JP2015031418A - Ventilator - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide a ventilator which prevents pressure drop and performs continuous ventilation, while preventing steam from entering into a body box.SOLUTION: A ventilator includes a damper unit having a planar ventilation member movably provided in an air-supply passage and having air permeability, a humidity sensor detecting the humidity in the air-supply passage, and a control unit controlling the damper unit on the basis of the detection result of the humidity sensor to move the ventilation member.

Description

  The present invention relates to a ventilation device.

  The ventilation device has a main body box on which a blower or the like is mounted, and the main body box communicates with the room and the outside via a duct, an outdoor hood, and the like. Here, when fog is generated outdoors or it is raining, moisture such as mist and rainwater is taken into the main body box together with the air forced into the main body box by the blower. May end up.

  Nowadays, there is an increasing need for ventilating the air-conditioned space for 24 hours. Fog, high humidity air, etc. are likely to occur early in the morning and late at night, and if the ventilator is operated during this time period, the possibility of moisture intruding into the main body box increases accordingly. In particular, when the ventilation device is a ceiling-embedded type, there is a problem that water flows out from between members constituting the main body box and wets the ceiling on which the main body box is installed.

  For this reason, in order to remove such moisture, for example, there is a method in which the internal air passage of an outdoor hood used to take in outside air is bent in a complicated manner and air is collided in the air passage to remove the moisture. Has been.

  In addition, a ventilation device that controls the blower by detecting the humidity of air with a humidity detection sensor has been proposed (see, for example, Patent Document 1). The technique described in Patent Document 1 performs ventilation by operating a fan when the measured value of the outside air humidity detected by a humidity detection sensor provided outside the room is lower than a preset value.

  Further, when the measured value of the outside air humidity detected by the humidity detection sensor is smaller than a preset value, control is performed to stop the operation of the air supply blower in order to stop taking in the air supply into the main body box. A ventilation device has been proposed (see, for example, Patent Document 2).

  Further, an indoor ventilation system has been proposed in which indoor humidity is detected at predetermined time intervals by a humidity detection sensor attached to an indoor ventilation fan, and the operation of the ventilation fan is stopped (see, for example, Patent Document 3).

  In addition, an air supply state detector (condensation sensor) that detects the state of air intake taken from the outdoor suction port is provided in the air supply passage, and it is determined that moisture has entered the main body box based on the detection result of the condensation sensor. A ventilation device has been proposed that stops or intermittently operates an air supply blower (see, for example, Patent Document 4). It should be noted that during this intermittent operation, intermittent operation is carried out by reducing the air volume to suppress the intrusion of moisture into the main body box, compared to the case where it is determined that water has not entered the main body box. An exhaust fan has also been proposed (see, for example, Patent Document 5).

Japanese Patent Laid-Open No. 08-014611 (for example, see FIG. 1) Japanese Patent Laid-Open No. 05-280774 (for example, see FIG. 3) Japanese Patent Laid-Open No. 05-311956 (see, for example, abstract) JP 2009-293880 A (see, for example, claim 1) JP 2012-172961 A (for example, refer to claim 1)

  The above-described means for bending the internal air passage of the outdoor hood in a complicated manner is a method of removing mist or the like of outdoor air by sharply bending the air passage in the outdoor hood, so that the pressure loss increases accordingly. There are challenges.

  As in the technique described in Patent Literature 1-5, fog or the like enters the main body box by stopping the operation of the blower or performing the intermittent operation based on the detection result of the humidity detection sensor or the like. Although this can be suppressed, there is a problem that a period in which the blower is stopped and intake air is not taken in, and continuous ventilation cannot be performed.

  The present invention has been made to solve the above-described problems, and provides ventilation that suppresses intrusion of mist and the like into the main body box while realizing suppression of pressure loss and continuous ventilation. An object is to provide an apparatus.

  A ventilator according to the present invention includes a main body box having an air supply air passage communicating with an air supply inlet and an air supply outlet, an exhaust air passage communicating with the exhaust air inlet and the exhaust air outlet, and an air supply air passage. An air supply blower that is provided and takes air into the air supply air passage and discharges it into the air conditioning target space; and an exhaust air blower that is provided in the exhaust air passage and takes air into the air exhaust air passage and discharges it outside the air conditioning target space; A damper unit that has a plate-like ventilation member that is movably provided in the air supply air passage, has air permeability, a humidity sensor that detects the humidity of the air supply air passage, and controls the damper unit based on the detection result of the humidity sensor. And a control device for moving the ventilation member.

