JP7154149B2 - Brush nozzle for vacuum cleaner and vacuum cleaner having the same - Google Patents

Description

TECHNICAL FIELD The present invention relates to a brush nozzle for a vacuum cleaner and a vacuum cleaner provided with the same.

A conventional electric vacuum cleaner includes a cleaner body having wheels, a flexible hose detachably connected to the cleaner body, an extension tube detachably connected to the flexible hose, and detachable to the extension tube. There are canister-type vacuum cleaners with a floor-cleaning suction port to which they can be connected. In addition, such a conventional canister type vacuum cleaner has an attachment for cleaning places that are difficult to clean with the suction port, such as places where electric cords are gathered on the floor and shelves where small items are placed. , A detachable brush nozzle may be attached to the tip of the flexible hose.

For example, Patent Literature 1 discloses a canister-type vacuum cleaner having a detachable brush nozzle at the tip of a flexible hose. This vacuum cleaner sucks dust-laden air from the brush nozzle, traps the dust in the dust collecting section through the double-pipe structure, and circulates part of the exhaust air through the double-pipe structure. It is configured to blow off dust on the surface to be cleaned by blowing from the center of the brush nozzle, and to remove dust by sucking the dust from the periphery of the center.

JP-A-2002-219079

Conventional vacuum cleaners with a double-pipe structure have a complicated structure. The brush nozzle and flexible hose are large and heavy, making the brush nozzle difficult to handle. Depending on the dust adhering to the surface to be cleaned, it may not be possible to lift it from the surface to be cleaned even by the wind blowing from the brush nozzle. There is a problem that the dust may be swept to the surroundings when the dust is lifted up by sweeping.

SUMMARY OF THE INVENTION It is an object of the present invention to provide a brush nozzle for a vacuum cleaner that is easy to handle and can efficiently remove dust, and a vacuum cleaner equipped with the same.

According to the present invention, a nozzle body having a nozzle port for sucking air containing dust on a surface to be cleaned, and a nozzle provided in the nozzle body rotatably about an axis perpendicular to the surface to be cleaned a turbine brush and
A brush nozzle for a vacuum cleaner is provided, wherein the nozzle opening is arranged around the turbine brush, and the turbine brush is rotated by an airflow flowing into the nozzle body.
Further, according to the present invention, a nozzle body having a nozzle port for sucking air containing dust on a surface to be cleaned, and a nozzle provided in the nozzle body rotatably about an axis perpendicular to the surface to be cleaned and a motor provided in the nozzle body,
A brush nozzle is provided in which the nozzle mouth is arranged around the brush and the brush is configured to be rotated by the motor.
Further, according to the present invention, there is provided a vacuum cleaner comprising a cleaner body and the brush nozzle connected to the cleaner body.

According to the present invention, during cleaning, the brush is rotated around an axis perpendicular to the surface to be cleaned by an air current or a motor, and dust on the surface to be cleaned is lifted by the rotating brush. can be removed by suction from the nozzle openings around the brush, dust can be efficiently removed with a simple structure.

BRIEF DESCRIPTION OF THE DRAWINGS It is a perspective view which shows each component of 1st Embodiment of the vacuum cleaner of this invention. It is a partial cross-sectional front view of the brush nozzle of 1st Embodiment. It is a partial cross section left side view of the brush nozzle of 1st Embodiment. FIG. 3 is a perspective view of a turbine brush unit in the brush nozzle of the first embodiment, viewed from above; FIG. 3 is a perspective view of a turbine brush unit in the brush nozzle of the first embodiment as viewed from below; It is a figure explaining a mode that the turbine brush in the brush nozzle of 1st Embodiment rotates. It is a cross-sectional front view which shows a part of 1st modification of the brush nozzle of 1st Embodiment. It is a cross-sectional front view which shows a part of 2nd modification of the brush nozzle of 1st Embodiment. It is a bottom view which shows a part of 3rd modification of the brush nozzle of 1st Embodiment. It is a bottom view which shows a part of 4th modification of the brush nozzle of 1st Embodiment. (A) of the brush nozzle of 2nd Embodiment is a partial cross section front view, (B) is a partial cross section left side view. It is a perspective view which shows each component of the vacuum cleaner of 3rd Embodiment.

(First embodiment)
<Regarding the overall configuration of the vacuum cleaner>
FIG. 1 is a perspective view showing each component of the first embodiment of the electric vacuum cleaner of the present invention.
This electric vacuum cleaner 1 includes a canister-type cleaner main body 10 having wheels, a flexible hose 20 as a connector detachably connected to the cleaner main body 10, and a flexible hose 20 detachably attached. An extension pipe 30 as a connection tool to be connected, a suction port body 40 detachably connected to the extension pipe 30, and a brush nozzle 50 as an attachment detachably connected to the flexible hose 20. Prepare.

