JP2018173253A - Blower - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide a blower which inhibits air cleaning effect from being reduced according to an air passage switching state.SOLUTION: A bathroom ventilation dry heater 1A includes: a circulation ventilation fan 2A which suctions air in a bathroom and blows the air; an air passage switching damper 6A which switches a passage of the air suctioned by the circulation ventilation fan 2A; and an ion generator 10 which discharges air cleaning elements for cleaning the air blown into the bathroom by the circulation ventilation fan 2A. The ion generator 10 is provided at the air passage switching damper 6A.SELECTED DRAWING: Figure 1

Description

  The present invention relates to a blower that is installed in a bathroom or the like and blows out air corresponding to warm air or room temperature.

  2. Description of the Related Art Conventionally, there has been proposed a blower device that is installed on a ceiling of a bathroom or the like and blows out hot air or air according to room temperature to realize functions such as heating a room and drying an object to be dried. Many of such blowers have a function of ventilating indoor air to the outside, and are called bathroom ventilation dryers / heaters.

  The bathroom ventilation dryer is equipped with a suction port through which air in the bathroom is sucked in, a blow-out port that blows air into the bathroom, a ventilation blow-out port that exhausts air sucked from the suction port to the outside, a blow-out port and a ventilation blow-out port. Is provided on the ceiling of the bathroom so that the air inlet and the outlet face the interior of the bathroom. Patent Literature 1 describes a bathroom ventilation drying / heating machine that generates ions and supplies the bathroom to the bathroom in order to clean the air in the bathroom.

JP2015-148347A

  In a conventional bathroom ventilation dryer, even if an air purification factor such as ions is generated to clean the air, the air purification factor is discharged from the ventilation outlet to the outside of the bathroom depending on the switching condition of the air flow path. There was a problem that the effect of cleaning the air in the bathroom was lowered.

  The present invention has been made to solve such a problem, and an object of the present invention is to provide a blower that suppresses the reduction of the air cleaning effect depending on the switching state of the air flow path.

  In order to solve the above-described problems, the present invention cleans the air blown into the room by the blowing means that sucks and blows out the air in the room, a movable member that switches a flow path of the air sucked by the blowing means, and the blowing means. An air cleaning factor generator that discharges an air cleaning factor, and the air cleaning factor generator is provided on a movable member.

  In the present invention, since the air purifying factor generator is provided on the movable member, the air purifying factor generator releases the air purifying factor toward the air blown into the room by the air blowing means even if the movable member is moved.

  In the present invention, even if the movable member is moved, the cleaning effect of the air blown into the room by the blowing means can be maintained.

It is a block diagram which shows an example of the bathroom ventilation drying heater of this Embodiment. It is a block diagram which shows an example of the bathroom ventilation drying heater of this Embodiment. It is a block diagram which shows an example of the bathroom ventilation drying heater of this Embodiment. It is a block diagram which shows the example of installation of the bathroom ventilation drying heater of this Embodiment. It is a block diagram which shows the example of a control function of the bathroom ventilation drying heater of this Embodiment. It is explanatory drawing which shows the operation | movement of the air path switching damper in the bathroom ventilation drying heater of this Embodiment. It is explanatory drawing which shows the operation | movement of the air path switching damper in the bathroom ventilation drying heater of this Embodiment. It is explanatory drawing which shows the operation | movement of the air path switching damper in the bathroom ventilation drying heater of this Embodiment. It is explanatory drawing which shows the flow of the air in the bathroom in the bathroom ventilation drying heater of this Embodiment. It is a block diagram which shows the modification of the air path switching damper of this Embodiment.

  Hereinafter, with reference to drawings, an embodiment of a bathroom ventilation drying heater as a blower of the present invention will be described.

<Configuration example of bathroom ventilation dryer / heater of this embodiment>
1 to 3 are configuration diagrams showing an example of a bathroom ventilation dryer / heater according to the present embodiment, FIG. 1 is a side view showing the internal configuration of the bathroom ventilation dryer / heater, and FIG. 2 is a bottom view. FIG. FIG. 3 is a plan view of the front panel attached. FIG. 4 is a configuration diagram illustrating an installation example of the bathroom ventilation dryer / heater according to the present embodiment. FIG. 5 is a block diagram illustrating an example of a control function of the bathroom ventilation dryer / heater according to the present embodiment.

  1 A of bathroom ventilation drying heaters of this Embodiment are attached to the ceiling of the bathroom 100 with the main-body part 3A which has the circulation ventilation fan 2A exposed the front panel 4A.

  The bathroom ventilation dryer 1A has a circulation ventilation inlet 20A through which air in the bathroom 100 is sucked by a circulation ventilation fan 2A as a blowing means for sucking and blowing air, and a heater 5, and the heater 5 is driven. The first air outlet 21A from which the warm air and the heater 5 are not driven and the air blown according to the room temperature in the bathroom 100 is blown out, and the second air outlet 22A from which the air that stirs the air in the bathroom 100 is blown out. Is provided.

  In addition, the bathroom ventilation dryer 1A includes a ventilation outlet 23A that exhausts air sucked from the circulation ventilation inlet 20A by the circulation ventilation fan 2A to the outside. Furthermore, the bathroom ventilation dryer 1A is a movable member that switches an air flow path (hereinafter referred to as an air flow path) between the first air outlet 21A, the second air outlet 22A, and the ventilation air outlet 23A. An air path switching damper 6A is provided. In the bathroom ventilation dryer / heater 1 </ b> A, the air path switching damper 6 </ b> A includes an air purification factor generator that releases an air purification factor that purifies the air blown into the bathroom 100.

  The air path switching damper 6 </ b> A forms an air path that communicates with the air outlet from which air is blown into the bathroom 100. For example, when the air path switching damper 6A forms an air path communicating with the first air outlet 21A, the air purification factor generator cleans the air blown into the bathroom 100 from the first air outlet 21A. Further, for example, when the air path switching damper 6A forms an air path that communicates with the first air outlet 21A and the second air outlet 22A, the air purification factor generator is connected to the first air outlet 21A and the second air outlet 21A. The air blown into the bathroom 100 from the air outlet 22A is cleaned.

