JP2020183842A - Ventilation device - Google Patents

Abstract

To provide a ventilation device for enabling the continuation of heat exchange operation when dew condensation or freezing occurs, without increasing the size.SOLUTION: A ventilation device (10) includes an air supply flow path (16) for supplying outdoor air into an indoor side, an exhaust flow path (17) for exhausting indoor air to an outdoor side, a total heat exchange element (40) having a first flow path (46) and a second flow path (47), and changeover mechanisms (50, 60) for changing over between a first state and a second state. In the first state, the first flow path (46) and the second flow path (47) of the total heat exchange element (40) are communicated with the air supply flow path (16) and the exhaust flow path (17), respectively. In the second state, the second flow path (47) and the first flow path (46) of the total heat exchange element (40) are communicated with the air supply flow path (16) and the exhaust flow path (17), respectively.SELECTED DRAWING: Figure 2

Description

The present disclosure relates to a ventilation system.

Conventionally, a ventilation device including a plurality of heat exchangers that exchange heat between an exhaust flow and a supply air flow has been known (for example, Patent Document 1). The ventilation system of the same document continuously switches the heat exchange air operation at the time of freezing and the defrost operation in a plurality of heat exchangers, so that the heat exchange air operation of the main body is continuously performed even if it is operated in winter in a cold region. can do.

Japanese Unexamined Patent Publication No. 2010-96384

However, although the ventilation device of Patent Document 1 can continue the heat exchange air operation even if dew condensation or freezing occurs, the size of the entire device becomes large because it includes a plurality of heat exchangers.

An object of the present disclosure is to enable the heat exchange air operation to be continued even if dew condensation or freezing occurs without increasing the size of the ventilation device.

The first aspect of the present disclosure is directed to a ventilator (10). The ventilation device (10) includes an air supply flow path (16) for supplying outdoor air into the room, an exhaust flow path (17) for exhausting indoor air to the outside, and a first flow path (46) and a second flow path. The total heat exchange element (40) having (47) and the first flow path (46) of the total heat exchange element (40) are in the air supply flow path (16), and the second flow path (47) is in the air supply flow path (16). The first state communicating with the exhaust flow path (17) and the second flow path (47) of the total heat exchange element (40) are connected to the air supply flow path (16) and the first flow path (46). ) Is provided with a switching mechanism (50, 60) for switching between the second state and the exhaust flow path (17).

In the first aspect, when dew condensation or freezing occurs in the first flow path (46) or the second flow path (47), the switching mechanism (50, 60) causes the first state and the first state of the ventilation device (10). By switching between the two states, the condensed water can be evaporated or the ice can be thawed. In order to realize this function, it is not necessary to provide a plurality of total heat exchange elements (40). Therefore, the heat exchange air operation can be continued even if dew condensation or freezing occurs without increasing the size of the ventilation device (10).

In the second aspect of the present disclosure, in the first aspect, the switching mechanism (50,60) has the inlet portion of the first flow path (46) in the first state, and the entrance portion of the first flow path (46) in the second state. It is characterized in that the first state and the second state are switched so as to be the outlet portion of the first flow path (46).

In the second aspect, when dew condensation water is generated at the inlet portion of the first flow path (46) in the first state, the inlet portion is used as the outlet portion of the first flow path (46) in the second state. Therefore, the condensed water can be efficiently evaporated.

In the third aspect of the present disclosure, in the first or second aspect, in the switching mechanism (50,60), the inlet portion of the second flow path (47) in the first state is the second. It is characterized in that the first state and the second state are switched so as to be the outlet portion of the second flow path (47) in the state.

In the third aspect, when dew condensation water or ice is generated at the inlet of the second flow path (47) in the first state, the inlet is used as the outlet of the second flow path (47) in the second state. By doing so, the condensed water or ice can be efficiently evaporated or thawed.

A fourth aspect of the present disclosure is that in any one of the first to third aspects, the switching mechanism (50,60) rotates the total heat exchange element (40) to cause the first aspect. It is a rotation mechanism (50) that switches between a state and the second state.

In the fourth aspect, the air supply flow path (16) and the exhaust flow path (17) can be used as they are in both the first state and the second state. Therefore, the ventilation device (10) can be miniaturized.

A fifth aspect of the present disclosure is, in any one of the first to third aspects, communicating with the first flow path (46) of the total heat exchange element (40) and in the first state. The first air supply / exhaust flow path (18) that constitutes the air supply flow path (16) and constitutes the exhaust flow path (17) in the second state, and the second flow of the total heat exchange element (40). A second air supply / exhaust flow path (19) communicating with the road (47), forming the exhaust flow path (17) in the second state, and forming the air supply flow path (16) in the second state. The switching mechanism (50,60) includes a plurality of dampers (61 to 68) provided at the inlet and outlet of the first air supply / exhaust flow path (18) and the second air supply / exhaust flow path (19). It is a damper mechanism (60) that switches between the first state and the second state by opening and closing the dampers (61 to 68).

