Patent Application
20240337409
The present disclosure relates to a heat exchanger, a ventilator, and a method for manufacturing the heat exchanger.
Japanese Unexamined Patent Publication No. H7-208891 discloses a heat exchanger configured to exchange heat between two different kinds of air. In this heat exchanger, an interval between partition plates stacked is maintained by separation plates. The partition plates and the separation plates are adhered to each other with an adhesive.
A first aspect of the present disclosure is directed to a heat exchanger including a plurality of flow pass elements. Each flow pass element includes a partition member that is a moisture permeable sheet shaped member, and a frame forming an air flow path by joining to the partition member. The heat exchanger is configured by stacking the plurality of flow pass elements. In each of the plurality of flow pass elements, the partition member is joined to the frame in direction contact.
Embodiments will be described below. A ventilator (100) of this embodiment includes a heat exchanger (10) and configured to supply air to and exhaust air from an indoor space.
As illustrated in
The air supply passage (121) has two ends respectively connected to the outdoor air inlet (111) and the air supply port (112). The exhaust passage (122) has two ends respectively connected to the indoor air inlet (113) and the exhaust port (114). In the ventilator (100), outdoor air flows through the air supply passage (121) toward the inside of the room, and room air flows through the exhaust passage (122) toward the outside of the room.
The heat exchanger (10) is located to intersect the air supply passage (121) and the exhaust passage (122). The heat exchanger (10) is disposed in the casing (110) such that the first passage (21) communicates with the air supply passage (121) and the second passage (51) communicates with the exhaust passage (122).
The ventilator (100) further includes an air supply fan (131) and an exhaust fan (132). The air supply fan (131) is disposed downstream of the heat exchanger (10) in the air supply passage (121). The exhaust fan (132) is disposed downstream of the heat exchanger (10) in the exhaust passage (122).
A heat exchanger (10) of this embodiment is a so-called total heat exchanger. In the ventilator (100), this heat exchanger (10) causes outdoor air (supply air) supplied into a room and room air (exhaust air) exhausted out of the room to exchange sensible heat and latent heat (moisture).
As illustrated in
The main heat exchange section (11) is located at the middle of the heat exchanger (10) in the right-to-left direction in
The heat exchanger (10) includes a plurality of first elements (20) and a plurality of second elements (50). The first elements (20) and the second elements (50) are flow path elements. The first elements (20) and the second elements (50) are alternately stacked in the heat exchanger (10). Each of the first elements (20) forms a first passage (21). The first passage (21) is an air flow path which allows supply air to flow therethrough. Each of the second elements (50) forms a second passage (51). The second passage (51) is an air flow path which allows exhaust air to flow therethrough. In the heat exchanger (10), the first passages (21) and the second passages (51) are alternately formed in the stacking direction of the first elements (20) and the second elements (50).
The heat exchanger (10) has a first inflow port (22a), a first outflow port (22b), a second inflow port (52a), and a second outflow port (52b) which are formed in side surfaces thereof (surfaces parallel to the stacking direction of the first elements (20) and the second elements (50)). The first inflow port (22a) and the first outflow port (22b) are formed in the first element (20) and communicate with the first passage (21). The second inflow port (52a) and the second outflow port (52b) are formed in the second element (50) and communicate with the second passage (51).
The first inflow port (22a), the first outflow port (22b), the second inflow port (52a), and the second outflow port (52b) are formed on different side surfaces of the heat exchanger (10). In one of the auxiliary heat exchange sections (12a) of the heat exchanger (10), the first inflow port (22a) is open on one side surface, and the second outflow port (52b) is open on a different side surface. In the other auxiliary heat exchange section (12b) of the heat exchanger (10), the first outflow port (22b) is open on one side surface, and the second inflow port (52a) is open on a different side surface.
The side surfaces of the heat exchanger (10) are formed by the outer peripheral surface of a stack of the first elements (20) and the second elements (50). The side surfaces of the heat exchanger (10) are substantially flat surfaces.
