JP6904010B2 - Blower - Google Patents

Description

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

Conventionally, a blower device that is installed on the ceiling of a bathroom or the like and blows warm air or air according to room temperature into the room to realize functions such as heating the room and drying the object to be dried in the room has been proposed. .. Many of such blowers have a ventilation function of exhausting indoor air to the outside, and are called bathroom ventilation drying heaters.

In the bathroom ventilation drying heater, a technique has been proposed in which a generator of a functional factor such as an ion is provided in the air passage and the functional factor is supplied to the bathroom (see, for example, Patent Document 1). Further, in an ion generator having a needle-shaped discharge electrode, a technique for reducing the amount of ions generated has been proposed in order to suppress corrosion of the electrode (see, for example, Patent Document 2). Further, a technique has been proposed in which an ion generator is provided with a hooking mechanism that allows the ion generator to be reattached to the main body of the device (see, for example, Patent Document 3).

Japanese Patent No. 5640891 Japanese Unexamined Patent Publication No. 2013-243099 Japanese Patent No. 4114602

If the amount of ions generated is reduced in order to extend the life of the ion generator, the desired performance due to the action of ions cannot be exhibited. Further, even if the ion generator is provided with a hooking mechanism, it is necessary to remove the panel member or the like from the main body of the device, the ion generator cannot be easily attached and detached, and the life of the ion generator can be easily extended. Can't.

The present invention has been made to solve such a problem, and an object of the present invention is to provide a blower device capable of easily extending the life of a functional factor generating unit.

In order to solve the above-mentioned problems, the present invention has a main body having a blowing means for sucking and blowing out indoor air, a panel member attached to the main body, and a function of being supplied to the flow of air generated by the blowing means. It is provided with a functional factor generating part that generates a factor and a mounting part to which the functional factor generating part is attached, and the blowing means is driven by a heating means, a suction port through which air sucked by the blowing means passes, and a heating means. The hot air has a first outlet in which the heating means is not driven and air corresponding to the inside of the bathroom is blown out, and a second outlet in which air for stirring the air in the room is blown out. The members are provided on the surface having the suction port, the first air outlet, and the second air outlet, and the suction port grill communicating with the suction port and the first air outlet grill communicating with the first air outlet. The second outlet grill that communicates with the second outlet and the attachment / detachment means for attaching / detaching the functional factor generating portion to / from the mounting portion are provided, and the functional factor generating portion has a functional factor emitting portion. The release unit is installed so as to be exposed in the second air outlet, and the attachment / detachment means is a blower device provided with an opening / closing member that opens and closes a part of the panel member facing the position of the attachment portion.

In the present invention, when the main body is installed at the installation location, the panel member is exposed at the installation location. By operating the attachment / detachment means provided on the panel member exposed at the installation location, the functional factor generating portion can be attached / detached.

According to the present invention, the functional factor generating portion can be attached and detached without removing the main body from the installation location, and the functional factor generating portion can be easily replaced. Further, according to the present invention, it is possible to clean the functional factor generating portion without removing the main body portion from the installation location. This makes it possible to extend the life of the functional factor generating part. Further, since the life of the functional factor generating portion can be extended, it is not necessary to reduce the output of the functional factor generating portion, and the desired performance due to the action of the functional factor can be exhibited.

It is a block diagram which shows an example of the bathroom ventilation drying heater of 1st Embodiment. It is a block diagram which shows an example of the bathroom ventilation drying heater of 1st Embodiment. It is a block diagram which shows an example of the bathroom ventilation drying heater of 1st Embodiment. It is a block diagram which shows the installation example of the bathroom ventilation drying heater of 1st Embodiment. It is a block diagram which shows an example of the control function of the bathroom ventilation drying heater of 1st Embodiment. It is explanatory drawing which shows the operation of the air passage switching damper in the bathroom ventilation drying heater of 1st Embodiment. It is explanatory drawing which shows the operation of the air passage switching damper in the bathroom ventilation drying heater of 1st Embodiment. It is explanatory drawing which shows the operation of the air passage switching damper in the bathroom ventilation drying heater of 1st Embodiment. It is explanatory drawing which shows the air flow in the bathroom in the bathroom ventilation drying heater of 1st Embodiment. It is an operation explanatory view which shows the operation of exchanging an ion generator. It is an operation explanatory view which shows the operation of exchanging an ion generator. It is a block diagram of the bathroom ventilation drying heater which shows the other example of the installation place of an ion generator. It is a block diagram of the bathroom ventilation drying heater which shows the other example of the installation place of an ion generator. It is a block diagram of the bathroom ventilation drying heater which shows the other example of the installation place of an ion generator. It is a block diagram which shows an example of the bathroom ventilation drying heater of the 2nd Embodiment.

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

<Structure example of bathroom ventilation drying heater of the first embodiment>
1 to 3 are configuration views showing an example of the bathroom ventilation drying heater according to the first embodiment, FIG. 1 is a side view showing the internal configuration of the bathroom ventilation drying heater, and FIG. 2 is a lower surface side. It is a plan view seen from. Further, FIG. 3 is a plan view with the front panel attached. Further, FIG. 4 is a configuration diagram showing an installation example of the bathroom ventilation drying heater according to the first embodiment.

Explaining the outline of the bathroom ventilation drying heater 1A of the first embodiment, the bathroom ventilation drying heater 1A is installed in a form in which the main body 3A having the circulation ventilation fan 2A exposes the front panel 4A. It is attached to the ceiling of the bathroom 100, which is the place. In the bathroom ventilation drying heater 1A, the side to which the front panel 4A is attached is the lower side.

The bathroom ventilation drying heater 1A has a circulation ventilation fan 2A that sucks in and blows out air, a circulation ventilation suction port 20A in which air is sucked by the circulation ventilation fan 2A, and the heater 5 is driven so that warm air and the heater 5 are not used. It is provided with a first outlet 21A in which air corresponding to the room temperature in the bathroom 100 is blown out by driving, and a second outlet 22A in which air for stirring the air in the bathroom 100 is blown out.

Further, the bathroom ventilation drying heater 1A includes a ventilation outlet 23A that exhausts the air sucked from the circulation ventilation suction port 20A by the circulation ventilation fan 2A to the outside. Further, the bathroom ventilation drying heater 1A includes an air passage switching damper 6A that switches the air passage between the first air outlet 21A and the second air outlet 22A and the ventilation air outlet 23A.