  According to the ventilator according to the present invention, since it has the above-described configuration, it is possible to suppress mist and the like from entering the main body box while realizing suppression of pressure loss and continuous ventilation. Can do.

It is an example of outline composition of a ventilator concerning an embodiment of the invention. It is a longitudinal cross-sectional schematic diagram which shows the state which the damper unit of the ventilation apparatus shown in FIG. 1 is open. It is a longitudinal cross-sectional schematic diagram which shows the state which the damper unit of the ventilation apparatus shown in FIG. 1 is closed. It is explanatory drawing in the state in which the damper unit of the ventilation apparatus which concerns on embodiment of this invention is open. It is explanatory drawing in the state which the damper unit of the ventilation apparatus which concerns on embodiment of this invention has closed. It is explanatory drawing of the state which the damper board of the ventilation apparatus which concerns on embodiment of this invention is open. It is explanatory drawing of the state with which the damper board of the ventilation apparatus which concerns on embodiment of this invention is closed. It is a front view of a damper board and a damper axis.

Hereinafter, embodiments of the present invention will be described with reference to the drawings.
Embodiment.
FIG. 1 is a schematic configuration diagram of a ventilation device 50 according to an embodiment. FIG. 2 is a schematic longitudinal sectional view showing a state where the damper unit 17 of the ventilation device 50 shown in FIG. 1 is open. FIG. 3 is a schematic longitudinal sectional view showing a state where the damper unit 17 of the ventilation device 50 shown in FIG. 1 is closed. In addition, in FIG. 1, the state which removed the top | upper surface part 1A which comprises the upper surface side among the main body boxes 1 which are the outlines of the ventilation apparatus 50 is illustrated. Moreover, in FIG.2 and FIG.3, illustration is abbreviate | omitted about this top | upper surface part 1A. Furthermore, the arrows indicated by reference signs A, B, and C shown in FIGS. 1 to 3 indicate the flow of exhaust, and the arrows indicated by reference signs D, E, and F indicate the flow of supply air.
The ventilator 50 according to the present embodiment is an improvement in which mist and the like are prevented from entering the main body box 1 while realizing suppression of pressure loss and continuous ventilation. is there.

  The ventilation device 50 can take in air in an air-conditioning target space (for example, a house, building, warehouse, etc.) and discharge it outside the air-conditioning target space, and can take in air outside the air-conditioning target space and supply it to the air-conditioning target space. Is. In the following description, a case where the air-conditioning target space is in a house will be described as an example. Further, “outdoor air” corresponds to the supply air supplied from the ventilator 50 to the room, and “indoor air” corresponds to “exhaust air” discharged from the ventilator 50 to the outside of the room.

[Description of configuration]
The ventilation device 50 includes a main body box 1 on which various devices are mounted, a heat exchanger 10 that exchanges heat between the taken-out outdoor air and indoor air, and an air supply filter 21 that is attached to the heat exchanger 10. The air supply fan 8 for taking in outdoor air, the exhaust fan 9 for taking in indoor air, and moisture (fog etc.) contained in the outdoor air taken in the main body box 1 are used. A damper unit 17 and a humidity sensor 16 are provided.
Although not shown in the drawing, the ventilation device 50 outputs the detection result of the humidity sensor 16 and outputs the rotational speeds of the air supply fan 8 and the exhaust fan 9, the drive unit 17 </ b> C of the damper unit 17 described later, and the like. A control device for controlling is provided. The control device is composed of, for example, a microcomputer.