The first elements (20) and the second elements (50) constituting the heat exchanger (10) each have six notches (38, 68). In each of the elements (20, 50), the notches (38, 68) open on the outer peripheral surface of the element (20, 50).
The notches (38, 68) provided in one element (20, 50) correspond to the respective notches (38, 68) of each of the other elements (20, 50). In the heat exchanger (10), corresponding notches (38, 68) in the elements (20, 50) are aligned in a row in the stacking direction of the elements (20, 50).
The heat exchanger (10) of this embodiment is provided with seals (81) so as to fill notches (38, 68) aligned in a row. The seals (81) are formed by filling the notches (38, 68) aligned in a row with a filler such as a silicon sealing agent and solidifying the filler.
As illustrated in
In each of the auxiliary heat exchange sections (12a, 12b) of the heat exchanger (10), the supply air in the first passage (21) and the exhaust air in the second passage (51) flow in directions intersecting with each other. In the main heat exchange section (11) of the heat exchanger (10), the supply air in the first passage (21) and the exhaust air in the second passage (51) flow in opposite directions.
The heat exchanger (10) causes the supply air flowing through the first passage (21) and the exhaust air flowing through the second passage (51) to exchange sensible heat and latent heat (moisture). Of the supply air and the exhaust air in the heat exchanger (10), one with the higher temperature transfers heat to the other with the lower temperature. Further, of the supply air and the exhaust air in the heat exchanger (10), one with the higher humidity transfers moisture to the other with the lower humidity.
As illustrated in
Each of the first frame (25) and the second frame (55) is a grid-like member. In the following description, the upper surfaces of the first frame (25) and the second frame (55) in
The first element (20) includes the partition sheet (15) bonded to a back surface of the first frame (25). The partition sheet (15) covers substantially the entire back surface of the first frame (25). The second element (50) includes the partition sheet (15) bonded to a back surface of the second frame (55). The partition sheet (15) covers substantially the entire back surface of the second frame (55).
As illustrated in
The first frame (25) has a single middle area (26) and two end areas (27a, 27b). The middle area (26) is a horizontally oriented rectangular area, and is located at the middle in the right-to-left direction in
The first frame (25) includes a frame portion (30). The frame portion (30) is a portion extending along the outer periphery of the first frame (25) over the entire perimeter of the first frame (25). The frame portion (30) extends along the periphery of the partition sheet (15).
The frame portion (30) of the first frame (25) has two first communication openings (22). Each first communication opening (22) provided in each frame portion (30) allows the first passage (21) surrounded by the frame portion (30) to communicate with the outside of the frame portion (30). In the frame portion (30) illustrated in
As illustrated in
As illustrated in
The cross-sectional shape of the elongated recess (35) corresponds to the cross-sectional shape of a ridge (64), which will be described later, of the second frame (55). The ridge (64) of the second frame (55) fits into the elongated recess (35) of the first frame (25).
As illustrated in
The first frame (25) includes first inner ribs (40) and first holding ribs (41). The first inner ribs (40) and the first holding ribs (41) are provided in each end area (27a, 27b) of the first frame (25).
Each of the first inner ribs (40) is formed in a straight bar shape, and extends in a direction intersecting with the first communication opening (22). In this embodiment, the height of the first inner ribs (40) is substantially equal to the thickness of the first passage (21).
Each of the first holding ribs (41) is formed in a straight bar shape, and extends in a direction substantially orthogonal to the first inner ribs (40). Each of the first holding ribs (41) extends from one of an adjacent pair of the first inner ribs (40) to the other. Each of the first holding ribs (41) is less than half as thick as the first inner ribs (40).
The first frame (25) includes intra-first passage ribs (45) and first support ribs (46). The intra-first passage ribs (45) and the first support ribs (46) are provided in the middle area (26) of the first frame (25).