In the fifth aspect, in the first state, indoor air is discharged to the outside of the room through the first air supply / exhaust flow path (18) and the first flow path (46) of the total heat exchange element (40). Outdoor air is supplied into the room through the second air supply / exhaust flow path (19) and the second flow path (47) of the total heat exchange element (40). On the other hand, in the second state, the indoor air is discharged to the outside of the room through the second air supply / exhaust flow path (19) and the second flow path (47) of the total heat exchange element (40), and the first air supply / exhaust is performed. Outdoor air is supplied into the room through the flow path (18) and the first flow path (46) of the total heat exchange element (40). In the fifth aspect, a damper (61 to 68) having an excellent sealing function is used to switch between the first state and the second state. Therefore, air leakage between the first air supply / exhaust flow path (18) and the second air supply / exhaust flow path (19) can be suppressed.

A sixth aspect of the present disclosure is that in any one of the first to fifth aspects, the total heat exchange element (40) is the first flow path (46) and the second flow path (47). ) Is provided, and the partition plate (41) includes a base material (42) having a first main surface (42a) and a second main surface (42b), and the base material (42). It is characterized by having a moisture permeable film (43) provided on the first main surface (42a) side of the above.

Here, as a general material for the partition plate, paper impregnated with a hygroscopic agent such as lithium chloride or calcium chloride is used, but in that case, dripping may occur due to excessive hygroscopicity. In the sixth aspect, since the moisture permeable membrane (43) is provided on the partition plate (41), the above-mentioned problems can be suppressed.

In the seventh aspect of the present disclosure, in the sixth aspect, the switching mechanism (50,60) has the first main surface (42a) of the base material (42) and the air supply flow path (16). It is characterized in that the first state and the second state are switched so that the water vapor pressure at the inlet of the flow path is arranged on the lower side of the exhaust flow path (17).

In the seventh aspect, the first main surface (42a) of the base material (42) provided with the moisture permeable membrane (43) is the flow path inlet of the air supply flow path (16) and the exhaust flow path (17). The amount of water passing through the partition plate (41) (hereinafter, also referred to as the amount of moisture permeation movement) can be increased as compared with the case where the water vapor pressure is higher.

FIG. 1 is a schematic configuration diagram of the ventilation device of the first embodiment. FIG. 2 is a diagram for explaining a switching operation of the ventilation device of the first embodiment when the outdoor air is hot and humid. FIG. 3 is a diagram for explaining a switching operation of the ventilation device of the first embodiment when the outdoor air is low temperature and low humidity. FIG. 4 is a schematic perspective view of the total heat exchange element. FIG. 5 is a cross-sectional view of a main part of the total heat exchange element. FIG. 6 is a schematic configuration diagram of the ventilation device of the second embodiment. FIG. 7 is a diagram for explaining a switching operation of the ventilation device of the second embodiment when the outdoor air is hot and humid. FIG. 8 is a diagram for explaining a switching operation of the ventilation device of the second embodiment when the outdoor air is low temperature and low humidity. FIG. 9 is a cross-sectional view of a main part of the total heat exchange element of the other embodiment.

<< Embodiment 1 >>
The first embodiment will be described. The ventilation device (10) of the present embodiment is a heat exchange type ventilation device that ventilates while exchanging sensible heat and moisture (latent heat) between indoor air and outdoor air.

As shown in FIG. 1, the ventilator (10) includes a casing (11) that houses the total heat exchange element (40). The casing (11) is provided with an outside air suction port (12), an air supply port (13), an inside air suction port (14), and an exhaust port (15). An air supply flow path (16) and an exhaust flow path (17) are formed in the internal space of the casing (11). An outside air suction port (12) is connected to one end of the air supply flow path (16). An air supply port (13) is connected to the other end of the air supply flow path (16). An inside air suction port (14) is connected to one end of the exhaust flow path (17). An exhaust port (15) is connected to the other end of the exhaust flow path (17).

The total heat exchange element (40) is arranged so as to cross the air supply flow path (16) and the exhaust flow path (17). In the total heat exchange element (40), the first flow path (46) described later has a number of stations with one of the air supply flow path (16) and the exhaust flow path (17), and the second flow path (47) described later has. It is installed in the casing (11) so as to communicate with the other of the air supply flow path (16) and the exhaust flow path (17). Details of the total heat exchange element (40) will be described later.

The ventilator (10) further comprises an air supply fan (26) and an exhaust fan (27). The air supply fan (26) is arranged on the downstream side (in other words, the air supply port (13) side) of the total heat exchange element (40) in the air supply flow path (16). The exhaust fan (27) is arranged on the downstream side (in other words, the exhaust port (15) side) of the total heat exchange element (40) in the exhaust flow path (17).