The cleaner body 10 has a drive device 11 containing an electric blower (not shown) and a dust collector 12 detachably attached to the drive device 11 .
The drive device 11 has a cord reel or a battery connectable to a commercial power supply at its rear portion, and has a placement portion on which the dust collector 12 is detachably placed on its front portion. is provided with a connecting portion 11a.
The dust collection device 12 has a dust collection container connectable to the connection portion 11a of the drive device 11, and a filter portion detachably attached to the dust collection container. In addition, although the dust collector 12 of this embodiment is of a cyclone type, it may be of a disposable paper pack type.

The flexible hose 20 has a hose body 21 and an operation portion 22 provided at the upstream end of the hose body 21 in the airflow direction (airflow direction).
A connection portion 21 a that is detachably connected to the connection portion 11 a of the drive device 11 is provided at the downstream end portion of the hose body 21 in the airflow direction.
The operating portion 22 has a handle 22a, a plurality of switches 22b and 22c provided upstream of the handle 22a in the airflow direction, and a connecting portion 22d provided upstream of the switch 22c in the airflow direction.

The extension pipe 30 has an outer cylinder portion 31 arranged on the downstream side in the airflow direction and an inner cylinder portion 32 arranged on the upstream side in the airflow direction. You can adjust the length by sliding in the direction.
A connection portion 31 a that is detachably connected to the connection portion 22 d of the flexible hose 20 is provided on the downstream side of the outer cylinder portion 31 in the airflow direction.
A connection portion 32 a that is detachably connected to a connection pipe portion 43 of the suction port body 40 , which will be described later, is provided on the upstream side of the inner cylinder portion 32 in the airflow direction.

The suction port body 40 includes a suction port main body 41 having a suction port (not shown) facing the surface to be cleaned, a joint portion 42 connected to the suction port main body 41, and the connecting pipe portion connected to the joint portion 42. 43, and the connecting tube portion 43 can be rotated in the forward/rearward and leftward/rightward directions of the user when in use.
Further, the suction port body 40 may be provided with a rotating brush inside the suction port main body 41 that is rotated by a drive motor. In this case, the suction port body 40, the extension pipe 30, the flexible hose 20 and the driving device 11 are provided with a wiring path for supplying electric power to the driving motor, and respective connecting portions connecting these components to each other. A power supply terminal and a power reception terminal are provided on the end face of the wiring path.

<About the brush nozzle>
FIG. 2 is a partially sectioned front view of the brush nozzle of the first embodiment, and FIG. 3 is a partially sectioned left side view of the brush nozzle of the first embodiment. 4 is a top perspective view of the turbine brush unit in the brush nozzle of the first embodiment, and FIG. 5 is a bottom perspective view of the turbine brush unit in the brush nozzle of the first embodiment. FIG. 6 is a diagram for explaining how the turbine brush in the brush nozzle of the first embodiment rotates. 2 and 3, arrows indicate the front, rear, left, right, up and down directions of the brush nozzle during use.

As shown in FIGS. 2 and 3, the brush nozzle 50 includes a nozzle body 51 having a nozzle port 51bc for sucking air containing dust on the surface F to be cleaned, and a lower side of the nozzle body to the surface F to be cleaned during use. and a turbine brush 52 provided in the nozzle body 51 so as to be rotatable around an axis P perpendicular to the surface F to be cleaned when facing the surface F, and the nozzle port 51bc extends around the turbine brush 52 ( (outside of the turbine brush 52) and configured to rotate the turbine brush 52 by the air A1 flowing into the nozzle body 51. As shown in FIG. It should be noted that the vertical direction of the axis P allows for some inclination.

[About the nozzle body]
As shown in FIGS. 2 to 6, the nozzle body 51 has an outer wall portion 51a and a concave inner wall portion 51b provided inside the outer wall portion 51a so as to accommodate the turbine brush 52 therein.
The outer wall portion 51a has a substantially bowl-shaped first accommodating portion 51aa that accommodates the inner wall portion 51b and the turbine brush 52, and a connecting pipe portion. The connecting pipe portion has a bent neck portion 51ab connected to communicate with the inside of the first accommodating portion 51aa, and a connection portion 51ac provided at the downstream end of the neck portion 51ab in the airflow direction and thinner than the neck portion 51ab. .

As shown in FIG. 3, in the outer wall portion 51a, the neck portion 51ab is vertically connected to the upper wall of the first housing portion 51aa and is bent toward the downstream side in the airflow direction (arrow A direction). When the flexible hose 20 is used to clean a floor surface or a shelf, the flexible hose 20 is connected to the connecting portion 22d (see FIG. 1) while being bent obliquely upward in the rear direction.

Further, in the outer wall portion 51a, a first air introduction port 51ad is provided around the first accommodating portion 51aa. The first air introduction port 51ad is arranged, for example, at a rear position on the side where the neck portion 51ab is inclined. As a result, the first air introduction port 51ad is not conspicuous from the user, and when the user holds the brush nozzle 50, the first air introduction port 51ad is less likely to be blocked with a finger. Note that the role of the first air introduction port 51ad will be described later.