  That is, even if the air path switching damper 6A is moved to switch the air path, the air purification factor generator releases the air purification factor toward the air blown into the bathroom 100. The cleaning effect of the air blown out can be maintained.

  Below, the detail of 1 A of bathroom ventilation drying heaters is demonstrated. The circulation ventilation fan 2A includes a multiblade impeller 25A, a circulation ventilation fan motor 26A that drives the impeller 25A, and a circulation ventilation fan case 27A that forms an air passage. The impeller 25A is driven and rotated by the circulation ventilation fan motor 26A to generate a flow of air blown in the centrifugal direction from the inner side to the outer peripheral side.

  The circulation ventilation fan case 27A rectifies air blown in the centrifugal direction of the impeller 25A in a shape combining a circular portion along the outer periphery of the impeller 25A and a portion along the tangential direction of the impeller 25A. Then, as shown by the arrow A1, a flow of air blown out along the tangential direction of the impeller 25A is generated.

  The circulation ventilation fan 2A is configured in such a manner that the direction of the rotation shaft of the impeller 25A is along the vertical direction in a state where the bathroom ventilation dryer 1A is installed on the ceiling of the bathroom which is a predetermined installation location.

  As a result, the circulation ventilation fan case 27A forms a blowout air passage 28A through which the circulation ventilation fan 2A blows air sucked from below along the rotation axis of the impeller 25A in the tangential direction of the impeller 25A.

  The circulation ventilation fan 2A includes a circulation ventilation inlet 20A through which air is sucked on the lower surface of the circulation ventilation fan case 27A. Further, the circulation ventilation fan 2A has air heated by driving the heater 5 on the lower surface of the circulation ventilation fan case 27A or air corresponding to the temperature in the bathroom 100 by deactivating the heater 5. A first air outlet 21A is provided.

  Furthermore, the circulation ventilation fan 2A includes a second air outlet 22A through which air for stirring the bathroom 100 is blown out on the lower surface of the circulation ventilation fan case 27A. The circulation ventilation fan 2A includes a ventilation outlet 23A through which air is blown out to the outside on the side surface of the circulation ventilation fan case 27A.

  The circulation ventilation suction port 20A is configured by providing a circular opening called a bell mouth below the rotation axis of the impeller 25A. 21 A of 1st blower outlets are comprised by providing the rectangular opening which made the short side the side along the blowing direction of the air by the circulation ventilation fan case 27A in the lower surface of the blowing air path 28A.

  The second air outlet 22A circulates a rectangular opening having a short side along the air blowing direction by the circulation ventilation fan case 27A on the lower surface of the air outlet 28A with respect to the first air outlet 21A. It is provided on the opposite side of the ventilation inlet 20A.

  The blowout air passage 28A configured by the circulation ventilation fan case 27A is widened at a portion where the first air outlet 21A and the second air outlet 22A are provided, and is narrowed at a portion where the ventilation air outlet 23A is provided. In the first air outlet 21A and the second air outlet 22A, the long side intersecting the side along the air blowing direction by the circulation ventilation fan case 27A is adjusted to the length in the width direction of the main body 3A. .

  The first air outlet 21A and the second air outlet 22A are constituted by an air passage forming frame body 50A provided on the lower surface of the circulation ventilation fan case 27A. The first air outlet 21A and the second air outlet 22A are partitioned by a partition member 51A provided inside the air passage forming frame body 50A, and the heated air blowing air through which the air blown from the first air outlet 21A passes. A stirring air blowing air passage through which the air and the air blown out from the second air outlet 22A pass is formed.

  The air path switching damper 6A receives the driving force of the damper motor 64A and rotates about the shaft 60A as a fulcrum. By this rotation, the air path switching damper 6A is in a circulation position that is a first position indicated by a solid line in FIG. 1, a circulation ventilation position that is a second position indicated by a broken line, and a third position indicated by a one-dot chain line. The first air outlet 21A, the second air outlet 22A, and the ventilation air outlet 23A are opened and closed by being displaced to a certain ventilation position.

  The air path switching damper 6A is provided with a shaft 60A for opening / closing operation by rotation. The shaft 60A has a predetermined distance from the branch part 52A upstream from the branch part 52A between the first outlet 21A and the second outlet 22A formed by the partition member 51A in the air flow direction. Open and provided. Further, the shaft 60A is provided in the vicinity of the height of the lower end of the ventilation outlet 23A. Thereby, when the air path switching damper 6A is in the circulation ventilation position and the ventilation position, the amount of projection of the air path switching damper 6A to the air path communicating with the ventilation air outlet 23A is reduced, and the air communicating with the ventilation air outlet 23A is reduced. Ventilation resistance on the road is reduced.

  In the air path switching damper 6A, a portion upstream of the shaft 60A with respect to the direction in which the air flows is in a direction to open and close the first air outlet 21A and the ventilation air outlet 23A by a rotational operation with the shaft 60A as a fulcrum. Displace. Further, in the air path switching damper 6A, a portion downstream of the shaft 60A with respect to the air flow direction is displaced in a direction to open and close the second outlet 22A by a rotational operation with the shaft 60A as a fulcrum.

  Thereby, the air path switching damper 6A is a part extending upstream from the shaft 60A in the air flow direction, and mainly switches the air path between the first air outlet 21A and the ventilation air outlet 23A. At the same time, a main air path switching unit 61A for switching the opening degree of the ventilation outlet 23A is configured. The air path switching damper 6A is a portion extending downstream from the shaft 60A with respect to the direction of air flow. The air path switching damper 6A mainly opens and closes the second air outlet 22A, and the air path switching damper on the inner surface. The air passage to the first air outlet 21A, the air passage to the first air outlet 21A, and the second air outlet 22A are formed according to the opening degree of 6A, and the air passage to the ventilation air outlet 23A is formed on the outer surface. An auxiliary air passage switching unit 62A in which an air passage is formed is configured. Furthermore, the air path switching damper 6A extends along the direction of the rotation operation with the shaft 60A as a fulcrum on the tip side of the auxiliary air path switching unit 62A, and the second air outlet 22A with respect to the ventilation air outlet 23A. A backflow prevention unit 63A is provided.

