JP3234348U - Circulator - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide a circulator capable of efficiently heating air sucked from the outside. SOLUTION: A circulator 1 includes a rotary shaft 31 extending in the front-rear direction, a rear intake port 214 provided on a rear surface of the rotary shaft 31 in the extending direction, a blade housing 21, and a plurality of circulators. It includes blades 32, a motor, and a heating unit 4 provided at a position rearward from the positions of the plurality of blades 32 along the extending direction of the rotating shaft 31. The rotating shaft 31 extends forward from the motor through the heating portion 4, and the heating portion 4 is fixed to the blade housing 21 and is attached to the insulating portion 411 and the insulating portion 411 that surround the rotating shaft 31. Includes a wound heating element 421. [Selection diagram] Fig. 3

Description

The present invention relates to a circulator, and more specifically to a circulator provided with a heating unit.

Circulators are known as home appliances that circulate the air in the space in which they are installed. Circulators are used for purposes such as ventilating a room, improving the efficiency of cooling or heating, and promoting the drying of laundry.

The following Patent Document 1 discloses an electric stove that also serves as a fan that heats air sucked from the outside with a heater by rotating a plurality of blades around a rotation axis and blows the heated air to the outside. .. This electric stove that also serves as an electric fan includes a reflector placed on the front of the main body, a fan provided in the substantially central part of the reflector at a distance from the reflector, and a motor that rotationally drives the fan. It includes a heater provided near the outside of the fan and a control unit that controls forward and reverse rotation of the motor. This electric stove that also serves as an electric fan sucks in outside air from the central part and discharges it from the outside when the heater is energized, and sucks in outside air from the outside and discharges from the central part when the heater is shut off.

Japanese Unexamined Patent Publication No. 2013-209794

As a method of further promoting the drying of the laundry or a method of using the circulator itself as heating, a method of mounting a heating unit on the circulator can be considered. However, when the heating unit is mounted on the circulator, the air sucked from the outside cannot be efficiently heated by the heating unit, and the temperature of the blown air is low.

The present invention is for solving the above problems, and an object of the present invention is to provide a circulator capable of efficiently heating air sucked from the outside.

The circulator according to one aspect of the present invention includes a rotating shaft extending in the front-rear direction, a rear intake port provided on the rear surface of the rotating shaft in the extending direction, and a front side of the rotating shaft in the extending direction. A housing including an air outlet provided on the surface and a plurality of blades fixed to a rotating shaft, and air outside the housing is sucked into the inside of the housing from the rear intake port, and the sucked air is sucked. A plurality of blades sent from the air outlet to the outside of the housing, a motor for rotationally driving the rotating shaft and the plurality of blades, and a position rearward of the positions of the plurality of blades along the extending direction of the rotating shaft are provided. A heating unit that heats the air sucked into the housing from the rear intake port is provided, the rotating shaft extends forward from the motor through the heating unit, and the heating unit is fixed to the housing. It includes an insulating portion that surrounds the circumference of the rotating shaft, and a heat generating element that is wound around the insulating portion.

The circulator preferably includes a support portion that is fixed to the housing and supports the first and second insulating portions.

In the above circulator, preferably, when viewed from the extending direction of the rotating shaft, the heat generating element has a longer portion existing on the outer diameter side than the insulating portion than a portion existing on the inner diameter side of the insulating portion. ..

Preferably, in the circulator, the housing further includes a filter provided detachably with respect to at least a part of the rear intake port.

In the above circulator, preferably, the housing further includes a side intake port provided on the side surface of the housing.

In the above circulator, preferably, at least a part of the air flow path from the side intake port to the plurality of blades is shielded, and at least a part of the air flow path of the air flow path is shielded in the closed state. A shutter that switches between the open state and the open state is further provided.

The circulator preferably further includes a control unit that controls the shutter state, and the control unit closes the shutter state when the rotation speed of the plurality of blades is the first speed, and rotates the plurality of blades. When the speed is a second speed higher than the first speed, the shutter state is opened.

