantially equal to the height of the protruding portion (34) of the first frame (25). The thickness of the first end surface member (91) is, for example, 0.5 mm. The thickness of the second end surface member (92) may be the same as or different from the thickness of the first end surface member (91).

The first end surface member (91) is formed in an octagonal shape that corresponds to the shape of the first frame (25). The periphery of the first end surface member (91) follows the inner edge of the outer rib (33) of the first frame (25).

As shown in Figures 8 and 9, one first end surface member (91) is attached to each of the one end frame (81) and the other end frame (82). One first end surface member (91) covers the inner area of the outer rib (33) of the one end frame (81) and is in close contact with the front surface (upper surface) of the one end frame (81). The other first end surface member (91) covers the inner area of the outer rib (33) of the other end frame (82) and is in close contact with the front surface (lower surface) of the other end frame (82).

The second end surface member (92) is formed in an octagonal shape corresponding to the shape of the first frame (25). The periphery of the second end surface member (92) follows the outer edge of the outer rib (33) of the first frame (25). Therefore, the second end surface member (92) is larger than the first end surface member (91).

As shown in Figures 8 and 9, one second end member (92) is attached to each of the one end frame (81) and the other end frame (82).

The second end surface member (92) on one side covers the protruding end surface (upper surface) of the protruding rib portion (34) of the one end frame (81) and the entire first end surface member (91) attached to the one end frame (81), and is in close contact with both the protruding rib portion (34) of the one end frame (81) and the first end surface member (91). This second end surface member (92) on one side covers substantially the entire protruding end surface of the protruding rib portion (34) of the one end frame (81). Therefore, the airtightness of the first flow path (21) surrounded by the one end frame (81) is maintained.

The other second end surface member (92) covers the protruding end surface (lower surface) of the protruding rib portion (34) of the other end frame (82) and the entire first end surface member (91) attached to the other end frame (82), and is in close contact with both the protruding rib portion (34) of the other end frame (82) and the first end surface member (91). This one second end surface member (92) covers substantially the entire protruding end surface of the protruding rib portion (34) of the other end frame (82). Therefore, the airtightness of the second flow path (51) surrounded by the other end frame (82) is maintained.

- Fixing structure of element and end surface member -
2 and 3, in the heat exchanger (10) of this embodiment, all of the first elements (20) and second elements (50), and the first end surface members (91) and second end surface members (92) are fixed to one another by eight fixing members (95). As shown in Fig. 8, each fixing member (95) includes one bolt (97), one nut (98), and one collar (96).

When the first element (20) and the second element (50) are stacked with the first frame (25) constituting the other end frame (82), the corresponding inner protrusions (48, 78) of each frame (25, 55) are aligned in a row in the stacking direction of the first element (20) and the second element (50) (in other words, the vertical direction of the heat exchanger (10)). In this state, the insertion holes (48a, 78a) of the corresponding inner protrusions (48, 78) of each frame (25, 55) are positioned substantially coaxially.

The collar (96) is a straight circular tube made of metal. The outer diameter of the collar (96) is substantially equal to the diameter of the insertion holes (48a, 78a) of the inner protrusions (48, 78). The collar (96) is inserted into the insertion holes (48a, 78a) of the inner protrusions (48, 78) arranged in a row. The outer peripheral surface of the collar (96) is in close contact with the inner walls of the insertion holes (48a, 78a). The length of the collar (96) is substantially equal to the distance from the upper surface of the second end member (92) covering the one-end frame (81) to the lower surface of the second end member (92) covering the other-end frame (82).

The bolt (97) is inserted through the collar (96). The head of the bolt (97) contacts the second end member (92) that covers the one-end frame (81). The nut (98) is attached to the bolt (97). The nut (98) contacts the second end member (92) that covers the other-end frame (82).