In the ventilation device (10), the outdoor air flows in the air supply flow path (16) toward the room, and the indoor air flows in the exhaust flow path (17) toward the outside. The outdoor air flowing through the air supply flow path (16) and the indoor air flowing through the exhaust flow path (17) exchange sensible heat and moisture (latent heat) in the total heat exchange element (40).

The ventilator (10) further comprises a rotating mechanism (50) that rotates the total heat exchange element (40). The rotation mechanism (50) includes an electric motor fixed to the casing (11) and applying torque to the total heat exchange element (40), and a stopper (not shown) that regulates the rotation angle range of the total heat exchange element (40). It is composed of, but is not limited to. The rotation mechanism (50) rotates the total heat exchange element (40) around the rotation axis extending in the direction orthogonal to the paper surface of FIG. 1, and as shown in FIG. 3 or 4, the first ventilation device (10). Switch between the state and the second state. The rotation mechanism (50) constitutes a switching mechanism.

As shown in FIGS. 4 and 5, the total heat exchange element (40) is a orthogonal flow type heat exchanger in which a plurality of first flow paths (46) and a plurality of second flow paths (47) are formed. .. The total heat exchange element (40) is formed into a square columnar shape as a whole by alternately stacking a plurality of partition plates (41) and spacing members (44). In the total heat exchange element (40), the distance between adjacent partition plates (41) is kept substantially constant by the distance holding member (44).

The partition plate (41) is a flat sheet-like member formed in a substantially square shape in a plan view. The partition plate (41) has a porous base material (42) and a moisture permeable membrane (43). The thickness of the partition plate (41) is 30 μm or less, but is not limited to this.

The porous base material (42) is a plate-shaped member having a first main surface (42a) and a second main surface (42b). The material of the porous base material (42) is, for example, a non-woven fabric such as resin, metal, glass or pulp, or a film such as resin or metal. The thickness of the porous substrate (42) is several tens of μm, but the thickness is not limited to this. The porous substrate (42) is permeable to moisture. The porous substrate (42) constitutes the substrate.

The moisture permeable membrane (43) is a sheet-like member provided on the first main surface (42a) of the porous base material (42). The moisture permeable membrane (43) is not provided on the second main surface (42b) of the porous substrate (42). The material of the moisture permeable membrane (43) is, for example, a polymer material containing a hydrophilic group and a hydrophobic group (for example, polyurethane). The thickness of the moisture permeable membrane (43) is several μm or less, but is not limited to this. The moisture permeable membrane (43) is permeable to moisture.

The interval holding member (44) is a corrugated plate-shaped member formed in a substantially square shape in a plan view. The space-holding member (44) holds the space between the partition plates (41) arranged on both sides thereof. In FIG. 5, the interval holding member (44) is not shown.

In the total heat exchange element (40), the partition plate (41) and the spacing member (44) are laminated (in other words, in the central axis direction of the total heat exchange element (40)) with the first flow path (46). The second flow path (47) is alternately formed. The adjacent first flow path (46) and second flow path (47) are separated from each other by a partition plate (41).

In the total heat exchange element (40), the spacing members (44) adjacent to each other across the partition plate (41) are arranged in a posture in which the ridgeline directions of the respective waveforms are substantially orthogonal to each other. As a result, in the total heat exchange element (40), the first flow path (46) is opened on the pair of facing side surfaces of the total heat exchange element (40), and the second flow path (46) is opened on the remaining pair of facing side surfaces. 47) opens.

As shown in FIG. 5, in each partition plate (41), the first main surface (42a) provided with the moisture permeable membrane (43) is arranged toward the first flow path (46). In other words, in each partition plate (41), the second main surface (42b) to which the moisture permeable membrane (43) is not provided is arranged toward the second flow path (47). The partition plates (41) adjacent to each other with the first flow path (46) in between have their first main surfaces (42a) facing each other. The second main surfaces (42b) of the partition plates (41) adjacent to each other with the second flow path (47) facing each other face each other.

-Rotating mechanism switching operation-
The operation of switching between the first state and the second state by the rotation mechanism (50) in the ventilation device (10) will be described.

First, with reference to FIG. 2, a switching operation when the outdoor air is hot and humid, for example, in summer, will be described. In FIG. 2, the first-state ventilator (10) is shown above, and the second-state ventilator (10) is shown below.

In the first state, the first flow path (46) of the total heat exchange element (40) communicates with the air supply flow path (16), and the second flow path (47) of the total heat exchange element (40) is an exhaust flow. It communicates with the road (17). In the second state, the second flow path (47) of the total heat exchange element (40) communicates with the air supply flow path (16), and the first flow path (46) of the total heat exchange element (40) is an exhaust flow. It communicates with the road (17).

When the ventilation device (10) is operated in the first state when the outdoor air is hot and humid, dew condensation mainly occurs in the inlet region (hatched region in FIG. 2) of the first flow path (46). Water can be produced. This is because in this region, the outdoor air having a relatively high humidity and temperature is cooled by exchanging heat with the indoor air having a relatively low humidity and temperature.