Each of the intra-first passage ribs (45) is formed in a straight bar shape, and extends in a direction parallel to the long side of the middle area (26). The height of the intra-first passage ribs (45) is substantially equal to the thickness of the first passage (21).
Each of the first support ribs (46) is formed in a straight bar shape, and extends in a direction substantially orthogonal to the intra-first passage ribs (45). Each of the first support ribs (46) is provided to extend from one of an adjacent pair of the intra-first passage ribs (45) to the other. The first support ribs (46) are integral with the intra-first passage ribs (45), and keep a space between an adjacent pair of the intra-first passage ribs (45). Each of the first support ribs (46) is less than half as thick as the intra-first passage ribs (45).
As illustrated in
As illustrated in
The second frame (55) has a single middle area (56) and two end areas (57a, 57b). The middle area (56) is a horizontally oriented rectangular area, and is located at the middle in the right-to-left direction in
The second frame (55) includes a frame portion (60). The frame portion (60) is a portion extending along the outer periphery of the second frame (55) over the entire perimeter of the second frame (55). The frame portion (60) extends along the periphery of the partition sheet (15).
The frame portion (60) of the second frame (55) has two second communication openings (52). Each second communication opening (52) provided in each frame portion (60) allows the second passage (51) surrounded by the frame portion (60) to communicate with the outside of the frame portion (60). In the frame portion (60) illustrated in
As illustrated in
As illustrated in
The cross-sectional shape of the elongated recess (65) corresponds to the cross-sectional shape of the ridge (34) of the first frame (25). The ridge (34) of the first frame (25) fits into the elongated recess (65) of the second frame (55).
As illustrated in
The second frame (55) includes second inner ribs (70) and second holding ribs (71). The second inner ribs (70) and the second holding ribs (71) are provided in each end area (57a, 57b) of the second frame (55).
Each of the second inner ribs (70) is formed in a straight bar shape, and extends in a direction intersecting with the second communication opening (52). In this embodiment, the height of the second inner ribs (70) is substantially equal to the thickness of the second passage (51).
Each of the second holding ribs (71) is formed in a straight bar shape, and extends in a direction substantially orthogonal to the second inner ribs (70). Each of the second holding ribs (71) is provided to extend from one of an adjacent pair of the second inner ribs (70) to the other. Each of the second holding ribs (71) is less than half as thick as the second inner ribs (70).
The second frame (55) includes intra-second passage ribs (75) and second support ribs (76). The intra-second passage ribs (75) and the second support ribs (76) are provided in the middle area (56) of the second frame (55).
Each of the intra-second passage ribs (75) is formed in a straight bar shape, and extends in a direction parallel to the long side of the middle area (56). The height of the intra-second passage ribs (75) is substantially equal to the thickness of the second passage (51).
Each of the second support ribs (76) is formed in a straight bar shape, and extends in a direction substantially orthogonal to the intra-second passage ribs (75). Each of the second support ribs (76) is provided to extend from one of an adjacent pair of the intra-second passage ribs (75) to the other. The second support ribs (76) are integral with the intra-second passage ribs (75), and keep a space between the adjacent pair of the intra-second passage ribs (75). Each of the second support ribs (76) is less than half as thick as the intra-second passage ribs (75).
As illustrated in
As illustrated in
The porous base (16) is a porous, sheet-like member made of polyolefin-based resin, for example. The porous base (16) may be non-woven fabric made of fibrous resin. The porous base (16) has a thickness of 10 μm, for example. Preferably, the porous base (16) is an element that serves as a support for the moisture permeable layer (17), and exhibits excellent moisture permeability.
The first surface (16a), i.e., one of the surfaces of the porous base (16), is subjected to hydrophilic treatment. Examples of the hydrophilic treatment include corona discharge treatment and plasma treatment. The hydrophilic treatment allows generation of a carboxy group, a hydroxy group, or a carbonyl group on the first surface (16a) of the porous base (16).