In the bathroom ventilation drying heater 1A of the first embodiment, the functional factor generating unit is replaced as a performance maintaining means for maintaining the performance of the functional factor generating unit that generates the functional factor released into the air blown into the room. Equipped with easy attachment / detachment means.

The details of the bathroom ventilation drying heater 1A will be described below. The circulation ventilation fan 2A is an example of a ventilation means composed of a centrifugal fan, and is a circulation ventilation fan motor for driving a multi-blade impeller 25A and an impeller 25A. It includes 26A and a circulation ventilation fan case 27A that forms an air passage. The impeller 25A is driven by the circulation ventilation fan motor 26A and rotates to generate a flow of air blown out from the inside of the impeller 25A to the outer peripheral side in the centrifugal direction.

The circulation ventilation fan 2A includes a circulation ventilation suction port 20A on the lower surface of the circulation ventilation fan case 27A for sucking air. The circulation ventilation suction port 20A is configured by providing a circular opening called a bell mouth below along the rotation axis of the impeller 25A. The circulation ventilation fan case 27A is an example of a case portion, and has a shape in which a tongue portion 27A1 is formed between a substantially circular portion along the outer circumference of the impeller 25A and a portion along the tangential direction of the impeller 25A. The circulation ventilation fan case 27A rectifies the air blown out in the centrifugal direction of the impeller 25A to generate a flow of air blown out along the tangential direction of the impeller 25A.

The circulation ventilation fan 2A is configured such that the direction of the rotation axis of the impeller 25A is along the vertical direction in a state where the bathroom ventilation drying heater 1A is installed on the ceiling of the bathroom 100.

As a result, the circulation ventilation fan 2A has a blowout air passage 28A that blows out the air sucked from the lower circulation ventilation suction port 20A along the rotation axis of the impeller 25A in the tangential direction of the impeller 25A, and the circulation ventilation fan case 27A. Is formed by.

The circulation ventilation fan 2A blows out air heated by driving the heater 5 or air corresponding to the temperature in the bathroom 100 by not driving the heater 5 on the lower surface of the circulation ventilation fan case 27A. The first air outlet 21A is provided.

Further, the circulation ventilation fan 2A is provided with a second outlet 22A on the lower surface of the circulation ventilation fan case 27A to blow out the air that agitates the inside of the bathroom 100. Further, the circulation ventilation fan 2A is provided with a ventilation outlet 23A on the side surface of the circulation ventilation fan case 27A, in which air is blown out to the outside.

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

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

The first outlet 21A and the second outlet 22A are composed of an air passage forming frame 50A provided on the lower surface of the circulation ventilation fan case 27A. The first outlet 21A and the second outlet 22A are partitioned by a partition member 51A provided inside the air passage forming frame 50A, and the circulating air outlet air through which the air blown from the first outlet 21A passes passes. A passage and an agitated air outlet air passage through which the air blown from the second outlet 22A passes are formed.

The air passage switching damper 6A is an example of an air passage opening / closing means, in which a driving force of a damper motor (not shown) is transmitted and rotates around a shaft 60A as a fulcrum to provide a first outlet 21A, a second outlet 22A, and a ventilation outlet. It opens and closes with the outlet 23A.

The air passage switching damper 6A is predetermined from the branch portion 52A on the upstream side with respect to the air flow direction from the branch portion 52A between the first outlet 21A and the second outlet 22A composed of the partition member 51A. A shaft 60A for opening / closing operation by rotation is provided at a distance of.

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

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

In the bathroom ventilation drying heater 1A, assuming that the position of the air passage switching damper 6A is the circulation position shown by the solid line in FIG. 1, which is the first position, the main air passage on the upstream side of the axis 60A with respect to the air flow direction. In the switching portion 61A, the tip of the main air passage switching portion 61A, which is one end of the air passage switching damper 6A, comes into contact with the upper inner surface of the circulation ventilation fan case 27A.

Further, in the secondary air passage switching portion 62A on the downstream side of the shaft 60A with respect to the air flow direction, the tip of the secondary air passage switching portion 62A, which is the other end of the air passage switching damper 6A, comes into contact with the branch portion 52A. .. Further, the backflow prevention unit 63A closes the second outlet 22A with respect to the ventilation 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 suction port 20A to the first air outlet 21A is formed. ..

In the bathroom ventilation drying heater 1A, assuming that the position of the air passage switching damper 6A is rotated from the circulation position to the axis 60A as a fulcrum to be the second position, which is the circulation ventilation position shown by the broken line in FIG. 1, from the axis 60A. The main air passage switching portion 61A on the upstream side moves downward, and one end of the air passage switching damper 6A is located near the middle of the blowout air passage 28A.

Further, the secondary air passage switching portion 62A on the downstream side of the shaft 60A moves upward away from the branch portion 52A. As a result, both the first air outlet 21A and the second air outlet 22A and the ventilation air outlet 23A are opened, and both the circulation air passage and the ventilation air passage communicating from the circulation ventilation suction port 20A to the ventilation air outlet 23A. Is formed.

In the bathroom ventilation drying heater 1A, assuming that the position of the air passage switching damper 6A is rotated from the circulation ventilation position to the axis 60A as a fulcrum to be the ventilation position shown by the one-point chain line in FIG. 1, which is the third position, the axis 60A. The main air passage switching portion 61A on the upstream side moves downward, and one end of the air passage switching damper 6A comes into contact with the lower inner surface of the circulation ventilation fan case 27A. Further, the auxiliary air passage switching portion 62A on the downstream side of the shaft 60A moves upward, and the other end of the air passage switching damper 6A comes into 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 the ventilation air passage is formed.

As a result, in the bathroom ventilation drying heater 1A, one circulation ventilation fan 2A sucks in the air in the bathroom 100 and blows out the sucked air into the bathroom 100, exhausts the sucked air to the outside, and sucks in. A part of the air is blown into the bathroom 100, and the rest is exhausted to the outside.

Further, in the bathroom ventilation drying heater 1A, one air passage switching damper 6A opens and closes the first air outlet 21A, the second air outlet 22A, and the ventilation air outlet 23A.

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

The first outlet 21A and the second outlet 22A are partitioned by a partition member 51A, and the air blown from the second 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, but a heater such as a heat exchanger using hot water may also be used.

The main body 3A includes a main body chassis 30A constituting the circulation ventilation fan case 27A and a metal case 31A covering the main body chassis 30A. The main body chassis 30A is made of a resin material, and a circulating 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 3A are integrally formed.