The rotation mechanism (50) switches the ventilation device (10) from the first state to the second state by rotating the total heat exchange element (40) by 90 ° in the counterclockwise direction in FIG. As a result, the inlet portion of the first flow path (46) in the first state becomes the outlet portion of the first flow path (46) in the second state. The indoor air flowing through the outlet of the first flow path (46) in the second state exchanges heat with the hot and humid outdoor air, and the temperature rises. Therefore, in the region of the outlet portion of the first flow path (46) in the second state, the condensed water generated during the operation in the first state can be efficiently evaporated. The rotation mechanism (50) rotates the total heat exchange element (40) by 270 ° in the counterclockwise direction in FIG. 2, or rotates the total heat exchange element (40) by 90 ° in the clockwise direction in FIG. Alternatively, the ventilation device (10) may be switched from the first state to the second state by rotating the ventilation device (10) by 270 °.

After that, the rotation mechanism (50) switches the ventilation device (10) from the second state to the first state by rotating the total heat exchange element (40) by 90 ° in the counterclockwise direction in FIG. As a result, the inlet portion of the second flow path (47) in the second state becomes the outlet portion of the second flow path (47) in the first state. Therefore, as described above for the first flow path (46), the dew condensation water generated in the region of the inlet of the second flow path (47) during the operation in the second state is the first in the first state. It can evaporate efficiently in the area of the outlet of the two channels (47). The rotation mechanism (50) rotates the total heat exchange element (40) by 270 ° in the counterclockwise direction in FIG. 2, or rotates the total heat exchange element (40) by 90 ° in the clockwise direction in FIG. Alternatively, the ventilation device (10) may be switched from the second state to the first state by rotating the ventilation device (10) by 270 °.

Next, with reference to FIG. 3, a switching operation when the outdoor air is low temperature and low humidity, for example, in winter, will be described. In FIG. 3, the first-state ventilator (10) is shown above, and the second-state ventilator (10) is shown below.

When the ventilation device (10) is operated in the first state when the outdoor air is low temperature and low humidity, dew condensation mainly occurs in the inlet region (hatched region in FIG. 3) of the second flow path (47). Water or ice can form. This is because the indoor air having a relatively high humidity and temperature is cooled by exchanging heat with the outdoor air having a relatively low humidity and temperature in this region.

The rotation mechanism (50) switches the ventilation device (10) from the first state to the second state by rotating the total heat exchange element (40) by 90 ° in the clockwise direction in FIG. As a result, the inlet portion of the second flow path (47) in the first state becomes the outlet portion of the second flow path (47) in the second state. The outdoor air flowing through the outlet of the second flow path (47) in the second state exchanges heat with the indoor air having a high temperature, and the temperature rises. Therefore, in the region of the outlet portion of the second flow path (47) in the second state, the condensed water or ice generated during the operation in the first state can be efficiently evaporated or thawed. The rotation mechanism (50) rotates the total heat exchange element (40) by 270 ° in the clockwise direction in FIG. 3, or rotates the total heat exchange element (40) by 90 ° in the counterclockwise direction in FIG. Alternatively, the ventilation device (10) may be switched from the first state to the second state by rotating the ventilation device (10) by 270 °.

After that, the rotation mechanism (50) switches the ventilation device (10) from the second state to the first state by rotating the total heat exchange element (40) by 90 ° in the clockwise direction in FIG. As a result, the inlet portion of the first flow path (46) in the second state becomes the outlet portion of the first flow path (46) in the first state. Therefore, as described above for the second flow path (47), the condensed water or ice generated in the region of the inlet of the first flow path (46) during the operation in the second state is in the first state. Can efficiently evaporate or thaw in the region of the outlet of the first flow path (46) in. The rotation mechanism (50) rotates the total heat exchange element (40) by 270 ° in the clockwise direction in FIG. 3, or rotates the total heat exchange element (40) by 90 ° in the counterclockwise direction in FIG. Alternatively, the ventilation device (10) may be switched from the second state to the first state by rotating the ventilation device (10) by 270 °.

Regardless of the state of the outdoor air, the switching operation between the first state and the second state by the rotation mechanism (50) may be executed at any timing. For example, the rotation mechanism (50) may switch between the first state and the second state at predetermined time intervals, and may respond to a signal of a detecting means (not shown) for detecting the occurrence of condensed water. , The first state and the second state may be switched when a predetermined amount of dew condensation water is generated.