In the above circulator, preferably, the intake port is not provided on the side surface of the housing.

According to the present invention, it is possible to provide a circulator capable of efficiently heating the air sucked from the outside.

It is a perspective view which shows typically the structure of the circulator 1 in one Embodiment of this invention. It is a front view which shows typically the structure of the circulator 1 in one Embodiment of this invention. It is sectional drawing which shows the internal structure of the blade housing 21 and the like when the shutter 6 is in an open state. It is a front view which shows typically the structure of the heating part 4 and the support part 5. It is a figure which shows typically the structure of the heating part 4. FIG. 5 is a perspective view schematically showing a state in which the filter 213 is removed from the rear case 212. FIG. 5 is a cross-sectional perspective view showing the internal configuration of the blade housing 21 when the shutter 6 is in the open state and when the shutter 6 is in the closed state. It is a figure which shows the relationship between the air which goes from the rear intake port 214 to the air outlet 216, and the heat generating elements 421 and 422 in one Embodiment of this invention. It is sectional drawing which shows the internal structure of the blade housing 21 in the modification of one Embodiment of this invention.

Hereinafter, an embodiment of the present invention will be described with reference to the drawings. In the following description, the direction toward the air outlet 216 along the extending direction of the rotating shaft 31 (an example of the rotating shaft) is referred to as the front, and the direction toward the rear intake port 214 along the rotating shaft 31 is referred to as the rear. It is written.

1 and 2 are diagrams schematically showing the configuration of the circulator 1 according to the embodiment of the present invention. FIG. 1 is a perspective view, and FIG. 2 is a front view.

With reference to FIGS. 1 and 2, the circulator 1 (an example of a circulator) includes a housing 2, a blower 3, a heating part 4 (an example of a heating part), and a support part 5 (an example of a support part). , A shutter 6 (an example of a shutter) and a control unit 7 (an example of a control unit) are provided. Inside the housing 2, a blower unit 3, a heating unit 4, a support unit 5, a shutter 6, and a control unit 7 are provided.

The housing 2 includes a blade housing 21 (an example of the housing), a neck portion 22, and a stand 23. Inside the blade housing 21, a blower portion 3, a heating portion 4, a support portion 5, and a shutter 6 are provided. The blade housing 21 can swing around the shaft AX1 with respect to the neck portion 22 as indicated by the arrow AR1. The blade housing 21 may be rotated around the shaft AX1 by the electric power supplied from the control unit 7 so as to be blown in an appropriate direction, or may be rotated around the shaft AX1 by the user of the circulator 1. You may.

The neck portion 22 is provided at the lower part of the blade housing 21. The neck portion 22 connects the stand 23 and the blade housing 21. The neck 22 extends upward from the stand 23. The blade housing 21 and the neck portion 22 can swing around the shaft AX2 with respect to the stand 23 as shown by the arrow AR2 by the electric power supplied from the control unit 7. The function of the blade housing 21 and the neck portion 22 swinging around the axis AX2 with respect to the stand 23 as indicated by the arrow AR2 is called a swing function.

The stand 23 is provided below the neck portion 22. The stand 23 houses the control unit 7. An operation unit 231 is provided on the upper surface of the stand 23. The operation unit 231 accepts the operation of the user of the circulator 1. The operation unit 231 uses, for example, an operation of turning on and off the power of the circulator 1, an operation of adjusting the air volume, an operation of switching the operating state of the circulator 1 between the heating mode, the clothes drying mode, and the ventilation mode, and the power supply of the circulator 1. It accepts an operation of setting an on or on time, an operation of turning on or off the swing function of the blade housing 21, and the like.

The control unit 7 controls the operation of the entire circulator 1 based on the setting or operation received by the operation unit 231.

FIG. 3 is a cross-sectional view showing an internal configuration of the blade housing 21 and the like when the shutter 6 is in the open state. FIG. 3 shows a cross section along lines III-III of FIG.

