JP4872428B2 - Ventilation equipment - Google Patents

Description

  The present invention relates to a ventilator including a heat exchange element for exchanging heat between outdoor air supplied to a room and indoor air discharged to the room.

  Conventionally, as disclosed in, for example, Patent Document 1 and Patent Document 2, a ventilator including a heat exchange element is known. This ventilation device performs supply of air into the room and exhaust from the room. At that time, outdoor air sent to the room and indoor air discharged to the outside pass through the heat exchange element. The heat exchange element constitutes a cross flow type heat exchanger in which the passage direction of outdoor air and the passage direction of indoor air are orthogonal to each other. In the heat exchange element, heat is exchanged between outdoor air sent to the room and indoor air discharged to the outside. In the heat exchange element, moisture is also exchanged between outdoor air and indoor air.

  In the ventilation device of Patent Document 1, two heat exchange elements are arranged side by side. These two heat exchange elements are arranged in parallel with each other in the flow path of outdoor air or indoor air. That is, a part of the outdoor air taken into the ventilation device passes only through one heat exchange element, and the rest passes only through the other heat exchanger element. In addition, part of the room air taken into the ventilator passes only through one heat exchange element, and the rest passes through only the other heat exchanger element.

In the ventilation device of Patent Document 2, two heat exchange elements are arranged side by side. These two heat exchange elements are arranged in series in the outdoor air flow path. The outdoor air passes through the two heat exchange elements in order and is supplied to the room. This ventilator takes in indoor air and ceiling air. The room air passes through only one heat exchange element and is then discharged outside the room. The ceiling air passes only through the other heat exchanger element and is then sent back to the space behind the ceiling.
Japanese Patent Laid-Open No. 06-257817 JP 2002-349924 A

  Here, as a measure for improving the heat recovery efficiency in the ventilator, it is conceivable to increase the heat transfer area by increasing the number of heat exchange elements installed in the ventilator. However, when two heat exchange elements are arranged in parallel in the air passage as in the ventilator of Patent Document 1, the flow rates of outdoor air and indoor air that pass through one heat exchange element are reduced.

  In general, as the flow rate of fluid passing through the heat exchanger decreases, the heat transfer coefficient between the heat exchanger and the fluid passing therethrough decreases accordingly. That is, when the flow velocity of the air passing through the heat exchange element decreases, the efficiency of heat exchange between the outdoor air and the indoor air decreases. For this reason, when two heat exchange elements are arranged in parallel in the air passage, an increase in the amount of exchange heat corresponding to the increase in the heat transfer area cannot be expected, and the performance of the ventilator may not be sufficiently improved. .

  On the other hand, in the ventilator of Patent Document 2, the flow rate of air passing through each heat exchange element is equivalent to the case where only one heat exchange element is provided, so the amount of exchange heat corresponding to the increase in the heat transfer area is increased. Can be expected. However, in this ventilator, not only indoor and outdoor air but also air in the ceiling must be circulated in the ventilator. For this reason, in addition to the air supply fan and the exhaust fan, a fan for circulating the air in the ceiling is required, and there is a problem that the configuration of the ventilation device is complicated.

  This invention is made | formed in view of this point, The objective is to aim at the performance improvement, without complicating the structure of the ventilator provided with a heat exchange element.

The present invention includes an air supply fan (50) for supplying outdoor air to the room, an exhaust fan (55) for discharging indoor air to the outside, and the outdoor air supplied to the room and the outside. A heat exchange element (41, 42) for exchanging heat with room air is housed in the casing (20), and the heat exchange element (41, 42) is formed in a quadrangular prism shape, and the heat exchange element (41, 42) 42) covers a ventilator in which an outdoor air flow path (45) is opened on one of the adjacent side surfaces and an indoor air flow path (46) is opened on the other side. In the casing (20), the outdoor air passage (37) and the indoor air flow are deformed by coming into contact with and deforming the corner (47) along the axial direction of the heat exchange element (41, 42). A seal member (75) for sealing between the passages (38) is provided. In the seal member (75), the seal member (75) is provided on a surface facing the corner (47) of the heat exchange element (41, 42). A notch (76) extending along the corner (47) of the heat exchange element (41, 42) at a depth not penetrating through 75) is formed.