When the nut (98) is tightened, a pressing force acts on the stacked first element (20) and second element (50) and the first end surface member (91) and second end surface member (92) from both sides in the stacking direction (vertical direction), so that the frames (25, 55) of each element (20, 50) are in close contact with each other. In addition, the first end surface member (91) and the second end surface member (92) located at the upper end of the heat exchanger (10) are in close contact with the one-end frame (81), and the first end surface member (91) and the second end surface member (92) located at the lower end of the heat exchanger (10) are in close contact with the other-end frame (82). As a result, the airtightness of the first flow path (21) and the second flow path (51) of the heat exchanger (10) is maintained.

--Features of the embodiment (1)--
In the heat exchanger of this embodiment, a first end surface member (91) is provided on each of the one end frame (81) and the other end frame (82) located at the ends in the stacking direction of the partition sheet (15) and the frames (25, 55). The first end surface member (91) covers the inner area of the protruding rib portion (34) of each of the one end frame (81) and the other end frame (82).

The first end surface member (91) does not cover the side surfaces of the stacked elements (20, 50) and prevents air from leaking from the flow path (21, 51) surrounded by the frame portion (30, 60) of the frame (25, 55). Therefore, in the heat exchanger (10) of this embodiment, the flow of air flowing into the heat exchanger (10) is not obstructed by the first end surface member (91), and the air pressure loss in the heat exchanger (10) is reduced.

--Features of the embodiment (2)--
In the heat exchanger (10) of this embodiment, the first end member (91) is a flat metal member, and the surface of the first end member (91) facing the one-end frame (81) or the other-end frame (82) is flat. Therefore, even when the fastening force of the fixing member (95) acts on the first end member (91), deformation of the first end member (91) is suppressed, and the deformed first end member (91) does not protrude into the flow path (21, 51) surrounded by the one-end frame (81) or the other-end frame (82). Therefore, the air pressure loss in the flow path (21, 51) surrounded by the one-end frame (81) or the other-end frame (82) is suppressed.

--Feature of the embodiment (3)--
In the heat exchanger (10) of this embodiment, the protruding rib portion (34) of the one end frame (81) and the protruding rib portion (34) of the other end frame (82) each face outward from the heat exchanger (10). A first end surface member (91) is attached to each of the one end frame (81) and the other end frame (82), and one end side and the other end side of the heat exchanger (10) are closed by the first end surface member (91). Therefore, according to this embodiment, a common member can be used to close the upper and lower ends of the heat exchanger (10).

In addition, in the heat exchanger (10) of this embodiment, the members that close the upper and lower ends of the heat exchanger (10) are common, and the same number of first flow paths (21) and second flow paths (51) can be formed. Therefore, according to this embodiment, the pressure loss of the supply air and the pressure loss of the exhaust air when passing through the heat exchanger (10) can be made substantially equal.

--Feature of the embodiment (4)--
In the heat exchanger (10) of this embodiment, the one end frame (81) and the other end frame (82) to which the first end member (91) is attached are each covered with the second end member (92). As a result, airtightness can be maintained at the upper and lower ends of the heat exchanger (10), and leakage of air from the flow paths (21, 51) can be suppressed.

--First Modification of the Embodiment--
In the heat exchanger (10) of this embodiment, the material of the first end surface member (91) and the second end surface member (92) is not limited to metal. Examples of the material of the first end surface member (91) and the second end surface member (92) include hard resin, foamed resin, rubber, etc. In addition, the material of the first end surface member (91) and the material of the second end surface member (92) may be the same or different.

In the heat exchanger (10) shown in FIG. 10, the first end surface member (91) is made of metal, and the second end surface member (92) is made of foamed resin.

In the heat exchanger (10) of FIG. 10, all the stacked elements (20, 50) and the first end surface member (91) are fixed to each other by the fixing member (95). Specifically, the collar (96) of the fixing member (95) is inserted through all the stacked elements (20, 50), the first end surface member (91) covering the one end frame (81), and the first end surface member (91) covering the other end frame (82). Then, a nut (98) is attached to the bolt (97) inserted through the collar (96). When the nut (98) is tightened, the stacked elements (20, 50) and the first end surface member (91) are pressed from both sides in the stacking direction (vertical direction) and are tightly attached to each other.