With reference to FIG. 3, the blade housing 21 includes a front case 211, a rear case 212, a filter 213 (an example of a filter), a rear intake port 214 (an example of a rear intake port), and a side intake. It includes a port 215 (an example of a side intake port), a blower port 216 (an example of a blower port), and a handle 217. The front case 211 and the rear case 212 are fitted to each other to form an internal space of the blade housing 21. The front case 211 is detachably fixed to the rear case 212 by a screw (not shown). The front case 211 has a substantially cylindrical shape. Inside the front case 211, a plurality of blades 32 and sleeves 35 of the blower portion 3 are provided. An air outlet 216 is provided on the front surface (front surface) of the rotating shaft 31 in the extending direction of the front case 211. The air outlet 216 is mainly composed of a plurality of holes having an arc shape. A side intake port 215 is provided on the side surface of the blade housing 21 (front case 211). The side intake port 215 is provided, for example, in a region on the side surface of the blade housing 21 (front case 211) at least in front of the position of the front end 4a of the heating portion 4 along the extending direction of the rotating shaft 31. .. The side intake port 215 is composed of a plurality of holes having a rectangular or circular shape.

The rear case 212 is provided at a position rearward from the position of the front case 211 along the extending direction of the rotation shaft 31. The rear case 212 has a substantially hemispherical shape. A heating unit 4 and the like are provided inside the rear case 212. A rear intake port 214 and a handle 217 are provided on the rear surface (rear surface) of the rotating shaft 31 in the extending direction of the rear case 212. The rear intake port 214 is mainly composed of a plurality of holes having a rectangular shape. The handle 217 is a portion that is gripped by the user of the circulator 1 when the circulator 1 is carried.

The filter 213 is detachably provided with respect to at least a part of the rear intake port 214. The filter 213 prevents dust and the like in the air from entering the heating unit 4.

The blower portion 3 includes a rotating shaft 31, a plurality of blades 32 (an example of a plurality of blades), a motor 33, a female screw 34, and a sleeve 35. The rotation shaft 31 extends in the front-rear direction. The rear end of the rotating shaft 31 is fixed to the motor 33, and the rotating shaft 31 projects forward from the motor 33. The rotating shaft 31 penetrates the heating unit 4.

Each of the plurality of blades 32 is integrated with the sleeve 35 and is fixed to the rotating shaft 31. Each of the plurality of blades 32 extends from the sleeve 35 to the outer diameter side. The sleeve 35 is fixed to the rotating shaft 31, and the plurality of blades 32 and the sleeve 35 rotate together with the rotating shaft 31. The plurality of blades 32 suck the air outside the blade housing 21 into the housing from each of the rear intake port 214 and the side intake port 215. The plurality of blades 32 send the sucked air from the air outlet 216 to the outside of the blade housing 21.

The motor 33 rotationally drives the rotary shaft 31 by the electric power supplied from the control unit 7. The motor 33 is provided at a position rearward from the position of the heating portion 4 along the extending direction of the rotating shaft 31.

The female screw 34 is fitted into the male screw formed at the tip of the rotating shaft 31 by a screwing action. The female screw 34 fixes the positions of the plurality of blades 32 and the sleeve 35 along the rotation axis 31 by sandwiching the sleeve 35 with the support portion 5. By removing the female screw 34 from the rotating shaft 31, the plurality of blades 32 and the sleeve 35 can be removed from the rotating shaft 31.

The heating unit 4 heats the air sucked into the blade housing 21 from the rear intake port 214. The heating unit 4 is provided at a position rearward from the positions of the plurality of blades 32 and the sleeve 35 along the extending direction of the rotating shaft 31.

The support portion 5 is fixed to the blade housing 21. The support portion 5 supports the heating portion 4. Further, the support portion 5 fixes the positions of the plurality of blades 32 and the sleeve 35 along the rotation shaft 31.