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

The metal case 31A is provided with 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.

In the bathroom ventilation drying heater 1A, the front panel 4A is attached to the lower surface of the main body 3A. The front panel 4A is an example of a panel member, and the suction port grill 40A is formed by opening the lower surface of the circulation ventilation fan 2A facing the circulation ventilation suction port 20A.

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

The first outlet grill 41A is composed of a rectangular opening having an elongated length along the lateral direction, which is the direction along one side of the main body 3A. Further, the second outlet grill 42A, like the first outlet grill 41A, has a rectangular opening having an elongated length along the lateral direction, which is the direction along one side of the main body 3A. It is composed.

The first outlet grill 41A is provided with a straightening vane so that air is blown out along the longitudinal direction. The second outlet grill 42A blows air toward the outside of the main body 3A opposite to the first outlet grill 41A along the lateral direction parallel to the first outlet grill 41A. As such, the rectifying plate 43A is provided. The front panel 4A may be a member independent of the main body 3A, or may be a member integrated with the main body 3A. The integration of the front panel 4A and the main body 3A includes a form in which the front panel 4A is integrated with the circulation ventilation fan case 27A constituting the main body 3A, and is integrated with the main body chassis 30A.

The bathroom ventilation drying heater 1A includes an ion generator 10 as a functional factor generator. The ion generator 10 generates and releases ions as a functional factor to remove bacteria. Therefore, the ions mainly function as an air purifying factor that purifies the air, and the ion generator 10 functions as an air purifying factor generator that generates and releases ions.

The ion generator 10 generates both positive and negative ions or at least either positive or negative ions. The principle of the generation of positive ions and negative ions, oxygen or moisture in the air is ionized by receiving energy by ionizing by corona discharge, H ⁺ and (H ₂ O) _{m (m} is an arbitrary natural number), O ₂ ^- (H ₂ O) _n (n is an arbitrary natural number) emits the main ion.

These H ⁺ (H ₂ O) _m and _{^{O 2 - (H 2 O)}} n is attached to the surface of the bacteria, to produce a H ₂ O ₂ or · OH which is an active species by a chemical reaction. H ₂ O ₂ or · OH exhibits extremely strong activity, which allows them to surround and eliminate the fungus. Here, ・ OH is one of the active species and indicates radical OH.

As a result, the bathroom ventilation drying heater 1A generates approximately the same number of positive and negative ions in conjunction with the operation of the circulation ventilation fan 2A, and blows air containing approximately the same number of positive and negative ions to circulate. Both the airborne bacteria contained in the air and the airborne bacteria in the air of the bathroom 100 can be removed to suppress the generation of mold and the like. In addition, bacteria adhering to the bathroom 100 can be removed to suppress the growth of mold and the like. Further, it is possible to remove bacteria adhering to clothes and suppress the generation of odor.

It should be noted that the ion generator 10 may generate only positive ions or only negative ions, and may use other methods instead of corona discharge. Further, as an air purifying factor for removing both airborne bacteria contained in the circulating air and airborne bacteria in the bathroom air, other air purifying factors such as ozone may be used instead of ions. Further, the air purifying factor generating part may use a spraying means for spraying silver ions, a chemical for deodorizing and sterilizing, a chemical for promoting a moisturizing effect, etc., and adheres to airborne bacteria, clothing, etc. Any form of air treatment means that imparts a specific function to air, such as those that suppress the growth of bacteria, those that remove bacteria, and those that release functional factors that have a moisturizing effect. It may be one.

The ion generator 10 includes an electrode needle that discharges corona and a cover (not shown) that covers the electrode needle, and comprises an ion emitting portion 10A. The ion generator 10 is installed at a position where it can be easily attached to and detached from the main body 3A.

Next, the installation location of the ion generator 10 will be described. The ion generator 10 is installed at a predetermined position on the lower surface side of the circulation ventilation fan case 27A. In the examples shown in FIGS. 1 and 2, in order to supply ions to the air blown from the second outlet 22A, the ion generator 10 exposes the ion emitting portion 10A into the second outlet 22A. It is installed on the lower surface side of the circulation ventilation fan case 27A.

Therefore, the bathroom ventilation drying heater 1A is provided with the attachment portion 201A of the ion generator 10 on the lower surface of the circulation ventilation fan case 27A adjacent to the second outlet 22A. Alternatively, the front panel 4A is provided with the attachment portion 201A of the ion generator 10 adjacent to the second outlet grill 42A.

The mounting portion 201A includes a fixing portion 202A for fixing the ion generator 10 in a predetermined position. The fixing portion 202A detachably fixes the ion generator 10 to the circulation ventilation fan case 27A or the front panel 4A by a combination of uneven shapes and a fastening member such as a screw.

The front panel 4A includes a cover portion 401A that opens and closes a position facing the mounting portion 201A. The cover portion 401A is an example of an opening / closing member constituting the attachment / detachment means. In this example, a part of the front panel 4A is opened / closed by a rotational operation with the shaft 402A as a fulcrum.

By opening the cover portion 401A, the ion generator 10 can be attached to and detached from the mounting portion 201A. Further, by mounting the ion generator 10 on the mounting portion 201A and closing the cover portion 401A, the ion generator 10 is fixed to the mounting portion 201A.

In this example, the ion generator 10 may be fixed to the main body 3A side or the front panel 4A side. Further, although the cover portion 401A is provided on the front panel 4A, it may be provided on the circulation ventilation fan case 27A.

The bathroom ventilation drying heater 1A includes a cutoff switch 203A in the mounting portion 201A. The cutoff switch 203A is an example of the cutoff means, and operates by opening / closing the cover portion 401A. When the cover portion 401A is in the closed state, when the bathroom ventilation drying heater 1A is connected to the power source, the state in which the power is supplied is maintained. On the other hand, the cutoff switch 203A cuts off the supply of the power supply when the cover portion 401A is opened and the bathroom ventilation drying heater 1A is connected to the power supply.

The cutoff switch 203A detects, for example, the presence or absence of the cover portion 401A with a magnetic sensor. Alternatively, the presence or absence of the cover portion 401A is detected by an optical sensor. Alternatively, the presence or absence of the cover portion 401A is detected by a mechanical switch such as a micro switch.

<Installation example of bathroom ventilation drying heater of the first embodiment>
Next, an installation example of the bathroom ventilation drying heater 1A according to the first embodiment will be described with reference to each figure.