In the present invention , the heat exchange elements (41, 42) are provided in the casing (20). When the air supply fan (50) is operated, outdoor air is taken into the casing (20), passes through the heat exchange elements (41, 42), and then supplied to the room. On the other hand, when the exhaust fan (55) is operated, room air is taken into the casing (20), passes through the heat exchange elements (41, 42), and is discharged to the outside.

In the present invention , in the rectangular columnar heat exchange element (41, 42), an outdoor air flow channel (45) is opened on one of the side surfaces adjacent to each other, and an indoor air flow channel (46) is opened on the other side. In the state where the heat exchange element (41, 42) is installed in the casing (20), the outdoor air passage (37) formed in the casing (20) is the outdoor air passage ( 45), the indoor air passage (38) formed in the casing (20) communicates with the indoor air flow path (46) provided in the heat exchange element. That is, in the casing (20), the outdoor air passage (37) and the indoor air passage (38) are connected to the corner (47) (that is, the outdoor space) along the axial direction of the heat exchange element (41, 42). The corners between the side surface where the air flow channel (45) opens and the side surface where the indoor air flow channel (46) opens are adjacent to each other.

In the present invention , in a state where the heat exchange element (41, 42) is installed in the casing (20), the corner (47) of the heat exchange element is pressed against the seal member (75). Between the outdoor air passage (37) and the indoor air passage (38) formed in the casing (20), the corner (47) of the heat exchange element (41, 42) is connected to the seal member (75). Sealed by close contact. In the sealing member (75), a notch (76) is formed on the surface facing the corner (47) of the heat exchange element (41, 42). When the corner (47) of the heat exchange element (41, 42) is pressed against the seal member (75), the corner (47) of the heat exchange element (41, 42) enters the notch (76). It becomes a state.

  Here, the heat exchange elements of Patent Document 1 and Patent Document 2 are formed in the shape of a quadrangular prism having a square end surface, and a flow path for outdoor air is provided on one of the side surfaces adjacent to each other, and a flow path for indoor air is provided on the other side. Each is open. That is, in this heat exchange element, the outdoor air flow path is opened on one of the side surfaces adjacent to each other across the corner along the axial direction, and the indoor air flow path is opened on the other side. For this reason, in the casing of the ventilator, a passage through which outdoor air flows and a passage through which room air flows are formed across the corners of the heat exchange element.

  In the ventilator having such a structure, it is required to reliably seal between the outdoor air passage and the indoor air passage and to reduce the amount of air leaking from one of the two passages to the other as much as possible. . Generally, the outdoor air passage and the indoor air passage are often sealed by pressing corner portions of a heat exchange element against a sealing member made of a flexible material such as sponge. However, simply pressing the corners of the heat exchange element against the seal member does not sufficiently deform the seal member, and there is a possibility that a sufficient contact area between the seal member and the heat exchange element cannot be secured.

In contrast, in the present invention , the notch (76) is formed in the seal member (75), and the corner (47) of the heat exchange element (41, 42) is pressed against the seal member (75). The corner (47) of the heat exchange element (41, 42) enters the notch (76). Therefore, the contact area between the seal member (75) and the heat exchange element (41, 42) can be increased as compared with the case where the notch (76) is not provided in the seal member. Therefore, according to the present invention , it is possible to reliably seal between the outdoor air passage (37) and the indoor air passage (38), and the outdoor air passage (37) and the indoor air passage (38). The amount of air leaking from one of the two to the other can be reduced.

  Hereinafter, embodiments of the present invention will be described in detail with reference to the drawings. Note that the terms “right”, “left”, “upper”, “lower”, “front”, and “back” used in the following description all mean that in the state shown in FIG.

  As shown in FIG.1 and FIG.2, the ventilation apparatus (10) of this embodiment is provided with the horizontally long and flat rectangular parallelepiped casing (20). 1 and 2 show a state where a top plate of the casing (20) and a part of the side plate on the near side are removed.

  The left side plate (21) of the casing (20) is provided with an outside air suction duct connection portion (26) and an exhaust duct connection portion (29) one by one. In the left side plate (21), the outside air suction duct connection portion (26) is disposed on the near side, and the exhaust duct connection portion (29) is disposed on the back side. Although not shown, an outdoor air duct extending from the outdoor space is connected to the outdoor air suction duct connecting portion (26), and an exhaust duct extending to the outdoor space is connected to the exhaust duct connecting portion (29).