The connection portion 51ac of the outer wall portion 51a is formed in a cylindrical shape having a thickness that allows it to be inserted into the circular connection port of the connection portion 22d of the flexible hose 20 (see FIG. 1). Also, the connecting portion 51ac may be formed in a tapered shape that slightly decreases in diameter toward the downstream side in the airflow direction.
In the case of the vacuum cleaner 1 in which a rotating brush that is rotated by a drive motor is provided in the suction port body 40, the connection portion 51ac of the brush nozzle 50 is inserted into the connection port of the connection portion 22d of the flexible hose 20 (see FIG. 1). By inserting and connecting, a power supply terminal (power supply terminal port) (not shown) exposed at the end face side of the connection part 22d is blocked by the step surface between the connection part 51ac and the neck part 51ab. As a result, when dust is sucked by the brush nozzle 50, the dust is less likely to adhere to the power supply terminal.

The inner wall portion 51b includes a substantially concave second accommodation portion 51ba that accommodates the turbine brush 52, a flange portion 51bb that is continuous along the opening end of the second accommodation portion 51ba, and a flange portion 51bb that extends in the circumferential direction. A plurality (four in this embodiment) of the nozzle ports 51bc are provided.
Further, the inner wall portion 51b includes a second air introduction port 51bd provided in the peripheral wall portion 51bf of the second accommodation portion 51ba, and an air guide for guiding the air introduced from the first air introduction port 51ad to the second air introduction port 51bd. It has a passage 51be and a pair of air outlets 51bh provided in a circular top plate portion 51bg of the inner wall portion 51b for discharging the air A1 introduced into the inner wall portion 51b through the second air inlet port 51bd.

The air guide path 51be is formed integrally with the peripheral wall portion 51bf and the flange portion 51bb of the second accommodating portion 51ba.
In this embodiment, the outer wall portion 51a and the inner wall portion 51b are made of separate members, and the inner wall portion 51b is combined with the turbine brush 52 to form a turbine brush unit 53. FIG. When the brush nozzle 50 is assembled, the upper end of the outer peripheral portion R of the flange portion 51bb of the turbine brush unit 53 and the opening edge of the outer wall portion 51a are connected by adhesion, fusion, or the like. At this time, the turbine brush unit 53 is assembled so that the air guide passage 51be of the turbine brush unit 53 faces the first air introduction port 51ad of the outer wall portion 51a.

As shown in FIG. 6, the pair of air outlets 51bh are provided at 180° facing positions centering on the axis P. As shown in FIG. In addition, the pair of air outlets 51bh are arranged at different positions in the circumferential direction about the axis P so as not to coincide with the position of the second air inlet 51bd. Further, the pair of air outlets 51bh are not arranged equidistant from the second air inlet 51bd in the circumferential direction, but one air outlet 51bh is arranged closer than the other air outlet 51bh. ing.

In this embodiment, when the turbine brush 52 is viewed from above as shown in FIG. The other air outlet 51bh is provided in the range of center angles θ3 to θ4 in the counterclockwise direction. It is approximately 120°. Note that θ1 to θ4 are not limited to the above ranges.

By arranging the pair of air outlets 51bh in this way, as shown in FIGS. is discharged to the outside of the second accommodating portion 51ba through the pair of air outlets 51bh. At this time, the air A1 tends to flow toward the air outlet 51bh closer to the second air inlet 51bd, so the turbine section 52b, which will be described later, starts to rotate clockwise. The operation of the brush nozzle 50 during suction cleaning will be described later in detail.

[About the turbine brush]
As shown in FIGS. 2 to 6, the turbine brush 52 is arranged on the axis P perpendicular to the surface F to be cleaned when the lower side of the nozzle body 51 faces the surface F to be cleaned during use. A shaft portion 52a provided, a turbine portion 52b connected to the shaft portion 52a, a brush portion 52c connected to the shaft portion 52a via the turbine portion 52b, and an end portion of the shaft portion 52a on the side of the surface to be cleaned F. and a circular shielding plate 52d provided on the .

The shaft portion 52a is rotatably attached to a through hole provided at the center position of the top plate portion 51bg of the inner wall portion 51b of the turbine brush unit 53 via a bearing 52e. A slide bearing, a rolling bearing, or the like can be used as the bearing 52e.

The turbine portion 52b includes a base portion 52ba having a circular concave shape when viewed from the direction of the axis P, a boss portion 52bb provided at the center of the base portion 52ba and into which the shaft portion 52a is inserted and fixed, and the base portion 52ba. It has a plurality of blade portions 52bc radially provided on the upper surface of the upper wall portion of the body, and is formed in a face gear shape. Note that the turbine portion 52b is not limited to such a face gear type, and may be, for example, a bevel gear type.
When the shaft portion 52a is inserted into and fixed to the boss portion 52bb of the turbine portion 52b, the lower end of the shaft portion 52a protrudes downward from the boss portion 52bb. A shielding plate 52d is provided at the lower end of the shaft portion 52a, and the shielding plate 52d is accommodated in the base portion 52ba with a slight gap from the peripheral wall portion of the base portion 52ba.