As shown in FIG. 4, the bathroom ventilation drying heater 1A 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 drying heater 1A is attached, and the bathroom ventilation drying heater 1A is provided behind the ceiling with, for example, a screw whose flange portion 32A is not shown. It is attached to the ceiling panel 101 in a form of being fixed to the reinforcing member.

In the bathroom ventilation drying heater 1A, the front panel 4A is attached to the lower surface of the main body 3A, and the suction port grill 40A of the front panel 4A and the first outlet grill 41A and the second outlet grill 42A are provided. It is arranged facing the bathroom 100.

In the bathroom ventilation drying heater 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) in which the bathroom 100 is installed, and the bathroom ventilation drying heater 1A is connected to the outside via the exhaust duct 102.

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

The bathroom 100 includes a land repipe 105, which is a clothes-drying member, above the bathtub 103. The land repipe 105 extends along the longitudinal direction of the bathtub 103 and is attached between the opposing wall surfaces 106a and 106b of the bathroom 100.

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

The bathroom ventilation drying heater 1A is installed on the upper part of the bathtub 103 so that the longitudinal direction of the first outlet grill 41A and the second outlet grill 42A is orthogonal to the longitudinal direction of the land repipe 105. Will be done.

As a result, in the bathroom ventilation drying heater 1A, the air blown out from the first outlet grill 41A spreads mainly in the direction orthogonal to the land repipe 105. On the other hand, the air blown from the second outlet grill 42A is directed to the wall surface 106a of the bathroom 100 on the side where the second outlet grill 42A is provided.

<Example of control function of bathroom ventilation drying heater of the first embodiment>
FIG. 5 is a block diagram showing an example of a control function of the bathroom ventilation drying heater according to the first embodiment. The bathroom ventilation drying heater 1A includes a control unit 81A composed of a CPU, a memory, and the like, a circulation ventilation fan motor 26A described with reference to FIG. 1, a damper motor 65A for driving an air passage switching damper 6A, a heater 5, and a heater 5. The ion generator 10, the cutoff switch 203A, the operation unit 82, and the like are connected.

The control unit 81A is an example of the control means, and executes, for example, a dry operation mode, a circulation ventilation operation mode, a heating operation mode, a ventilation operation mode, and the like by a program stored in a memory or the like (not shown).

These operation modes are selected by a user such as a bather operating the operation unit 82 or the like. The operation unit 82 is an example of an operation means, for example, a remote control device independent of the main body of the bathroom ventilation / drying / heating machine 1A, and is attached to a wall surface of a washroom / dressing room adjacent to the bathroom 100.

The control unit 81A drives the circulation ventilation fan motor 26A based on the program for executing the operation mode selected by the operation unit 82, and controls 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 65A is controlled to control the opening degree of the air passage switching damper 6A. In addition, the ion generator 10 is driven to control the presence / absence and amount of ions generated.

In the bathroom ventilation drying heater 1A, the air volume of the air blown out from the first outlet 21A 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. Further, by controlling the opening degree of the air passage switching damper 6A, the air passage through which air is blown and the air volume in each air passage are controlled.

In the bathroom ventilation drying heater 1A, the operation mode selection information based on the operation or the like in the operation unit 82 is acquired. In the bathroom ventilation drying heater 1A circulation ventilation fan case, based on the acquired operation mode selection information, the air volume of the air blown from the first outlet 21A, the temperature of the air blown from the first outlet 21A, and ions. The output of the bathroom ventilation drying heater 1A is controlled, such as the presence or absence of the release of air, the amount of ions released, and the like.

The control unit 81A measures the time for driving the ion generator 10 and determines the replacement time of the ion generator 10 from the cumulative value of the time for driving the ion generator 10. When the control unit 81A determines that it is time to replace the ion generator 10, the operation unit 82 or the like notifies the control unit 81A.

<Operation example of the bathroom ventilation drying heater of the first embodiment>
6 to 8 are explanatory views showing the operation of the air passage switching damper in the bathroom ventilation drying heater of the first embodiment, and FIG. 9 shows the inside of the bathroom in the bathroom ventilation drying heater of the first embodiment. Next, with reference to each figure, an operation example of the bathroom ventilation drying heater 1A of the first embodiment will be described.

In the dry operation mode, the control unit 81A sets the air passage switching damper 6A to the circulation ventilation position shown in FIG. 7, drives the circulation ventilation fan motor 26A to rotate the impeller 25A, and energizes the heater 5.

In the bathroom ventilation drying heater 1A, when the impeller 25A rotates, the 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.

In the dry operation mode, since the air passage switching damper 6A is in the circulation ventilation position, in the outlet air passage 28A, the circulation air passage communicating from the circulation ventilation suction port 20A to the first outlet 21A and the second outlet 22A , Both ventilation air passages communicating from the circulation ventilation suction port 20A to the ventilation outlet 23A are formed.

As a result, a part of the air RA of the bathroom 100 sucked from the circulation ventilation suction port 20A by rotating the impeller 25A flows to the first air outlet 21A and the second air outlet 22A. Further, the rest of the air of the bathroom 100 sucked from the circulation ventilation suction port 20A flows to the ventilation outlet 23A, passes through the exhaust duct 102, and is exhausted to the outside as exhaust EA from the outdoor grill 102a.

In the drying operation mode, the air flowing through the first outlet 21A is heated by the heater 5, so that the warm air HA is blown out from the first outlet grill 41A of the front panel 4A. Since the air flowing through the second outlet 22A does not pass through the heater 5, the air A corresponding to the room temperature is blown out from the second outlet grill 42A of the front panel 4A.

In the bathroom ventilation drying heater 1A, the air blown from the first outlet grill 41A spreads in the longitudinal direction of the land repipe 105 and in the direction orthogonal to the land repipe 105.

However, since the bathroom ventilation drying heater 1A is arranged so that the longitudinal direction of the first outlet grill 41A is orthogonal to the land repipe 105, the air blown out from the first outlet grill 41A is mainly. It spreads in the direction orthogonal to the land repipe 105.

Therefore, warm air is blown to the entire width direction of the object to be dried such as clothes hung on the land repipe 105 immediately below the first outlet grill 41A. On the other hand, for the object to be dried hung on the land repipe 105 located away from directly below the first outlet grill 41A, the warm air blown out from the first outlet grill 41A directly. It's hard to hit.

In the bathroom ventilation drying heater 1A, the air A blown out from the second outlet grill 42A is on the side where the second outlet grill 42A is provided with respect to the first outlet grill 41A by the rectifying plate 43A. It is directed to the wall surface 106a of the bathroom 100.