  Of the internal space of the casing (20), a portion along the left side plate (21) is partitioned into a supply side fan chamber (31) on the front side and an exhaust side fan chamber (32) on the back side. The supply-side fan chamber (31) communicates with an outside air duct (not shown) via an outside air suction duct connecting portion (26). The exhaust side fan chamber (32) is connected to an exhaust duct (not shown) via an exhaust duct connection part (29).

  An air supply fan (50) is accommodated in the air supply side fan chamber (31), and an exhaust fan (55) is accommodated in the exhaust side fan chamber (32). The supply fan (50) and the exhaust fan (55) are configured by a fan body (51, 56) that is a so-called sirocco fan and a fan motor (52, 57) that drives the fan main body (51, 56). The fan motor (52) of the air supply fan (50) and the fan motor (57) of the exhaust fan (55) are both brushless DC motors.

  The right side plate (22) of the casing (20) is provided with one inside air suction duct connection portion (27) and two air supply duct connection portions (28). In the right side plate (22), the air supply duct connection portion (28) is arranged side by side on the front side, and the inside air suction duct connection portion (27) is arranged on the back side. Although not shown, an internal air duct extending from the indoor space is connected to the internal air suction duct connecting portion (27), and an air supply duct extending to the indoor space is connected to the air supply duct connecting portion (28).

  A portion of the internal space of the casing (20) along the right side plate (22) is partitioned into a supply side chamber (33) on the front side and an exhaust side chamber (34) on the back side. The air supply side chamber (33) accommodates a filter unit (65) for air purification. The air supply side chamber (33) communicates with an air supply duct (not shown) via an air supply duct connection (28). The exhaust side chamber (34) is connected to an outside air duct (not shown) via an inside air suction duct connecting portion (27).

  A bypass passage (35) is formed in a portion along the back side plate (24) in the internal space of the casing (20). The bypass passage (35) communicates with the exhaust-side fan chamber (32) at one end thereof. A damper unit (60) is installed on the other end side of the bypass passage (35). The other end of the bypass passage (35) is opened and closed by a damper plate (61) of the damper unit (60).

  The damper unit (60) is provided with a rotatable damper plate (61). In the damper unit (60), the damper plate (61) has a position (a position indicated by a solid line in FIG. 2) where the inside air suction duct connection portion (27) is blocked from the bypass passage (35), and an inside air suction duct connection portion. It moves between the position (27) communicating with the bypass passage (35) (the position indicated by the two-dot chain line in FIG. 2).

  In the internal space of the casing (20), a main chamber (36) is formed at the center in the longitudinal direction of the casing (20). The main chamber (36) accommodates the first total heat exchange element (41) and the second total heat exchange element (42). Each of these total heat exchange elements (41, 42) constitutes a heat exchange element.

  As shown in FIG. 3, each of the total heat exchange elements (41, 42) is formed in a quadrangular prism shape having a square end surface. In the total heat exchange element (41, 42), the flat plate members (43) and the corrugated plate members (44) are alternately arranged in the longitudinal direction. In this total heat exchange element (41, 42), an outdoor air flow path (45) for flowing outdoor air and an internal air flow path (46) for flowing indoor air are alternately sandwiched between flat plate members (43). Is formed. In the square columnar total heat exchange element (41, 42), the outside air flow path (45) is opened on one of the adjacent side surfaces, and the inside air flow path (46) is opened on the other side. Thus, the total heat exchange elements (41, 42) constitute a cross flow type heat exchanger in which the extension direction of the outside air flow path (45) and the extension direction of the inside air flow path (46) are orthogonal to each other. .

  The flat plate member (43) of the total heat exchange element (41, 42) is made of a moisture-permeable material such as paper. In the total heat exchange element (41, 42), heat and moisture move from one of the outdoor air flowing through the outdoor air flow path (45) and the indoor air flowing through the indoor air flow path (46) to the other. That is, in the total heat exchange element (41, 42), enthalpy is exchanged between the humid airs.

  As shown in FIG. 1, the total heat exchange element (41, 42) has an angle formed between the side surface and the bottom plate (25) of the casing (20) of 45 °, and its longitudinal direction is the depth direction of the casing (20). It is installed in the main chamber (36) in a posture that extends along (the direction from the front side plate (23) to the back side plate (24)). In the main chamber (36), the two total heat exchange elements (41, 42) are arranged side by side. The first total heat exchange element (41) is disposed near the left side plate (21) of the casing (20), and the second total heat exchange element (42) is disposed near the right side plate (22) of the casing (20). .