  The bathroom ventilation dryer 1A includes an ion generator 10 as an example of an air purifying factor generator that purifies air blown into the bathroom 100 in the air path switching damper 6A. The ion generator 10 emits an air cleaning factor such as ions containing both positive ions and negative ions or at least one of positive ions and negative ions. In the ion generator 10, when the air path switching damper 6 </ b> A is set to the circulation position or the circulation ventilation position, the discharge surface 10 </ b> A that is a surface on the side that discharges the air purification factor is exposed toward the air blown into the bathroom 100. .

The principle of generation of positive ions and negative ions is that corona discharge causes oxygen or moisture in the air to be ionized by ionization, and H ⁺ (H ₂ O) _m (m is an arbitrary natural number) and O ₂ ⁻ (H ₂ O) _n (n is an arbitrary natural number) emits ions mainly.

These H ⁺ (H ₂ O) _m and O ₂ ⁻ (H ₂ O) _n adhere to the surface of the floating bacteria and chemically react to generate H ₂ O ₂ or .OH as an active species. Since H ₂ O ₂ or .OH exhibits very strong activity, they can surround and remove airborne bacteria. Here, .OH is one kind of active species, and represents radical OH.

  Thereby, in the bathroom ventilation / drying / heating machine 1A, the circulation ventilation fan 2A is linked with the operation of the circulation ventilation fan 2A to generate approximately the same number of positive ions and negative ions, and air is circulated by blowing air containing approximately the same number of positive ions and negative ions By removing both airborne bacteria contained in the air and airborne bacteria in the bathroom, generation of mold and the like can be suppressed. Note that ions may be generated by the ion generator 10 using only positive ions or only negative ions, and other methods may be used instead of corona discharge. Further, as means for removing both the floating bacteria contained in the circulating air and the floating bacteria in the bathroom air, other air treatment means may be used instead of ions. In addition, the air purification factor generator may use spraying means for spraying silver ions, ozone, deodorizing and sterilizing agents, agents that promote the moisturizing effect, etc., and adheres to airborne bacteria or clothing in the air. To release bacteria that suppress the growth of bacteria, those that decompose allergens and harmful substances, those that remove bacteria and viruses, those that have a deodorizing and deodorizing effect, and functional factors that have a moisturizing effect As long as it is an air processing means for giving a specific function to the air, any form may be used.

  The air path switching damper 6 </ b> A is provided with a cover 10 </ b> B as a rectifying member that covers the ion generator 10. The cover 10 </ b> B covers a portion of the ion generator 10 that protrudes on the opposite side of the air cleaner switching surface 6 </ b> A from the air path switching damper 6 </ b> A. The cover 10B protects the ion generator 10 from moisture or the like contained in the air sucked from the bathroom 100. Further, the cover 10B has an upstream surface that is inclined with respect to the air flow direction with respect to the air path switching damper 6A, and this inclination guides the air flow to flow from the upstream side to the downstream side. .

  In the bathroom ventilation dryer 1A, when the position of the air path switching damper 6A is the circulation position, the tip of the main air path switching section 61A that is one end of the air path switching damper 6A is connected to the circulation ventilation fan case 27A. Touch the upper inner surface. The tip of the sub air path switching unit 62A that is the other end of the air path switching damper 6A is in contact with the branching unit 52A. Furthermore, the backflow prevention unit 63A closes the second air outlet 22A with respect to the ventilation air outlet 23A. As a result, the first air outlet 21A is opened, the second air outlet 22A and the ventilation air outlet 23A are closed, and a circulation air passage communicating from the circulation ventilation inlet 20A to the first air outlet 21A is formed. .

  Moreover, 10 A of discharge surfaces of the air cleaner factor of the ion generator 10 oppose the blowing air path 28A and the 1st blower outlet 21A, and the cover 10B opposes the ventilation blower outlet 23A.

  When the position of the air path switching damper 6A becomes the circulation position, the vicinity of the front end of the main air path switching unit 61A is oriented along the inner surface of the circulation ventilation fan case 27A. As a result, even if the air path switching damper 6A is slightly opened from the circulation position, air hardly passes and airtightness is maintained.

  Note that the air path switching damper 6A and the circulation ventilation fan case 27A or the branching portion 52A are not only in close contact with each other, but also in a state where a certain amount of air can pass and a certain amount of air can be maintained. Good.

  In the state where the position of the air path switching damper 6A is the circulation position, the end of the main air path switching unit 61A and the circulation ventilation fan case 27A and the auxiliary air path switching unit 62A and the circulation ventilation fan are thus formed. By providing a predetermined gap between the case 27A and the air path switching damper 6A and the circulation ventilation fan case 27A, it is possible to prevent the air flow switching damper 6A and the circulation ventilation fan case 27A from being fixed due to components contained in water vapor, bathing agent, or the like. .

  In the bathroom ventilation dryer 1A, when the position of the air path switching damper 6A is rotated from the circulation position about the shaft 60A to the circulatory ventilation position, the main air path switching section 61A on the upstream side of the shaft 60A moves downward. The one end of the air path switching damper 6A is located near the middle of the blowout air path 28A. The auxiliary air passage switching unit 62A on the downstream side of the shaft 60A moves upward away from the branching unit 52A. As a result, both the first air outlet 21A and the second air outlet 22A and the ventilation air outlet 23A are opened, the circulation air passage communicating with the first air outlet 21A and the second air outlet 22A, and the circulation Both ventilation air paths communicating from the ventilation inlet 20A to the ventilation outlet 23A are formed.

  The discharge surface 10A of the air purifying factor of the ion generator 10 faces the blowout air passage 28A, the first air outlet 21A, and the second air outlet 22A, and the discharge surface 10A is opposed to the air passage switching damper 6A. A cover 10B provided on the opposite side faces the ventilation outlet 23A.