The ventilation device 50 includes an air supply inlet 3 that is used to take outdoor air from the outdoor side to the main body box 1 side, and an air supply that is used to supply air from the main body box 1 side to the indoor side. The air outlet 4 and the air supply air path 7 which is provided in the main body box 1 and connects the air supply inlet 3 and the air supply outlet 4 are provided.
In addition, the ventilator 50 includes an exhaust air inlet 2 that is used to take room air from the indoor side to the main body box 1 side, and an exhaust blower that is used to exhaust air from the main body box 1 side to the outdoor side. It has an outlet 5 and an exhaust air passage 6 provided in the main body box 1 and connecting the exhaust inlet 2 and the exhaust outlet 5.
Although not shown in FIGS. 1 to 3, the exhaust suction port 2 and the air supply / discharge port 4 communicate with the room through, for example, a duct 22 (see FIGS. 6 and 7). The supply air inlet 3 and the exhaust outlet 5 are also in communication with the outside through, for example, a duct 22.

(Main box 1)
The main body box 1 constitutes the outline of the ventilation device 50 and has an air passage through which air supply and exhaust flow. The main body box 1 is mounted with at least an air supply fan 8, an exhaust fan 9, a heat exchanger 10, and a damper unit 17.
The main body box 1 has a first side surface portion 1a in which an opening 11 used for attaching and removing the heat exchanger 10 to the main body box body 1 is formed, and a first side surface portion 1a. The second side surface portion 1b, the third side surface portion 1c provided with the exhaust air suction port 2 and the air supply outlet 4, the air supply air inlet 3 and the exhaust air outlet 5 are parallel to each other. It has the 4th side part 1d provided. Further, the main body box 1 has a top surface portion 1 </ b> A that constitutes an outer surface on the upper surface side, and a lower surface portion 1 </ b> B that constitutes an outer surface on the lower surface side of the main body box 1. The top surface portion 1A and the bottom surface portion 1B are provided so as to be orthogonal to the first side surface portion 1a, the second side surface portion 1b, the third side surface portion 1c, and the fourth side surface portion 1d.
The first side surface portion 1a is provided with a maintenance cover 14 at the position where the opening 11 is formed, which is opened when the heat exchanger 10 is attached or removed.

The main body box 1 is provided with a casing 15 in which a damper plate 17A and a damper shaft 17B of a damper unit 17 described later are provided (see FIGS. 6 and 7). The casing 15 is provided so that the downstream side communicates with the heat exchanger 10 so that the upstream side communicates with the air supply inlet 3. As shown in FIG. 1, the casing 15 is on the fourth side surface 1 d side from the installation position of the heat exchanger 10 in the space in the main body box 1 and is the first side surface from the exhaust fan 9. It is provided on the part 1a side.
The casing 15 is provided on the top surface portion 1A side, and an upper surface portion 15A that rotatably supports an upper end side of a damper shaft 17B, which will be described later, and a lower end side of the damper shaft 17B are rotatably supported, and a humidity sensor 16 is provided. And the lower surface portion 15B. The lower surface portion 15B has an inclined surface 15a that is inclined downward from the side supporting the damper shaft 17B toward the air supply inlet 3 side. As a result, the water dropped as water droplets on the damper plate 17 </ b> A is discharged to the outside through the air supply inlet 3 and the duct 22 along the inclined surface 15 a.

The main body box 1 has an air supply passage 7 through which supply air flows and an exhaust air passage 6 through which exhaust flows. The supply air path 7 and the exhaust air path 6 are provided independently of each other so that the supply air and the exhaust air are not mixed. The main body box 1 is provided with a heat exchanger 10 so that heat can be exchanged between the supply air from the supply air passage 7 and the exhaust from the exhaust air passage 6.
The air flowing through the air supply air passage 7 flows from the upstream side through the air supply inlet 3, the humidity sensor 16, the damper unit 17, the heat exchanger 10, the air supply blower 8, and the air supply outlet 4. Further, the air flowing through the exhaust air passage 6 flows from the upstream side through the exhaust air inlet 2, the heat exchanger 10, and the exhaust fan 9.