As a result, as shown in FIG. 9A, the air A blown out from the second outlet grill 42A in the drying mode is applied to one wall surface 106a of the bathroom 100, and the wall surface 106a is shown by the arrow A1. Flows downward along. 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 shown by the arrow A2.

In the bathroom ventilation drying heater 1A, the air RA sucked from the suction port grill 40A creates a flow for circulating air in the bathroom 100, so that 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 shown by the arrow A3, and is sucked from the suction port grill 40A.

As described above, in the bathroom ventilation drying heater 1A, the air blown from the second outlet grill 42A goes downward along one wall surface 106a of the bathroom 100, and the vicinity of the lower layer of the bathroom 100 is the other wall surface 106b. It is possible to generate an upward flow of air along the other wall surface 106b.

In the dry operation mode, the air blown from the first outlet grill 41A of the bathroom ventilation drying heater 1A is warm air heated by the heater 5, and the relative humidity is lowered, so that the second outlet grill Lighter than the air blown from 42A.

Therefore, the air blown out from the second outlet grill 42A, which is heavier than the air blown out from the first outlet grill 41A, flows to the lower layer of the bathroom 100 and agitates the air throughout the bathroom 100. It can create a flow of wind.

As a result, the warm air blown out from the first outlet grill 41A can be easily hit even in the vicinity of the object to be dried hung on the land repipe 105 located away from directly below the first outlet grill 41A. It can create a flow of air.

In the dry operation mode, when the ion generator 10 is driven, unheated air containing ions is blown out from the second outlet grill 42A. The air blown out from the second outlet grill 42A can flow to the lower layer of the bathroom 100, and can generate a flow of wind that agitates the air containing ions throughout the bathroom 100.

As a result, while drying the clothes hung on the land repipe 105, the air containing ions hits the entire clothes hung on the land repipe 105 to suppress the growth of bacteria adhering to the clothes. , Deodorizing effect can be obtained.

In the circulation ventilation operation mode, the control unit 81A sets the air passage switching damper 6A to the circulation ventilation position shown in FIG. 7, sets the heater 5 as non-drive, drives the circulation ventilation fan motor 26A, and rotates the impeller 25A. Here, in the above-mentioned dry operation mode and circulation ventilation operation mode, the opening degree of the air passage switching damper 6A is ventilated so that the ventilation air volume, which is the air volume exhausted to the outside, is larger in the circulation ventilation operation mode. It may be changed to a position where the opening degree of the outlet 23A becomes wider.

In the bathroom ventilation drying heater 1A, the impeller 25A rotates, so that the 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.

In the circulation ventilation operation mode, since the air passage switching damper 6A is in the circulation ventilation position, a part of the air of the bathroom 100 sucked from the circulation ventilation suction port 20A is the first outlet 21A and the second outlet 22A. Flow to. Further, the rest of the air in the bathroom 100 sucked from the circulation ventilation suction port 20A flows to the ventilation outlet 23A and is exhausted to the outside.

In the circulation ventilation operation mode, since the heater 5 is not driven for the air flowing through the first outlet 21A, the air CA corresponding to the room temperature is blown out from the first outlet grill 41A of the front panel 4A. Since the air flowing through the second outlet 22A does not pass through the heater 5, the air A corresponding to the room temperature is blown out from the second outlet grill 42A of the front panel 4A.

In the bathroom ventilation drying heater 1A, as shown in FIG. 9B, even in the circulation ventilation operation mode, the air blown from the second outlet grill 42A moves downward along one wall surface 106a of the bathroom 100. Facing, the vicinity of the lower layer of the bathroom 100 can be directed toward the other wall surface 106b, and an upward air flow can be generated along the other wall surface 106b.

As a result, even in the circulation ventilation operation mode, it is possible to generate a flow of air that agitates the air in the entire bathroom 100, and the air blown out from the first outlet grill 41A directly in the bathroom 100. It is possible to create an air flow even in a place where it is difficult to hit.

Therefore, the drying time of each wall surface, floor surface, etc. of the bathroom 100 can be shortened. Further, since a part of the air in the bathroom 100 is exhausted to the outside to be ventilated, it is possible to discharge moisture and the like to promote the drying of each wall surface, floor surface and the like of the bathroom 100.

Even in the circulation ventilation operation mode, when the ion generator 10 is driven, unheated air containing ions is blown out from the second outlet grill 42A. The air blown out from the second outlet grill 42A can flow to the lower layer of the bathroom 100, and can generate a flow of wind that agitates the air containing ions throughout the bathroom 100.

As a result, the air containing ions can be applied to the entire ceiling, wall surface, and floor surface of the bathroom 100 to suppress the growth of bacteria and the growth of mold.

As another operation mode executed by the bathroom ventilation drying heater 1A, in the heating operation mode, the air passage switching damper 6A is set to the circulation position shown in FIG. 6, the heater 5 is energized, and the circulation ventilation fan motor 26A is operated. Drive to rotate the impeller 25A.

In the bathroom ventilation drying heater 1A, the impeller 25A rotates, so that the 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.

In the heating operation mode, since the air passage switching damper 6A is in the circulation position, substantially all of the air in the bathroom 100 sucked from the circulation ventilation suction port 20A flows to the first outlet 21A. In the heating operation mode, the air flowing through the first outlet 21A is heated by the heater 5, so that warm air is blown out from the first outlet grill 41A of the front panel 4A.

In the heating operation mode, since the air passage switching damper 6A is in the circulation position, the air in the bathroom 100 is not ventilated. As a result, in the heating operation mode, the air in the bathroom 100 is circulated while blowing warm air from the first outlet grill 41A, so that the temperature in the bathroom 100 can be raised to a temperature suitable for bathing. it can.

Further, when the air passage switching damper 6A is in the circulation position, the second outlet 22A is blocked in addition to the ventilation outlet 23A, so that the air that does not pass through the heater 5 is not blown out. As a result, even in the heating operation mode executed during bathing, the air not heated by the heater 5 is not blown out, and the bather does not feel cold.

Further, when the air passage switching damper 6A is in the circulation position, the second outlet 22A is blocked by the backflow prevention portion 63A with respect to the ventilation outlet 23A, so that the outside air can be prevented from flowing back into the bathroom 100. Can be done.

In the ventilation operation mode, the air passage switching damper 6A is set to the ventilation position shown in FIG. 8, the heater 5 is not driven, and the circulation ventilation fan motor 26A is driven to rotate the impeller 25A.