  In the bathroom ventilation dryer 1A, when the position of the air path switching damper 6A is rotated from the circulation ventilation position to the ventilation position by using the shaft 60A as a fulcrum, the main air path switching unit 61A on the upstream side of the shaft 60A moves downward. The one end of the air path switching damper 6A comes into contact with the lower inner surface of the circulation ventilation fan case 27A. Further, the secondary air path switching unit 62A on the downstream side of the shaft 60A moves upward, and the other end of the air path switching damper 6A is in contact with the inner surface of the circulation ventilation fan case 27A below the ventilation outlet 23A. As a result, the ventilation outlet 23A is opened, the first outlet 21A and the second outlet 22A are closed, and a ventilation air passage is formed. The discharge surface 10A of the air cleaner factor of the ion generator 10 faces the first air outlet 21A and the second air outlet 22A, and the cover 10B faces the air outlet 28A.

  Even when the position of the air path switching damper 6A is set to the ventilation position, between the end of the main air path switching section 61A and the circulation ventilation fan case 27A, and between the auxiliary air path switching section 62A and the circulation ventilation fan case 27A. By providing a predetermined gap that maintains a certain airtightness therebetween, the air path switching damper 6A and the circulation ventilation fan case 27A are fixed by water vapor contained in the air, components contained in the bathing agent, or the like. It is suppressed.

  The heater 5 is an example of a heating unit. In this example, the heater 5 is a PTC heater, and is provided in a heated air blowing air passage through which air blown from the first blower outlet 21A passes. When the heater 5 is driven and energized, the heater 5 is heated to heat the air passing through the first air outlet 21A, and hot air is blown out from the first air outlet 21A.

  The first air outlet 21A and the second air outlet 22A are partitioned by a partition member 51A, and the air blown from the second air outlet 22A does not pass through the heater 5. In this example, the heater 5 driven by electricity has been described as an example of the heating means. However, a heater such as a heat exchanger using warm water may be used.

  The main body 3A includes a main body chassis 30A that constitutes the circulation ventilation fan case 27A and a metal case 31A that covers the main body chassis 30A. The main body chassis 30A is made of a resin material, and a circulation ventilation fan case 27A covered with a metal case 31A and a flange portion 32A protruding outward from the peripheral edge of the lower end of the main body portion 3A are integrally formed.

  The main body chassis 30A has a lower cover 33A attached to the lower surface exposed from the metal case 31A. In the circulation ventilation fan 2A, a circulation ventilation suction port 20A, a first air outlet 21A, and a second air outlet 22A are provided in the lower cover 33A, and an air passage forming frame body 50A is attached to the lower cover 33A.

  The metal case 31A has an opening facing the ventilation outlet 23A of the circulation ventilation fan 2A, and an exhaust duct joint 34A communicating with the ventilation outlet 23A is attached to the side surface.

  As for bathroom ventilation drying heating machine 1A, front panel 4A is attached to the undersurface of body part 3A. The front panel 4A opens a lower surface facing the circulation ventilation inlet 20A of the circulation ventilation fan 2A to form an inlet grill 40A.

  Further, the front panel 4A opens a lower surface facing the first air outlet 21A of the circulation ventilation fan 2A to form a first air outlet grill 41A, and a lower surface facing the second air outlet 22A. A second air outlet grille 42A is formed by opening.

  41 A of 1st blower outlet grilles are comprised by the rectangular opening which lengthened the length along the transversal direction which is a direction along one edge | side of the main-body part 3A. Moreover, the 2nd blower outlet grille 42A is a rectangular opening which lengthened the length along the transversal direction which is a direction along one side of the main-body part 3A similarly to the 1st blower outlet grille 41A. Composed.

  The first outlet grille 41A is provided with a current plate so that air is blown out along the longitudinal direction. The second outlet grille 42A is blown out toward the outside of the main body 3A opposite to the first outlet grille 41A along the short direction parallel to the first outlet grille 41A. As shown, a rectifying plate 43A is provided.

  FIG. 5 is a block diagram showing an example of the control function of the bathroom ventilation dryer / heater of this embodiment. The bathroom ventilation dryer 1A includes a control unit 81A composed of a CPU, a memory, and the like, a damper motor 64A that drives the ion generator 10, the circulation ventilation fan motor 26A, and the air path switching damper 6A described in FIG. The heater 5 is connected to the operation unit 82 operated by the user. The operation unit 82 is an example of an operation means, and is attached to, for example, a wall surface of a bathroom changing room adjacent to the bathroom 100 by a remote control device independent of the main body of the bathroom ventilation dryer 1A. In addition, although not shown in figure, 1 A of bathroom ventilation drying heaters may be provided with a temperature sensor, and 81 A of control parts may control each part according to the temperature information detected with the temperature sensor. Although not shown, the bathroom ventilation dryer 1A includes a louver that changes the blowing direction of the air blown from at least one of the first air outlet 21A and the second air outlet 22A, and the control unit 81A has a louver. By controlling this, the blowing direction of the air blown out from at least one of the first blower outlet 21A and the second blower outlet 22A may be controlled.

  The controller 81A executes various operation modes by a program stored in a memory or the like (not shown). Although various operation modes are not described in detail, each unit connected to the control unit 81A is controlled to operate.

  These operation modes are selected by the user operating the operation unit 82 or the like. Based on the program for executing the selected operation mode, the control unit 81A drives the circulation ventilation fan motor 26A to control the fan rotation speed of the circulation ventilation fan 2A. Further, the heater 5 is driven to control the output of the heater 5. Further, the damper motor 64A is controlled to control the opening degree of the air path switching damper 6A. Moreover, the ion generator 10 is driven and the presence or absence of the generation | occurrence | production of an air purifying factor, and the generation amount of an air purifying factor are controlled.

  In the bathroom ventilation dryer 1A, the air volume of the air blown from the first air outlet 21A and the second air outlet 22A is controlled by controlling the fan rotation speed of the circulation ventilation fan 2A. Further, by controlling the output of the heater 5, the temperature of the air blown out from the first outlet 21A is controlled. Furthermore, by controlling the opening degree of the air path switching damper 6A, the air path through which air is blown out and the air volume in each air path are controlled.

<Installation example of bathroom ventilation drying heater of this embodiment>
Next, with reference to each figure, the installation example of 1 A of bathroom ventilation drying heaters of this Embodiment is demonstrated.