The brush portion 52c has a plurality of bristles arranged in an annular shape along the opening edge at the lower end of the base portion 52ba of the turbine portion 52b. Although the brush bristles are shown only partially in FIG. 5, the brush bristles are actually arranged in an annular shape as described above. In addition, the plurality of bristles are outwardly opened so as to be inclined outward toward the tip end side in contact with the surface F to be cleaned. Further, as shown in FIG. 3, the lower end of the brush bristles (the end on the side of the surface to be cleaned) is closer to the floor surface than the outer peripheral portion of the lower end of the brush nozzle 50 (the lower end of the outer peripheral portion R of the flange portion 51bb of the turbine brush unit 53). located in By doing so, the brush is brought into contact with the surface to be cleaned while providing a gap between the outer peripheral portion of the lower end of the brush nozzle 50 (the lower end of the outer peripheral portion R of the flange portion 51bb of the turbine brush unit 53) and the surface to be cleaned F. can be made
In addition, in order to provide a gap between the outer peripheral portion of the lower end of the brush nozzle 50 and the surface to be cleaned F, a rolling portion such as a wheel or a ball, a rib or a dome-shaped convex portion is provided on a part of the outer peripheral portion of the lower end of the brush nozzle 50. may be provided. By doing so, it is possible to easily provide a gap between the outer peripheral portion of the lower end of the brush nozzle 50 and the surface F to be cleaned during use.
The material of each brush bristle is not particularly limited. The soft brush portion 52c can be formed by forming the brush bristles with a multifilament made of twisted thin fibers (for example, about 6 to 13 denier), and the monofilament made of thick fibers (for example, about 70 denier) can be used for the brush. If bristles are formed, the hard brush portion 52c can be configured.

<Operation of the brush nozzle during suction cleaning>
As shown in FIG. 1, when the surface to be cleaned is a floor surface, it can be cleaned efficiently by connecting the extension pipe 30 to which the suction port 40 is connected to the connecting portion 22d of the flexible hose 20. .
On the other hand, if the surface to be cleaned is a location on the floor where electrical cords are gathered, a shelf on which small items are placed, or a location that is difficult to clean with the suction port 40, such as decorations on the shelf, the brush nozzle 50 is used. By inserting and connecting to the connecting portion 22d of the flexible hose 20 or the connecting portion 32a of the extension pipe 30, cleaning can be performed efficiently.

In cleaning with the brush nozzle 50, as shown in FIGS. 1 to 6, by driving the driving device 11, the inside of the brush nozzle 50 becomes negative pressure, and the brush nozzle 50 located away from the surface F to be cleaned is at the first position. Air A1 flows into the second accommodation portion 51ba from the first air introduction port 51ad. The air A1 flows counterclockwise in the second accommodation portion 51ba when viewed from above and is discharged from the pair of air outlets 51bh to the outside of the second accommodation portion 51ba. The turbine brush 52 rotates counterclockwise due to the impingement of each blade portion 52bc.

In addition, when the inside of the brush nozzle 50 becomes negative pressure, the surface to be cleaned F flows from the plurality of nozzle openings 51bc around the turbine brush 52 into the brush nozzle 50 (the space S between the outer wall portion 51a and the inner wall portion 51b). Air A2 containing dust from above flows in. At this time, air A2 is sucked into each nozzle port 51bc together with dust from the periphery of the gap between the lower outer peripheral portion of the brush nozzle 50 (the lower end of the outer peripheral portion R of the flange portion 51bb of the turbine brush unit 53) and the surface to be cleaned F. be

Further, as the turbine brush 52 rotates while being in contact with the surface F to be cleaned, dust adhering to the surface F to be cleaned is swept outward by the outwardly-opening brush portion 52c. It is sucked into the brush nozzle 50 (space S) together with the air A2 flowing into the plurality of nozzle ports 51bc. Therefore, even dust on the surface to be cleaned F that is difficult to be sucked up by only the suction force (flow of the air A2) can be removed by mechanically rubbing the surface to be cleaned F with the rotating brush portion 52c to float the dust. It can be aspirated and removed without scattering around.

Inside the brush nozzle 50, the air A1 that has passed through the turbine brush 52 and the dust-containing air A2 that has passed through the plurality of nozzle ports 51bc join in the space S and pass through the neck 51ab, and the joined air is flexible. It flows into the dust collecting device 12 of the main body 10 of the cleaner through the air hose 20 . Dust is captured by the dust collector 12 , and the dust-removed air is discharged to the outside from an exhaust port (not shown) of the drive device 11 .
According to this brush nozzle 50, since the air A1 at a position distant from the surface F to be cleaned is taken into the second accommodation portion 51ba of the inner wall portion 51b inside the brush nozzle 50, the air A1 near the bearing 52e of the shaft portion 52a of the turbine brush 52 is taken in. The trouble that the rotation of the turbine brush 52 is hindered due to the fibrous matter such as lint as dust and hair being wound around the turbine brush 52 is suppressed.
A filter may be provided in at least one of the first air inlet 51ad, the second air inlet 51bd, and the air guide passage 51be. By doing so, it is possible to suppress the intrusion of dust and fibrous substances into the inside of the second accommodating portion 51ba.