(Heat exchanger 10)
The heat exchanger 10 exchanges heat between outdoor air introduced into the main body box 1 and indoor air. That is, the heat exchanger 10 performs heat exchange between the supply air that passes through the supply air passage 7 and the exhaust that passes through the exhaust air passage 6. Thus, the heat exchanger 10 has a function of recovering the heat quantity of the exhaust gas with the supply air. The heat exchanger 10 is provided from the first side surface portion 1a side to the second side surface portion 1b side. In addition, an air supply filter 21 that removes dust, dust, and the like contained in the air to be supplied is attached to the heat exchanger 10. In addition, the flow path of the heat exchanger 10 in the supply air path 7 through which the outdoor air flowing into the heat exchanger 10 flows and the flow path of the heat exchanger 10 in the exhaust air path 6 through which the indoor air flow intersect. However, the heat exchanger 10 is configured so that the outdoor air and the indoor air that have flowed in do not mix.

(Air supply filter 21)
The air supply filter 21 collects dust, dust, and the like of air passing through the air supply air passage 7. The air supply filter 21 is attached upstream of the heat exchanger 10 on the air supply air path 7 side. The air supply filter 21 is attached so as to be in close contact with the heat exchanger 10, for example.
By providing the air supply filter 21, it is possible to prevent dust, dust, and the like from entering the heat exchanger 10 and the air supply fan 8, and the flow path of the heat exchanger 10 is clogged. Therefore, it is possible to avoid the heat exchange capability from being reduced or the supply air blower 8 from being broken. Moreover, it can suppress that dust, dust, etc. are discharged | emitted indoors from the air supply blower outlet 4. FIG.

(Air supply fan 8 and exhaust fan 9)
The air supply blower 8 and the exhaust blower 9 are constituted by rotating blades 12, an electric motor 13 for rotating the blades 12, and the like, and take in and discharge air into the main body box 1. The air supply blower 8 is provided at a position facing the third side surface portion 1c, and is provided on the first side surface portion 1a side. Further, the exhaust fan 9 is provided at a position facing the fourth side surface portion 1d, and is provided on the second side surface portion 1b side.

(Damper unit 17)
The damper unit 17 prevents moisture (such as mist) contained in the outdoor air taken into the main body box 1 from flowing into the air supply air path 7 more downstream than itself. The damper unit 17 includes a ventilation member 170 made of, for example, a fiber, a damper plate 17A on which the ventilation member 170 is bonded with an adhesive, and a damper shaft 17B that rotatably supports the damper plate 17A on the main body box 1. And a drive part 17C that rotates the damper shaft 17B to rotate the damper plate 17A, and a link part 17D that connects the damper shaft 17B and the drive part 17C.
The ventilation member 170 is configured by arranging fibers in a mesh shape. For this reason, although mist, rainwater, etc. are received by the mesh-like fiber, since there is a gap between the mesh-like fibers, it has air permeability. The ventilation member 170 is attached to the damper plate 17A, and is provided movably in the supply air passage 7 by the damper plate 17A. As shown in FIGS. 2 and 3, the damper plate 17 </ b> A to which the ventilation member 170 is attached is disposed on the supply air inlet 3 side of the supply air passage 7. Infiltration of fog, rainwater, etc. is more reliably suppressed. The damper unit 17 will be described in detail later.

(Humidity sensor 16)
The humidity sensor 16 detects the humidity of the supply air taken into the main body box 1. The humidity sensor 16 is provided upstream of the damper plate 17 </ b> A of the damper unit 17 in the supply air path 7. More specifically, the humidity sensor 16 is provided on the lower surface portion 15B of the casing 15. If the humidity sensor 16 is provided on the downstream side of the damper plate 17A, it is possible to accurately detect whether or not the humidity is lower than a preset value when the damper plate 17A is closed. Therefore, in order to avoid such a situation, it is provided upstream of the damper plate 17A.
The humidity sensor 16 is electrically connected to a control device (not shown), and the detection result of the humidity sensor 16 is output to the control device. Upon receiving the detection result of the humidity sensor 16, the control device controls the drive unit 17C of the damper unit 17 to rotate the damper plate 17A.

[Explanation of supply and exhaust flow]
In the ventilation device 50 configured as described above, for air conditioning ventilation using the heat exchanger 10, the indoor air is supplied via the duct 22 by operating the air supply fan 8 and the exhaust fan 9. Then, the air is sucked in from the exhaust suction port 2 as indicated by arrow A, passes through the heat exchanger 10 and the exhaust air passage 6 as indicated by arrow B, and is blown out from the exhaust blowout port 5 by the exhaust blower 9 as indicated by arrow C.