The moisture permeable layer (17) is a coating covering the entirety of the first surface (16a) of the porous base (16). The moisture permeable layer (17) is made of a polymer having moisture permeability. The polymer forming the moisture permeable layer (17) is a copolymer having a first constitutional unit and a second constitutional unit. The moisture permeable layer (17) has a thickness of 1 μm, for example. The thickness of the moisture permeable layer (17) is not particularly limited, and is preferably 0.05 μm to 1 μm, more preferably 0.1 μm to 0.5 μm. In a case where the thickness of the moisture permeable layer (17) is 0.05 μm or more, favorable film formability is exhibited, leading to improvement in gas barrier properties. In a case where the above-described thickness is 1 μm or less, more favorable moisture permeability is exhibited.
Examples of monomer forming the first constitutional unit may include 2-methacryloyloxyethyl phosphorylcholine. Examples of monomer forming the second constitutional unit may include (meth)acrylic acid alkyl ester having an alkyl group with a carbon number of 2 or more in an ester moiety, such as (meth)acrylic acid stearyl. In the copolymer forming the moisture permeable layer (17), the form of copolymer having the first constitutional unit and the second constitutional unit is not particularly limited, and the copolymer forming the moisture permeable layer (17) may be any of a block copolymer, an alternating copolymer, and a random copolymer.
A step of forming a moisture permeable layer (17) on a porous base (16) includes an applying step and a heating-drying step. The applying step is a step of applying a raw material liquid for forming a moisture permeable layer (17) to a first surface (16a) of the porous base (16). The heating-drying step is a step of heating a coating film formed in the applying step to evaporate the solvent.
The raw material liquid used in the applying step is a liquid obtained by diluting a stock solution with water. The stock solution is a mixture of a polymer forming the moisture permeable layer (17) and a solvent (ethanol in this embodiment). Thus, the raw material liquid of this embodiment is a liquid containing, as main components, a polymer forming a moisture permeable layer (17), and ethanol and water as solvents. The polymer forming the moisture permeable layer (17) is a first substance. Main components of the solvents composing the raw material liquid is ethanol and water. The solvent may contain a sub-component such as an additive. Ethanol, which is a main component of the solvent, is a second substance. The polymer, which is the first substance, is dissolved in ethanol, which is the second substance.
As mentioned above, in the applying step, the raw material liquid is applied to the first surface (16a) of the porous base (16). The first surface (16a) of the porous base (16) is subjected to a hydrophilic treatment in advance. Thus, the thickness of the coating formed on the first surface (16a) becomes uniform. The moisture permeable layer (17) with an uniform thickness is formed accordingly.
A method for manufacturing the heat exchanger (10) will be described below. As illustrated in
As illustrated in
The pretreatment step (201) is a first substep of causing a treatment liquid (250) to adhere to a joining surface (28, 58) of the frame (25, 55). In the pretreatment step (201), the treatment liquid (250) is sprayed or applied to the joining surface (28, 58) of the frame (25, 55).
The treatment liquid (250) contains ethanol and water as main components. The main components of the treatment liquid (250) include ethanol (second substance), which is a main component of the solvent of raw material liquid for forming a moisture permeable layer (17). The mixing ratio of ethanol and water in the treatment liquid (250) may be the same as or difference from the mixing ratio of ethanol and water in the solvent of the raw material liquid. The treatment liquid (250) may contain a sub-component such as an additive. The sub-component contained in the treatment liquid (250) may be the same as or different from the sub-component contained in the solvent of the raw material liquid.
The joining surface (28, 58) of the frame (25, 55) is apparently flat. However, the frame (25, 55) is manufactured by injection molding, and the joining surface (28, 58) is not finished. Thus, as illustrated in
In the pretreatment step (201), the technique of causing the treatment liquid (250) to be adhered to the joining surface (28, 58) of the frame (25, 55) can be any of various techniques. For example, the treatment liquid (250) is adhered to the joining surface (28, 58) of the frame (25, 55) by using an instrument such as a spray gun, a roll coater, or a curtain coater. For example, an operator may use an instrument such as a spatula, a brush, and a hand roller to adhere the treatment liquid (250) to the joining surface (28, 58) of the frame (25, 55).