The shutter 6 is provided on the outer peripheral surface of the outer diameter side support portion 52 of the support portion 5. The shutter 6 can move in the front-rear direction along the outer peripheral surface of the outer diameter side support portion 52. The shutter 6 is provided over the entire circumference of the outer peripheral surface of the outer diameter side support portion 52. The shutter 6 may be provided only on a part of the outer peripheral surface of the outer diameter side support portion 52 of the support portion 5. The shutter 6 opens and closes the internal intake port 54 of the support portion 5. The shutter 6 may be provided on the side surface of the blade housing 21, or may open and close the side intake port 215.

FIG. 4 is a front view schematically showing the configurations of the heating portion 4 and the support portion 5. FIG. 5 is a diagram schematically showing the configuration of the heating unit 4. 5 (a) is a front view and FIG. 5 (b) is a perspective view. Note that in FIGS. 4 and 5, the illustration of each portion of the heat generating elements 421 and 422 existing on the inner diameter side of the insulating portions 411 and 412 is omitted.

With reference to FIGS. 3 to 5, the heating portions include an insulating portion 411 (an example of a first insulating portion), an insulating portion 412 (an example of a second insulating portion), and a heat generating element 421 (first heat generating portion). It includes an element example), a heat generating element 422 (an example of a second heat generating element), a substrate 43, and a fixing portion 44.

Each of the insulating portions 411 and 412 is made of an insulator and is fixed to the blade housing 21 via the supporting portion 5. Each of the insulating portions 411 and 412 holds each of the heat generating elements 421 and 422 in a state of being insulated from the housing 2. Each of the insulating portions 411 and 412 has, for example, an annular shape when viewed from the extending direction of the rotating shaft 31. The insulating portion 411 surrounds the rotation shaft 31. The insulating portion 412 surrounds the rotating shaft 31 at a position rearward from the position of the insulating portion 411 along the extending direction of the rotating shaft 31. The extending direction of each of the insulating portions 411 and 412 is orthogonal to the extending direction of the rotating shaft 31.

Each of the heat generating elements 421 and 421 is a conducting wire and is wound around each of the insulating portions 411 and 412. A current flows through each of the heat generating elements 421 and 422 by the electric power supplied by the control unit 7. As a result, each of the heat generating elements 421 and 422 generates heat and heats the air inside the blade housing 21. Each of the heating elements 421 and 422 is made of, for example, a nichrome wire. The heat generating element 421 is fixed to the insulating portion 411 by sandwiching the insulating portion 411 from the front-rear direction at the fixing position 423. The heat generating element 422 is fixed to the insulating portion 412 by sandwiching the insulating portion 412 from the front-rear direction at the fixing position 424.

When viewed from the extending direction of the rotating shaft 31, each of the fixed positions 423 and 424 is provided on the inner diameter side of each of the heat generating elements 421 and 422 with respect to the central portion in the radial direction. In other words, the heat generating elements 421 and 422 existing on the outer diameter side of the insulating portions 411 and 421 with respect to the respective parts of the heat generating elements 421 and 422 existing on the inner diameter side of each of the insulating portions 411 and 412. Each part is longer. As a result, each of the heat generating elements 421 and 422 protrudes into the space on the outer diameter side of each of the insulating portions 411 and 412, so that most of the air from the rear intake port 214 to the air outlet 216 is generated by the heat generating elements 421 and 422. Will pass through. As a result, the air can be efficiently heated inside the blade housing 21.

The substrate 43 includes, for example, an electric circuit (such as a fuse) for urgently stopping the supply of electric power to each of the heat generating elements 421 and 422 when the circulator 1 overheats.

The fixing portion 44 supports each of the insulating portions 411 and 412 from the inner diameter side of each of the insulating portions 411 and 412. A hole 441 for passing the rotating shaft 31 is formed in the central portion of the fixed portion 44 when viewed from the extending direction of the rotating shaft 31.