Further, since the shield plate 52d is provided at the lower end of the shaft portion 52a, fibrous substances (dust) are prevented from entering the lower portion (inside the recess) of the turbine portion 52b. That is, in the absence of the shielding plate 52d, fibrous material may wind around the boss portion 52bb in the concave portion of the turbine portion 52b, or dust may accumulate. Wrapping around is suppressed. Since the turbine portion 52b is fixed to the shaft portion 52a, rotation of the turbine portion 52b is unlikely to be hindered even if a fibrous material winds around the boss portion 52bb.
In addition, since the turbine portion 52b and the brush portion 52c rotate integrally, the rotational force of the turbine portion 52b is directly transmitted to the brush portion 52c without passing through a pulley, a belt, or the like, and the brush portion 52c can be efficiently moved even with a weak suction force. can rotate well.

(First Modification of First Embodiment)
FIG. 7 is a cross-sectional front view showing part of a first modification of the brush nozzle of the first embodiment. In addition, in FIG. 7, the same reference numerals are given to the same elements as those in FIG.
In the brush nozzle 50A of the first modified example, as shown in FIG. An outwardly-opening annular auxiliary brush 61 is provided along the lower end.
By providing the auxiliary brush 61 in the brush nozzle 50A, the gap between the nozzle main body 51 and the surface F to be cleaned can be reduced to increase the suction force. Also, the dust accumulated on the corner N of the surface F to be cleaned can be scraped out by the auxiliary brush 61 and sucked by the nozzle port 51bc.

(Second Modification of First Embodiment)
FIG. 8 is a cross-sectional front view showing part of a second modification of the brush nozzle of the first embodiment. In addition, in FIG. 8, the same reference numerals are given to the same elements as those in FIG.
In the brush nozzle 50B of the second modified example, as shown in FIG. An annular elastic body 62 made of rubber, silicon resin, or the like is provided along the lower end.
Also by providing the elastic body 62 in the brush nozzle 50B, the gap between the nozzle body 51 and the surface F to be cleaned can be reduced to increase the suction force. Further, for example, even if there is a wall surface W at the corner N of the surface to be cleaned F, the elastic body 62 contacts the wall surface W, so that the nozzle body 51 can be prevented from contacting the wall surface W and damaging it.

(Third modification of the first embodiment)
FIG. 9 is a bottom view showing part of a third modification of the brush nozzle of the first embodiment. In addition, in FIG. 9, elements similar to those in FIG. 5 are given the same reference numerals.
In the brush nozzle of the third modification, as shown in FIG. 9, a shielding plate 52d of a turbine brush 52C is provided with a length substantially equal to the radius of the shielding plate 52d in the radial direction from the axis P on the surface of the turbine brush 52C facing the surface to be cleaned. An inner brush portion 63 is provided.
By providing the inner brush portion 63, the inner area of the brush portion 52c on the surface to be cleaned can be swept to send dust toward the brush portion 52c, thereby improving the cleaning efficiency.

(Fourth modification of the first embodiment)
FIG. 10 is a bottom view showing part of a fourth modification of the brush nozzle of the first embodiment. In FIG. 10, elements similar to those in FIG. 5 are given the same reference numerals.
In the brush nozzle of the fourth modification, as shown in FIG. 10, a shielding plate 52d of a turbine brush 52D is provided with a length substantially equal to the diameter of the shielding plate 52d in a diametrical direction passing through the axis P on the surface of the turbine brush 52D facing the surface to be cleaned. An inner brush portion 64 is provided.
Also by providing the inner brush portion 64, the inner area of the brush portion 52c on the surface to be cleaned can be swept and dust can be sent to the brush portion 52c side, so that the cleaning efficiency is improved to the same or higher level than that of the third modification. .

(Second embodiment)
11A and 11B are a partial cross-sectional front view and a partial cross-sectional left side view of the brush nozzle of the second embodiment. In FIGS. 11A and 11B, elements similar to those in FIGS. 2 and 3 are denoted by the same reference numerals.
While the brush nozzle 50 having one turbine brush 52 is illustrated in the first embodiment (FIGS. 1-6), the brush nozzle 150 of the second embodiment has two turbine brushes 152. FIG.
In this case, as shown in FIG. 11, the neck portion 51ab and the connection portion 51ac of the nozzle body 151 are the same in shape, length, and thickness as those in the first embodiment, but the nozzle body 151 is larger than that in the first embodiment. The width L1 of the first accommodation portion 151aa in the left-right direction is set narrow, and the length L2 of the first accommodation portion 151aa in the front-rear direction is set long. That is, the nozzle body 151 is formed elongated in the front-rear direction.