In the heat exchanger (10) of FIG. 10, the second end surface member (92) is fixed by adhesive to the one end side frame (81) or the other end side frame (82) and the first end surface member (91) attached thereto. Specifically, one second end surface member (92) is adhered to the outer rib (33) of the one end side frame (81) and the first end surface member (91), and covers the head of the bolt (97). The other second end surface member (92) is adhered to the outer rib (33) of the other end side frame (82) and the first end surface member (91), and covers the nut (98).

--Second Modification of the Embodiment--
In the heat exchanger (10) of this embodiment, the second elements (50) may be disposed at each of one end and the other end in the stacking direction of the elements (20, 50) (in other words, the up-down direction of the heat exchanger (10)). In the heat exchanger (10) of this modification, the number of second elements (50) is two more than the number of first elements (20).

In the heat exchanger (10) of this modified example, the second frame (55) of the uppermost second element (50) constitutes the one-end frame (81). In the heat exchanger (10) of this modified example, the second frame (55) constituting the other-end frame (82) is disposed below the lowermost second element (50). The orientation of the convex rib portion (64) in the other-end frame (82) is opposite to the orientation of the convex rib portion (64) in the one-end frame (81).

In the heat exchanger (10) of this modified example, the upper surface of the one end frame (81) is covered by the first end surface member (91) and the second end surface member (92), and the lower surface of the other end frame (82) is covered by the first end surface member (91) and the second end surface member (92). In the heat exchanger (10) of this modified example, the same number of first flow paths (21) and second flow paths (51) are formed.

--Third Modification of the Embodiment--
In the heat exchanger (10) of the above embodiment, the fixing member (95) is not limited to the one including the bolt (97), the nut (98), and the collar (96). For example, the fixing member (95) may include the bolt (97) and the nut (98) but may not include the collar (96). Furthermore, the fixing member (95) may be a rivet.

--Fourth Modification of the Embodiment--
The heat exchanger (10) of the above embodiment may be a sensible heat exchanger that exchanges only sensible heat between the supply air and the exhaust air. In this case, the partition sheet (15) of the heat exchanger (10) is made of a material having low moisture permeability or no moisture permeability at all (e.g., a resin film or a thin metal plate).

--Fifth Modification of the Embodiment--
The shape of the heat exchanger (10) in the above embodiment is not limited to an octagonal prism, and may be, for example, a hexagonal prism or a quadrangular prism.

Although the embodiments and modifications have been described above, it will be understood that various modifications of form and details are possible without departing from the spirit and scope of the claims. Furthermore, the elements of the above embodiments, modifications, and other embodiments may be combined or substituted as appropriate. Furthermore, the descriptions "first," "second," "third," etc. in the specification and claims are used to distinguish the words to which these descriptions are attached, and do not limit the number or order of the words.

As described above, the present disclosure is useful for heat exchangers and ventilation devices.

10 Heat exchanger
15 Partition sheet (partition material)
21 First flow path
25 First frame (spacing member)
30 Frame section
34 Convex stripe
35 Concave section
51 Second flow path
55 Second frame (spacing member)
60 Frame
64 Convex strip
65 Concave section
81 One end frame (one end spacing member)
82 Other end frame (other end spacing member)
91 First end surface member
92 Second end surface member
95 Fixing member
100 Ventilation Equipment

Claims (8)