The support portion 5 includes an inner diameter side support portion 51, an outer diameter side support portion 52, a plurality of connection portions 53, an internal intake port 54, and four male screws 55. The inner diameter side support portion 51 fixes the fixing portion 44. A hole 511 for passing the rotating shaft 31 is formed in the central portion of the inner diameter side support portion 51 when viewed from the extending direction of the rotating shaft 31.

The outer diameter side support portion 52 is provided on the outer diameter side of the inner diameter side support portion 51. The outer diameter side support portion 52 has a substantially cylindrical shape, and is fixed to the rear side case 212 by four male screws 55. The outer diameter side support portion 52 surrounds the outer circumference of the heating portion 4. The position of the front end of the outer diameter side support portion 52 along the extending direction of the rotating shaft 31 is substantially the same as the position of the front end of the rear side case 212 along the rotating shaft 31, and is in the extending direction of the rotating shaft 31. It exists on the front side of the position of the front end 4a of the heating portion 4 along the line. The position of the rear end of the outer diameter side support portion 52 along the rotating shaft 31 exists on the rear side of the position of the rear end of the heating portion 4. A side intake port 215 exists on the outer diameter side of the outer diameter side support portion 52. As shown by the arrow AR3, the outer diameter side support portion 52 guides the air sucked from the rear side intake port 214 into the blade housing 21 to the air outlet 216.

Each of the plurality of connecting portions 53 projects in the outer diameter direction from the inner diameter side support portion 51, and connects the inner diameter side support portion 51 and the outer diameter side support portion 52.

The internal intake port 54 is provided on the side surface of the outer diameter side support portion 52. As shown by the arrow AR4, the internal intake port 54 blows air sucked into the inside of the blade housing 21 from the side intake port 215 (air existing on the outer diameter side of the outer diameter side support portion 52) to the blower portion 3 ( Guide to the inner diameter side of the outer diameter side support portion 52).

FIG. 6 is a perspective view schematically showing a state in which the filter 213 is removed from the rear case 212.

With reference to FIG. 6, the filter 213 includes a plurality of engaging portions 213a, a handle 213b, a frame body 213c, and a filter film 213d. A plurality of rectangular holes are formed in the frame body 213c. The filter film 213d is detachably fixed to the frame body 213c so as to cover these holes from the front side of the frame body 213c. The frame body 213c is provided with a plurality of engaging portions 213a and handles 213b. The filter 213 is fixed to the rear case 212 by engaging each of the plurality of engaging portions 213a with each of the plurality of engaging portions 212a provided on the rear case 212. On the other hand, by pulling the handle 213b rearward, the engagement between each of the plurality of engaging portions 212a and each of the plurality of engaging portions 213a is released, and the filter 213 is removed from the rear case 212. When the filter 213 is removed, the portion of the rear intake port 214 covered by the filter 213 is exposed to the outside of the blade housing 21.

FIG. 7 is a cross-sectional perspective view showing the internal configuration of the blade housing 21 when the shutter 6 is in the closed state and when the shutter 6 is in the open state. FIG. 7A is a closed state, and FIG. 7B is an open state.

With reference to FIG. 7, the state of the shutter 6 switches between the closed state and the open state. The closed state is a state in which at least a part of the air flow path (flow path indicated by the arrow AR4) from the side intake port 215 to the plurality of blades 32 is shielded. In the present embodiment, the closed state is a state in which the shutter 6 completely covers the internal intake port 54 existing on the air flow path from the side intake port 215 to the plurality of blades 32. The open state is a state in which at least a part of the air flow path shielded in the closed state is open among the air flow paths from the side intake port 215 to the plurality of blades 32. In the present embodiment, in the open state, a part of the internal intake port 54 existing on the air flow path from the side intake port 215 to the plurality of blades 32 is opened, and the other part is covered with the shutter 6. be. The state of the shutter 6 is controlled by the control unit 7. The state of the shutter 6 may be switched by the user of the circulator 1.