  Each total heat exchange element (41, 42) is supported on the casing (20) via four guide rails (70). Each guide rail (70) holds a corner (47) along the axial direction of the total heat exchange element (41, 42). Details of the guide rail (70) will be described later.

  In the main chamber (36), the upper left part of the first total heat exchange element (41) and the part sandwiched between the first total heat exchange element (41) and the second total heat exchange element (42) The side and the upper right portion of the second total heat exchange element (42) constitute an air supply side passage (37) that is a passage of outdoor air. The air supply side passageway (37) has a left upper part of the first total heat exchange element (41) communicating with the air supply side fan chamber (31), and an upper right part of the second total heat exchange element (42). Communicates with the supply side chamber (33).

  In the main chamber (36), the lower left portion of the first total heat exchange element (41) and the portion sandwiched between the first total heat exchange element (41) and the second total heat exchange element (42). And the lower right portion of the second total heat exchange element (42) constitute an exhaust side passage (38) that is a passage for indoor air. In the exhaust side passage (38), the lower right part of the second total heat exchange element (42) communicates with the exhaust side chamber (34), and the lower left part of the first total heat exchange element (41) exhausts. It communicates with the side fan chamber (32).

  In the ventilator (10) of this embodiment, the pressure loss of the air from the inside air suction duct connecting part (27) through the bypass passage (35) to the exhaust side fan chamber (32) is reduced by the inside air suction duct. The shape of the bypass passage (35) is set so as to be smaller than the pressure loss of air from the connection portion (27) through the main chamber (36) chamber to the exhaust side fan chamber (32).

  The guide rail (70) is an elongated member having substantially the same length as the total heat exchange element (41, 42). As shown in FIG. 4A, the guide rail (70) is composed of a main body portion (71) and a slope portion (72). The main body (71) has a U-shaped cross section. The slope (72) extends obliquely downward from the upper ends on both sides of the main body (71) in FIG. 4 (A).

  A rod-shaped seal member (75) is fitted into the bowl-shaped main body (71). The seal member (75) is made of a flexible material such as a sponge-like foamed resin. The cross-sectional shape of the seal member (75) is a quadrangular shape along the inner surface of the main body (71). A cut (76) extending along the axial direction of the seal member (75) is formed on the upper surface of the seal member (75) in FIG. The depth of the notch (76) is shorter than the thickness of the seal member (75) and does not penetrate the seal member (75).

  In the casing (20), the guide rail (70) is such that the opening side of the main body (71) (that is, the side where the seal member (75) is exposed) is the corner of the total heat exchange element (41, 42). Arranged in a posture facing (47). The total heat exchange element (41, 42) is slidable along the guide rail (70). When the total heat exchange element (41, 42) is attached to or detached from the casing (20), the total heat exchange element (41, 42) moves while being guided by the guide rail (70).

  As shown in FIG. 4B, when the total heat exchange element (41, 42) is accommodated in the casing (20), the corner (47) of the total heat exchange element (41, 42) is placed in the seal member (75). ) Is pressed. In this state, the corner (47) of the total heat exchange element (41, 42) enters the cut (76) of the seal member (75) and comes into close contact with the seal member (75). Between the supply side passage (37) and the exhaust side passage (38) in the main chamber (36), the corner (47) of the total heat exchange element (41, 42) is in close contact with the seal member (75). Sealed by.

-Driving action-
In the ventilation device (10) of the present embodiment, switching between total heat exchange ventilation operation and normal ventilation operation is possible.

<Total heat exchange ventilation operation>
The total heat exchange ventilation operation will be described. This operation is performed when there is a large temperature difference or humidity difference between the outdoor and the air-conditioned indoor, such as in winter or summer.

  In the total heat exchange ventilation operation, the damper plate (61) of the damper unit (60) is set to a position (position indicated by a solid line in FIG. 2) that closes the bypass passage (35). In this state, when the air supply fan (50) and the exhaust fan (55) are operated, the outdoor air flows into the casing (20) through the outside air suction duct connection (26), and the room air is connected to the inside air suction duct. It flows into the casing (20) through the part (27).