Further, the air is sucked from the air supply inlet 3 through the duct 22 (see FIGS. 5 and 6) as indicated by an arrow D, passes through the heat exchanger 10 and the air supply air passage 7 as indicated by the arrow E, and is supplied as a blower 8 is blown out from the air supply outlet 4 as indicated by the arrow F, and is supplied into the room through the duct 22.
At this time, in the heat exchanger 10, heat exchange is performed between the exhaust flow and the supply air flow, and the exhaust heat can be recovered to reduce the cooling / heating load. Control of the rotational speed of the exhaust fan 9 and the air supply fan 8 is performed by a control device (not shown).

[Damper unit 17]
Drawing 4 is an explanatory view in the state where damper unit 17 of ventilation device 50 concerning an embodiment is opened. Drawing 5 is an explanatory view in the state where damper unit 17 of ventilation device 50 concerning an embodiment is closed. Drawing 6 is an explanatory view in the state where damper board 17A of ventilation device 50 concerning an embodiment is opened. FIG. 7 is an explanatory diagram of a state in which the damper plate 17A of the ventilation device 50 according to the embodiment is closed. FIG. 8 is a front view of the damper plate 17A and the damper shaft 17B. 4 and 5 are perspective views in which the lower surface of the main body box 1 is removed and the ventilation device 50 is viewed from the lower surface side. With reference to FIGS. 4-8, the structure and operation | movement of the damper unit 17 are demonstrated.

  The damper plate 17A is a frame having a preset shape. More specifically, the upper portion 17A1, the lower portion 17A2 facing the upper portion 17A1, the first standing portion 17A3 and the second standing portion connected so as to be orthogonal to the upper portion 17A1 and the lower portion 17A2. 17A4, the first connecting portion 17A5 connected to the central portion of the upper portion 17A1 and the central portion of the lower portion 17A2, the central portion of the first upright portion 17A3 and the central portion of the second upright portion 17A4 It is a frame which has 2nd connection part 17A6 to connect. Then, air is passed through the frame (damper plate 17A) constituted by the upper portion 17A1, the lower portion 17A2, the first standing portion 17A3, the second standing portion 17A4, the first connecting portion 17A5 and the second connecting portion 17A6. The member 170 is attached.

  The damper plate 17A is provided with a ventilation member 170 configured by arranging the fibers in a mesh shape. Therefore, it is possible to prevent rainwater, fog, and the like from being scattered downstream of the damper plate 17A and to supply air. Can be passed. The ventilation member 170 means that mist and rainwater are captured by the fibers themselves, but air passes through the gaps between the mesh-like fibers. Thus, even if the damper plate 17A is parallel to the air path surface of the air supply air passage 7 (perpendicular to the air flow direction), the air supply is supplied into the room through the ventilation members 170 of the damper plate 17A. It is like that.

  The shape of the damper plate 17A will be described as an example of a rectangular shape, but is not limited thereto. For example, the shape may be changed according to the shape of the airway surface on which the damper plate 17A is installed. . When the air passage surface of the casing 15 on which the damper plate 17A is installed is circular, the gap formed between the damper plate 17A and the casing 15 can be reduced if the shape of the damper plate 17A is also circular. And the mist can be received more reliably by the damper plate 17A.

The ventilation member 170 is described as an example of a plate-like member configured by arranging fibers in a mesh shape, but is not limited thereto. For example, an aspect in which a plurality of metal wires are provided in a mesh shape may be used. Moreover, the aspect which has porous, such as sponge which has a hygroscopic property so that fog and rainwater can be captured more, may be sufficient. However, the mesh-like fibers are moderately rougher than the sponge or the like, so that air permeability when the damper plate 17A is closed is easily obtained. Moreover, the mesh-processed fiber is less rusted and cheaper than the metal wire. Moreover, it is not limited to mesh shape (lattice shape), You may comprise the ventilation member 170 by arrange | positioning a some fiber in parallel so that arrangement | positioning of a some fiber may become a fence shape.
Furthermore, the damper plate 17A has been described by way of example in which the ventilation member 170 is affixed with an adhesive or the like. However, the damper plate 17A is not limited thereto, and may be fixed with, for example, a nail-like pin member. Good.