-Effect of Embodiment 1-
The ventilation device (10) of the present embodiment includes an air supply flow path (16) for supplying outdoor air into the room, an exhaust flow path (17) for exhausting indoor air to the outside, a first flow path (46), and the like. The total heat exchange element (40) having the second flow path (47) and the first flow path (46) of the total heat exchange element (40) are connected to the air supply flow path (16) and the second flow path. The first state in which (47) communicates with the exhaust flow path (17) and the second flow path (47) of the total heat exchange element (40) are connected to the air supply flow path (16). A switching mechanism (50, 60) for switching between the second state in which the flow path (46) communicates with the exhaust flow path (17) is provided. Therefore, when dew condensation or freezing occurs in the first flow path (46) or the second flow path (47), the switching mechanism (50, 60) switches between the first state and the second state of the ventilation device (10). By switching, the condensed water can be evaporated or the ice can be thawed. In order to realize this function, it is not necessary to provide a plurality of total heat exchange elements (40). Therefore, the heat exchange air operation can be continued even if dew condensation or freezing occurs without increasing the size of the ventilation device (10).

Further, in the ventilation device (10) of the present embodiment, the switching mechanism (50,60) has the inlet portion of the first flow path (46) in the first state, and the first flow in the second state. The first state and the second state are switched so as to be the exit portion of the road (46). Here, when the outdoor air is hot and humid (typically in summer in Japan), the indoor air flowing through the outlet of the first flow path (46) in the second state exchanges heat with the hot outdoor air. And the temperature is high. Therefore, in the region of the outlet portion of the first flow path (46) in the second state, the condensed water generated during the operation in the first state can be efficiently evaporated. In addition, the humidity due to the condensed water can be discharged to the outside, and the rise in the humidity inside the room can be suppressed.

Further, in the ventilation device (10) of the present embodiment, the switching mechanism (50,60) has the inlet portion of the second flow path (47) in the first state, and the second flow in the second state. The first state and the second state are switched so as to be the exit portion of the road (47). Here, when the outdoor air is low temperature and low humidity (typically in winter in Japan), the outdoor air flowing through the outlet of the second flow path (47) in the second state exchanges heat with the indoor air having a high temperature. And the temperature is getting higher. Therefore, in the region of the outlet portion of the second flow path (47) in the second state, the condensed water or ice generated during the operation in the first state can be efficiently evaporated or thawed. In addition, the humidity from the condensed water can be supplied to the room to humidify the indoor air.

Further, in the ventilation device (10) of the present embodiment, the switching mechanism (50,60) is a rotating mechanism that switches between the first state and the second state by rotating the total heat exchange element (40). (50). Therefore, the air supply flow path (16) and the exhaust flow path (17) can be used as they are in both the first state and the second state. Therefore, the ventilation device (10) can be miniaturized.

Further, the ventilation device (10) of the present embodiment includes a partition plate (41) in which the total heat exchange element (40) separates the first flow path (46) and the second flow path (47). The partition plate (41) has a porous base material (42) having a first main surface (42a) and a second main surface (42b), and the first main surface (42) of the porous base material (42). It has a moisture permeable membrane (43) provided on the 42a) side. Here, as a general material for the partition plate, paper impregnated with a hygroscopic agent such as lithium chloride or calcium chloride is used, but in that case, dripping may occur due to excessive hygroscopicity. In the present embodiment, since the moisture permeable membrane (43) is provided on the partition plate (41), the above-mentioned problems can be suppressed.

<< Embodiment 2 >>
The second embodiment will be described. The ventilation device (10) of the present embodiment is different from the first embodiment in that it includes a damper mechanism (60) instead of a rotation mechanism (50) as a switching mechanism. Hereinafter, the differences from the first embodiment will be mainly described.

As shown in FIG. 6, in the internal space of the casing (11), an outside air suction chamber (21), an air supply chamber (22), an inside air suction chamber (23), an exhaust chamber (24), and a first An air supply / exhaust flow path (18) and a second air supply / exhaust flow path (19) are formed. An air supply fan (26) is arranged in the air supply room (22). An exhaust fan (27) is arranged in the exhaust chamber (24).

The outside air suction chamber (21) and the exhaust chamber (24) are arranged on one end side (left end side in FIG. 6) in the casing (11). The outside air suction chamber (21) and the exhaust chamber (24) are separated from each other by a first partition wall (31). The inside air suction chamber (23) and the air supply chamber (22) are arranged on the other end side (right end side in FIG. 6) in the casing (11). The inside air suction chamber (23) and the air supply chamber (22) are separated from each other by a second partition wall (32). The outside air suction chamber (21) and the exhaust chamber (24) and the first and second air supply / exhaust flow paths (18, 19) are separated from each other by a third partition wall (33). The inside air suction chamber (23) and the air supply chamber (22) and the first and second air supply / exhaust flow paths (18, 19) are separated from each other by a fourth partition wall (34).

The total heat exchange element (40) is arranged so as to cross the first air supply / exhaust flow path (18) and the second air supply / exhaust flow path (19). In the total heat exchange element (40), the first flow path (46) communicates with the first supply / exhaust flow path (18), and the second flow path (47) communicates with the second supply / exhaust flow path (19). It is installed in the casing (11) so that it does.