In the bathroom ventilation drying heater 1A, the impeller 25A rotates, so that the 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.

In the ventilation operation mode, since the air passage switching damper 6A is in the ventilation position, the first air outlet 21A and the second air outlet 22A are blocked, and the air in the bathroom 100 sucked from the circulation ventilation suction port 20A is abbreviated. The entire amount flows to the ventilation outlet 23A and is exhausted to the outside. Therefore, in the ventilation operation mode, steam and humidity in the bathroom 100 can be discharged to suppress dew condensation and the like, and the generation of mold can be suppressed.

10 to 11 are operation explanatory views showing an operation of exchanging the ion generator. The electrode of the ion generator 10 is consumed by the operation of generating ions. Therefore, the ion generator 10 is replaced at a predetermined timing. For example, the control unit 81A measures the time for driving the ion generator 10 and determines the replacement time of the ion generator 10 from the cumulative value of the time for driving the ion generator 10. When the control unit 81A determines that it is time to replace the ion generator 10, the operation unit 82 or the like notifies the control unit 81A.

When the cover portion 401A is opened as shown by an arrow C1 in FIG. 10, the ion generator 10 is exposed from the front panel 4A, and the ion generator 10 can be attached and detached. By providing the cover portion 401A, the ion generator 10 can be attached and detached without removing the entire front panel 4A from the main body portion 3A.

Further, when the cover portion 401A is opened, the power supply is cut off by the cutoff switch 203A. This prevents the ion generator 10 from being driven while the ion generator 10 is exposed.

By opening the cover portion 401A and operating the fixing portion 202A, the ion generator 10 can be removed from the mounting portion 201A. Since electricity is supplied to the ion generator 10, it is electrically connected to the main body 3A side. Therefore, the presence or absence of electrical connection between the ion generator 10 and the main body 3A side can be switched by using a detachable connector or the like.

The cover portion 401A is opened and the fixing portion 202A is operated to remove the used ion generator 10 from the mounting portion 201A as shown by an arrow D1 in FIG. 11, and electricity between the ion generator 10 and the main body portion 3A side. Disconnect the connection.

A new ion generator 10 is attached to the attachment portion 201A from which the used ion generator 10 has been removed as shown by arrow D2 in FIG. 11, and is fixed to the attachment portion 201A by the fixing portion 202A, and the ion generator 10 and the attachment portion 201A are fixed. Makes an electrical connection with the main body 3A side. Here, in the state where the cover portion 401A is open, the power supply is cut off by the cutoff switch 203A, so that even if the ion generator 10 and the main body portion 3A side are electrically connected, the ion generator 10 is still connected. Electricity does not flow.

Then, as shown by the arrow C2 in FIG. 10, the cover portion 401A is closed. When the cover portion 401A is closed, the power is supplied by the cutoff switch 203A, and the bathroom ventilation drying heater 1A can be operated.

As described above, the ion generator 10 can be replaced without lowering the bathroom ventilation drying heater 1A from the ceiling of the bathroom 100 where it is installed. The ion generator 10 can be replaced by opening the cover portion 401A, and it is not necessary to remove the front panel 4A. Further, since the power supply is cut off by opening the cover portion 401A, even if the operation of the switchboard for shutting off the power supply for the bathroom ventilation drying heater 1A is forgotten, ions are generated when the ion generator 10 is exposed. No electricity flows through the vessel 10.

As a result, the ion generator 10 can be replaced with a simple operation, and the performance of the ion generator 10 can be maintained for a long period of time. Further, since the performance of the ion generator 10 can be maintained for a long period of time, it is not necessary to reduce the output of the ion generator 10, and the desired performance due to the action of ions can be exhibited. In particular, it can be effective in removing not only airborne bacteria but also attached bacteria attached to the walls of the bathroom 100 and the like. Further, it is possible to execute an operation mode in which ions are constantly generated.

<Variation example of the bathroom ventilation drying heater of the first embodiment>
12 to 14 are block diagrams of a bathroom ventilation drying heater showing another example of the installation location of the ion generator. In the embodiment shown in FIG. 12, in order to supply ions to the air blown out from the first outlet 21A, the ion generator 10 exposes the ion emitting portion 10A into the first outlet 21A. , Installed on the lower surface side of the circulation ventilation fan case 27A.

Therefore, the bathroom ventilation drying heater 1A is provided with the attachment portion 201B of the ion generator 10 on the lower surface of the circulation ventilation fan case 27A adjacent to the first outlet 21A. The mounting portion 201B includes a fixing portion 202B for fixing the ion generator 10 at a predetermined position on the lower surface of the circulation ventilation fan case 27A. The fixing portion 202B detachably fixes the ion generator 10 to the circulation ventilation fan case 27A by a combination of uneven shapes and a fastening member such as a screw.

The front panel 4A includes a cover portion 401B that opens and closes a position facing the mounting portion 201B. The cover portion 401B is an example of an opening / closing member constituting the attachment / detachment means. In this example, a part of the front panel 4A is opened / closed by a rotational operation with the shaft 402B as a fulcrum.

By opening the cover portion 401B, the ion generator 10 can be attached to and detached from the mounting portion 201B. Further, by mounting the ion generator 10 on the mounting portion 201B and closing the cover portion 401B, the ion generator 10 is fixed to the mounting portion 201B.

In this example, the ion generator 10 is fixed to the main body 3A side, but it may be fixed to the front panel 4A side. Further, although the cover portion 401B is provided on the front panel 4A, it may be provided on the circulation ventilation fan case 27A.

The bathroom ventilation drying heater 1A includes a cutoff switch 203B on the mounting portion 201B. The cutoff switch 203B is an example of the cutoff means, and operates by opening and closing the cover portion 401B. When the cover portion 401B is in the closed state, when the bathroom ventilation drying heater 1A is connected to the power source, the state in which the power is supplied is maintained. On the other hand, when the cover portion 401B is opened, the cutoff switch 203B cuts off the power supply when the bathroom ventilation drying heater 1A is connected to the power supply.

In the embodiment shown in FIG. 13, in order to supply ions to the air blown from the first air outlet 21A and the second air outlet 22A, the ion generator 10 blows the ion discharge portion 10A through the air passage 28A. It is exposed inside and installed on the lower surface of the circulation ventilation fan case 27A.