Also, the two turbine brushes 152 are made smaller than in the first embodiment, and unitized as one turbine brush unit 153 . That is, one inner wall portion 151b having two second housing portions 151ba for housing two turbine brushes 152 in front and rear positions is prepared, and two turbine brushes 152 are incorporated in this inner wall portion 151b to form a turbine brush unit 153. is configured.

In this turbine brush unit 153 , a plurality of nozzle openings 151bc are arranged at front and rear positions and left and right positions of each turbine brush 152 . Further, in the turbine brush unit 153, two second air introduction ports 151bd and two air guide passages 151be corresponding to each turbine brush 152 are provided on one left and right side (left side in this case). A pair of corresponding air outlets 151bh are provided at the front and rear positions, respectively.

In addition, a pair of first air introduction ports 151ad are provided at front and rear positions facing the front and rear air guide passages 151be on one of the left and right side surfaces (the left side surface in this case) of the housing portion 151aa in the outer wall portion 151a of the nozzle body 151. It is
According to the brush nozzle 150 of the second embodiment, during suction, each turbine brush 152 rotates and sweeps dust on the surface to be cleaned by the same action as in the first embodiment, and the swept dust is removed together with the air. It is sucked and removed from a plurality of nozzle ports 151bc arranged around the turbine brush 152 . The second embodiment is particularly suitable for efficiently cleaning narrow spaces.

(Third embodiment)
FIG. 12 is a perspective view showing each component of the electric vacuum cleaner of the third embodiment.
In the first embodiment (see FIG. 1), the brush nozzle 50 is used as an attachment for the canister-type vacuum cleaner 1, but as shown in FIG. 12, the brush nozzle 50 is used as an attachment for a stick-type vacuum cleaner 101. can also
In the case of the stick-type vacuum cleaner 101 shown in FIG. A mouth body 140 is provided, and a brush nozzle 50 as an attachment detachably connected to the cleaner body 110 is provided.

A cleaner main body 110 incorporates an electric blower (not shown), a driving device 111 detachably mounted with a battery 113 for supplying power to the electric blower, and a dust collector detachably mounted on the driving device 111. 112.
The driving device 111 has an extension tube 130, a connecting portion 111a detachably provided at the front end, and a handle 111b and a switch 111c provided at the rear end.
The dust collection device 112 has a dust collection container and a filter portion detachably attached to the dust collection container. In addition, although the dust collector 112 of this embodiment is of a cyclone type, it may be of a disposable paper pack type.

The extension pipe 130 is detachably connected to a connecting portion 130a provided at the downstream end in the airflow direction so as to be detachable from the connecting portion 111a of the cleaner main body 110, and to a connecting pipe portion 143 of the suction port body 140, which will be described later. and a connecting portion 130b provided at the upstream end in the airflow direction.
The suction port body 140 has a suction port main body 141, a joint portion 142, and a connection pipe portion 143 similar to those of the first embodiment.

In the case of this stick-type vacuum cleaner 101 as well, when the surface to be cleaned is a floor surface, the extension pipe 30 connected to the suction port 140 is connected to the connection portion 111a of the cleaner main body 110 to efficiently clean. be able to.
On the other hand, if the surface to be cleaned is a location on the floor where electrical cords are gathered, a shelf on which small items are placed, or a location that is difficult to clean with the suction port 140, such as decorations on the shelf, the brush nozzle 50 is used. By inserting and connecting to the connection portion 111a of the cleaner body 110 or the connection portion 130b of the extension pipe 130, cleaning can be performed efficiently.

(Other embodiments)
1. The brush nozzle 150 of the second embodiment may be appropriately combined with the first to fourth modifications of the first embodiment.
2. In the first embodiment, the case where the air guide passage 51be is provided so that the air A1 flows in from a direction perpendicular to the tangent line of the rotation locus of the turbine portion 52b when viewed in plan is illustrated, but the turbine portion 52b is provided. The air guide path 51be may be provided so that the air flows in from the direction tangential to the locus of rotation.
3. In the first embodiment, the turbine brush 52 is provided with two air outlets 51bh, but the number of air outlets 51bh may be one. In this case, it is preferable to provide the air outlet 51bh at a position avoiding the vicinity of the central angle of 180° in order to increase the rotation efficiency of the turbine portion 52b.