  As shown in FIG. 4, the bathroom ventilation dryer 1 </ b> A is installed on the ceiling panel 101 of the bathroom 100. The ceiling panel 101 of the bathroom 100 is formed with an opening to which the main body 3A of the bathroom ventilation dryer 1A is attached. For example, the bathroom ventilation dryer 1A has a flange portion 32A provided on the back of the ceiling with a screw (not shown). It is attached to the ceiling panel 101 in a form fixed to the reinforcing member.

  The bathroom ventilation dryer / heater 1A has a front panel 4A attached to the lower surface of the main body 3A, and an inlet grill 40A, a first outlet grill 41A, and a second outlet grill 42A of the front panel 4A, It is arranged facing the bathroom 100.

  In the bathroom ventilation dryer 1A installed on the ceiling panel 101 of the bathroom 100, the exhaust duct 102 is attached to the exhaust duct joint 34A of the main body 3A. The exhaust duct 102 is connected to an outdoor grill 102a attached to an outer wall of a building (not shown) where the bathroom 100 is installed, and the bathroom ventilation / drying heater 1A is connected to the outdoors via the exhaust duct 102.

  The bathroom 100 includes a bathtub 103 and a washing place 104. The bathtub 103 is generally rectangular, and the bathtub 103 and the washing place 104 are arranged along the short direction of the bathtub 103.

  The bathroom 100 includes a land pipe 105 that is a clothes-drying member at the top of the bathtub 103. The land pipe 105 extends along the longitudinal direction of the bathtub 103 and is attached between the opposing wall surfaces 106 a and 106 b of the bathroom 100.

  In addition, the number of the land re-pipe 105 installed in the bathroom 100 is about one or two. In this example, an example in which one land re-pipe 105 is arranged is shown. Further, the clothes drying member is not limited to a pipe-shaped member, and may be a string or other members as long as an object to be dried such as laundry can be dried.

  The bathroom ventilation dryer 1A is installed in the upper part of the bathtub 103 so that the longitudinal direction of the first outlet grille 41A and the second outlet grille 42A is orthogonal to the longitudinal direction of the land pipe 105. Is done.

  Thereby, in the bathroom ventilation drying / heating machine 1 </ b> A, the air blown out from the first outlet grille 41 </ b> A mainly spreads in a direction orthogonal to the land pipe 105. On the other hand, the air blown out from the second outlet grille 42A is directed to the wall surface 106a of the bathroom 100 on the side where the second outlet grille 42A is provided.

<Operation example of bathroom ventilation dryer / heater of this embodiment>
6-8 is explanatory drawing which shows operation | movement of the air-path switching damper in the bathroom ventilation drying heater of this Embodiment, FIG. 9 is the flow of the air in the bathroom in the bathroom ventilation drying heater of this Embodiment. Next, with reference to each figure, the operation example of 1 A of bathroom ventilation drying heaters of this Embodiment is demonstrated. Hereinafter, it is assumed that the control unit 81A operates each unit according to various operation modes selected by the user using the operation unit 82 illustrated in FIG.

  As shown in FIG. 6, when the air path switching damper 6A is positioned at the circulation position, the heater 5 is energized, and the circulation ventilation fan motor 26A is driven to rotate the impeller 25A. As the impeller 25A rotates, air in the bathroom 100 is sucked into the circulation ventilation suction port 20A from the suction port grill 40A of the front panel 4A.

  Since the air path switching damper 6A is in the circulation position, a circulation air path that communicates from the circulation ventilation inlet 20A to the first air outlet 21A is formed in the blowout air path 28A. Almost all of the air in the bathroom 100 sucked from the circulation ventilation inlet 20A flows to the first outlet 21A. The air flowing through the first air outlet 21A is heated by the heater 5 so that warm air is blown out from the first air outlet grill 41A of the front panel 4A.

  When the position of the air path switching damper 6A is in the circulation position, the air purification factor released by the ion generator 10 is sucked from the circulation ventilation inlet 20A and touches the air passing through the blowout air path 28A. Therefore, the air passing through the blowout air passage 28A is blown out from the first air outlet 21A in a state including an air cleansing factor. That is, the ion generator 10 can clean the air blown into the bathroom 100 from the first air outlet 21A.

  When the air path switching damper 6A is in the circulation position, the air in the bathroom 100 is not ventilated. At this time, the ventilation outlet 23 </ b> A is blocked by the air path switching damper 6 </ b> A, so that air containing an air cleaning factor is not discharged outside the bathroom 100. Therefore, 1 A of bathroom ventilation drying heaters can blow out in the bathroom 100, without reducing the density | concentration of the air purifying factor which the ion generator 10 generate | occur | produced.

  Further, when the air path switching damper 6A is in the circulation position, the second air outlet 22A is blocked by the backflow prevention portion 63A, so that unheated air is blown out without passing through the heater 5, or outside air is blown into the bathroom. It is possible to prevent backflow into 100.

  As shown in FIG. 7, when the air path switching damper 6A is positioned at the circulation ventilation position, the heater 5 is energized and the circulation ventilation fan motor 26A is driven to rotate the impeller 25A. When the impeller 25A rotates, air in the bathroom 100 is sucked into the circulation ventilation suction port 20A from the suction port grill 40A of the front panel 4A.

  Since the air path switching damper 6A is in the circulation ventilation position, in the blowout air path 28A, a circulation air path communicating from the circulation ventilation inlet 20A to the first outlet 21A and the second outlet 22A, and the circulation ventilation inlet Both ventilation air paths communicating from 20A to the ventilation outlet 23A are formed. Thereby, the air in the bathroom 100 sucked from the circulation ventilation suction port 20A by the rotation of the impeller 25A is directed to the first air outlet 21A and the second air outlet 22A and to the ventilation air outlet 23A. It is shunted in the direction.

  Part of the diverted air flows to the first air outlet 21A and the second air outlet 22A in a state including an air purifying factor. The air flowing through the first air outlet 21A is heated by the heater 5 and is then blown out as hot air HA from the first air outlet grill 41A of the front panel 4A as shown in FIG. 9A. Since the air flowing through the second air outlet 22A does not pass through the heater 5, it is blown out as air A corresponding to the room temperature from the second air outlet grill 42A of the front panel 4A.