When the state of the shutter 6 is controlled by the control unit 7, the control unit 7 may control the operating state of the circulator 1 according to the set mode as follows.

The heating mode is a mode in which a small amount of air having a relatively high temperature is blown. When the operating state of the circulator 1 is set to the heating mode, the control unit 7 sets the rotation speed of the plurality of blades 32 to the first speed (low speed), thereby reducing the amount of air blown by the blower unit 3 to a small amount. Control. The control unit 7 sets the shutter 6 to a closed state (FIG. 7A). Further, the control unit 7 heats the heating unit 4 by supplying electric power to the heating unit 4. In the heating mode, air is sucked only from the rear intake port 214 and not from the side intake port 215, so that the amount of air sucked into the blade housing 21 is reduced. Further, the air sucked from the rear intake port 214 is guided to the air outlet 216 by the outer diameter side support portion 52 as shown by the arrow AR3, and at that time, is heated by passing through the heating unit 4 and is heated by the air outlet. It is blown from 216. As a result, a small amount of air is introduced into the heating unit 4 and heated, so that a relatively small amount of air is blown at a relatively high temperature.

The clothes drying mode is a mode in which a large amount of air at a relatively low temperature is blown. When the operating state of the circulator 1 is set to the clothes drying mode, the control unit 7 blows air by setting the rotation speed of the plurality of blades 32 to a second speed (high speed) faster than the first speed. A large amount of air is controlled in the unit 3. The control unit 7 sets the shutter 6 state to the open state (FIG. 7B). Further, the control unit 7 heats the heating unit 4 by supplying electric power to the heating unit 4. In the clothes drying mode, air is sucked from the side intake port 215 in addition to the rear side intake port 214. As shown by the arrow AR4, the air sucked from the side intake port 215 goes to the plurality of blades 32 via the internal intake port 54 without passing through the heating unit 4, and is blown from the air outlet 216. As a result, along with the air heated by the heating unit 4, the low-temperature air sucked from the side intake port 215 is also blown, so that a relatively large amount of air is blown at a relatively low temperature (higher than room temperature).

The blowing mode is a mode in which air at room temperature is blown. When the operating state of the circulator 1 is set to the blowing mode, the control unit 7 controls the blowing amount of the blowing unit 3 to the set amount. The control unit 7 opens the shutter 6 state. Further, the control unit 7 stops the supply of electric power to the heating unit 4. As a result, the air at room temperature sucked from each of the rear intake port 214 and the side intake port 215 is blown as it is, so that the temperature of the blown air becomes room temperature.

[Effect of Embodiment]

FIG. 8 is a diagram showing the relationship between the air from the rear intake port 214 to the air outlet 216 and the heat generating elements 421 and 422 in one embodiment of the present invention.

With reference to FIG. 8, in the present embodiment, each of the two heat generating elements 421 and 422 arranged in the extending direction of the rotating shaft 31 is each of the insulating portions 411 and 412 surrounding the circumference of the rotating shaft 31. It is wound around. As a result, most of the air from the rear intake port 214 to the air outlet 216 (air flowing in the direction indicated by the arrow AR3) passes through the four heat generating elements 422a, 422b, 421a, and 421b in this order. As a result, the air sucked from the outside can be efficiently heated.

[Modification example]

FIG. 9 is a cross-sectional view showing the internal configuration of the blade housing 21 in the modified example of the embodiment of the present invention.

With reference to FIG. 9, in this modification, the side intake port is not provided on the side surface of the blade housing 21. The intake port of the blade housing 21 is only the rear intake port 214 provided on the rear surface of the blade housing 21.

According to this modification, the inflow of air into the inside of the blade housing 21 through the side surface of the blade housing 21 is blocked. As a result, inside the blade housing 21, the air flow (air flow indicated by the arrow AR3) passing through each of the rear intake port 214, the heating unit 4, the air blower 3 and the air blower 216 in this order is allowed to flow. It will be easier to make. As a result, the air sucked from the outside can be efficiently heated.