The ventilator (10) includes a damper mechanism (60) that switches between a first state and a second state by opening and closing a plurality of dampers (61 to 68). The damper mechanism (60) has first to eighth dampers (61 to 68). The damper mechanism (60) constitutes a switching mechanism.

The first to fourth dampers (61 to 64) of the damper mechanism (60) are provided on the third partition wall (33). The first damper (61) is provided between the outside air suction chamber (21) and the first air supply / exhaust flow path (18). In other words, the first damper (61) is provided at the inlet of the first air supply / exhaust flow path (18) in the second state (FIG. 7 or 8). The second damper (62) is provided between the outside air suction chamber (21) and the second air supply / exhaust flow path (19). In other words, the second damper (62) is provided at the inlet of the second air supply / exhaust flow path (19) in the first state (FIG. 7 or 8). The third damper (63) is provided between the exhaust chamber (24) and the first air supply / exhaust flow path (18). In other words, the third damper (63) is provided at the outlet of the first air supply / exhaust flow path (18) in the first state. The fourth damper (64) is provided between the exhaust chamber (24) and the second air supply / exhaust flow path (19). In other words, the fourth damper (64) is provided at the outlet of the second air supply / exhaust flow path (19) in the second state.

The fifth to eighth dampers (65 to 68) of the damper mechanism (60) are provided on the fourth partition wall (34). The fifth damper (65) is provided between the inside air suction chamber (23) and the second air supply / exhaust flow path (19). In other words, the fifth damper (65) is provided at the inlet of the second air supply / exhaust flow path (19) in the second state. The sixth damper (66) is provided between the inside air suction chamber (23) and the first air supply / exhaust flow path (18). In other words, the sixth damper (66) is provided at the inlet of the first air supply / exhaust flow path (18) in the first state. The seventh damper (67) is provided between the air supply chamber (22) and the second air supply / exhaust flow path (19). In other words, the seventh damper (67) is provided at the outlet of the second air supply / exhaust flow path (19) in the first state. The eighth damper (68) is provided between the air supply chamber (22) and the first air supply / exhaust flow path (18). In other words, the eighth damper (68) is provided at the outlet of the first air supply / exhaust flow path (18) in the second state.

-Damper mechanism switching operation-
The operation of switching between the first state and the second state by the damper mechanism (60) in the ventilation device (10) will be described.

First, with reference to FIG. 7, a switching operation when the outdoor air is hot and humid, for example, in summer, will be described. In FIG. 7, the first state ventilator (10) is shown on the left, and the second state ventilator (10) is shown on the right. In FIG. 7, open dampers (61 to 68) are shown in white, and closed dampers (61 to 68) are shown in black.

In the first state, the damper mechanism (60) closes the first damper (61), the fourth damper (64), the fifth damper (65), and the eighth damper (68), while the second damper (62). , 3rd damper (63), 6th damper (66), and 7th damper (67) are opened. As a result, in the first state, the first air supply / exhaust flow path (18) constitutes the air supply flow path (16), and the second air supply / exhaust flow path (19) constitutes the exhaust flow path (17).

In the second state, the damper mechanism (60) opens the first damper (61), the fourth damper (64), the fifth damper (65), and the eighth damper (68), while the second damper (62). , 3rd damper (63), 6th damper (66), and 7th damper (67) are closed. As a result, in the second state, the first air supply / exhaust flow path (18) constitutes the exhaust flow path (17), and the second air supply / exhaust flow path (19) constitutes the air supply flow path (16).

When the ventilation device (10) is operated in the first state when the outdoor air is hot and humid, dew condensation mainly occurs in the inlet region (hatched region in FIG. 7) of the first flow path (46). Water can be produced. This is because in this region, the outdoor air having a relatively high humidity and temperature is cooled by exchanging heat with the indoor air having a relatively low humidity and temperature.

The damper mechanism (60) switches the ventilator (10) from the first state to the second state. As a result, the inlet portion of the first flow path (46) in the first state becomes the outlet portion of the first flow path (46) in the second state. The indoor air flowing through the outlet of the first flow path (46) in the second state exchanges heat with the hot and humid outdoor air, and the temperature rises. Therefore, in the region of the outlet portion of the first flow path (46) in the second state, the condensed water generated during the operation in the first state can be efficiently evaporated. In addition, the humidity due to the condensed water is discharged to the outside, and the rise in the humidity inside the room is suppressed.

After that, the damper mechanism (60) switches the ventilation device (10) from the second state to the first state. As a result, the inlet portion of the second flow path (47) in the second state becomes the outlet portion of the second flow path (47) in the first state. Therefore, as described above for the first flow path (46), the dew condensation water generated in the region of the inlet of the second flow path (47) during the operation in the second state is the first in the first state. It can evaporate efficiently in the area of the outlet of the two channels (47).

