JP2023018237A - Blower - Google Patents

Abstract

To provide a blower capable of realizing various blowing patterns.SOLUTION: A blower includes: a generation mechanism generating first air flow and second air flow; a blowout mechanism provided with a first blowout port and a second blowout port respectively blowing out the first air flow and the second air flow in a manner of arranging the first blowout port and the second blowout port in a first direction; a first wind direction plate disposed on the first blowout port and capable of changing a wind direction in a second direction crossing the first direction of the first air flow; a second wind direction plate disposed on the second blowout port and capable of changing a wind direction in the second direction of the second air flow; and a control portion capable of allowing the first wind direction plate and the second wind direction plate to independently change the wind direction in the second direction, of the first air flow and the second air flow.SELECTED DRAWING: Figure 1

Description

The present disclosure relates to blowers.

In the electric fan disclosed in Patent Document 1, a signal from a transmitter is received by a receiver. Also, the wind direction changing motor and the vertical swinging motor are driven so that the horizontal position and elevation angle of the head of the fan are directed toward the transmitter (abstract).

JP-A-5-033795

In the electric fan described in Patent Document 1, air is sent exclusively to the person holding the transmitter. Therefore, it is difficult to realize various air blowing patterns.

The present disclosure has been made in view of this problem. An object of one aspect of the present disclosure is to provide a fan capable of realizing various air blowing patterns.

A blower according to one aspect of the present disclosure includes a generation mechanism that generates a first airflow and a second airflow, and a first outlet and a first outlet that blow out the first airflow and the second airflow, respectively. a blowing mechanism having two blowing openings, wherein the first blowing opening and the second blowing opening are arranged in a first direction; a first wind direction plate capable of changing the wind direction in a second direction that intersects with the first direction of; a second wind direction plate capable of changing the direction of the wind, and the first air direction and the second direction of the air flow in the second direction of the first air flow and the second air direction, respectively. and a control unit that can change the wind direction independently of each other.

A fan according to another aspect of the present disclosure includes a generation mechanism that generates a first airflow and a second airflow, and a first outlet that blows out the first airflow and the second airflow, respectively. and a second outlet are formed, and the first outlet and the second outlet are arranged in a first direction; a first wind direction plate capable of changing the direction of the air flow; a second wind direction plate arranged at the second outlet and capable of changing the direction of the second air flow; The first airflow direction plate and the second airflow direction plate can change the wind directions of the first airflow and the second airflow independently of each other, and the first airflow and the second airflow can be changed independently of each other. causing the generation mechanism to change the air volumes of the first air flow and the second air flow so that changes in air volume of the air flows are different from each other; Control to change the wind directions of the first airflow and the second airflow, respectively, by the first wind direction plate and the second wind direction plate so that the changes in wind direction are different from each other. and

It is a perspective view which illustrates the air blower of 1st Embodiment typically. It is a top view which illustrates the air blower of 1st Embodiment typically. It is a side view which illustrates the air blower of 1st Embodiment typically. It is a perspective view which illustrates the inside of the air blower of 1st Embodiment typically. 3 is a block diagram schematically illustrating a control system of the blower of the first embodiment; FIG. It is a top view which illustrates typically the operation part with which the air blower of 1st Embodiment is equipped. 4 is a flowchart showing operations performed by the blower of the first embodiment in response to selection of an air cleaning/blowing mode; 4 is a flowchart showing operations performed by the blower of the first embodiment in response to selection of an air cleaning/blowing mode; 4 is a flow chart showing operations performed by the blower of the first embodiment in response to selection of an air cleaning/following air blowing mode. 4 is a flowchart showing operations performed by the blower of the first embodiment in response to selection of a sterilization mode; 9 is a flowchart showing another example of the operation performed by the blower of the first embodiment in response to selection of the sterilization mode; 4 is a flowchart showing operations performed by the blower of the first embodiment in response to selection of an enhanced air circulation mode; 7 is a flow chart showing operations performed by the blower of the first embodiment in response to selection of a dust removal mode; 4 is a flow chart showing operations performed by the blower of the first embodiment in response to selection of an air agitation mode;

Hereinafter, embodiments of the present disclosure will be described with reference to the drawings. In the drawings, the same or equivalent elements are denoted by the same reference numerals, and overlapping descriptions are omitted.

1. First Embodiment 1.1 Outline of Blower FIG. 1 is a perspective view schematically illustrating the blower of the first embodiment. FIG. 2 is a top view schematically illustrating the blower of the first embodiment; FIG. FIG. 3 is a side view schematically illustrating the blower of the first embodiment; FIG.

The blower 1 of the first embodiment illustrated in FIGS. 1, 2 and 3 has a blowing function, an air cleaning function, a heating function and a sterilization function. The blower 1 may have functions other than these functions. For example, the blower 1 may have a cooling function, a humidifying function, a dehumidifying function, a deodorizing function, an insect repelling function, and the like.

The blower 1 blows out a first airflow 801L and a second airflow 801R illustrated in FIGS. The blower 1 can change the wind directions of the first airflow 801L and the second airflow 801R in the first direction D1 independently of each other. The wind direction in the second direction D2 can be changed independently of each other, and the air volumes of the first airflow 801L and the second airflow 801R can be changed independently of each other. Thereby, the blower 1 can realize various blowing patterns. Changing the wind direction of the first airflow 801L and the second airflow 801R in the first direction D1 is the direction in which the first airflow 801L and the second airflow 801R travel in the first direction D1. Each means to change an ingredient. Changing the wind direction in the second direction D2 of the first airflow 801L and the second airflow 801R means changing the direction in which the first airflow 801L and the second airflow 801R travel in the second direction D2. Each means to change an ingredient.

The blower 1 rotates the first airflow 801L and the second airflow 801R in the first direction D1 so that the first airflow 801L and the second airflow 801R join together to generate a combined airflow 811. can be oriented in the wind.

The second direction D2 intersects the first direction D1. The second direction D2 forms 90° with the first direction D1, the first direction D1 is horizontal and the second direction D2 is vertical. The second direction D2 may form an angle other than 90° with the first direction D1, the first direction D1 may be a direction other than the horizontal direction, and the second direction D2 may be a direction other than the vertical direction. It can be a direction.

As illustrated in FIGS. 1, 2 and 3, the fan 1 includes a housing 11 and has a first outlet 21L and a second outlet 21R.

The blower 1 blows out a first airflow 801L and a second airflow 801R from the first blowout port 21L and the second blowout port 21R, respectively.

The first outlet 21L and the second outlet 21R are arranged in the first direction D1.

Each of the first outlet 21L and the second outlet 21R has a slit-like shape extending in the second direction D2. Therefore, each of the first airflow 801L and the second airflow 801R blown out from the first blowout port 21L and the second blowout port 21R is a belt-like airflow. The width direction of the band-shaped airflow is the second direction D2.

The first outlet 21L and the second outlet 21R have the same size and are arranged at the same position in the second direction D2. As a result, the entire first airflow 801L and the entire second airflow 801R can be uniformly merged.

By forming each of the first air flow 801L and the second air flow 801R into a belt-shaped air flow and uniformly joining the entire first air flow 801L and the entire second air flow 801R, strength is achieved at the center. is the strongest and the intensity gradually weakens from the center toward the periphery.

The housing 11 has a surface 11S arranged between the first outlet 21L and the second outlet 21R. The surface 11S is a flat surface. The housing 11 has a rectangular parallelepiped shape. Surface 11 S is included on one side of housing 11 . All or part of the surface 11S may be curved. The housing 11 may have a shape other than the rectangular parallelepiped shape. Surface 11S may be included on a surface other than one side surface of housing 11 .

The first airflow 801L and the second airflow 801R leave the surface 11S and meet at a junction location 821 away from the surface 11S.

By separating the first airflow 801L and the second airflow 801R from the surface 11S, pressure loss in the first airflow 801L and the second airflow 801R can be suppressed. As a result, the blowing efficiency of the blower 1 can be increased.

1.2 Internal Structure of Blower FIG. 4 is a perspective view schematically illustrating the inside of the blower of the first embodiment.

As illustrated in FIG. 4 , the blower 1 includes a generation mechanism 12 , a filter 13 , a heating mechanism 14 , a blowout mechanism 15 and a wind direction changing mechanism 16 .

The generating mechanism 12 , the filter 13 , the heating mechanism 14 , the blowing mechanism 15 and the wind direction changing mechanism 16 are arranged inside the housing 11 .

The generating mechanism 12 generates a first airflow 801L and a second airflow 801R. The generated first airflow 801L and second airflow 801R flow from the outside of the fan 1 to the outside of the fan 1 via the filter 13, the generation mechanism 12, the heating mechanism 14, and the blowing mechanism 15 in sequence.

As illustrated in FIG. 4, the generating mechanism 12 includes a first fan motor 31L, a second fan motor 31R, a first fan 32L, a second fan 32R, a first duct 33L and a second duct. 33R.