4. In the first to third embodiments, the turbine portion 52b is fixed to the shaft portion 52a of the turbine brush 52, but the turbine portion 52b may be rotatably connected to the shaft portion 52a via a bearing. Further, in this case, the shaft portion 52a may be fixed to the inner wall portion 51b.
5. In the first to third embodiments, the case where the brush nozzle 50 is configured so that the air flowing into the turbine brush 52 is taken in from a position distant from the surface F to be cleaned is illustrated, but the air flowing from the vicinity of the surface F to be cleaned causes the turbine brush to 52 may be configured to rotate. In this case, for example, the first and second air introduction ports 51ad and 51bd are closed, the air guide passage 51be and the shielding plate 52d are omitted, and a plurality of slits are formed in the upper wall of the turbine section 52b to form a plurality of blades. The turbine section is rotated by the air flowing through the plurality of slits. In this case, it is preferable to provide a pivoting structure for connecting the shaft portion 52a to the inner wall portion 51b to prevent fibrous dust particles from winding around the shaft portion 52a and hindering the rotation of the turbine portion.
6. In the first to third embodiments, the brush nozzle having the turbine brush was exemplified, but instead of the turbine brush, a brush nozzle rotating the brush by a drive motor may be used. In the case of a brush nozzle equipped with this driving motor, the power receiving terminal that can be mechanically and electrically connected to the power feeding terminal of each connecting part of the drive device of the vacuum cleaner to which it is connected, the flexible hose or the extension tube is the nozzle. A wiring path is provided in the nozzle body, which is provided in the connection portion of the main body and electrically connects the power receiving terminal and the drive motor. Further, in this case, the ventilation path (the first air inlet, the air guide path, the second air inlet, and the air outlet) for the second accommodation portion accommodating the turbine brush in the first to third embodiments is omitted. Alternatively, the drive motor accommodated in the second accommodating portion may be cooled by blowing an air stream while leaving a ventilation path. In this case, the contents of the first to third embodiments and other embodiments 1 to 5 may be combined as long as there is no contradiction.

(summary)
A brush nozzle for a vacuum cleaner of the present invention comprises a nozzle body having a nozzle port for sucking air containing dust on a surface to be cleaned, and the nozzle rotatable about an axis perpendicular to the surface to be cleaned. A turbine brush provided in the main body,
The nozzle port is arranged around the turbine brush, and the turbine brush is rotated by an air flow flowing into the nozzle body.
According to this configuration, the turbine brush is rotated by the suction force, and dust on the surface to be cleaned is mechanically rubbed by the rotating turbine brush to be lifted, and the lifted dust is removed by suction from the nozzle port around the turbine brush. Therefore, dust can be removed efficiently with a simple structure. In particular, it is effective for cleaning places on the floor where electrical cords are gathered, and for cleaning the shelves and objects (small items, decorations, etc.) on the shelves.
Further, the rotation of the turbine brush does not require a driving motor and a power supply, and the turbine brush can be efficiently rotated by the airflow in the nozzle body.
In addition, if an air path for the wind that rotates the turbine brush is secured, it is possible to deal with various shapes of connecting portions, and the degree of freedom in design is large.

The brush nozzle for a vacuum cleaner of the present invention may be configured as follows, or may be combined as appropriate.

- the turbine brush has a shaft portion provided on the axial center and a turbine portion connected to the shaft portion;
The nozzle body includes an outer wall portion, a concave inner wall portion provided inside the outer wall portion so as to accommodate the turbine brush, a flange portion connecting the outer wall portion and the inner wall portion, and a first air inlet provided in the outer wall so as to suck in air away from the surface to be cleaned; a second air inlet provided in the inner wall; an air guide passage for guiding air introduced from an air inlet to the second air inlet; and air provided in the inner wall for discharging air introduced into the inner wall via the second air inlet. and an outlet;
The turbine section of the turbine brush within the inner wall may be configured to be rotated by an airflow.
According to this configuration, since air away from the surface to be cleaned flows into the turbine section, it is difficult for dust to flow into the turbine section, and it is possible to suppress the rotation of the turbine section from being hindered by the winding of fibrous materials on the shaft section. can.

- When viewed from the axial direction, the air outlet may be displaced from the second air inlet in the rotational direction of the turbine section.
According to this configuration, the turbine section can be efficiently rotated.

- the turbine brush has a shaft portion provided on the axial center and a brush portion connected to the shaft portion;
The brush portion has a plurality of bristles arranged in an annular shape about the axial center, and the plurality of bristles are outwardly opened, slanting outward toward the tip side where the plurality of bristles come into contact with the surface to be cleaned. good too.
According to this configuration, the dust on the surface to be cleaned can be swept outward by the rotating brush portion and removed by suction from the nozzle openings around the brush portion. Therefore, it is difficult for dust to scatter to the outside of the brush nozzle.

- An auxiliary brush or an elastic body may be provided along the edge portion around the nozzle opening in the outer wall portion of the nozzle body.
According to this configuration, the gap between the nozzle body and the surface to be cleaned can be reduced by the auxiliary brush or the elastic body, and the suction force can be increased. In addition, the auxiliary brush also has a function of raking out dust accumulated at the corners of the surface to be cleaned so that the dust can be easily sucked by the nozzle port. In addition, the elastic body functions as a bumper having a cushioning property so that the nozzle body does not hit and damage the wall surface or the like near the surface to be cleaned.