[others]

The heating portion may include only one insulating portion fixed to the housing and surrounding the circumference of the rotating shaft, and only one heat generating element wound around the insulating portion.

The embodiments and modifications described above should be considered exemplary and not restrictive in all respects. The scope of the present invention is indicated not by the above description but by the scope of the utility model registration claims, and is intended to include all changes within the meaning and scope equivalent to the scope of the utility model registration claims.

1 Circulator (an example of a circulator)
2 Housing 3 Blower 4 Heating unit (example of heating unit)
4a Front end of heating part 5 Support part (example of support part)
6 Shutter (an example of shutter)
7 Control unit (example of control unit)
21 Blade housing (example of housing)
22 Neck of the housing 23 Stand of the housing 31 Rotating shaft of the blower (an example of the rotating shaft)
32 Multiple blades of the blower (an example of multiple blades)
33 Blower motor 34 Blower female screw 35 Blower sleeve 43 Heating part substrate 44 Heating part fixing part 51 Inner diameter side support part of support 52 Outer diameter side support part of support 53 Support part connection part 54 Internal intake port of support 55 Male screw of support 211 Front case of blade housing 212 Rear case of blade housing 212a Engagement part of rear case 213 Filter of blade housing (example of filter)
213a Filter engagement part 213b Filter handle 213c Filter frame 213d Filter filter film 214 Rear intake port of blade housing (example of rear intake port)
215 Side intake port of the blade housing (an example of side intake port)
216 Air outlet of the blade housing (an example of the air outlet)
217 Handle of blade housing 231 Operation part of main body 411,412 Insulation part of heating part (example of first and second insulation part)
421, 422, 421a, 421b, 422a, 422b Heat-generating element of heating unit (example of first and second heat-generating elements)
423,424 Fixing position of heat generating element 441 Hole of fixing part of heating part 511 Hole of inner diameter side support part

Claims (8)

It ’s a circulator,
A rotation axis that extends in the front-back direction,
A housing including a rear intake port provided on the rear surface of the rotating shaft in the extending direction and an air outlet provided on the front surface of the rotating shaft in the extending direction.
A plurality of blades fixed to the rotating shaft, the air outside the housing is sucked into the inside of the housing from the rear intake port, and the sucked air is sucked from the air outlet to the outside of the housing. With multiple blades to send,
A motor that rotationally drives the rotating shaft and a plurality of blades,
It is provided at a position rearward from the position of the plurality of blades along the extending direction of the rotation shaft, and includes a heating unit for heating the air sucked into the inside of the housing from the rear intake port.
The rotating shaft extends forward from the motor through the heating portion.
The heating part is
An insulating portion fixed to the housing and surrounding the rotating shaft,
A circulator including a heat generating element wound around the insulating portion. The circulator according to claim 1, further comprising a support portion fixed to the housing and supporting the insulating portion. When viewed from the extending direction of the rotating shaft, the portion of the heat generating element located on the outer diameter side of the insulating portion is longer than the portion existing on the inner diameter side of the insulating portion. Item 3. The circulator according to Item 1 or 2. The circulator according to any one of claims 1 to 3, wherein the housing further includes a filter provided detachably with respect to at least a part of the rear intake port. The circulator according to any one of claims 1 to 4, wherein the housing further includes a side intake port provided on a side surface of the housing. At least a part of the air flow path from the side intake port to the plurality of blades is shielded, and at least a part of the air flow path shielded in the closed state is opened. The circulator according to claim 5, further comprising a shutter that switches between the open state and the open state. A control unit for controlling the state of the shutter is further provided.
The control unit closes the shutter state when the rotation speeds of the plurality of blades are the first speed, and the second speed at which the rotation speeds of the plurality of blades are faster than the first speed. The circulator according to claim 6, wherein the shutter state is opened in the case of. The circulator according to any one of claims 1 to 4, wherein an intake port is not provided on the side surface of the housing.

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