The first fan motor 31L and the second fan motor 31R rotate the first fan 32L and the second fan 32R, respectively. The first fan 32L and the second fan 32R thereby generate a first airflow 801L and a second airflow 801R, respectively.

The first fan 32L and the second fan 32R are sirocco fans suitable for generating zonal airflow. As a result, the first airflow 801L and the second airflow 801R, which are band-shaped airflows, can be easily generated.

A first duct 33L directs a first airflow 801L from the first fan 32L to the first heater 51L described below. A second duct 33R directs a second airflow 801R from the second fan 32R to the second heater 51R described below.

The first fan 32L and the second fan 32R are arranged in the second direction D2. Thereby, the area occupied by the fan 1 can be reduced when the fan 1 is installed.

As illustrated in FIG. 4, the first fan 32L comprises the first two fans 41L. The first two fans 41L are arranged in the second direction D2. The first fan motor 31L is a double shaft motor, is arranged between the first two fans 41L, and drives the first two fans 41L to rotate.

As illustrated in FIG. 4, the second fan 32R comprises a second two fans 41R. The second two fans 41R are arranged in the second direction D2. The second fan motor 31R is a double shaft motor, is arranged between the second two fans 41R, and drives the second two fans 41R to rotate.

Filter 13 comprises a filter that removes inclusions contained in first air flow 801L and second air flow 801R from first air flow 801L and second air flow 801R. The filter may be a high efficiency particulate air (HEPA) filter, a dust collection filter, a deodorizing filter, an integrated dust collecting and deodorizing filter, or the like. Filter 13 may comprise a filter that introduces fresh inclusions into first airflow 801L and second airflow 801R. The filter is a humidification filter or the like.

The heating mechanism 14 heats the first airflow 801L and the second airflow 801R.

As illustrated in FIG. 4, the heating mechanism 14 includes a first heater 51L and a second heater 51R.

The first heater 51L and the second heater 51R heat the first airflow 801L and the second airflow 801R, respectively.

The blowout mechanism 15 blows out the first airflow 801L and the second airflow 801R to the outside of the blower 1 .

As illustrated in FIG. 4, the blowing mechanism 15 includes a first nozzle 62L and a second nozzle 62R.

A first outlet 21L and a second outlet 21R are formed in the first nozzle 62L and the second nozzle 62R, respectively.

As illustrated in FIG. 4, the wind direction changing mechanism 16 includes a first louver 72L and a second louver 72R.

As illustrated in FIG. 4, the first louver 72L and the second louver 72R are provided with a first wind deflector 81L and a second wind deflector 81R, respectively.

The first wind direction plate 81L and the second wind direction plate 81R are arranged at the first outlet 21L and the second outlet 21R, respectively.

The first airflow direction plate 81L and the second airflow direction plate 81R direct the wind direction of the first airflow 801L and the second airflow 801R in a direction according to the orientation of the first airflow direction plate 81L and the second airflow direction plate 81R. Bend each to The postures of the first wind direction plate 81L and the second wind direction plate 81R can be changed. Therefore, the first airflow direction plate 81L and the second airflow direction plate 81R can change the wind directions of the first airflow 801L and the second airflow 801R, respectively. The first airflow direction plate 81L and the second airflow direction plate 81R can change the wind direction of the first airflow 801L and the second airflow 801R in the second direction D2, respectively.

The blower 1 may include elements other than the elements described above. For example, the blower 1 may include a cooling mechanism or the like that cools the first airflow 801L and the second airflow 801R.

1.3 Control System of Air Blower FIG. 5 is a block diagram schematically illustrating the control system of the air blower according to the first embodiment.

As illustrated in FIG. 5, the blower 1 includes a generating mechanism 12, a blowing mechanism 15, an air direction changing mechanism 16, a sterilization mechanism 17, an acquisition unit 101, a human sensor 102, a temperature sensor 103, a detection unit 104, and an air direction acquisition unit. A unit 105 , a cleanliness detection unit 106 and a control unit 111 are provided.

The acquisition unit 101 acquires mode information 841 indicating the selected mode, wind direction information 842 indicating the selected wind direction, air volume information 843 indicating the selected air volume, and diffuse setting 844 indicating whether or not to diffuse. Then, the acquired mode information 841 , wind direction information 842 , air volume information 843 and diffuse setting 844 are supplied to the control unit 111 .

The acquisition unit 101 may acquire the mode information 841, the wind direction information 842, the air volume information 843, and the diffuse setting 844 from the operation performed by the user, or acquire the mode information 841 and the wind direction information from the signal received from another device. 842, air volume information 843 and diffuse setting 844 may be obtained. Other devices are remote controllers, personal computers, smartphones, tablets, cloud servers, and the like.

Modes that can be selected include an air cleaning/ventilation mode, an air cleaning/heating mode, an air cleaning/follow-ventilation mode, a sterilization mode, an enhanced air circulation mode, a dust removal mode, and an air agitation mode.

The human sensor 102 detects a person, acquires human information 851 that is information about the detected person, and supplies the acquired human information 851 to the control unit 111 . As illustrated in FIG. 5, the human sensor 102 includes a distance sensor 121 that detects the distance to the detected person, and the acquired human information 851 includes the distance to the detected person.

The temperature sensor 103 detects temperature, acquires temperature information 861 indicating the detected temperature, and supplies the acquired temperature information 861 to the control unit 111 .

The detection unit 104 detects a wall, acquires wall information 871 that is information about the detected wall, and supplies the acquired wall information 871 to the control unit 111 . As illustrated in FIG. 5, the detection unit 104 includes a distance sensor 131 that detects the detected distance to the wall, and the acquired wall information 871 includes the detected distance to the wall.

The wind direction acquisition unit 105 acquires wind direction information 881 indicating the wind direction of air flows other than the first air flow 801L and the second air flow 801R, and supplies the acquired wind direction information 881 to the control unit 111 . The airflow is, for example, airflow generated by an air conditioner. If the airflow is generated by an air conditioner, the wind direction acquisition unit 105 acquires the wind direction information 881 from the data received from the air conditioner.

The cleanliness detection unit 106 detects the cleanliness of the air, acquires cleanliness information 891 indicating the detected cleanliness of the air, and supplies the acquired cleanliness information 891 to the control unit 111 . As shown in FIG. 5, the cleanliness detection unit 106 includes a dust sensor 141 that detects the amount of dust and an odor sensor 142 that detects the strength of odor. including the amount of dust collected and the intensity of the odor.

As illustrated in FIG. 5, the generation mechanism 12 includes the above-described first fan motor 31L, second fan motor 31R, first fan 32L, and second fan 32R.

As illustrated in FIG. 5, the blowout mechanism 15 includes a first damper motor 151L, a second damper motor 151R, a first damper 152L and a second damper 152R.

As illustrated in FIG. 5, the first damper 152L and the second damper 152R are provided with a first wind deflector 161L and a second wind deflector 161R, respectively.

The first air deflector 161L and the second air deflector 161R are arranged at the first air outlet 21L and the second air outlet 21R, respectively, behind the first air deflector 81L and the second air deflector 81R, respectively. placed.

The first airflow direction plate 161L and the second airflow direction plate 161R direct the wind direction of the first airflow 801L and the second airflow 801R in a direction according to the attitude of the first airflow direction plate 161L and the second airflow direction plate 161R. Bend each to The postures of the first wind direction plate 161L and the second wind direction plate 161R can be changed. Therefore, the first airflow direction plate 161L and the second airflow direction plate 161R can change the wind directions of the first airflow 801L and the second airflow 801R, respectively. The first airflow direction plate 161L and the second airflow direction plate 161R can change the first direction D1 of the first airflow 801L and the second airflow 801R, respectively.

The control unit 111 includes a processor, memory and storage. The processor may be a central processing unit (CPU), a graphics processing unit (GPU), a digital signal processor (DSP), or the like. The memory may be random access memory (RAM), read only memory (ROM), or the like. The storage may be flash memory, solid state drive (SSD), hard disk drive, or the like. A control program is installed in the storage. The installed control program is loaded into memory. The loaded program is executed by the processor. As a result, the control unit 111 implements the functions described below. All or part of the functions realized by the control unit 111 may be realized by hardware.

The controller 111 supplies a first control signal 901L and a second control signal 901R to the first fan motor 31L and the second fan motor 31R, respectively. The first fan motor 31L and the second fan motor 31R rotate the first fan 32L and the second fan 32R at rotation speeds corresponding to the supplied first control signal 901L and second control signal 901R, respectively. rotationally driven. Thereby, the control unit 111 can cause the first fan 32L and the second fan 32R to change the air volumes of the first airflow 801L and the second airflow 801R, respectively.

The controller 111 can independently supply the first control signal 901L and the second control signal 901R. Thereby, the control unit 111 can independently change the air volumes of the first air flow 801L and the second air flow 801R in the first fan 32L and the second fan 32R.