The adhering step (202) is a second substep of joining the partition sheet (15) to the joining surface (28, 58) of the frame (25, 55).
As illustrated in
As mentioned above, a polymer forming the moisture permeable layer (17) is dissolved in ethanol, which is a main component of the treatment liquid (250). Thus, when the partition sheet (15) is placed over the joining surface (28, 58) of the frame (25, 55) to which the treatment liquid (250) has been adhered, a surface layer portion of an area of the moisture permeable layer (17) facing the joining surface (28, 58) comes into contact with ethanol contained in the treatment liquid (250). As a result, the polymer forming the moisture permeable layer (17) enters fine irregularities formed on the joining surface (28, 58).
The drying step (203) is a step of evaporating the treatment liquid (250). The drying step (203) is a step of keeping the frame (25, 55) over which the partition sheet (15) has been placed in the adhering step (202) at room temperature for a predetermined period of time. When the treatment liquid (250) evaporates, portion of the moisture permeable layer (17) which as been temporally dissolved in the adhering step (202) is solidified. As a result, as illustrated in
In the stacking step (210), a plurality of first elements (20) and a plurality of second elements (50) are provided, and are stacked alternately. When the first elements (20) and the second elements (50) are alternately stacked, the partition sheets (15) and the frames (25, 55) are alternately stacked. As a result, a plurality of first passages (21) and a plurality of second passages (51) into which the partition sheets (15) partition are formed.
The first elements (20) and the second elements (50) stacked are fixed to each other to form a stack. In the stack, the elements (20, 50) stacked are fixed to each other with bolts penetrating the elements (20, 50) in the stacking direction and nuts attached to the bolts. The bolts and nuts are not shown.
In the stack formed in the stacking step (210), corresponding notches (38, 68) provided in the frames (25, 55) of the elements (20, 50) are aligned in a row in the stacking direction of the elements (20, 50).
In the sealing step (211), an operation of filling the notches (38, 68) aligned in a row with a filler having fluidity is performed. The filler having fluidity may be a fluid having a relatively high viscosity such as a silicon sealing agent.
Next, in the sealing step (211), an operation of solidifying the filler with which the notches (38, 68) have been filled is performed. In this operation, the stack which has undergone the filling is heated for a predetermined period of time, or kept at room temperature for a predetermined period of time in order to vaporize a solvent component contained in the filler. As a result, the filler with which the notches (38, 68) are filled is solidified to form seals (81).
As illustrated in
As described above, in the element (20, 50) of this embodiment, the partition sheet (15) is joined directly to the frame (25, 55) without an adhesive intervened therebetween. In each element (20, 50), the moisture permeable layer (17) of the partition sheet (15) comes into direct contact with the frame (25, 55), whereas the porous base (16) of the partition sheet (15) does not come into contact with the frame (25, 55).
A joining strength of the partition sheet (15) to the frame (25, 55) is a joining strength at which the partition sheet (15) is not broken when the partition sheet (15) is peeled off from the frame (25, 55). The joining strength of the partition sheet (15) to the frame (25, 55) is lower than the breaking strength of the partition sheet (15).
The breaking strength P1 of the partition sheet (15) is a pressure which acts on the partition sheet (15) when it is broken in a test based on the testing method B for water resistance defined in Japanese Industrial Standard (JIS L 1092:2009).
The joining strength P2 of the partition sheet (15) to the frame (25, 55) is determined by a test using the element (20, 50) of this embodiment.