  The outdoor air that has flowed into the casing (20) is blown out to the air supply side passage (37) by the air supply fan (50), and then the outdoor air flow path (45) of the first total heat exchange element (41), It passes through the outside air flow path (45) of the second total heat exchange element (42) in order. On the other hand, the room air flowing into the casing (20) flows into the exhaust side passage (38) through the exhaust side chamber (34), and then the inside air flow path (46 of the second total heat exchange element (42)). ) And the internal air flow path (46) of the first total heat exchange element (41).

  In each total heat exchange element (41, 42), heat and moisture are exchanged between outdoor air flowing through the outdoor air flow path (45) and indoor air flowing through the internal air flow path (46).

  For example, in a state where the room is air conditioned in winter, the temperature and humidity of the indoor air are higher than the temperature and humidity of the outdoor air. Therefore, when the total heat exchange ventilation operation is performed in this state, heat and moisture move from the indoor air to the outdoor air in the total heat exchange elements (41, 42). That is, the outdoor air supplied to the room is heated and humidified by the room air discharged to the outside.

  Moreover, in a state where the room is air-conditioned in summer, the temperature and humidity of the indoor air are lower than the temperature and humidity of the outdoor air. Therefore, when the total heat exchange ventilation operation is performed in this state, heat and moisture move from the outdoor air to the indoor air in the total heat exchange elements (41, 42). That is, the outdoor air supplied to the room is cooled and dehumidified by the room air discharged to the outside.

  The outdoor air that has passed through the first total heat exchange element (41) and the second total heat exchange element (42) in this order flows into the supply side chamber (33), is purified by the filter unit (65), and then supplied. It is sent out from the casing (20) through the air duct connection (28). On the other hand, the room air that has passed through the second total heat exchange element (42) and the first total heat exchange element (41) in turn flows into the exhaust fan chamber (32) and is connected to the exhaust duct from the exhaust fan (55). It blows out toward the part (29).

<Normal ventilation operation>
The normal ventilation operation will be described. This operation is performed when the temperature difference and humidity difference between the outdoor and the air-conditioned indoor are not so large, such as in the intermediate period (spring or autumn).

  In the normal ventilation operation, the damper plate (61) of the damper unit (60) is set to a position (a position indicated by a two-dot chain line in FIG. 2) where the bypass passage (35) communicates with the inside air suction duct connection portion (27). . In this state, the damper plate (61) blocks between the inside air suction duct connecting portion (27) and the exhaust side passage (38). In this state, when the air supply fan (50) and the exhaust fan (55) are operated, the outdoor air flows into the casing (20) through the outside air suction duct connection (26), and the room air is connected to the inside air suction duct. It flows into the casing (20) through the part (27).

  The room air flowing into the casing (20) flows through the bypass passage (35) and flows into the exhaust-side fan chamber (32). That is, in the casing (20), the room air flows directly into the exhaust-side fan chamber (32), bypassing the total heat exchange element (41, 42).

  On the other hand, the outdoor air that has flowed into the casing (20) is blown out to the air supply side passage (37) by the air supply fan (50), and then the outdoor air flow path (45) of the first total heat exchange element (41). And the outside air flow path (45) of the second total heat exchange element (42). At that time, room air does not flow in the internal air flow paths (46) of the total heat exchange elements (41, 42). For this reason, the outdoor air simply passes through each of the total heat exchange elements (41, 42), and flows into the air supply side chamber (33) in the same state as when it flows into the casing (20). The outdoor air that has flowed into the air supply side chamber (33) is purified by the filter unit (65) and then sent out from the casing (20) through the air supply duct connection (28).

  In recent years, since the introduction of OA equipment such as personal computers has progressed, the thermal load in the office tends to increase. For this reason, when the outside air temperature is not so high, such as an intermediate period, a cooling effect can be expected only by supplying outdoor air to the room, and the period during which such a cooling effect can be expected tends to be longer. Therefore, from the viewpoint of energy saving, it is desirable to use as much as possible the cooling effect by such normal ventilation operation.

−Seal structure of corner of total heat exchange element−
As described above, in the ventilation device (10) of the present embodiment, the seal between the air supply side passage (37) and the exhaust side passage (38) in the main chamber (36) is the total heat exchange element (41). , 42) is ensured by close contact with the sealing member (75). At that time, the corners (47) of the total heat exchange elements (41, 42) are in a state of entering the notches (76) of the seal member (75). For this reason, the width | variety of the part which contacts a sealing member (75) among total heat exchange elements (41,42) becomes long compared with the case where the general sealing member (90) without a notch | incision (76) is used. . This point will be described below.