The control unit 111 supplies a first control signal 911L and a second control signal 911R to the first damper motor 151L and the second damper motor 151R, respectively. The first damper motor 151L and the second damper motor 151R respectively rotate the first wind direction plate 161L and the second wind direction plate 161R by rotation angles according to the supplied first control signal 911L and second control signal 911R. rotationally driven. Thereby, the control unit 111 can cause the first airflow direction plate 161L and the second airflow direction plate 161R to change the wind direction of the first airflow 801L and the second airflow 801R in the first direction D1, respectively. .

The controller 111 can independently supply the first control signal 911L and the second control signal 911R. As a result, the control unit 111 causes the first airflow direction plate 161L and the second airflow direction plate 161R to independently change the wind direction of the first airflow 801L and the second airflow 801R in the first direction D1. be able to.

The blowout mechanism 15 may include a first nozzle motor and a second nozzle motor instead of the first damper motor 151L, the second damper motor 151R, the first damper 152L and the second damper 152R. In this case, the controller 111 supplies the first control signal and the second control signal to the first nozzle motor and the second nozzle motor, respectively. The first nozzle motor and the second nozzle motor rotate the first nozzle 62L and the second nozzle 62R by rotation angles according to the supplied first control signal and second control signal, respectively. Thereby, the control unit 111 can cause the first nozzle 62L and the second nozzle 62R to change the wind directions of the first airflow 801L and the second airflow 801R in the first direction D1, respectively.

As illustrated in FIG. 5 , the wind direction changing mechanism 16 includes a first louver motor 71L and a second louver motor 71R, and includes the above-described first louver 72L and second louver 72R.

As illustrated in FIG. 5, the first louver 72L and the second louver 72R are provided with the above-described first wind direction plate 81L and second wind direction plate 81R, respectively.

The control unit 111 supplies a first control signal 921L and a second control signal 921R to the first louver motor 71L and the second louver motor 71R, respectively. The first louver motor 71L and the second louver motor 71R rotate the first wind direction plate 81L and the second wind direction plate 81R by rotation angles according to the supplied first control signal 921L and second control signal 921R, respectively. rotationally driven. Thereby, the control unit 111 can cause the first airflow direction plate 81L and the second airflow direction plate 81R to change the wind directions of the first airflow 801L and the second airflow 801R in the second direction D2, respectively. .

The controller 111 can independently supply the first control signal 921L and the second control signal 921R. As a result, the control unit 111 causes the first airflow direction plate 81L and the second airflow direction plate 81R to independently change the wind direction of the first airflow 801L and the second airflow 801R in the second direction D2. be able to.

The sterilization mechanism 17 imparts sterilization power to the first airflow 801L and the second airflow 801R. The sterilization mechanism 17 generates ions or active species in the first airflow 801L and the second airflow 801R, and supplies the ions or active species to the first airflow 801L and the second airflow 801R. By doing so, the first air flow 801L and the second air flow 801R are given the sterilizing power.

As a method of imparting sterilization power, a discharge device, which is an example of the sterilization mechanism 17, generates a discharge generation factor, and the generated discharge generation factor is applied to the first air flow 801L and the second air flow 801R. method.

Discharge generation factors include, for example, ions or active species. As ions, positive ions (eg, H ⁺ (H ₂ O) _m (m is an arbitrary integer)), negative ions (eg, O ₂ ⁻ (H ₂ O) _n (n is an arbitrary integer)), or A combination of Examples of active species include hydroxyl radical (.OH), hydrogen radical (.H), oxygen radical (.O), hydroperoxy radical (.HO ₂ ), hydrogen peroxide (H ₂ O ₂ ), ozone (O ₃ ) and the like.

When the discharge generation factor is ions, for example, the discharge electrodes of the discharge device are arranged in each of the first air passage leading to the first air outlet 21L and the second air passage leading to the second air outlet 21R. be. One of positive ions and negative ions may be emitted from each outlet of the first outlet 21L and the second outlet 21R, or both positive ions and negative ions may be emitted. good. When one of positive ions and negative ions is emitted from each outlet, positive ions may be emitted from the first outlet 21L and positive ions may be emitted from the second outlet 21R, Positive ions may be emitted from the first outlet 21L and negative ions may be emitted from the second outlet 21R. Negative ions may be released.

The control section 111 supplies a control signal 931 to the sterilization mechanism 17 . The sterilization mechanism 17 applies sterilization power to the first airflow 801L and the second airflow 801R according to the supplied control signal 931 . Thereby, the control unit 111 can cause the sterilization mechanism 17 to impart sterilization power to the first airflow 801L and the second airflow 801R.

1.4 Operation Unit FIG. 6 is a plan view schematically illustrating the operation unit provided in the blower according to the first embodiment.

When the acquisition unit 101 acquires the mode information 841, the wind direction information 842, the air volume information 843, and the diffuse setting 844 from the operation performed by the user, the acquisition unit 101 includes the operation unit 201 illustrated in FIG.

The operation unit 201 has a power button 211 .

Fan 1 terminates its operation in response to pressing of power button 211 while fan 1 is in operation. Further, fan 1 starts operating in response to pressing of power button 211 while fan 1 is not operating.

The operation unit 201 includes an air cleaning/ventilation button 221 , an air cleaning/heating button 222 , an air cleaning/following ventilation button 223 , a sterilization button 224 , an air circulation enhancement button 225 , a dust removal button 226 and an air agitation button 227 .

The air cleaning/ventilation button 221, the air cleaning/heating button 222, the air cleaning/following ventilation button 223, the sterilization button 224, the air circulation enhancement button 225, the dust removal button 226, and the air agitation button 227 are pressed. In this case, the air cleaning/ventilation mode, the air cleaning/heating mode, the air cleaning/following ventilation mode, the sterilization mode, the enhanced air circulation mode, the dust removal mode, and the air agitation mode are selected.

When the air cleaning/ventilation button 221 is pressed while the air cleaning/ventilation mode is selected, the selected air volume is cyclically switched. The selectable air volumes include two or more fixed air volumes and automatic air volumes.

When the air cleaning/heating button 222 is pressed while the air cleaning/heating mode is selected, the selected air volume is cyclically switched. The selectable air volumes include two or more fixed air volumes and automatic air volumes.

The operation unit 201 includes a second wind direction button 231 .

When the second direction wind direction button 231 is pressed while the air cleaning/blowing mode or the air cleaning/heating mode is selected, the wind direction in the selected second direction D2 circulates. switchable.

The operation unit 201 has a diffuse button 241 .

When the diffuse button 241 is pressed while the diffuse setting 844 is off, the diffuse setting 844 is turned on. When the diffuse button 241 is pressed while the diffuse setting 844 is on, the diffuse setting 844 is turned off.

Power button 211, air cleaning/ventilation button 221, air cleaning/heating button 222, air cleaning/following ventilation button 223, sterilization button 224, air circulation enhancement button 225, dust removal button 226, air stirring button 227, second button All or part of the directional wind direction button 231 and the diffuse button 241 may be replaced with operation members other than buttons. Operation members other than buttons are touch panels, switches, dials, sliders, and the like.

1.5 Mode and Diffuse Setting When the air cleaning/blowing mode is selected, the fan 1 performs both or one of the air cleaning operation to clean the air in the room and the air blowing operation to blow air toward people. conduct.

When the fan 1 performs only the air cleaning operation, the fan 1 uses both the first airflow 801L and the second airflow 801R for the air cleaning operation.

When the fan 1 performs both the air cleaning operation and the air blowing operation, the fan 1 uses one of the first airflow 801L and the second airflow 801R for the air cleaning operation, and uses the first airflow 801L and the second airflow 801R for the air cleaning operation. The other of the two airflows 801R is used for blowing operation.

When the fan 1 performs only the blowing operation, the fan 1 uses both the first airflow 801L and the second airflow 801R for the blowing operation.

The blower 1 is provided with an air cleaning/blowing mode in which both or one of the air cleaning operation and the blowing operation is performed instead of the air cleaning mode in which the air cleaning operation is performed and the air blowing mode in which the air blowing operation is performed. Further, it is left to the user's will whether to use each of the first air flow 801L and the second air flow 801R for the air cleaning operation or the air blowing operation. This is possible because the blower 1 directs the first air flow 801L and the second air flow 801R to the first airflow direction plate 161L and the second airflow direction plate 161R. can be independently changed, and the wind direction of the second direction D2 of the first air flow 801L and the second air flow 801R can be independently changed in the first air flow direction plate 81L and the second air flow direction plate 81R, respectively. This is because the first fan 32L and the second fan 32R can independently change the air volumes of the first air flow 801L and the second air flow 801R, respectively.

When the air cleaning/heating mode is selected, the blower 1 causes the first heater 51L and the second heater 51R to heat the first airflow 801L and the second airflow 801R, respectively.