The test for determining the joining strength P2 will be described below with reference to
An area of the partition sheet (15) surrounded by the intra-first passage ribs (45) and the first support ribs (46) is defined as a target area (300). A force is applied to the center point C of the target area, and a force F when the partition sheet (15) is peeled off from the intra-first passage ribs (45) or the first support ribs (46) is measured. The joining strength P2 is calculated by dividing the force F by the area A of the target area (300) (P2=F/A).
In the element (20, 50) of this embodiment, the joining strength P2 of the partition sheet (15) to the frame (25, 55) is smaller than the breaking strength P1 of the partition sheet (15). The joining strength P2 of the partition sheet (15) to the frame (25, 55) is desirably 75% or less, more desirably 50% or less of the breaking strength P1 of the partition sheet (15).
When the partition sheet (15) is joined to the frame (25, 55) with an adhesive in the element (20, 50), the adhesive may spread beyond the joining portion between them. If the adhesive which has been spread beyond the joining portion between them covers the partition sheet (15), the adhesive hinders the movement of heat and moisture from one of the supply air or the exhaust air to the other.
On the other hand, in each element (20, 50) of this embodiment, the partition sheet (15) is joined to the frame (25, 55) in direct contact. Thus, the portion of the partition sheet (15) that is in contact with the air flowing through the air flow path (21, 51) is larger than that in the case where the partition sheet (15) is adhered to the frame (25, 55) with an adhesive, thereby improving the heat exchange performance of the heat exchanger (10).
In each element (20, 50) of this embodiment, the partition sheet (15) is joined to a flat joining surface (28, 58) formed on the frame (25, 55). Thus, adhesion of the partition sheet (15) to the frame (25, 55) becomes high, so that the joining strength of the partition sheet (15) to the frame (25, 55) becomes high.
In the element (20, 50) of this embodiment, the joining strength P2 of the partition sheet (15) to the frame (25, 55) is smaller than the breaking strength P1 of the partition sheet (15). Thus, the partition sheet (15) can be peeled off from the frame (25, 55) without breaking the partition sheet (15). As a result, the work of separating the partition sheet (15) and the frame (25, 55) from each other when the heat exchanger (10) is discarded is facilitated.
If the partition sheet (15) is bonded to an inappropriate position of the frame (25, 55) in the element assembling step (200), the partition sheet (15) can be once removed from the frame (25, 55), and the removed partition sheet (15) can be re-adhered to the frame (25, 55). As a result, it is possible to reduce materials discarded due to an operation error in the process of manufacturing the heat exchanger (10).
In the element assembling step (200) of the method for manufacturing the heat exchanger (10) of this embodiment, portion of the moisture permeable layer (17) forming the partition sheet (15), facing the frame (25, 55) is temporally dissolved, and then, the portion of the moisture permeable layer (17) which has been temporally dissolved is solidified, so that the partition sheet (15) is fixed to the frame (25, 55) without an adhesive intervened therebetween. Thus, according to this embodiment, the partition sheet (15) can be joined to the frame (25, 55) without an adhesive.
In the element assembling step (200) of the method for manufacturing the heat exchanger (10) of this embodiment, the moisture permeable layer (17) forming the partition sheet (15) is temporally dissolved by the treatment liquid (250) containing a second substance as a main component.
The ethanol is a main component of a solvent composing a raw material liquid used to form the moisture permeable layer (17). Thus, even when the moisture permeable layer (17) is temporally dissolved and then solidified to fix the partition sheet (15) to the frame (25, 55), the moisture permeable layer (17) is not deteriorated. Accordingly, the partition sheet (15) can be joined to the frame (25, 55) without deterioration of the moisture permeability of the partition sheet (15), thereby keeping the performance of the heat exchanger (10) from decreasing.
Here, the solvent which is a component of the commonly used adhesive contains a substance which gradually volatilizes over a long period of time. Thus, when the heat exchanger is attached to the ventilator, the solvent contained in the adhesive evaporates and flows into the room with the air, and the smell of the solvent may impair the comfort of the indoor space.