  Further, the remaining air in the bathroom 100 sucked from the circulation ventilation inlet 20A flows to the ventilation outlet 23A, passes through the exhaust duct 102, and is exhausted to the outside as the exhaust EA from the outdoor grill 102a.

  Since the ion generator 10 exposes the air purification factor discharge surface 10A to the circulation air passage, the air purification factor released by the ion generator 10 flows through the blowout air passage 28A to the first air outlet 21A. And the air flowing to the second outlet 22A is touched. Therefore, the air passing through the blowout air passage 28A is blown out from the first air outlet 21A and the second air outlet 22A in a state including an air cleansing factor. That is, the ion generator 10 can clean the air blown into the bathroom 100 from the first air outlet 21A and the second air outlet 22A.

  On the other hand, the cover 10B provided on the opposite side of the discharge surface 10A is opposed to the air path switching damper 6A in the ventilation air path communicating from the circulation ventilation inlet 20A to the ventilation outlet 23A. The air purifying factor released from does not touch the air discharged from the ventilation outlet 23A after blowing out in the tangential direction of the impeller 25A. Therefore, the air containing an air purifying factor is not discharged out of the bathroom 100 from the ventilation outlet 23A. Therefore, 1 A of bathroom ventilation drying heaters can blow out in the bathroom 100, without reducing the density | concentration of the air purifying factor which the ion generator 10 generate | occur | produced.

  When the air passage switching damper 6A is in the circulation ventilation position, a part of the air in the bathroom 100 sucked from the circulation ventilation suction port 20A flows to the outside of the air passage switching damper 6A and is exhausted. The amount of air blown into the bathroom 100 is smaller than when 6A is in the circulation position. However, since the ion generator 10 is provided in the air path switching damper 6A, when the air path switching damper 6A is rotated, the angle at which the ion generator 10 releases the air cleansing factor is also the direction toward the first air outlet 21A. To the direction toward the first air outlet 21A and the second air outlet 22A. Therefore, even if the air path switching damper 6A is displaced from the circulation position to the circulation ventilation position, the amount of the air purification factor blown into the bathroom 100 can be maintained.

  The flow of air in the bathroom 100 when the air path switching damper 6A is in the circulation ventilation position will be described with reference to FIG. The air A blown out from the second outlet grille 42A is in a state containing an air cleansing factor released by the ion generator 10, and the second airflow is discharged from the first outlet grille 41A by the rectifying plate 43A. It is directed to the wall surface 106a of the bathroom 100 on the side where the air outlet grille 42A is provided.

  Thereby, the air A blown out from the second outlet grille 42A is applied to one wall surface 106a of the bathroom 100 and flows downward along the wall surface 106a as indicated by an arrow A2. The air flowing downward along the wall surface 106a flows in the vicinity of the lower layer of the bathroom 100 mainly toward the other wall surface 106b, as indicated by an arrow A3.

  In the bathroom ventilation dryer 1A, the air RA sucked from the suction grill 40A causes a flow of circulating air in the bathroom 100, so the air flowing in the vicinity of the lower layer of the bathroom 100 toward the other wall surface 106b. Flows upward along the wall surface 106b as indicated by an arrow A4, and is sucked from the suction grill 40A.

  As described above, in the bathroom ventilation dryer 1A, the air blown from the second outlet grille 42A is directed downward along the one wall surface 106a of the bathroom 100, and the vicinity of the lower layer of the bathroom 100 is moved to the other wall surface 106b. And an upward air flow is generated along the other wall surface 106b.

  The air blown from the first blower outlet grill 41A of the bathroom ventilation dryer / heater 1A is warm air HA heated by the heater 5 and the relative humidity is lowered, so that the air blown out from the second blower outlet grill 42A. Lighter than the air used.

  For this reason, the air blown out from the second blowout grille 42A, which is heavier than the air blown out from the first blowout grille 41A, flows to the lower layer of the bathroom 100, and the air is agitated throughout the bathroom 100. Wind flow occurs. Thereby, since the air containing an air purifying factor can be circulated in the whole in the bathroom 100, the air in the whole bathroom 100 can be cleaned.

  Although the case where the air path switching damper 6A is at the circulation ventilation position and the heater 5 is driven at the same time as the circulation ventilation fan 2A is started to drive the warm air HA from the beginning of the operation has been described, the invention is not limited thereto. For example, the air flow switching damper 6A may be placed in the circulation ventilation position, and the circulation ventilation fan 2A may be driven while the heater 5 is not driven. In the beginning of operation, the heater 5 is not driven and air blown according to room temperature is blown out. After a predetermined time has elapsed, the heater 5 may be driven to blow out hot air. When the driving of the heater 5 is stopped or delayed, the energy required for driving the bathroom ventilation dryer 1A can be reduced.

  In this case, in the bathroom ventilation dryer 1A, as shown in FIG. 9B, unheated air CA is blown out from the first outlet grill 41A. The air A blown out from the second outlet grille 42A is directed downward along one wall surface 106a of the bathroom 100, is directed near the lower layer of the bathroom 100 toward the other wall surface 106b, and is moved upward along the other wall surface 106b. A flow of air toward the Accordingly, since the air CA and the air A circulate in the bathroom 100, a flow of air for stirring the air can be generated in the entire bathroom 100. In the bathroom 100, the first blowing is performed. Even in a place where the air CA blown from the outlet grille 41A is difficult to hit directly, an air flow can be generated.

  As shown in FIG. 8, when the air path switching damper 6A is positioned at the ventilation position, the heater 5 is not driven and the circulation ventilation fan motor 26A is driven to rotate the impeller 25A. As the impeller 25A rotates, air in the bathroom 100 is sucked into the circulation ventilation suction port 20A from the suction port grill 40A of the front panel 4A.

  Since the air path switching damper 6A is in the ventilation position, the first air outlet 21A and the second air outlet 22A are closed, and substantially the entire amount of air in the bathroom 100 sucked from the circulation ventilation air inlet 20A is the ventilation air outlet. It flows to 23A and is exhausted outdoors.