Therefore, the bathroom ventilation drying heater 1A is provided with the attachment portion 201C of the ion generator 10 on the lower surface of the circulation ventilation fan case 27A adjacent to the first outlet 21A. The mounting portion 201C includes a fixing portion 202C for fixing the ion generator 10 at a predetermined position on the lower surface of the circulation ventilation fan case 27A. The fixing portion 202C detachably fixes the ion generator 10 to the circulation ventilation fan case 27A by a combination of uneven shapes and a fastening member such as a screw.

The front panel 4A includes a cover portion 401B that opens and closes a position facing the mounting portion 201C. In this example, the cover portion 401B opens and closes a part of the front panel 4A by a rotational operation with the shaft 402B as a fulcrum. By opening the cover portion 401B, the ion generator 10 can be attached to and detached from the mounting portion 201C. Further, by mounting the ion generator 10 on the mounting portion 201C and closing the cover portion 401B, the ion generator 10 is fixed to the mounting portion 201C.

The bathroom ventilation drying heater 1A includes a cutoff switch 203B on the mounting portion 201C. The cutoff switch 203B operates by opening and closing the cover portion 401B. When the cover portion 401B is in the closed state, when the bathroom ventilation drying heater 1A is connected to the power source, the state in which the power is supplied is maintained. On the other hand, when the cover portion 401B is opened, the cutoff switch 203B cuts off the power supply when the bathroom ventilation drying heater 1A is connected to the power supply.

In the embodiment shown in FIGS. 12 and 13, when the cover portion 401B is opened, the ion generator 10 is exposed from the front panel 4A, and the ion generator 10 can be attached and detached. By providing the cover portion 401B, the ion generator 10 can be attached and detached without removing the entire front panel 4A from the main body portion 3A.

Further, when the cover portion 401B is opened, the power supply is cut off by the cutoff switch 203B. This prevents the ion generator 10 from being driven while the ion generator 10 is exposed.

In the embodiment shown in FIG. 12, the ion generator 10 can be removed from the mounting portion 201B by opening the cover portion 401B and operating the fixing portion 202B. The cover portion 401B is opened and the fixing portion 202B is operated to remove the used ion generator 10 from the mounting portion 201B and disconnect the electrical connection between the ion generator 10 and the main body portion 3A side.

A new ion generator 10 is attached to the attachment portion 201B from which the used ion generator 10 has been removed, and is fixed to the attachment portion 201B by the fixing portion 202B, and the ion generator 10 and the main body portion 3A side are electrically connected. Make a connection. Here, in the state where the cover portion 401B is open, the power supply is cut off by the cutoff switch 203B, so that even if the ion generator 10 and the main body portion 3A side are electrically connected, the ion generator 10 is still connected. Electricity does not flow.

Then, the cover portion 401B is closed. When the cover portion 401B is closed, the power is supplied by the cutoff switch 203B, and the bathroom ventilation drying heater 1A can be operated.

Similarly, in the embodiment shown in FIG. 13, the ion generator 10 can be removed from the mounting portion 201C by opening the cover portion 401B and operating the fixing portion 202C. The cover portion 401B is opened and the fixing portion 202C is operated to remove the used ion generator 10 from the mounting portion 201C and disconnect the electrical connection between the ion generator 10 and the main body portion 3A side.

A new ion generator 10 is attached to the attachment portion 201C from which the used ion generator 10 has been removed, and is fixed to the attachment portion 201C by the fixing portion 202C, and the ion generator 10 and the main body portion 3A side are electrically connected. Make a connection.

Then, the cover portion 401B is closed. When the cover portion 401B is closed, the power is supplied by the cutoff switch 203B, and the bathroom ventilation drying heater 1A can be operated.

In the embodiment shown in FIG. 14, in order to supply ions to the air sucked from the circulation ventilation suction port 20A, the ion generator 10 directs the ion discharge portion 10A toward the circulation ventilation suction port 20A, and the circulation ventilation fan case. It is installed on the lower surface of 27A.

Therefore, the bathroom ventilation drying heater 1A is provided with the attachment portion 201D of the ion generator 10 on the lower surface of the circulation ventilation fan case 27A adjacent to the circulation ventilation suction port 20A. The mounting portion 201D includes a fixing portion 202D for fixing the ion generator 10 at a predetermined position on the lower surface of the circulation ventilation fan case 27A. The fixing portion 202D detachably fixes the ion generator 10 to the circulation ventilation fan case 27A by a combination of uneven shapes and a fastening member such as a screw.

The bathroom ventilation drying heater 1A includes a cutoff switch 203D on the mounting portion 201D. The cutoff switch 203D is an example of the cutoff means, and is operated by the attachment / detachment operation of the front panel 4A. When the front panel 4A is attached to the main body 3A, when the bathroom ventilation drying heater 1A is connected to the power source, the state in which the power is supplied is maintained. On the other hand, the cutoff switch 203B cuts off the power supply when the front panel 4A is removed from the main body 3A and the bathroom ventilation drying heater 1A is connected to the power supply.

In the embodiment shown in FIG. 14, when the front panel 4A is removed from the main body 3A, the ion generator 10 is exposed and the ion generator 10 can be attached and detached. When the front panel 4A is removed from the main body 3A, the power supply is cut off by the cutoff switch 203D. This prevents the ion generator 10 from being driven while the ion generator 10 is exposed.

By removing the front panel 4A from the main body 3A and operating the fixing portion 202D, the ion generator 10 can be removed from the mounting portion 201D. By operating the fixed portion 202D, the used ion generator 10 is removed from the mounting portion 201D, and the electrical connection between the ion generator 10 and the main body portion 3A side is disconnected.

A new ion generator 10 is attached to the attachment portion 201D from which the used ion generator 10 has been removed, and is fixed to the attachment portion 201D by the fixing portion 202D, and the ion generator 10 and the main body portion 3A side are electrically connected. Make a connection. Here, in the state where the front panel 4A is removed, the power supply is cut off by the cutoff switch 203D, so that even if the ion generator 10 and the main body 3A side are electrically connected, the ion generator 10 is connected. Does not flow electricity.

Then, the front panel 4A is attached to the main body 3A. When the front panel 4A is attached to the main body 3A, the power is supplied by the cutoff switch 203D, and the bathroom ventilation drying heater 1A can be operated.

By supplying ions to the air sucked from the circulation ventilation suction port 20A, the ions mainly function as a static elimination factor for static elimination of the impeller 25A, and the ion generator 10 generates and discharges ions. It functions as a factor generator.