When the air cleaning/following air blowing mode is selected, the fan 1 performs both an air cleaning operation for cleaning indoor air and a following air blowing operation for following a person and blowing air toward the person.

When the fan 1 performs the air cleaning operation and the follow-blowing operation, the fan 1 uses one of the first airflow 801L and the second airflow 801R for the air cleaning operation, and uses the first airflow 801L and the second airflow 801R for the air cleaning operation. The other airflow 801R is used for follower blowing operation.

When the sterilization mode, the enhanced air circulation mode, the dust removal mode, and the air agitation mode are selected, the blower 1 performs the sterilization operation for sterilizing the room, the first air flow 801L, and the second air flow 801R. An air circulation enhancing operation for enhancing the indoor air circulation by the air flow of , a dust removing operation for removing dust adhering to the ceiling, and an air agitating operation for agitating the indoor air are performed respectively.

When the air blower 1 performs the sterilization operation, the air circulation strengthening operation, the dust removing operation, and the air stirring operation, both the first air flow 801L and the second air flow 801R are sterilized, the air circulation strengthening operation, Used for dust removal and air agitation respectively.

When the diffuse setting 844 is on, the blower 1 performs a diffuse operation of sending air to both sides of the space in front of the blower 1 .

1.6 Wind Direction and Air Volume of Air Flow The first wind direction plate 161L directs the first direction D1 of the first air flow 801L to the center direction DHC, left direction DHL and right direction DHR shown in FIG. can be either The second airflow direction plate 161R can direct the first direction D1 of the second airflow 801R to any of the center direction DHC, left direction DHL and right direction DHR illustrated in FIG. The left direction DHL is a direction inclined leftward in the horizontal direction from the center direction DHC as viewed from the back of the fan 1 . The right direction DHR is a direction inclined horizontally rightward from the central direction DHC as viewed from the back of the fan 1 .

The first wind direction plate 81L can direct the second direction D2 of the first airflow 801L to any of the central direction DVC, the downward direction DVL and the upward direction DVU illustrated in FIG. The second wind direction plate 81R can direct the second direction D2 of the second air flow 801R to any of the central direction DVC, the downward direction DVL and the upward direction DVU illustrated in FIG. The center direction DVC is horizontal. The downward direction DVL is a direction inclined vertically downward from the center direction DVC when viewed from the side of the fan 1 . The upward direction DVU is a direction inclined vertically upward from the center direction DVC when viewed from the side of the fan 1 .

The first fan 32L can set the air volume of the first airflow 801L to either low, medium, or high. The second fan 32R can set the air volume of the second airflow 801R to any of low, medium and high. Medium is stronger than weak. Strong is stronger than medium.

1.7 Air Cleaning/Blowing Mode FIGS. 7 and 8 are flow charts showing operations performed by the blower of the first embodiment in response to selection of the air cleaning/ventilation mode.

The blower 1 executes steps S101 to S115 shown in FIGS. 7 and 8 in response to selection of the air cleaning/blowing mode.

In step S101, the control unit 111 starts control A shown in Table 1. Control A is the default control performed in response to the air cleaning/ventilation mode being selected.

When performing control A, the control unit 111 causes the first wind direction plate 161L to fix the wind direction of the first direction D1 of the first airflow 801L to the right direction DHR, which is the default wind direction, and the second direction plate 161L. wind direction plate 161R to fix the wind direction of the first direction D1 of the second air flow 801R to the left direction DHL, which is the default wind direction. As a result, the controller 111 instructs the blowout mechanism 15 to set the first airflow 801L and the second airflow 801R in the first direction D1 so that the first airflow 801L and the second airflow 801R Let the winds converge.

Further, when performing control A, the control unit 111 causes the first wind direction plate 81L to direct the second direction D2 of the first airflow 801L to the central direction DVC, which is the default wind direction. 2 wind direction plate 81R to direct the second direction D2 of the second airflow 801R to the default wind direction, the central direction DVC. As a result, the control unit 111 causes the wind direction changing mechanism 16 to cause the first airflow 801L and the second airflow 801R to have the same wind direction in the second direction D2.

In addition, when performing control A, the control unit 111 causes the first fan 32L to set the air volume of the first airflow 801L to the default air volume of low, and causes the second fan 32R to set the second The air volume of air flow 801R is set to weak, which is the default air volume. Thereby, the control unit 111 causes the generation mechanism 12 to make the air volumes of the first air flow 801L and the second air flow 801R the same.

In subsequent step S102, the control unit 111 acquires the wind direction information 842 and the air volume information 843, and determines whether or not the wind direction or the air volume in the second direction D2 has been selected based on the acquired wind direction information 842 and air volume information 843. judge. When determining that the wind direction or air volume in the second direction D2 is selected, the control unit 111 executes step S103 and then step S104. On the other hand, when the control unit 111 determines that the wind direction or air volume in the second direction D2 has not been selected, it executes step S104 without executing step S103.

In step S103, the control unit 111 starts control B shown in Table 1.

When performing control B, the control unit 111 causes the first wind direction plate 161L to fix the wind direction of the first direction D1 of the first airflow 801L to the right direction DHR, which is the default wind direction, and the second wind direction plate 161R to fix the wind direction of the first direction D1 of the second airflow 801R to the left direction DHL, which is the default wind direction. As a result, the controller 111 instructs the blowout mechanism 15 to set the first airflow 801L and the second airflow 801R in the first direction D1 so that the first airflow 801L and the second airflow 801R Let the winds converge.

Further, when the control unit 111 determines that the wind direction of the second direction D2 is selected, when performing the control B, the control unit 111 directs the first wind direction plate 81L to the second direction D2 of the first air flow 801L. is directed in the selected second direction D2, and the second wind direction plate 81R directs the second airflow 801R in the second direction D2 in the selected second direction D2. turn it into the wind. As a result, the control unit 111 causes the wind direction changing mechanism 16 to cause the first airflow 801L and the second airflow 801R to have the same wind direction in the second direction D2. This makes it possible to send air toward the half of the person's body. The wind direction of the second direction D2 that can be selected is the central direction DVC, the downward direction DVL or the upward direction DVU. The control unit 111 causes the first airflow direction plate 81L and the second airflow direction plate 81R to synchronously change the wind direction of the first airflow 801L and the second airflow 801R in the second direction D2.

Further, when the control unit 111 determines that the air volume is selected, when performing the control B, the control unit 111 causes the first fan 32L to set the air volume of the first air flow 801L to the selected air volume. of the second airflow 801R to the selected airflow. Thereby, the control unit 111 causes the generation mechanism 12 to make the air volumes of the first air flow 801L and the second air flow 801R the same. The air volume that can be selected is weak, medium or strong. The control unit 111 causes the first fan 32L and the second fan 32R to synchronously change the air volumes of the first airflow 801L and the second airflow 801R.

According to steps S102 and S103, in response to selecting the wind direction in the second direction D2, the wind direction in the second direction D2 of the first air flow 801L and the second air flow 801R is selected. The wind is directed in the second direction D2. Also, in response to the air volume being selected, the air volumes of the first air flow 801L and the second air flow 801R are set to the selected air volume. On the other hand, when the wind direction of the second direction D2 is not selected, the wind direction of the first airflow 801L and the second airflow 801R is maintained in the second direction D2. Moreover, when the air volume is not selected, the air volumes of the first air flow 801L and the second air flow 801R are maintained.

In step S<b>104 , the control unit 111 determines whether or not the automatic air volume is selected based on the acquired air volume information 843 . When the control unit 111 determines that the automatic air volume is selected, the control unit 111 executes step S105. On the other hand, when the control unit 111 determines that the automatic air volume has not been selected, the control unit 111 executes step S109.

In step S105, the control unit 111 acquires the cleanliness information 891, and based on the acquired cleanliness information 891, determines whether the cleanliness detected by the cleanliness detection unit 106 is higher than the standard cleanliness. do. When the control unit 111 determines that the cleanliness is higher than the standard cleanliness, the control unit 111 executes step S106. On the other hand, when the control unit 111 determines that the cleanliness is not higher than the reference cleanliness, it executes step S109.

In step S106, the control unit 111 starts measuring time.

In subsequent step S107, the control unit 111 acquires the cleanliness information 891, and based on the acquired cleanliness information 891, determines whether the cleanliness detected by the cleanliness detection unit 106 is less than the standard cleanliness. judge. When the control unit 111 determines that the cleanliness is less than the standard cleanliness, the control unit 111 executes step S108. On the other hand, when the control unit 111 determines that the cleanliness is not less than the standard cleanliness, it executes step S109.

In step S108, the control unit 111 ends the time measurement.

According to steps S104 to S108, the elapsed time is measured after the automatic air volume is selected and the cleanliness level becomes equal to or higher than the standard cleanliness level.