  If the position of the air path switching damper 6A is the ventilation position, the air purifying factor released by the ion generator 10 does not touch the air passing through the blowout air path 28A. Therefore, the ventilation air outlet 23A includes an air purifying factor. There is no air exhausted. Therefore, when the air path switching damper 6A is in the ventilation position, it is preferable to stop the release of the air purifying factor by the ion generator 10 in order to suppress the consumption of the ion generator 10. Further, even when the air path switching damper 6A is in the circulation position or the circulation ventilation position, the ion generator 10 may be stopped as necessary to suppress the consumption of the ion generator 10.

  As described above, in the bathroom ventilation dryer 1A of the present embodiment, the air purification factor of the ion generator 10 is formed in the circulation air passage formed by setting the air passage switching damper 6A to the circulation position or the circulation ventilation position. The emission surface 10A is exposed. Therefore, the air sucked from the bathroom 100 by the circulation ventilation fan 2A is blown into the bathroom 100 from the first air outlet 21A or the second air outlet 22A in a state including an air purifying factor. Further, since the discharge surface 10A is directed to the side opposite to the ventilation outlet 23A with respect to the air path switching damper 6A, the air containing the air cleaning factor is not discharged from the ventilation outlet 23A, and is not discharged from the ventilation outlet 23A. Cycle through. Therefore, since it can blow out into the bathroom 100 without reducing the amount of the air purifying factor released by the ion generator 10, even if the air path switching damper 6A is moved to switch the air path, the circulation ventilation fan 2A can be used in the bathroom 100. The cleaning effect of the air blown out can be maintained.

  Further, when the air path switching damper 6A is set to the ventilation position, the ion generator 10 is not exposed to the ventilation air path. Therefore, even if the air path switching damper 6A is moved to the circulation position, the circulation ventilation position, and the ventilation position, the air containing the air cleaning factor is not discharged from the ventilation outlet 23A.

  Further, the air passing through the blowout air path 28A flows toward the first air outlet 21A and the second air outlet 22A along the inner surface of the air path switching damper 6A, but inside the air path switching damper 6A. The closer to the surface, the faster the air flows. By providing the ion generator 10 in the air path switching damper 6A, the discharge surface 10A is positioned at a position where the flow velocity of the air that touches the discharge surface 10A of the air cleaning factor is fast, and the air cleaner that the ion generator 10 discharges. The air can be blown out from the first air outlet 21A or the second air outlet 22A in a state where the concentration of the factor is high.

  In the present embodiment, an example has been described in which the air path switching damper 6A is used as the circulation position, the circulation ventilation position, and the ventilation position, but the present invention is not limited thereto. Even if the opening degree of the air path switching damper 6A is changed to a position where the opening degree of the ventilation outlet 23A becomes wide so that the ventilation air volume, which is the air volume exhausted to the outdoors, increases from the circulation ventilation position, the ion generator The 10 air cleansing factor discharge surface 10A is in a state of facing the circulation air path toward the first air outlet 21A and the second air outlet 22A. Therefore, the air sucked from the bathroom 100 by the circulation ventilation fan 2A is blown out into the bathroom 100 from the first air outlet 21A and the second air outlet 22A in a state including an air cleansing factor.

  In the present embodiment, the air path switching damper 6A is provided with a shaft 60A at a predetermined distance from the branching portion 52A, upstream of the branching portion 52A in the air flow direction, and at an upstream side of the shaft 60A. A main air path switching unit 61A is provided, and a sub air path switching unit 62A is provided on the downstream side.

  Thereby, the rotation operation of the air path switching damper 6A with the shaft 60A as a fulcrum, the first air outlet 21A is opened and the second air outlet 22A and the ventilation air outlet 23A are closed, the first air outlet 21A and It is possible to switch between a state in which the second air outlet 22A and the ventilation air outlet 23A are opened, and a state in which the first air outlet 21A and the second air outlet 22A are closed and the ventilation air outlet 23A is opened.

  The air path switching damper 6A is not limited to the shape described above. For example, the main air path switching unit 61A and the sub air path switching unit 62A may be configured such that the components move integrally as a result of combining a plurality of components that are not integral. In addition, the shaft 60A is configured to be provided at a predetermined distance from the branching part 52A on the upstream side with respect to the air flowing direction from the branching part 52A. The air path switching damper 6A may be provided at the upstream end with respect to the air flow direction.

  In the present embodiment, the cover 10B that covers the ion generator 10 is provided on the air path switching damper 6A, but the cover 10B may be omitted. By providing the cover 10B in the present embodiment, the ion generator 10 can be protected from moisture and the like. In addition, although the inclination provided on the cover 10B may be omitted, in the present embodiment, the cover 10B is configured such that the upstream surface thereof is inclined with respect to the air path switching damper 6A with respect to the air flow direction. Therefore, this inclination can induce the air flow to flow from the upstream side to the downstream side. Therefore, even if the ion generator 10 protrudes from the outer surface of the air path switching damper 6A in the ventilation air path communicating from the circulation ventilation suction port 20A to the ventilation air outlet 23A, it is formed on the outer surface of the air path switching damper 6A. The ventilation resistance of the air flowing along can be reduced.

  By reducing the ventilation resistance in the ventilation air passage, a predetermined ventilation air volume can be secured without increasing the rotational speed of the circulation ventilation fan motor 26A by the circulation ventilation fan 2A. Thereby, an increase in sound and an increase in power consumption due to an increase in the rotation speed of the circulation ventilation fan motor 26A can be prevented.

  When the air purifying factor generated by the ion generator 10 is reduced by heat, when the air purifying factor is generated, the driving of the heater 5 is stopped or the output is reduced to suppress the decrease of the air purifying factor, and the air purifying factor It is preferable to drive the heater 5 in conjunction with the switching of the presence or absence of occurrence of this.

  The air blower of the present invention may be configured without a heater. Moreover, it is good also as a structure provided with the direction of a ventilation blower outlet in the side part of the direction substantially orthogonal to the air blowing direction instead of the side part of the direction along the air blowing direction by the circulation ventilation fan case 27A. The number of air outlets for blowing air into the room is not limited to two, and may be configured to include either the first air outlet or the second air outlet, or may include three or more air outlets. Furthermore, as a configuration in which a device provided with a circulation ventilation fan and a device provided with each outlet for blowing air into the room are connected via a duct, and a device provided with a suction port from the room are connected via a duct. Also good.