- the nozzle body has a connection pipe part that can be connected directly or via a connector to a connection port of the cleaner body,
The connecting pipe portion may be bent so as to be inclined with respect to the surface to be cleaned when the turbine brush is in contact with the surface to be cleaned.
According to this configuration, the user holding the suction unit (cleaner main body or connector connected to the cleaner main body) to which the brush nozzle is attached can clean in a natural posture without twisting the wrist.

- The turbine brush may have a shielding plate at the end of the shaft on the side of the surface to be cleaned.
According to this configuration, the dust on the surface to be cleaned can be prevented from rising toward the shaft by the shielding plate, so that fibrous materials can be prevented from winding around the shaft.

- The turbine brush may have an inner brush portion on a surface facing the surface to be cleaned of the shielding plate.
According to this configuration, the inner brush portion can sweep the inner area of the annular brush portion on the surface to be cleaned, thereby improving the cleaning efficiency.

- A plurality of the turbine brushes may be provided in the nozzle body.
According to this configuration, it is possible to form the brush nozzle to be elongated and efficiently clean the inside of the narrow gap.

Further, the brush nozzle of the present invention comprises a nozzle body having a nozzle port for sucking air containing dust on a surface to be cleaned, and a nozzle body rotatable about an axis perpendicular to the surface to be cleaned. and a drive motor provided within the nozzle body,
The nozzle opening may be arranged around the brush, and the brush may be rotated by the drive motor.
According to this configuration, the brush can be rotated at high speed by the motor, so that the dust adhering to the surface to be cleaned can be efficiently swept and the dust can be sucked by the nozzle openings on the outside of the periphery of the brush.

It should be noted that the disclosed embodiments should be considered as examples and not restrictive in all respects. The scope of the present invention is indicated by the scope of the claims rather than the above description, and is intended to include all modifications within the scope and meaning equivalent to the scope of the claims.

1, 101 vacuum cleaner 10, 110 vacuum cleaner main body 50, 50A, 50B, 150 brush nozzle 51, 151 nozzle main body 51a, 151a outer wall portion 51ab, 151ab neck portion of connection pipe portion 51ac, 151ac connection portion of connection pipe portion 51ad, 151ad First air inlets 51b, 151b Inner wall portion 51bb Flange portion 51bc, 151bc Nozzle ports 51bd, 151bd Second air inlets 51be, 151be Air guide passages 51bh, 151bh Air outlets 52, 52C, 52D, 152 Turbine brushes 52a Shaft Part 52b Turbine part 52c Brush part 52d Shield plate 61 Auxiliary brush 62 Elastic body 63, 64 Inner brush part F Surface to be cleaned P Axis center

Claims (7)

a nozzle body having a nozzle port for sucking air containing dust on a surface to be cleaned; and a turbine brush provided in the nozzle body rotatably about an axis perpendicular to the surface to be cleaned,
The nozzle port is arranged around the turbine brush, and the turbine brush is rotated by an airflow flowing into the nozzle body ,
The turbine brush has a shaft portion provided on the axial center and a turbine portion connected to the shaft portion,
The nozzle body includes an outer wall portion, a concave inner wall portion provided inside the outer wall portion so as to accommodate the turbine brush, a flange portion connecting the outer wall portion and the inner wall portion, and a first air inlet provided in the outer wall so as to suck in air away from the surface to be cleaned; a second air inlet provided in the inner wall; an air guide passage for guiding air introduced from an air inlet to the second air inlet; and air provided in the inner wall for discharging air introduced into the inner wall via the second air inlet. and an outlet;
A brush nozzle for a vacuum cleaner , wherein the turbine portion of the turbine brush in the inner wall portion is rotated by an air flow . 2. The brush nozzle according to claim 1 , wherein the air outlet is displaced from the second air inlet in the rotational direction of the turbine section when viewed from the axial direction. The turbine brush has a shaft portion provided on the axial center and a brush portion connected to the shaft portion,
The brush portion has a plurality of bristles arranged in an annular shape about the axial center, and the plurality of bristles are outwardly opened, slanting outward toward the tip side where the plurality of bristles come into contact with the surface to be cleaned. 3. A brush nozzle according to claim 1 or 2 . 3. The brush nozzle according to claim 1 , wherein an auxiliary brush or an elastic body is provided along the edge portion around the nozzle opening in the outer wall portion of the nozzle body. The nozzle body has a connection pipe part that can be connected directly or via a connector to a connection port of the cleaner body,
The brush nozzle according to any one of claims 1 to 4 , wherein the connecting pipe portion is bent so as to be inclined with respect to the surface to be cleaned when the turbine brush is in contact with the surface to be cleaned. 4. The brush nozzle according to claim 3 , wherein the turbine brush has a shielding plate at the end of the shaft on the side of the surface to be cleaned. A vacuum cleaner comprising a cleaner body and the brush nozzle according to any one of claims 1 to 6 connected to the cleaner body.

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