In step S109, the control unit 111 determines whether or not the time being measured is equal to or longer than the reference time. When the control unit 111 determines that the measured time is equal to or longer than the reference time, it executes step S110 and then step S111. On the other hand, when the control unit 111 determines that the measured time is not equal to or longer than the reference time, the control unit 111 executes step S111 without executing step S110.

In step S110, control unit 111 starts control C shown in Table 1.

When performing control C, the control unit 111 causes the first airflow direction plate 161L to direct the first direction D1 of the first air flow 801L to the central direction DHC, and causes the second airflow direction plate 161R to The wind direction of the first direction D1 of the second airflow 801R is made to be the center direction DHC. As a result, the controller 111 instructs the blowout mechanism 15 to set the first airflow 801L and the second airflow 801R in the first direction D1 so that the first airflow 801L and the second airflow 801R Make the wind direction parallel. The wind directions in the first direction D1 of the first airflow 801L and the second airflow 801R are not fixed. Therefore, the user can finely adjust the wind directions in the first direction D1 of the first airflow 801L and the second airflow 801R.

Further, when performing control C, the control unit 111 causes the first airflow direction plate 81L to direct the second direction D2 of the first air flow 801L to the downward direction DVL. Then, the wind direction of the second direction D2 of the second air flow 801R is made downward DVL. As a result, the control unit 111 causes the wind direction changing mechanism 16 to cause the first airflow 801L and the second airflow 801R to have the same wind direction in the second direction D2.

Further, when performing control C, the control unit 111 causes the first fan 32L to set the air volume of the first air flow 801L to medium, and causes the second fan 32R to set the air volume of the second air flow 801R to inside. Thereby, the control unit 111 causes the generation mechanism 12 to make the air volumes of the first air flow 801L and the second air flow 801R the same.

According to steps S104 to S110, when the automatic air volume is selected and the cleanliness level is higher than the standard cleanliness level for the reference time or longer, the first air deflector 81L and the second air deflector 81R are The wind direction of the first airflow 801L and the second airflow 801R can be made downward DVL. As a result, the first airflow 801L and the second airflow 801R are blown onto the floor, and the dust that has fallen on the floor is blown up by the first airflow 801L and the second airflow 801R. Dirty air containing dust and air blown up is sucked into the blower 1 . The sucked dirty air is cleaned as it passes through the filter 13 .

In step S111, the control unit 111 acquires the diffuse setting 844 and determines whether the acquired diffuse setting 844 is ON. When the control unit 111 determines that the diffuse setting 844 is ON, it executes step S112 and then step S113. On the other hand, when the control unit 111 determines that the diffuse setting 844 is not ON, it executes step S113 without executing step S112.

In step S112, the control unit 111 starts control D or E shown in Table 1.

When performing control D, the control unit 111 causes the first wind direction plate 161L to fix the wind direction of the first direction D1 of the first air flow 801L to the left direction DHL, and causes the second wind direction plate 161R to , the wind direction of the first direction D1 of the second air flow 801R is fixed to the right direction DHR. As a result, the controller 111 instructs the blowout mechanism 15 to set the first airflow 801L and the second airflow 801R in the first direction D1 so that the first airflow 801L and the second airflow 801R Let the wind blow away. As a result, air is sent toward both sides of the space in front of the blower 1 . This makes it difficult for the wind to hit the person. Such control may be performed when a mode other than the air cleaning/blowing mode is selected.

Further, when performing control D, the control unit 111 causes the first wind direction plate 81L to direct the second direction D2 of the first airflow 801L to the central direction DVC, and the second wind direction plate 81R Then, the wind direction of the second direction D2 of the second air flow 801R is made to be the central direction DVC. As a result, the control unit 111 causes the wind direction changing mechanism 16 to cause the first airflow 801L and the second airflow 801R to have the same wind direction in the second direction D2.

Further, when performing control D, the control unit 111 causes the first fan 32L to reduce the air volume of the first airflow 801L to the selected air volume or the default air volume, and the second fan 32R Second, the airflow of the second airflow 801R is reduced to the selected or default airflow. Thereby, the control unit 111 causes the generation mechanism 12 to make the air volumes of the first air flow 801L and the second air flow 801R the same. The air volume that can be selected is weak, medium or strong.

On the other hand, when performing control E, the control unit 111 acquires wall information 871 and identifies the wind direction along the wall based on the acquired wall information 871 . The wind direction along the wall is specified from the distance to the wall detected by the distance measuring sensor 131 . The direction of the wind along the wall is the direction of the wind that does not move towards the wall.

Further, when performing control E, the control unit 111 directs the first airflow direction plate 161L to direct the first direction D1 of the first airflow 801L so that the wind direction of the first airflow 801L follows the wall. The second airflow direction plate 161R is caused to direct the second airflow 801R in the first direction D1 so that the second airflow 801R follows the wall. As a result, the controller 111 causes the blowout mechanism 15 to direct the first airflow 801L and the second airflow 801R in the first direction D1 to the first airflow 801L and the second airflow 801R, respectively. The wind direction of 801R is made to be the wind direction along the wall. Table 1 shows an example in which the first direction D1 of the first airflow 801L is directed leftward DHL and the first direction D1 of the second airflow 801R is directed rightward DHR. It is

Further, when performing control E, the control unit 111 directs the first air flow direction plate 81L to direct the first air flow 801L in the second direction D2 so that the first air flow 801L follows the wall. The second direction D2 of the second air flow 801R is set to the wind direction in which the second air flow 801R follows the wall. As a result, the control unit 111 causes the wind direction changing mechanism 16 to change the wind direction of the first air flow 801L and the second air flow 801R in the second direction D2 to the first air flow 801L and the second air flow 801R, respectively. The wind direction of the flow 801R is made to follow the wall. Table 1 shows an example in which the direction of the second direction D2 of the first airflow 801L is the central direction DVC and the direction of the second direction D2 of the second airflow 801R is the central direction DVC. It is

Further, when performing control E, the control unit 111 causes the first fan 32L to increase the air volume of the first airflow 801L, and causes the second fan 32R to increase the air volume of the second airflow 801R. make strong. Thereby, the control unit 111 causes the generation mechanism 12 to make the air volumes of the first air flow 801L and the second air flow 801R the same.

In step S<b>113 , the control unit 111 acquires the human information 851 and determines whether or not the human sensor 102 detects a person based on the acquired human information 851 . When the control unit 111 determines that a person has been detected, the control unit 111 executes step S114. On the other hand, when the control unit 111 determines that no person has been detected, the control unit 111 executes step S102 again. For example, the control unit 111 determines whether or not the distance to the person is shorter than the reference distance. When the control unit 111 determines that the distance to the person is shorter than the reference distance, the control unit 111 executes step S114. On the other hand, when the control unit 111 determines that the distance to the person is not shorter than the reference distance, the control unit 111 executes step S102 again.

In step S114, the control unit 111 acquires the temperature information 861, and based on the acquired temperature information 861, determines whether the temperature detected by the temperature sensor 103 is higher than the reference temperature. When the control unit 111 determines that the temperature is higher than the reference temperature, the control unit 111 executes step S115. On the other hand, when the control unit 111 determines that the temperature is not higher than the reference temperature, it executes step S102 again.

In step S115, the control unit 111 starts control F shown in Table 1.

When performing control F, the control unit 111 causes the first wind direction plate 161L to direct the first direction D1 of the first airflow 801L to the central direction DHC or the right direction DHR, and the second wind direction The plate 161R directs the first direction D1 of the first air flow 801L to the central direction DHC or the left direction DHL. As a result, the controller 111 instructs the blowout mechanism 15 to set the first airflow 801L and the second airflow 801R in the first direction D1 so that the first airflow 801L and the second airflow 801R Direct parallel or converging winds. When the first airflow 801L and the second airflow 801R are in parallel, one of the first airflow 801L and the second airflow 801R can be used for the blowing operation, and the first airflow 801L and the second airflow 801R The other of the second air streams 801R can be used for air cleaning operations.

Further, when performing control F, the control unit 111 causes the first wind direction plate 81L to direct the second direction D2 of the first air flow 801L to the upward direction DVU, and the second wind direction plate 81R Then, the wind direction of the second direction D2 of the second air flow 801R is made downward DVL. Thereby, the control unit 111 causes the wind direction changing mechanism 16 to change the wind directions of the first airflow 801L and the second airflow 801R in the second direction D2 to different wind directions. This makes it possible to send wind toward the whole body of a person.

Further, when performing control F, the control unit 111 causes the first fan 32L to set the air volume of the first air flow 801L to medium, and causes the second fan 32R to set the air volume of the second air flow 801R to inside. Thereby, the control unit 111 causes the generation mechanism 12 to make the air volumes of the first air flow 801L and the second air flow 801R the same.

According to steps S113 to S115, when a person is detected and the temperature is higher than the reference temperature, the first airflow 801L and the second air flow 801L are applied to the first airflow deflector 81L and the second air deflector 81R, respectively. The wind direction of the second direction D2 of the airflow 801R can be made to be different from each other. As a result, when the temperature is high, the air can be blown toward the whole body of a nearby person.