A plurality of flat sheet-like partition members (15);
a plurality of spacing maintaining members (25, 55) that are alternately stacked with the partition members (15) to maintain a spacing between adjacent partition members (15),
A heat exchanger (10) in which first flow paths (21) and second flow paths (51) are alternately formed with the partition member (15) interposed therebetween,
The spacing member (25, 55) has a frame portion (30, 60) that fits along the periphery of the partition member (15),
The frame portion (30, 60) has a convex rib portion (34, 64) formed on one surface in the stacking direction of the partition member (15) and the spacing member (25, 55) and extending in the extension direction of the frame portion (30, 60), and a concave rib portion (35, 65) formed on the other surface and extending in the extension direction of the frame portion (30, 60),
The convex rib portion (34, 64) of one of the adjacent spacer members (25, 55) fits into the concave rib portion (35, 65) of the other spacer member (25, 55),
a first end surface member (91) that covers an inner region of the convex rib portion (34, 64) of the spacing member (25, 55) located at an end in a stacking direction of the partition member (15) and the spacing member (25, 55) and comes into contact with an inner portion of the convex rib portion (34, 64) of the frame portion (30, 60);
The plurality of spacing members (25, 55) include a one-end spacing member (81) located at one end in a stacking direction of the partition member (15) and the spacing members (25, 55), and an other-end spacing member (82) located at the other end in the stacking direction,
the one-end spacing member (81) is disposed in such a position that the orientation of the protruding strip portion (34, 64) is the same as that of the spacing members (25, 55) other than the other-end spacing member (82),
The other-end spacing member (82) is disposed in such a position that the orientation of the protruding strips (34, 64) is opposite to that of the one-end spacing member (81),
The heat exchanger comprises the first end surface member (91) attached to each of the one end spacer (81) and the other end spacer (82). 2. The heat exchanger (10) according to claim 1 ,
A heat exchanger comprising: a second end surface member (92) that covers the first end surface member (91) and the convex rib portion (34, 64) of the spacing member (25, 55) to which the first end surface member (91) is attached, and that contacts the protruding end surface of the convex rib portion (34, 64). A plurality of flat sheet-like partition members (15);
a plurality of spacing maintaining members (25, 55) that are alternately stacked with the partition members (15) to maintain a spacing between adjacent partition members (15),
A heat exchanger (10) in which first flow paths (21) and second flow paths (51) are alternately formed with the partition member (15) interposed therebetween,
The spacing member (25, 55) has a frame portion (30, 60) that fits along the periphery of the partition member (15),
The frame portion (30, 60) has a convex rib portion (34, 64) formed on one surface in the stacking direction of the partition member (15) and the spacing member (25, 55) and extending in the extension direction of the frame portion (30, 60), and a concave rib portion (35, 65) formed on the other surface and extending in the extension direction of the frame portion (30, 60),
The convex rib portion (34, 64) of one of the adjacent spacer members (25, 55) fits into the concave rib portion (35, 65) of the other spacer member (25, 55),
a first end surface member (91) covering an inner region of the protruding rib portion (34, 64) of the spacing member (25, 55) located at an end in the stacking direction of the partition member (15) and the spacing member (25, 55) and in contact with an inner portion of the protruding rib portion (34, 64) of the frame portion (30, 60);
a second end surface member (92) that covers the first end surface member (91) and the convex rib portion (34, 64) of the spacing member (25, 55) to which the first end surface member (91) is attached and that contacts the protruding end surface of the convex rib portion (34, 64). A heat exchanger (10) according to any one of claims 1 to 3 ,
A heat exchanger in which the surface of the first end surface member (91) facing the spacing member (25, 55) is a flat surface. A heat exchanger (10) according to claim 2 or 3 ,
The first end surface member (91) and the second end surface member (92) are each a flat plate-shaped member of the heat exchanger. A heat exchanger (10) according to claim 2, 3 or 5,
A heat exchanger comprising a fixing member (95) that is arranged to penetrate all of the stacked partition members (15) and spacing retaining members (25, 55), the first end surface member (91), and the second end surface member (92), and that fixes the partition members (15), the spacing retaining members (25, 55), the first end surface member (91), and the second end surface member (92). A heat exchanger (10) according to any one of claims 1 to 5,
A heat exchanger comprising a fixing member (95) that is arranged to penetrate all of the stacked partition members (15) and spacing members (25, 55) and the first end surface member (91), and that fixes the partition members (15), the spacing members (25, 55), and the first end surface member (91). A heat exchanger (10) according to any one of claims 1 to 7 ,
The ventilation system performs heat exchange in the heat exchanger (10) between supply air supplied from the outside of the room to the inside of the room and exhaust air discharged from the inside of the room to the outside of the room.