The damper shaft 17 </ b> B is provided in parallel to the direction from the lower surface 1 </ b> B side of the main body box 1 toward the top surface 1 </ b> A side of the main body box 1. As shown in FIG. 8, the damper shaft 17 </ b> B is composed of one that protrudes upward from the upper surface side of the upper portion 17 </ b> A <b> 1 and one that protrudes downward from the lower surface side of the lower portion 17 </ b> A <b> 2. ing. The lower end of the damper shaft 17B is rotatably supported by the lower surface portion 15B of the casing 15, and the upper end of the damper shaft 17B is rotatably supported by the upper surface portion 15A of the casing 15.
In the present embodiment, as shown in FIG. 8, the damper shaft 17 </ b> B is provided in parallel to the direction from the lower surface 1 </ b> B side of the main body box 1 to the top surface 1 </ b> A side of the main body box 1. Although described as an example, it is not limited thereto. For example, one of the damper shafts 17B is formed on the first upright portion 17A3, the other is formed on the second upright portion 17A4, and the rotation shaft extends from the first side surface portion 1a side of the main body box 1 to the main body box. You may comprise so that it may become parallel to the direction which goes to the 2nd side part 1b side of the body 1. FIG.

  The drive unit 17C is composed of, for example, a motor, and rotates the damper plate 17A. The drive portion 17C is provided on the lower surface portion 1B of the main body box 1, and is connected to the damper plate 17A via the link component 17D. The drive unit 17 </ b> C is provided in the supply air passage 7 on the downstream side of the damper plate 17 </ b> A and on the upstream side of the heat exchanger 10. The installation position of the drive unit 17C is not limited to this, and may be installed on the upstream side of the damper plate 17A, but fog is applied on the downstream side of the damper plate 17A. Therefore, it is possible to avoid a failure of an electrical component provided in the drive unit 17C.

  The link component 17D has one end connected to the drive unit 17C and the other end connected to the damper plate 17A. The other end side of the link component 17D is connected to a position (see point S in FIG. 8) of the damper plate 17A that is displaced with respect to the damper shaft 17B. More specifically, the link component 17D is connected to the lower portion 17A2 of the damper plate 17A, and is connected to a position shifted from the axis corresponding to the damper shaft 17B in the lower portion 17A2. Accordingly, when the drive unit 17C operates the link component 17D to move the position of the other end side of the link component 17D, the damper plate 17A connected to the other end side rotates about the damper shaft 17B. .

Next, the operation of the damper unit 17 will be described.
When rainwater, fog, or the like is included in the supply air, it is detected by the humidity sensor 16. When the humidity sensor 16 detects that the humidity of the outside air is equal to or higher than a preset value, the control device closes the damper plate 17A so that the air flow direction of the ventilation member 170 and the supply air passage 7 is vertical. The ventilation member 170 is moved so that it becomes. That is, when the humidity sensor 16 detects the high humidity of the outside air, the control device determines that the outside air contains rainwater and mist, closes the damper plate 17A, and places the rainwater downstream of the damper unit 17. Shut off so that fog does not flow.

An example of conditions for closing the damper plate 17A will be described. For example, when the control device determines that the detection result of the humidity sensor 16 is 80% RH or more, the drive unit 17C may be driven to close the damper plate 17A.
When the drive unit 17C is driven, the connecting portion with the damper plate 17A is pushed into the side away from the installation position side of the drive unit 17C by the link component 17D. In this way, when the damper plate 17A is pushed in by the link part 17D, the damper plate 17A rotates in the direction of the arrow G shown in FIG. 6 with the damper shaft 17B as an axis, and shifts from the state of FIG. 6 to the state of FIG. To do. As described above, when the damper plate 17A closes the supply air passage 7, the flow direction of the supply air and the damper plate 17A and the ventilation member 170 become vertical, and supply air is passed through the gap between the meshes of the ventilation member 170. Intrusion of rainwater and mist downstream of the damper unit 17 is suppressed.