Next, with reference to FIG. 8, a switching operation when the outdoor air is low temperature and low humidity, for example, in winter, will be described. In FIG. 8, the first state ventilator (10) is shown on the left, and the second state ventilator (10) is shown on the right. In FIG. 8, open dampers (61 to 68) are shown in white, and closed dampers (61 to 68) are shown in black.

When the ventilation device (10) is operated in the first state when the outdoor air is low temperature and low humidity, dew condensation mainly occurs in the inlet region (hatched region in FIG. 8) of the second flow path (47). Water or ice can form. This is because the indoor air having a relatively high humidity and temperature is cooled by exchanging heat with the outdoor air having a relatively low humidity and temperature in this region.

The damper mechanism (60) switches the ventilator (10) from the first state to the second state. As a result, the inlet portion of the second flow path (47) in the first state becomes the outlet portion of the second flow path (47) in the second state. The outdoor air flowing through the outlet of the second flow path (47) in the second state exchanges heat with the indoor air having a high temperature, and the temperature rises. Therefore, in the region of the outlet portion of the second flow path (47) in the second state, the condensed water or ice generated during the operation in the first state can be efficiently evaporated or thawed. In addition, the humidity from the condensed water is supplied to the room, and the room air is humidified.

After that, the damper mechanism (60) switches the ventilation device (10) from the second state to the first state. As a result, the inlet portion of the first flow path (46) in the second state becomes the outlet portion of the first flow path (46) in the first state. Therefore, as described above for the second flow path (47), the condensed water or ice generated in the region of the inlet of the first flow path (46) during the operation in the second state is in the first state. Can efficiently evaporate or thaw in the region of the outlet of the first flow path (46) in.

Regardless of the state of the outdoor air, the operation of switching between the first state and the second state by the damper mechanism (60) may be executed at any timing. For example, the damper mechanism (60) may switch between the first state and the second state at predetermined time intervals, or responds to a signal of a detecting means (not shown) for detecting the occurrence of condensed water. , The first state and the second state may be switched when a predetermined amount of dew condensation water is generated.

-Effect of Embodiment 2-
The ventilation device (10) of the present embodiment also has the same effect as that of the first embodiment.

Further, the ventilation device (10) of the present embodiment communicates with the first flow path (46) of the total heat exchange element (40) to form the air supply flow path (16) in the first state. In the second state, the first air supply / exhaust flow path (18) constituting the exhaust flow path (17) and the second flow path (47) of the total heat exchange element (40) are communicated with each other to form the second flow path (47). The exhaust flow path (17) is configured in the state, and the second supply / exhaust flow path (19) that constitutes the air supply flow path (16) in the second state is provided, and the switching mechanism (50,60) is provided. A plurality of dampers (61 to 68) provided at the inlet and outlet of the first air supply / exhaust flow path (18) and the second air supply / exhaust flow path (19), and the dampers (61 to 68) are provided. It is a damper mechanism (60) that switches between the first state and the second state by opening and closing. Therefore, in the first state, the indoor air is discharged to the outside of the room through the first air supply / exhaust flow path (18) and the first flow path (46) of the total heat exchange element (40), and the second air supply / exhaust flow path is provided. Outdoor air is supplied into the room through the flow path (19) and the second flow path (47) of the total heat exchange element (40). On the other hand, in the second state, the indoor air is discharged to the outside of the room through the second air supply / exhaust flow path (19) and the second flow path (47) of the total heat exchange element (40), and the first air supply / exhaust is performed. Outdoor air is supplied into the room through the flow path (18) and the first flow path (46) of the total heat exchange element (40). In this embodiment, dampers (61 to 68) having an excellent sealing function are used to switch between the first state and the second state. Therefore, air leakage between the first air supply / exhaust flow path (18) and the second air supply / exhaust flow path (19) can be suppressed.

<< Other Embodiments >>
The above embodiment may have the following configuration.

-First modification-
For example, in the switching mechanism (50,60), the first main surface (42a) of the porous base material (42) is a flow path of the air supply flow path (16) and the exhaust flow path (17). The first state and the second state may be switched so that the water vapor pressure at the inlet is arranged on the lower side. In this case, in the ventilator (10) of each embodiment, the rotating mechanism (50) or damper mechanism (60) provides the ventilator (10) when the relative humidity of the outdoor air is lower than the relative humidity of the indoor air. While switching to the first state, the ventilator (10) is switched to the second state when the relative humidity of the outdoor air is higher than the relative humidity of the indoor air.