1.8 Air Cleaning/Following Air Blowing Mode FIG. 9 is a flow chart showing operations performed by the blower of the first embodiment in response to selection of the air cleaning/following air blowing mode.

The fan 1 executes steps S121 and S122 shown in FIG. 9 in response to the selection of the air cleaning/following fan mode.

In step S<b>121 , the control unit 111 acquires the person information 851 .

In subsequent step S122, the control unit 111 performs the control G shown in Table 2.

When performing control G, based on the acquired human information 851, the control unit 111 causes the first wind direction plate 161L to direct the first direction D1 of the first airflow 801L to the human direction, The second wind direction plate 161R directs the first direction D1 of the second air flow 801R to the non-human direction. As a result, the control unit 111 causes the blowout mechanism 15 to direct the first direction D1 of the first airflow 801L toward the person, and directs the first direction D1 of the second airflow 801R to Make it inhuman direction. The direction of the person is the wind direction in which the first airflow 801L is directed toward the person detected by the human sensor 102 . The non-human direction is a wind direction in which the second airflow 801R is not directed toward a person detected by the human sensor 102 . This allows the first airflow 801L to be used for blowing operations and the second airflow to be used for air cleaning operations.

Further, when performing control G, based on the acquired human information 851, the control unit 111 directs the first wind direction plate 81L to direct the second direction D2 of the first air flow 801L to the human direction. and causes the second wind direction plate 81R to direct the second direction D2 of the second air flow 801R to the central direction DVC. As a result, the control unit 111 causes the wind direction changing mechanism 16 to direct the second direction D2 of the first airflow 801L toward the person, and directs the second direction D2 of the second airflow 801R to , to the center direction DVC. The direction of the person is the wind direction in which the first airflow 801L is directed toward the person detected by the human sensor 102 .

Further, when performing control G, the control unit 111 causes the first fan 32L to set the air volume of the first air flow 801L to medium, and causes the second fan 32R to set the air volume of the second air flow 801R to make strong. Thereby, the control unit 111 causes the generation mechanism 12 to set the air volumes of the first air flow 801L and the second air flow 801R to different air volumes.

After step S122 is executed, step S121 is executed again. As a result, the wind direction of the first airflow 801L changes as the person moves.

1.9 Sterilization Mode FIG. 10 is a flowchart showing operations performed by the blower of the first embodiment in response to selection of the sterilization mode.

Blower 1 performs steps S131 to S134 shown in FIG. 10 in response to selection of the sterilization mode.

In step S<b>131 , the control unit 111 acquires the human information 851 and determines whether or not the human sensor 102 detects a person based on the acquired human information 851 . When the control unit 111 determines that a person has been detected, the control unit 111 executes step S132. On the other hand, when the control unit 111 determines that no person has been detected, the control unit 111 executes step S134.

In step S132, the control unit 111 acquires the temperature information 861 and determines whether or not the temperature detected by the temperature sensor 103 is lower than the reference temperature based on the acquired temperature information 861. When the control unit 111 determines that the temperature is lower than the reference temperature, the control unit 111 executes step S133. On the other hand, when the control unit 111 determines that the temperature is not lower than the reference temperature, it executes step S134.

In step S133, the control unit 111 starts control H shown in Table 3. In step S134, control unit 111 terminates control H shown in Table 3.

When performing control H, the control unit 111 causes the sterilization mechanism 17 to impart sterilization power to the first airflow 801L and the second airflow 801R.

Further, when performing control H, the control unit 111 causes the first airflow direction plate 161L to direct the first direction D1 of the first air flow 801L to the left direction DHL, and the second airflow direction plate 161R. Then, the wind direction of the first direction D1 of the second airflow 801R is set to the right direction DHR. As a result, the controller 111 instructs the blowout mechanism 15 to set the first airflow 801L and the second airflow 801R in the first direction D1 so that the first airflow 801L and the second airflow 801R Let the wind blow away. The wind directions in the first direction D1 of the first airflow 801L and the second airflow 801R are not fixed. Therefore, the user can finely adjust the wind directions in the first direction D1 of the first airflow 801L and the second airflow 801R.

Further, when performing control H, the control unit 111 causes the first airflow direction plate 81L to direct the second direction D2 of the first air flow 801L to the central direction DVC, and the second airflow direction plate 81R. Then, the wind direction of the second direction D2 of the second air flow 801R is made to be the central direction DVC. As a result, the control unit 111 causes the wind direction changing mechanism 16 to cause the first airflow 801L and the second airflow 801R to have the same wind direction in the second direction D2.

Further, when performing control H, the control unit 111 causes the first fan 32L to increase the air volume of the first airflow 801L, and causes the second fan 32R to increase the air volume of the second airflow 801R. make strong. Thereby, the control unit 111 causes the generation mechanism 12 to make the air volumes of the first air flow 801L and the second air flow 801R the same.

As a result, when a person is detected and the temperature is lower than the reference temperature, the control unit 111 causes the sterilization mechanism 17 to impart sterilization power to the first air flow 801L and the second air flow 801R, and blows out the air. The mechanism 15 changes the first direction D1 of the first airflow 801L and the second airflow 801R to the direction in which the first airflow 801L and the second airflow 801R move away from each other. As a result, it is possible to send the air having the sterilizing power to both sides of the space in front of the blower 1 . As a result, it is possible to perform sterilization while avoiding people.

Control H may be performed when the air cleaning/blowing mode is selected and the diffuse setting is on.

FIG. 11 is a flow chart showing another example of the operation performed by the blower of the first embodiment in response to selection of the sterilization mode.

Blower 1 executes step S141 shown in FIG. 11 in response to selection of the sterilization mode.

In step S141, the control unit 111 starts control I or J shown in Table 4.

When performing control I or J, the control unit 111 causes the sterilization mechanism 17 to impart sterilization power to the first airflow 801L and the second airflow 801R.

Further, when performing control I or J, the control unit 111 causes the first wind direction plate 161L to direct the first direction D1 of the first airflow 801L to the right direction DHR, and the second direction DHR. The plate 161R directs the first direction D1 of the second airflow 801R to the left direction DHL. As a result, the control unit 111 instructs the blowout mechanism 15 to set the wind directions of the first airflow 801L and the second airflow 801R in the first direction D1 so that the first airflow 801L and the second airflow 801R Let the winds converge. The wind directions in the first direction D1 of the first airflow 801L and the second airflow 801R are not fixed. Therefore, the user can finely adjust the wind directions in the first direction D1 of the first airflow 801L and the second airflow 801R. A combined airflow 811 generated by combining the first airflow 801L and the second airflow 801R advances linearly and has a large air volume.

Further, when performing control I or J, the control unit 111 causes the first airflow direction plate 81L to direct the second direction D2 of the first airflow 801L to the central direction DVC, and the second direction DVC. The plate 81R directs the second direction D2 of the second airflow 801R to the central direction DVC. As a result, the control unit 111 causes the wind direction changing mechanism 16 to cause the first airflow 801L and the second airflow 801R to have the same wind direction in the second direction D2.

Further, when performing control I, the control unit 111 causes the first fan 32L to set the air volume of the first air flow 801L to medium, and causes the second fan 32R to set the air volume of the second air flow 801R to inside. Thereby, the control unit 111 causes the generation mechanism 12 to make the air volumes of the first air flow 801L and the second air flow 801R the same. On the other hand, when performing control J, the control unit 111 causes the first fan 32L to increase the air volume of the first airflow 801L, and causes the second fan 32R to increase the air volume of the second airflow 801R. inside. Thereby, the control unit 111 causes the generation mechanism 12 to set the air volumes of the first air flow 801L and the second air flow 801R to different air volumes. By setting the air volumes of the first air flow 801L and the second air flow 801R to different air volumes, the confluence generated when the air volumes of the first air flow 801L and the second air flow 801R are set to the same air volume A combined airflow 811 different from the airflow 811 can be generated. For example, a combined airflow 811 can be generated that has a large thickness.

1.10 Enhanced Air Circulation Mode FIG. 12 is a flow chart showing operations performed by the blower of the first embodiment in response to selection of the enhanced air circulation mode.

The fan 1 performs steps S151 and S152 shown in FIG. 12 in response to the air circulation enhancement mode being selected.

In step S<b>151 , the control unit 111 acquires the wind direction information 842 .

In subsequent step S152, control unit 111 performs control K shown in Table 5.

When performing control K, the control unit 111 causes the first wind direction plate 161L to direct the first direction D1 of the first airflow 801L to the right direction DHR, and the second wind direction plate 161R The wind direction of the first direction D1 of the second airflow 801R is set to the left direction DHL. As a result, the controller 111 instructs the blowout mechanism 15 to set the first airflow 801L and the second airflow 801R in the first direction D1 so that the first airflow 801L and the second airflow 801R Let the winds converge.