An example of conditions for opening the damper plate 17A will be described. For example, when the control device determines that the detection result of the humidity sensor 16 is less than 80% RH, the drive unit 17C may be driven to open the damper plate 17A.
When the drive unit 17C is driven, the connecting portion with the damper plate 17A is pulled by the link component 17D toward the side closer to the installation position side of the drive unit 17C. As described above, when the damper plate 17A is pulled by the link component 17D, the damper plate 17A rotates in the direction of the arrow H shown in FIG. 7 with the damper shaft 17B as an axis, and shifts from the state of FIG. 7 to the state of FIG. To do. Thus, when the damper plate 17A opens the air supply path 7, the damper plate 17A and the ventilation member 170 and the flow direction of the supply air are parallel to each other, so that the passage of the supply air is not hindered.

  Here, when the control device determines that the detection result of the humidity sensor 16 is less than 80% RH, the damper plate 17A is open. In this case, the damper plate 17A, the ventilation member 170, and the air flow are opened. The direction is parallel. The ventilation member 170 attached to the damper plate 17A may adhere to dust, dust, etc. contained in the supply air. The attached dust, dust, etc. are peeled off from the ventilation member 170 by the flow of supply air. Then, the air is collected by the air supply filter 21 on the downstream side. That is, the ventilation member 170 is prevented from being clogged with dust, dust, etc., and the dust, dust, etc. adhering to the ventilation member 170 are released into the room from the air supply outlet 4. Can be suppressed.

In the present embodiment, when the damper plate 17A is closed, the damper plate 17A, the ventilation member 170, and the flow direction of the supply air are perpendicular to each other. However, the present invention is not limited to this. Alternatively, the damper plate 17A, the ventilation member 170, and the flow direction of the air supply may be deviated from vertical. However, when the damper plate 17A and the ventilation member 170 are perpendicular to the flow direction of the supply air, the intrusion of fog and rainwater to the downstream side of the damper unit 17 can be more reliably suppressed.
In the present embodiment, when the damper plate 17A is opened, the damper plate 17A and the ventilation member 170 and the flow direction of the supply air are parallel to each other. However, the present invention is not limited to this. Alternatively, the damper plate 17A, the ventilation member 170, and the flow direction of the air supply may be shifted from parallel. However, the pressure loss of the supply air can be further suppressed when the damper plate 17A and the ventilation member 170 are parallel to the flow direction of the supply air.

[Effects of the ventilation device 50 according to the present embodiment]
Ventilation apparatus 50 according to the present embodiment has a damper plate 17A to which a mesh-like member made of fiber or the like is attached. For this reason, when the damper plate 17A is closed, it is possible to suppress the intrusion of rainwater, mist, etc. while realizing the passage of air supply.

  The ventilation device 50 according to the present embodiment is configured so that the air supply passes through the damper plate 17A even when the damper plate 17A is closed or open. Intrusion of rainwater, fog, etc. can be suppressed while implementing continuous ventilation without performing intermittent operation.

  Moreover, after installing the ventilation apparatus 50 in a building, it may become clear that fog tends to arise in this building. When exchanging with an outdoor hood that suppresses the intrusion of fog, for example, when the installation location is on the third floor or higher of the building, a work burden due to the exchange of the outdoor hood is generated. However, the ventilator 50 according to the present embodiment, when it is found that fog is likely to be generated in the building after being installed in the building, if the damper unit 17 is driven, the fog into the main body box 1 Invasion of rainwater and the like can be suppressed. For this reason, after installing the ventilation apparatus 50 in a building, it can avoid producing work burdens, such as changing to an outdoor hood.

  As the number of ventilations stipulated in the Building Standard Law, for example, it is determined to be 0.3 times / h or 0.5 times / h or more. For this reason, conventionally, in order to suppress fog and the like flowing into the main body box 1 while satisfying the ventilation frequency, it is necessary to stop the air supply blower 8 or to perform intermittent operation. However, since the ventilator 50 according to the present embodiment includes the damper unit 17, the ventilation device 50 can be ventilated without complicated control such as stopping the air supply fan 8 or performing intermittent operation. While satisfying the number of times, fog or the like flowing into the main body box 1 can be suppressed.