  First, a case where a general seal member (90) having no cut (76) is used will be described with reference to FIG. As shown in FIG. 5A, the width of the seal member (90) is assumed to be “2a”. The seal member (90) without the notch (76) is crushed by the corner (47) of the total heat exchange element (41, 42), and the upper surface of the seal member (90) in FIG. , 42) is in close contact with the corner (47). For this reason, as shown in FIG. 5B, the width L of the portion of the total heat exchange element (41, 42) contacting the seal member (90) is half the width of the seal member (90) (ie, It becomes almost equal to a) (L≈a). That is, the seal length 2L in this case is substantially the same as 2a.

  Next, the case where the sealing member (75) of this embodiment in which the notch (76) is formed will be described with reference to FIG. Also in this case, as shown in FIG. 4A, the width of the seal member (75) is assumed to be “2a”. Further, it is assumed that the depth of the notch (76) is “a”. As shown in FIG. 4B, the corners (47) of the total heat exchange elements (41, 42) enter the notches (76) of the seal member (75). The portions of the seal member (75) on both sides of the notch (76) are more easily deformed than the case without the notch (76), and the total heat exchange element ( In a state where the corners (47) of 41, 42) are inserted, these portions are greatly deformed. For this reason, as shown in the figure, the width L of the portion of the total heat exchange element (41, 42) that contacts the seal member (75) is half the width of the seal member (90) (ie, a). It is almost equal to (√2) times (L≈ (√2) a). That is, the seal length 2L in this case is substantially the same as 2 (√2) a.

  In this way, when the cut (76) is formed in the seal member (75) and the depth of the cut (76) is set to half the width of the seal member (75), the seal member without the cut (76) ( Compared with the case of using 90), the seal length 2L is about 1.4 times. For this reason, by forming the notch (76) in the seal member (75), the seal between the air supply side passage (37) and the exhaust side passage (38) in the main chamber (36) can be reliably performed. it can. Further, by changing the depth of the notch (76), the width L of the portion of the total heat exchange element (41, 42) that comes into contact with the seal member (90) can be adjusted.

-Effect of Embodiment 1-
In the present embodiment, the first total heat exchange element (41) and the second total heat exchange element (42) are arranged in series in the air supply side passage (37) and the exhaust side passage (38). Since the flow velocity of air passing through the total heat exchange elements (41, 42) is kept the same as when only one total heat exchange element is provided, the efficiency of heat exchange in each total heat exchange element (41, 42) is It does not decline. For this reason, according to the present embodiment, the amount of heat and moisture exchanged between the outdoor air and the indoor air can be increased by an amount corresponding to the expansion of the heat transfer area with the addition of the total heat exchange element. Moreover, in this embodiment, since it is only indoor air and outdoor air that need to flow through the casing (20), the structure of the ventilation device (10) is not complicated. Therefore, according to the present embodiment, it is possible to improve the performance without complicating the configuration of the ventilation device (10).

  Moreover, in this embodiment, the notch (76) is formed in the sealing member (75). For this reason, the width of the portion of the corner (47) of the total heat exchange element (41, 42) that is in close contact with the seal member (75) is smaller than that when the seal member (90) without the notch (76) is used. Can be long. That is, the contact area between the total heat exchange element (41, 42) and the seal member (75) can be increased. Therefore, according to the present embodiment, the space between the air supply side passage (37) and the exhaust side passage (38) can be reliably sealed, and the air supply side passage (37) and the exhaust side passage (38) can be sealed. By reducing the amount of air that leaks from one to the other, the performance of the ventilator (10) can be improved.

  In the present embodiment, both the air supply fan (50) and the exhaust fan (55) are provided on one side (near the left side plate (21) in FIG. 2) of the total heat exchange element (41, 42) in the casing (20). Is provided. For this reason, the air supply fan (50) and the exhaust fan (55) can be arranged by effectively using the internal space of the casing (20), and the ventilation device (10) can be downsized.