Further, when performing control K, the control unit 111 causes the first wind direction plate 81L to direct the wind direction of the first airflow 801L in the second direction D2 to the wind direction based on the acquired wind direction information 842. The wind direction of the second direction D2 of the second air flow 801R is caused to approach the wind direction of the second wind direction plate 81R. As a result, the control unit 111 causes the wind direction changing mechanism 16 to cause the first airflow 801L and the second airflow 801R to have the same wind direction in the second direction D2. The wind direction is the wind direction of the airflow being generated by the air conditioner. Thereby, it is possible to enhance the circulation of the indoor air by the air flow generated by the air conditioner.

Further, when performing control K, the control unit 111 causes the first fan 32L to set the air volume of the first air flow 801L to medium, and causes the second fan 32R to set the air volume of the second air flow 801R to medium. let me inside Thereby, the control unit 111 causes the generation mechanism 12 to make the air volumes of the first air flow 801L and the second air flow 801R the same.

After step S152 is executed, step S151 is executed again. As a result, the wind directions of the first airflow 801L and the second airflow change following the change in the wind direction of the airflow generated by the air conditioner. As a result, even if the direction of the airflow generated by the air conditioner changes, the indoor air circulation by the airflow can be continuously strengthened.

1.11 Dust Removal Mode FIG. 13 is a flow chart showing operations performed by the blower of the first embodiment in response to selection of the dust removal mode.

The blower 1 executes steps S161 to S163 shown in FIG. 13 in response to the dust removal mode being selected.

In step S<b>161 , the control unit 111 acquires the human information 851 and determines whether or not the human sensor 102 has detected a person based on the acquired human information 851 . When the control unit 111 determines that a person has been detected, the control unit 111 executes step S162. On the other hand, when the control unit 111 determines that no person has been detected, the control unit 111 executes step S163.

In step S162, control unit 111 terminates control L shown in Table 6. In step S163, control unit 111 starts control L shown in Table 6.

When performing control L, the control unit 111 causes the first wind direction plate 161L to direct the first direction D1 of the first airflow 801L to the right direction DHR, and the second wind direction plate 161R The wind direction of the first direction D1 of the second airflow 801R is set to the left direction DHL. As a result, the controller 111 instructs the blowout mechanism 15 to set the first airflow 801L and the second airflow 801R in the first direction D1 so that the first airflow 801L and the second airflow 801R Let the winds converge.

Further, when performing control L, the control unit 111 causes the first wind direction plate 81L to direct the second direction D2 of the first air flow 801L to the upward direction DVU, and the second wind direction plate 81R Then, the wind direction of the second direction D2 of the second air flow 801R is made to be the upward direction DVU. As a result, the control unit 111 causes the wind direction changing mechanism 16 to cause the first airflow 801L and the second airflow 801R to have the same wind direction in the second direction D2.

Further, when performing control L, the control unit 111 causes the first fan 32L to increase the air volume of the first airflow 801L, and causes the second fan 32R to increase the air volume of the second airflow 801R. make strong. Thereby, the control unit 111 causes the generation mechanism 12 to make the air volumes of the first air flow 801L and the second air flow 801R the same.

After step S162 or S163 is executed, step S161 is executed again.

As a result, the control unit 111 causes the first airflow direction plate 81L and the second airflow direction plate 81R to generate the second air flow 801L and the second airflow 801R, respectively, when no person is detected. The wind direction of the direction D2 of is made to be the upward direction DVU. As a result, the first airflow 801L and the second airflow 801R are blown onto the ceiling, and dust adhering to the ceiling is blown off by the first airflow 801L and the second airflow 801R. Dirty air containing blown dust and air is sucked into the blower 1 . The sucked dirty air is cleaned as it passes through the filter 13 .

1.12 Air Agitation Mode FIG. 14 is a flowchart showing operations performed by the blower of the first embodiment in response to selection of the air agitation mode.

Blower 1 executes step S171 shown in FIG. 14 in response to selection of the air agitation mode.

In step S171, the control unit 111 starts the control M shown in Table 7.

When performing the control M, the control unit 111 causes the first airflow direction plate 161L to change the direction of the first airflow 801L so that the changes in the wind direction of the first airflow 801L and the second airflow 801R are different from each other. The wind direction of the first direction D1 is changed, and the second wind direction plate 161R is made to change the wind direction of the second air flow 801R in the first direction D1. As a result, the control unit 111 causes the blowout mechanism 15 to direct the first airflow 801L and the second airflow 801R so that the changes in the wind direction of the first airflow 801L and the second airflow 801R are different from each other. The direction of the wind in the first direction D1 is changed. For example, while the direction of the first air flow 801L in the first direction D1 is changing from the left direction DHL to the right direction DHR, the control unit 111 controls the direction of the second air flow 801R in the first direction D1. The blowing mechanism 15 is caused to change the first direction D1 of the first air flow 801L and the second air flow 801R so that the wind direction changes from the right direction DHR to the left direction DHL.

Further, when performing the control M, the control unit 111 controls the first airflow direction plate 81L so that the changes in the wind directions of the first airflow 801L and the second airflow 801R are different from each other. 801L is caused to change the wind direction in the second direction D2, and the second wind direction plate 81R is caused to change the wind direction in the second direction D2 of the second air flow 801R. Accordingly, the control unit 111 causes the wind direction changing mechanism 16 to change the direction of the first air flow 801L and the second air flow 801R so that the changes in the wind direction of the first air flow 801L and the second air flow 801R are different from each other. to change the wind direction in the second direction D2. For example, the control unit 111 controls the direction of the second airflow 801R in the second direction D2 while the wind direction in the second direction D2 of the first airflow 801L is changing from the downward direction DVL to the upward direction DVU. The wind direction changing mechanism 16 changes the wind direction of the first airflow 801L and the second airflow 801R in the second direction D2 so that the wind direction changes from the upward direction DVU to the downward direction DVL.

Further, when performing the control M, the control unit 111 controls the first fan 32L to control the first airflow 801L so that the changes in the air volume of the first airflow 801L and the second airflow 801R are different from each other. to change the air volume of the second fan 32R to change the air volume of the second air flow 801R. As a result, the control unit 111 causes the generation mechanism 12 to control the first airflow 801L and the second airflow 801R so that the changes in the air volumes of the first airflow 801L and the second airflow 801R are different from each other. Vary the airflow. For example, the control unit 111 causes the generation mechanism 12 to change the air volume of the second air flow 801R from strong to weak while the air volume of the first air flow 801L is changing from weak to strong. The air volumes of the first airflow 801L and the second airflow 801R are changed.

These agitate the indoor air with the first airflow 801L and the second airflow 801R. Also, depending on the conditions, turbulence may occur.

The control unit 111 causes the blowing mechanism 15 to change the wind directions of the first airflow 801L and the second airflow 801R in the first direction D1, and causes the wind direction changing mechanism 16 to change the first airflow 801L and the second airflow 801R. Either changing the wind direction of the second air flow 801R in the second direction D2 or changing the air volume of the first air flow 801L and the second air flow 801R to the generating mechanism 12. . For example, the control unit 111 causes the wind direction changing mechanism 16 to change the wind direction of the first airflow 801L and the second airflow 801R in the second direction D2, and causes the generation mechanism 12 to change the first airflow Either changing the air volume of 801L and the second air flow 801R may be performed.

Control M may be performed immediately before the action performed in response to the air cleaning and blowing mode being selected. Thereby, the cleaning efficiency of air can be improved.

The blower mechanism 15 that allows the blower 1 to change the wind direction of the first airflow 801L and the second airflow 801R in the first direction D1 and the first airflow 801L and the second airflow 801R. A mechanism capable of changing the wind directions of the first airflow 801L and the second airflow 801R may be provided in addition to the wind direction changing mechanism 16 capable of changing the wind direction of the two directions D2. For example, the blower 1 rotates the generating mechanism 12, the filter 13, the heating mechanism 14, the blowing mechanism 15, the wind direction changing mechanism 16, and the sterilizing mechanism 17 as a center around a rotation axis extending in a direction parallel to the second direction D2. An oscillating motor that can be rotated to change the wind directions in the first direction D1 of the first airflow 801L and the second airflow 801R may be provided. Rotation by the swing motor may swing the first airflow 801L and the second airflow 801R in the first direction D1. The wind direction in the first direction D1 of the first airflow 801L and the second airflow 801R may be stopped at a specific wind direction. By changing the wind directions of the first airflow 801L and the second airflow 801R using a plurality of mechanisms in this way, various air blowing methods can be realized.