In this modification, the first main surface (42a) of the porous base material (42) provided with the moisture permeable membrane (43) is the flow path inlet of the air supply flow path (16) and the exhaust flow path (17). It is possible to increase the amount of moisture permeation movement as compared with the case where the water vapor pressure is higher. In other words, the amount of moisture permeation movement in the partition plate (41) provided with the moisture permeable membrane (43) can be maximized, and the partition plate (41) can be effectively utilized. Here, as a result of diligent research, the inventor of the present application considers that the moisture permeation resistance of the porous substrate (42) becomes smaller than the moisture permeation resistance of the moisture permeable film (43) depending on the relative humidity of the ambient environment. , It has been found that there can be both cases where the moisture permeation resistance of the moisture permeable film (43) is smaller than the moisture permeation resistance of the porous substrate (42). Furthermore, as a result of repeated diligent research, the inventor of the present application has made a case where the moisture permeable film (43) is provided on the first main surface (42a) side of the porous base material (42), especially when the porous base material is provided. Under relative humidity conditions where the moisture permeation resistance of (42) is smaller than the moisture permeation resistance of the moisture permeable film (43), the first main surface of the porous substrate (42) ( If 42a) is placed and the second main surface (42b) of the porous base material (42) is placed in a space where the water vapor pressure is relatively high and the partition plate (41) is used, the arrangement is reversed. It was found that the amount of moisture permeation was increased compared to using the same partition plate (41). This variant is an application of this finding.

-Second modification-
For example, the total heat exchange element (40) may be any type other than the orthogonal flow type, for example, a countercurrent type total heat exchange element.

-Third variant-
For example, as shown in FIG. 9, a moisture permeable membrane (43) may be provided inside the porous base material (42). Here, the moisture permeable membrane (43) is provided on the first main surface (42a) side of the porous base material (42). Specifically, the moisture permeable membrane (43) is an intermediate surface (one-dot chain line in FIG. 9) located between the first main surface (42a) and the second main surface (42b) in the porous base material (42). It is provided closer to the first main surface (42a) than (indicated by).

Although the embodiments and modifications have been described above, it will be understood that various modifications of the forms and details are possible without departing from the purpose and scope of the claims. In addition, the above embodiments and modifications may be appropriately combined or replaced as long as they do not impair the functions of the present disclosure.

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

10 Ventilator
16 Air supply flow path
17 Exhaust flow path
18 1st air supply / exhaust flow path
19 2nd air supply / exhaust flow path
40 Total heat exchange element
41 divider
42 Porous base material (base material)
42a 1st main surface
42b 2nd main surface
43 Moisture Permeable Membrane
46 1st channel
47 Second flow path
50 rotation mechanism (switching mechanism)
60 Damper mechanism (switching mechanism)
61-68 1st to 8th dampers

Claims (7)

An air supply channel (16) that supplies outdoor air into the room,
An exhaust flow path (17) that exhausts indoor air to the outside,
A total heat exchange element (40) having a first flow path (46) and a second flow path (47),
The first state in which the first flow path (46) of the total heat exchange element (40) communicates with the air supply flow path (16) and the second flow path (47) communicates with the exhaust flow path (17). The second flow path (47) of the total heat exchange element (40) communicates with the air supply flow path (16), and the first flow path (46) communicates with the exhaust flow path (17). A ventilation device characterized by having a switching mechanism (50, 60) for switching between two states. In claim 1,
In the switching mechanism (50, 60), the inlet portion of the first flow path (46) in the first state becomes the outlet portion of the first flow path (46) in the second state. A ventilation device characterized by switching between one state and the second state. In claim 1 or 2,
In the switching mechanism (50, 60), the inlet portion of the second flow path (47) in the first state becomes the outlet portion of the second flow path (47) in the second state. A ventilation device characterized by switching between one state and the second state. In any one of claims 1 to 3,
The switching mechanism (50, 60) is a ventilation device (50) that switches between the first state and the second state by rotating the total heat exchange element (40). In any one of claims 1 to 3,
It communicates with the first flow path (46) of the total heat exchange element (40), constitutes the air supply flow path (16) in the first state, and connects the exhaust flow path (17) in the second state. The first air supply / exhaust flow path (18) that composes,
The exhaust flow path (17) is configured in the second state by communicating with the second flow path (47) of the total heat exchange element (40), and the air supply flow path (16) is connected in the second state. It is equipped with a second air supply / exhaust flow path (19) that constitutes it.
The switching mechanism (50,60) has a plurality of dampers (61 to 68) provided at the inlet and outlet of the first air supply / exhaust flow path (18) and the second air supply / exhaust flow path (19). The ventilation device is a damper mechanism (60) that switches between the first state and the second state by opening and closing the dampers (61 to 68). In any one of claims 1 to 5,
The total heat exchange element (40) includes a partition plate (41) that separates the first flow path (46) and the second flow path (47).
The partition plate (41) is provided on a base material (42) having a first main surface (42a) and a second main surface (42b) and on the first main surface (42a) side of the base material (42). A ventilator characterized by having a moisture permeable membrane (43). In claim 6,
In the switching mechanism (50, 60), the first main surface (42a) of the base material (42) is the water vapor pressure at the inlet of the air supply flow path (16) and the exhaust flow path (17). A ventilation device characterized by switching between the first state and the second state so that is arranged on the lower side.

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