By generating approximately the same number of positive and negative ions in the ion generator 10 in conjunction with the operation of the circulation ventilation fan 2A in the bathroom ventilation drying heater 1A, the components in the positively charged air and the impeller 25A When is positively charged, the impeller 25A is statically charged with negative ions. Further, by generating positive ions from the ion generator 10, the negatively charged components in the air and, when the impeller 25A is negatively charged, the impeller 25A is discharged with positive ions.

<Structure example of bathroom ventilation drying heater of the second embodiment>
FIG. 15 is a configuration diagram showing an example of the bathroom ventilation drying heater of the second embodiment, and is a side view showing the internal configuration of the bathroom ventilation drying heater, which is a side view showing the internal configuration of the bathroom ventilation drying heater of the second embodiment. Machine 1B includes a cleaning means for cleaning the functional factor generating portion as a performance maintaining means for maintaining the performance of the functional factor generating portion that generates the functional factor released into the air blown into the room.

The bathroom ventilation drying heater 1B includes an ion generator 10 as a functional factor generator. The ion generator 10 generates and releases ions as a functional factor to remove bacteria. Therefore, the ions mainly function as an air purifying factor that purifies the air, and the ion generator 10 functions as an air purifying factor generator that generates and releases ions.

The bathroom ventilation drying heater 1B cleans the ion generator 10 by the operation of the air passage switching damper 6A. Therefore, the air passage switching damper 6A is provided with a brush 601 at the tip of the main air passage switching portion 61A on the upstream side of the shaft 60A with respect to the air flow direction. The brush 601 is an example of a cleaning means, and is displaced by drawing an arc locus 602 by the rotational operation of the air passage switching damper 6A with the shaft 60A as a fulcrum.

Since the bathroom ventilation drying heater 1B supplies ions to the air blown from the first air outlet 21A and the second air outlet 22A, the ion generator 10 blows the ion discharge portion 10A into the air passage 28A. It is exposed to the circulation ventilation fan case 27A.

Then, in order to clean the emission portion 10A of the ion generator 10 with the brush 601, the ion generator 10 emits ions on the locus 602 of the brush 601 by the rotational operation of the air passage switching damper 6A with the shaft 60A as the fulcrum. It is installed so that the portion 10A is located.

In this example, as shown by the solid line in FIG. 15, in the operation of moving the air passage switching damper 6A to the ventilation position, the inside of the circulation ventilation fan case 27A, which is the position where the brush 601 comes into contact with the emission portion 10A of the ion generator 10. The ion generator 10 is installed on the lower surface.

<Operation example of the bathroom ventilation drying heater of the second embodiment>
When the above-described ventilation operation mode is executed, the air passage switching damper 6A moves to the ventilation position, and the brush 601 comes into contact with the emission portion 10A of the ion generator 10. As a result, the emission portion 10A of the ion generator 10 is cleaned by the brush 601. In the ventilation operation mode, since the ion generator 10 is not driven, the brush 601 may come into contact with the emission unit 10A of the ion generator 10.

When the 24-hour ventilation operation mode is executed, the air passage switching damper 6A is stopped at the ventilation position, so that the discharge portion 10A of the ion generator 10 cannot be sufficiently cleaned by the brush 601.

Therefore, the ion generator 10 may be cleaned at a predetermined timing. For example, the control unit 81A measures the time when the ion generator 10 is driven, and determines the cleaning time of the ion generator 10 from the cumulative value of the time when the ion generator 10 is driven. When the control unit 81A determines that it is time to clean the ion generator 10, the operation unit 82 or the like notifies the control unit 81A.

Further, it has a cleaning mode for moving the air passage switching damper 6A to the ventilation position, and when the cleaning time comes, the operation unit 82 operates or automatically executes the cleaning mode. As a result, the ion generator 10 can be cleaned without attaching and detaching the ion generator 10 from the main body 3A, and the performance of the ion generator 10 can be maintained for a long period of time.

The present invention is applied to a blower installed in a space for drying an object to be dried, such as a bathroom.

1A: Bathroom ventilation drying heater, 10: Ion generator (functional factor generator), 10A: Discharge part, 2A: Circulation ventilation fan (blower means), 20A: Circulation ventilation suction Mouth (suction port), 21A ... 1st outlet (outlet), 22A ... 2nd outlet (outlet), 23A ... ventilation outlet, 25A ... impeller, 27A・ ・ ・ Circulation ventilation fan case, 201A ・ ・ ・ Mounting part, 202A ・ ・ ・ Fixed part, 203A ・ ・ ・ Breaking switch (cutting means), 3A ・ ・ ・ Main body part, 4A ・ ・ ・ Front panel (panel member) , 40A ... Suction port grill, 41A ... 1st air outlet grill, 42A ... 2nd air outlet grill, 401A ... Cover part (detachable means, opening / closing member), 402A ... Shaft 5, 5 ... heater, 6A ... air passage switching damper, 601 ... brush (cleaning means), 100 ... bathroom

Claims (4)

The main body that has a ventilation means that sucks in and blows out the air in the room,
The panel member attached to the main body and
A functional factor generating unit that generates a functional factor supplied to the air flow generated by the blowing means,
It is provided with a mounting portion to which the functional factor generating portion is mounted.
The blowing means includes a heating means, a suction port through which the air sucked by the blowing means passes, and warm air when the heating means is driven, and air corresponding to the inside of the bathroom when the heating means is not driven. It has a first outlet to be blown out and a second outlet to blow out the air that agitates the air in the room.
The panel member is provided on a surface having the suction port, the first air outlet, and the second air outlet, and communicates with the suction port grill that communicates with the suction port and the first air outlet. It has a first outlet grill, a second outlet grill communicating with the second outlet, and an attachment / detachment means for attaching / detaching the functional factor generating portion to / from the attachment portion.
The functional factor generating portion has a functional factor releasing portion, and the releasing portion is installed so as to be exposed in the second outlet .
The attachment / detachment means is a blower device including an opening / closing member that opens / closes a part of the panel member facing the position of the attachment portion. The blower according to claim 1, further comprising a shut-off means for shutting off the power supply when the opening / closing member is operated by the rotational operation of the opening / closing member and the opening / closing member is in an open state in which the functional factor generating portion can be attached / detached. apparatus. The blower according to claim 1 or 2, wherein the attachment portion detachably fixes the functional factor generating portion to the main body portion. The blower according to claim 1 or 2 , wherein the mounting portion detachably fixes the functional factor generating portion to the panel member.

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