The present disclosure is not limited to the above embodiments, but has substantially the same configuration, the same effect, or the same purpose as the configuration shown in the above embodiment. can be replaced with

1 Blower, 11 Housing, 12 Generation Mechanism, 13 Filter, 14 Heating Mechanism, 15 Blowing Mechanism, 16 Wind Direction Changing Mechanism, 17 Sterilization Mechanism, 21L First Outlet, 21R Second Outlet, 31L First Outlet fan motor, 32L first fan, 31R second fan motor, 32R second fan, 33L first duct, 33R second duct, 41L first two fans, 41R second two fans, 51L First heater 51R Second heater 61L First nozzle 61R Second nozzle 71L First louver motor 71R Second louver motor 72L First louver 72R Second louver 81L Second louver 1 wind direction plate 81R second wind direction plate 101 acquisition unit 102 motion sensor 103 temperature sensor 104 detection unit 105 wind direction acquisition unit 106 cleanliness detection unit 111 control unit 121 ranging sensor 131 Distance measuring sensor 141 Dust sensor 142 Odor sensor 151L First damper motor 151R Second damper motor 152L First damper 152R Second damper 161L First wind direction plate 161R Second wind direction plate 201 operation unit, 211 power button, 221 air cleaning/ventilation button, 222 air cleaning/heating button, 223 air cleaning/following ventilation button, 224 sterilization button, 225 air circulation enhancement button, 226 dust removal button, 227 air stirring button , 231 second direction wind direction button, 241 diffuse button, 801L first airflow, 801R second airflow, 841 mode information, 842 wind direction information, 843 air volume information, 844 diffuse setting, 851 person information, 861 Temperature information 871 Wall information 881 Wind direction information 891 Cleanliness information 901L First control signal 901R Second control signal 911L First control signal 911R Second control signal 921L First control signal , 921R second control signal, 931 control signal, D1 first direction, D2 second direction, DHC center direction, DHL left direction, DHR right direction, DVC center direction, DVL down direction, DVU up direction

Claims (17)

a generating mechanism for generating a first airflow and a second airflow;
A first outlet and a second outlet for blowing out the first air flow and the second air flow, respectively, are formed, and the first outlet and the second outlet are arranged in a first direction. an array of blowing mechanisms;
a first airflow direction plate disposed at the first air outlet and capable of changing a wind direction in a second direction intersecting the first direction of the first air flow;
a second wind direction plate disposed at the second outlet and capable of changing the direction of the second air flow in the second direction;
a control unit capable of causing the first wind direction plate and the second wind direction plate to independently change the wind directions of the first air flow and the second air flow in the second direction, respectively;
Blower with. The blower according to claim 1, wherein the blowing mechanism can change the wind directions of the first airflow and the second airflow in the first direction. The control unit causes the blowout mechanism to change the first direction of the first airflow and the second airflow to a direction in which the first airflow and the second airflow join. 3. The fan according to claim 2, wherein the first control is performed. An acquisition unit that acquires wind direction information indicating the selected wind direction and air volume information indicating the selected air volume,
The control unit causes the blowout mechanism to change the first direction of the first airflow and the second airflow to a direction in which the first airflow and the second airflow join. , causing the first wind direction plate and the second wind direction plate to set the wind direction of the first air flow and the second air flow in the second direction to the selected wind direction, and causing the generating mechanism to The blower according to claim 2 or 3, wherein second control is performed to set the air volume of the first air flow and the air volume of the second air flow to the selected air volume. The control unit causes the blowout mechanism to direct the first airflow and the second airflow in the first direction such that the first airflow and the second airflow move away from each other. 5. The fan according to any one of claims 2 to 4, wherein the third control is performed. A sterilization mechanism that imparts sterilization power to the first air flow and the second air flow,
The control unit causes the sterilization mechanism to impart sterilization power to the first airflow and the second airflow, and causes the blowout mechanism to apply the sterilization power to the first airflow and the second airflow. 6. The blower according to any one of claims 2 to 5, wherein a fourth control is performed so that the wind direction in the first direction is the wind direction in which the first airflow and the second airflow join. A sterilization mechanism that imparts sterilization power to the first air flow and the second air flow, a human sensor that detects a person, and a temperature sensor that detects temperature,
The control unit causes the sterilization mechanism to apply sterilization power to the first air flow and the second air flow when the person is detected by the human sensor and the temperature is lower than a reference temperature. and a fifth control for causing the blow-out mechanism to direct the first airflow and the second airflow in the first direction such that the first airflow and the second airflow move away from each other. 7. The blower according to any one of claims 2 to 6. A sterilization mechanism that imparts sterilization power to the first air flow and the second air flow,
The control unit causes the sterilization mechanism to impart sterilization power to the first airflow and the second airflow, and causes the blowout mechanism to apply the sterilization power to the first airflow and the second airflow. A wind direction in a first direction is made to be a wind direction in which the first air flow and the second air flow join, and the generation mechanism is caused to have different air volumes of the first air flow and the second air flow. The fan according to any one of claims 2 to 7, wherein the sixth control is performed. Equipped with a human sensor that detects people,
The control unit directs the blowout mechanism and the first wind direction plate to the first direction and the second direction of the first airflow, respectively. and performing a seventh control for causing the blowout mechanism to change the direction of the second airflow in the first direction to a direction in which the second airflow is not directed toward the person. A blower according to any one of the preceding claims. Equipped with a detection unit that detects walls,
The controller controls the blow-out mechanism and the first airflow direction plate so that the first direction and the second direction of the first airflow are directed to the wall, respectively. and directing the second air flow in the first direction and the second direction to the blowout mechanism and the second wind direction plate, respectively. 10. The fan according to any one of claims 2 to 9, wherein eighth control is performed to direct the wind along the wall. The control unit
causing the blow-out mechanism to change the wind directions of the first air stream and the second air stream in the first direction so that the changes in the wind directions of the first air stream and the second air stream are different from each other. matter,
The first airflow and the second airflow are applied to the first airflow direction plate and the second airflow direction plate, respectively, such that changes in the wind directions of the first airflow and the second airflow are different from each other. and changing the wind direction in the second direction of the generating mechanism such that the changes in the air volume of the first air flow and the second air flow are different from each other. changing the airflow volume of the
11. The blower according to any one of claims 1 to 10, wherein a ninth control for performing any of the above is performed. The control unit
The first airflow and the second airflow are applied to the first airflow direction plate and the second airflow direction plate, respectively, such that changes in the wind directions of the first airflow and the second airflow are different from each other. and changing the wind direction in the second direction of the generating mechanism such that the changes in the air volume of the first air flow and the second air flow are different from each other. changing the airflow volume of the
12. The blower according to any one of claims 1 to 11, wherein a tenth control for performing any of the above is performed. Equipped with a human sensor that detects a person and a temperature sensor that detects temperature,
When the person is detected by the human sensor and the temperature is higher than a reference temperature, the controller controls the first airflow and the second airflow through the first airflow direction plate and the second airflow direction plate, respectively. 13. The fan according to any one of claims 1 to 12, wherein an eleventh control is performed to make the second direction of the airflows of the two different from each other. A wind direction acquisition unit that acquires wind direction information indicating the wind direction of an air flow other than the first air flow and the second air flow,
The control unit causes the first airflow direction plate and the second airflow direction plate to bring the first airflow and the second airflow in the second direction closer to the airflow direction. 14. The fan according to any one of claims 1 to 13, wherein the twelfth control is performed. Equipped with a human sensor that detects people,
the second direction is a vertical direction;
When the person is not detected by the human sensor, the control unit causes the first airflow and the second airflow to flow through the first airflow direction plate and the second airflow direction plate, respectively. 15. The blower according to any one of claims 1 to 14, wherein a thirteenth control is performed to make the vertical wind direction inclined upward in the vertical direction from the horizontal direction. Equipped with a cleanliness detector that detects the cleanliness of the air,
the second direction is a vertical direction;
When the state in which the cleanliness level is higher than the reference cleanliness level continues for a reference time or longer, the control unit causes the first air flow and the second air flow to flow through the first airflow direction plate and the second airflow direction plate, respectively. 16. The blower according to any one of claims 1 to 15, wherein a fourteenth control is performed to make the direction of the air flow in the vertical direction inclined downward in the vertical direction from the horizontal direction. a generating mechanism for generating a first airflow and a second airflow;
A first outlet and a second outlet for blowing out the first air flow and the second air flow, respectively, are formed, and the first outlet and the second outlet are arranged in a first direction. an array of blowing mechanisms;
a first wind direction plate disposed at the first outlet and capable of changing the direction of the first airflow;
a second wind direction plate disposed at the second outlet and capable of changing the direction of the second airflow;
The first airflow direction plate and the second airflow direction plate can change the wind directions of the first airflow and the second airflow independently of each other, and the first airflow and the second airflow direction can be changed independently of each other. causing the generating mechanism to change the air volumes of the first air flow and the second air flow so that changes in air volume of the two air flows are different from each other, and the first air flow and the second air flow any control of causing the first airflow direction plate and the second airflow direction plate to change the wind direction of the first air flow and the second air flow, respectively, such that the changes in the wind direction of the flows are different from each other; a control unit that performs
Blower with.

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