In contrast, ethanol, which is a main component of the treatment liquid (250) used in the element assembling step (200) of this embodiment is a highly volatile substance. Thus, ethanol remaining in the element (20, 50) assembled in the element assembling step (200) substantially completely evaporates in a relatively short time. Therefore, when the heat exchanger (10) is attached to the ventilator (100), ethanol is substantially not present in the heat exchanger (10), and the comfort of the indoor space is not impaired by the smell of ethanol.
In the element assembling step (200) of the method for manufacturing the heat exchanger (10) of this embodiment, the partition sheet (15) may be joined to the frame (25, 55) by insert molding.
In such a case, in the element assembling step (200), an element (20, 50) in which the partition sheet (15) is joined to the frame (25, 55) is manufactured by injecting molten resin into a mold for injection molding in which the partition sheet (15) is disposed in advance. Also in the element (20, 50) manufactured in the element assembling step (200) of this variation, as in the element (20, 50) shown in
In the element assembling step (200) of the method for manufacturing the heat exchanger (10) of this embodiment, the partition sheet (15) may be joined to the frame (25, 55) by thermal welding.
In such a case, in the element assembling step (200), the partition sheet (15) is kept at a predetermined temperature (e.g., 120° C.) for a predetermined time (e.g., 25 seconds) in a state of being in close contact with the joining surface (28, 58) of the frame (25, 55). As a result, portion of the moisture permeable layer (17) of the partition sheet (15) is temporally dissolved or softened, and the dissolved or softened portion of the moisture permeable layer (17) enters fine irregularities of the joining surface (28, 58). Then, when the partition sheet (15) is cooled to solidify the moisture permeable layer (17), the partition sheet (15) is fixed to the joining surface (28, 58) of the frame (25, 55).
Further, in the element assembling step (200) of this embodiment, the partition sheet (15) may be joined to the frame (25, 55) by welding other than the thermal welding. Examples of the welding other than the thermal welding include high-frequency welding, ultrasonic welding, and laser welding.
When the partition sheet (15) is joined to the frame (25, 55) by high-frequency welding, portion of the moisture permeable layer (17) of the partition sheet (15) is dissolved or softened by irradiation with high-frequency waves (electromagnetic waves) of about several tens of MHz.
When the partition sheet (15) is joined to the frame (25, 55) by ultrasonic welding, portion of the partition sheet (15) which comes into contact with the frame (25, 55) is irradiated with ultrasonic waves to dissolve or soften portion of the moisture permeable layer (17) of the partition sheet (15) by frictional heat generated.
When the partition sheet (15) is joined to the frame (25, 55) by laser welding, portion of the moisture permeable layer (17) of the partition sheet (15) is dissolved or softened by irradiation with laser.
The shape of the heat exchanger (10) of the above embodiment is not limited to an octagonal prism. The shape of the heat exchanger (10) may be, for example, a hexagonal prism or a quadrangular prism.
While the embodiments and variations thereof have been described above, it will be understood that various changes in form and details may be made without departing from the spirit and scope of the claims. The elements according to embodiments, the variations thereof, and the other embodiments may be combined and replaced with each other. In addition, the expressions of “first,” “second,” “third,” . . . , in the specification and claims are used to distinguish the terms to which these expressions are given, and do not limit the number and order of the terms.
As can be seen from the foregoing description, the present disclosure is useful for a heat exchanger, a ventilator, and a method for manufacturing the heat exchanger.
| Number | Date | Country | Kind |
|---|---|---|---|
| 2021-212114 | Dec 2021 | JP | national |
This is a continuation of Application No. PCT/JP2022/047887 filed on Dec. 26, 2022, which claims priority to Japanese Patent Application No. 2021-212114, filed on Dec. 27, 2021. The entire disclosures of these applications are incorporated by reference herein.
| Number | Date | Country | |
|---|---|---|---|
| Parent | PCT/JP2022/047887 | Dec 2022 | WO |
| Child | 18748866 | US |