  In the present embodiment, the air supply fan (50) is disposed near the left side plate (21) of the casing (20), and is provided in the air supply side chamber (33) along the right side plate (22) of the casing (20). Two air supply duct connections (28) are in communication. Here, the air immediately after being blown out from the air supply fan (50) flows in a biased state in the space. That is, the air flow velocity distribution in the space is not uniform. For this reason, if a plurality of air supply duct connection parts (28) are made to communicate with the space in which the air supply fan (50) is arranged, the distribution ratio of air to each air supply duct connection part (28) is appropriately set. It becomes difficult. On the other hand, in the present embodiment, each supply duct connecting portion (in the supply side chamber (33) through which the outdoor air that has been blown out from the supply fan (50) and passed through the total heat exchange element (41, 42) flows. 28) is in communication. Therefore, according to this embodiment, even when a plurality of air supply duct connection portions (28) are provided in the casing (20), the distribution ratio of air to each air supply duct connection portion (28) is easily optimized. It becomes possible.

  Moreover, in the ventilator (10) of this embodiment, the pressure loss of the air from the inside air suction duct connection part (27) through the bypass passage (35) to the exhaust side fan chamber (32) is reduced by the inside air suction duct. It is smaller than the pressure loss of air from the connecting portion (27) through the main chamber (36) to the exhaust side fan chamber (32). For this reason, during normal ventilation operation, the power consumed by the fan motor (57) of the exhaust fan (55) can be reduced compared to during the total heat exchange operation. Therefore, according to the present embodiment, the energy saving effect by the normal ventilation operation is further increased.

  In the present embodiment, brushless DC motors are used as the fan motors (52, 57) of the air supply fan (50) and the exhaust fan (55). Therefore, the power consumption of the fan motor (52, 57) can be reduced as compared with the case where an AC motor is used as the fan motor (52, 57).

-Modification of Embodiment 1-
In the ventilator (10) of this embodiment, the total heat exchange element (41, 42) that exchanges both heat and moisture (that is, sensible heat and latent heat) between the outdoor air and the room air is used. Instead of this, a sensible heat exchange element that exchanges only sensible heat between the outdoor air and the indoor air may be used.

  Moreover, although the two total heat exchange elements (41, 42) are provided in the ventilation apparatus (10) of this embodiment, the number of total heat exchange elements is not limited to two, and three You may provide the above total heat exchange element in a ventilator (10). Further, only one total heat exchange element may be provided in the ventilator (10).

  In addition, the above embodiment is an essentially preferable illustration, Comprising: It does not intend restrict | limiting the range of this invention, its application thing, or its use.

  As described above, the present invention is useful for a ventilator including a heat exchange element that exchanges heat between outdoor air supplied to a room and indoor air discharged to the outside.

It is a perspective view which shows the structure of a ventilation apparatus. It is a top view which shows the structure of a ventilation apparatus. It is a schematic perspective view of a total heat exchange element. (A) is the enlarged view which looked at the guide rail and seal member in an embodiment from the front, (B) is the principal part enlarged view of the ventilator which shows the seal structure of the total heat exchange element in the ventilator of an embodiment. . (A) is the enlarged view which looked at the guide rail and seal member in a prior art from the front, (B) is the principal part enlarged view of the ventilation apparatus which shows the seal structure of the total heat exchange element in the conventional ventilation apparatus.

10 Ventilator
20 casing
28 Supply duct connection
37 Air supply side passage (outdoor air passage)
38 Exhaust-side passage (room air passage)
41 First total heat exchange element (first heat exchange element)
42 Second total heat exchange element (second heat exchange element)
45 Outside air flow path (outdoor air flow path)
46 Inside air passage (room air passage)
47 Corner
50 Air supply fan
55 Exhaust fan
75 Seal member
76 notches

Claims (1)

An air supply fan (50) for supplying outdoor air to the room, an exhaust fan (55) for discharging indoor air to the outside, and outdoor air supplied to the room and room air discharged to the outside The heat exchange element (41, 42) for heat exchange is housed in the casing (20),
The heat exchange element (41, 42) is formed in a quadrangular prism shape. In the heat exchange element (41, 42), an outdoor air flow path (45) is provided on one of adjacent side surfaces, and an indoor air flow path is provided on the other side. (46) is an open ventilator,
In the casing (20), the outdoor air passage (37) and the indoor air passage (inside the outer air passage (37) are deformed by contact with the corner portions (47) along the axial direction of the heat exchange element (41, 42). 38) is provided with a sealing member (75) for sealing between
In the sealing member (75), the heat exchange element (41, 42) has a depth not penetrating the seal member (75) on the surface facing the corner (47) of the heat exchange element (41, 42). A ventilator characterized in that a cut (76) extending along the corner (47) is formed.

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