  In the present embodiment, a damper shaft 17B is provided on one damper plate 17A, and the damper unit 17 configured so that the damper plate 17A rotates about the damper shaft 17B is described as an example. However, the present invention is not limited thereto. It is not something. For example, the damper unit 17 may be configured to have two damper plates 17A and so-called double doors. That is, one damper plate 17A is rotatably provided on one side of the casing 15 in the left-right direction, and the other damper plate 17A is rotatably provided on the other side of the casing 15 in the left-right direction. Even if it is such an aspect, the effect similar to the ventilator 50 which concerns on this Embodiment can be acquired. However, as described in the present embodiment, the damper unit 17 can be provided at a lower cost if it is configured by one damper plate 17A.

  DESCRIPTION OF SYMBOLS 1 Main body box body, 1A Top surface part, 1B Lower surface part, 1a 1st side surface part, 1b 2nd side surface part, 1c 3rd side surface part, 1d 4th side surface part, 2 Exhaust air inlet, 3 Supply air suction 4 Outlet, 5 Exhaust outlet, 6 Exhaust air passage, 7 Supply air passage, 8 Supply air blower, 9 Exhaust air blower, 10 Heat exchanger, 11 Opening, 12 blades, 13 Electric motor, 14 Maintenance Cover, 15 Casing, 15A Upper surface, 15B Lower surface, 15a Inclined surface, 16 Humidity sensor, 17 Damper unit, 17A Damper plate, 17A1 Upper part, 17A2 Lower part, 17A3 First standing part, 17A4 Second standing part Part, 17A5 first connection part, 17A6 second connection part, 17B damper shaft, 17C drive part, 17D link part, 21 air supply filter, 22 duct, 50 ventilator, 17 Ventilation member.

Claims (9)

A main body box having a supply air passage communicating with the intake suction port and the supply air outlet, and an exhaust air passage communicating with the exhaust suction port and the exhaust outlet;
An air supply blower that is provided in the air supply air passage, takes air into the air supply air passage, and discharges the air to a space to be air-conditioned;
An exhaust fan that is provided in the exhaust air passage, takes air into the exhaust air passage, and discharges the air outside the air-conditioning target space;
A damper unit that is provided movably in the air supply air passage and has a plate-like ventilation member having air permeability;
A humidity sensor for detecting the humidity of the supply air path;
A control device for controlling the damper unit based on the detection result of the humidity sensor and moving the ventilation member;
Ventilator characterized by comprising. The damper unit is
An openable and closable damper plate which is a frame of a preset shape;
The ventilation member attached to the damper plate;
A damper shaft provided on the damper plate such that the damper plate is rotatably supported by the main body box; and
A drive unit for rotating the damper plate;
The ventilation apparatus according to claim 1, further comprising a link part that connects the driving unit and the damper plate. The damper plate is
The ventilation apparatus according to claim 2, wherein the ventilation apparatus is provided on the supply air inlet side in the supply air path. The controller is
If the detection result of the humidity sensor is greater than or equal to a preset value, close the damper plate,
The ventilation device according to claim 2 or 3, wherein when the detection result of the humidity sensor is less than a preset value, the damper plate is opened. The controller is
When the detection result of the humidity sensor is equal to or greater than a preset value, the damper plate is rotated so that the air flow direction of the ventilation member and the supply air passage is vertical,
When the detection result of the humidity sensor is less than a preset value, the damper plate is rotated so that the air flow direction of the ventilation member and the supply air passage is parallel to each other. The ventilation apparatus according to claim 4. The lower surface part which comprises the outline of the lower surface side of the said main body box body inclines below from the attachment position side of the said damper unit to the said air supply inlet side, The any one of Claims 1-5 characterized by the above-mentioned. A ventilation device according to claim 1. The ventilation member is
The ventilation device according to any one of claims 1 to 6, wherein the fibers are arranged in a mesh shape. A heat exchanger provided in the main body box for exchanging heat between the air flowing through the supply air passage and the air flowing through the exhaust air passage;
The heat exchanger includes
The ventilation device according to any one of claims 1 to 7, further comprising a supply air filter that collects dust and dust. The humidity sensor
The ventilation apparatus according to any one of claims 1 to 8, wherein the ventilation apparatus is provided on an upstream side of the damper unit in the supply air passage.

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