<Modified example of air path switching damper of this embodiment>
FIG. 10 is a configuration diagram illustrating a modification of the air path switching damper according to the present embodiment. The air path switching damper 6B is obtained by changing the arrangement of the ion generator 10 and the cover 10B from the above-described air path switching damper 6A to the downstream side with respect to the air flow. In this figure, in the bathroom ventilation drying / heating machine 1A, the structure when the air path switching damper 6B is set to the circulation ventilation position is shown, similarly to the air path switching damper 6A shown in FIG. Although not shown, the air path switching damper 6B can also be displaced to the circulation position and the ventilation position by rotating the shaft 60A as a fulcrum, like the air path switching damper 6A. Hereinafter, the same members as those used in the air path switching damper 6A will be described with the same reference numerals.

  The air path switching damper 6B extends to the upstream side from the shaft 60A serving as a fulcrum of the rotation operation and the shaft 60A, and the air flow is switched between the first air outlet 21A and the ventilation air outlet 23A of the bathroom ventilation dryer 1A. A main wind path switching unit 61A that switches the path and switches the opening of the ventilation outlet 23A is provided.

  Further, the air path switching damper 6B extends downstream from the shaft 60A, and has a sub air path switching unit 62A that opens and closes the second air outlet 22A, and a shaft 60A on the tip side of the sub air path switching unit 62A. A backflow prevention portion 63A is provided that extends along the direction of the rotation operation as a fulcrum and blocks the second outlet 22A with respect to the ventilation outlet 23A.

  The air path switching damper 6B includes the ion generator 10 on the downstream side of the shaft 60A with respect to the air flow. Also in this modification, the ion generator 10 sets the air path switching damper 6B to the circulation position indicated by the air path switching damper 6A in FIG. 6 or the circulation ventilation position indicated by the air path switching damper 6A in FIG. Then, the air purification factor discharge surface 10A is exposed in each of the formed circulation air passages.

  The air path switching damper 6 </ b> B is provided with a cover 10 </ b> C as a rectifying member that covers the ion generator 10. The cover 10 </ b> C covers a portion of the air path switching damper 6 </ b> B that protrudes on the side opposite to the air cleaning factor discharge surface 10 </ b> A. In this modification, the cover 10C has an upstream end attached to the sub airflow switching unit 62A and an downstream end attached to the tip of the backflow prevention unit 63A with respect to the air flow direction.

  The cover 10 </ b> C is inclined so that the upstream surface narrows from the upstream side to the downstream side with respect to the air flow direction. This inclination induces air to flow from the upstream side to the downstream side, and reduces the ventilation resistance in the air passage.

  As described above, also in this modification, the air cleansing factor discharge surface 10A of the ion generator 10 is exposed to the circulation air passage formed by setting the air passage switching damper 6B to the circulation position or the circulation ventilation position. Therefore, the air sucked from the bathroom 100 is blown out into the bathroom 100 from the first air outlet 21A or the second air outlet 22A in a state including an air purifying factor. Further, since the discharge surface 10A is directed to the side opposite to the ventilation outlet 23A with respect to the air path switching damper 6B, the air containing the air cleansing factor is not discharged from the ventilation outlet 23A, and the inside of the bathroom 100 is exhausted. Circulate. Therefore, since it can blow out into the bathroom 100 without reducing the amount of the air purifying factor released by the ion generator 10, even if the air path switching damper 6B is moved to switch the air path, the circulation ventilation fan 2A can be used in the bathroom 100. The cleaning effect of the air blown out can be maintained.

  Since the cover 10C is provided downstream of the cover 10B with respect to the air blowing direction of the air path switching damper 6B, the air path switching damper in the ventilation air path communicating with the ventilation air outlet 23A from the air outlet 28A. The amount of protrusion from 6B is reduced, and the ventilation resistance in the ventilation air passage communicating with the ventilation outlet 23A can be reduced.

  The present invention is applied to a blower installed in a space such as a bathroom and provided with an air cleansing factor generator such as an ion generator.

  DESCRIPTION OF SYMBOLS 1A ... Bathroom ventilation drying heater (blower), 10 ... Ion generator (air purifying factor generator), 10A ... Release surface, 10B, 10C ... Cover (rectifier member), 2A ..Circulation ventilation fan, 20A ... circulation ventilation inlet, 21A ... first outlet, 22A ... second outlet, 23A ... ventilation outlet, 6A, 6B ... wind Path switching damper (movable member), 25A ... impeller (air blowing means), 26A ... circulating ventilation fan motor, 27A ... circulating ventilation fan case, 28A ... blowing air path, 3A ... main body Part, 30A ... body chassis, 31A ... metal case, 32A ... flange part, 33A ... lower cover, 34A ... exhaust duct joint, 4A ... front panel, 40A ... suction Mouth grille, 41A ... first outlet Grill, 42A ... 2nd blow-off grill, 5 ... Heater, 50A ... Air channel formation frame, 51A ... Partition member, 100 ... Bathroom, 101 ... Ceiling panel, 102 ... Exhaust duct, 102a ... Outdoor grill, 103 ... Ttub, 104 ... Washing area, 105 ... Land pipe, 106a, 106b ... Wall

Claims (5)

A blowing means for sucking in and blowing out indoor air;
A movable member that switches a flow path of the air sucked by the blowing means;
An air purifying factor generator that releases an air purifying factor that purifies the air blown into the room by the blowing means;
The blower characterized in that the air purification factor generator is provided on the movable member. 2. The blower according to claim 1, wherein the air purification factor generator is arranged such that a surface on the side from which the air purification factor is released is directed toward a blowout port that blows air into the room. The movable member is
It is a damper which divides the blowing direction of the air sucked from the room by the blowing means into at least a direction toward the blower outlet and a direction toward a ventilation blower that exhausts air to the outside of the room. 2. The air blower according to 2. The air purification factor generator is
The blower according to any one of claims 1 to 3, wherein the blower is provided downstream of the movable member with respect to a blowing direction of air sucked from the room. The movable member has a rectifying member for inducing a flow of air sucked by the blowing means,
The blower according to any one of claims 1 to 4, wherein the rectifying member is disposed so as to cover the air purification factor generator.

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