KR20120135297A - Rotating cleaning body unit, suction mouth body, and electric cleaner - Google Patents

Abstract

In the embodiment of the present invention, a rotary cleaning body using a turbine as a prime mover, and capable of driving the rotating cleaning body at a high torque without lowering the suction work rate of the vacuum cleaner, Suggest. The rotary cleaning body unit includes a turbine 41, a planetary gear mechanism 43 having a drive shaft connected to the turbine 41, and a rotary cleaning body 44 connected to the driven shaft of the planetary gear mechanism 43.

Description

ROTATING CLEANING BODY UNIT, SUCTION MOUTH BODY, AND ELECTRIC CLEANER}

One embodiment which concerns on this invention relates to the rotary cleaning body unit provided with the rotary cleaning body which uses a turbine as a prime mover, a suction inlet body, and an electric vacuum cleaner.

Generally, the electric vacuum cleaner has a suction port body. The suction port body has a suction port on the bottom face of the suction port body. The inlet port sucks dust on the surface to be cleaned together with air through the inlet port.

Background Art A suction inlet body having a rotary cleaning body disposed at the inlet port is known. The suction port includes a motor and a turbine as the prime mover of the rotary cleaning body.

The suction port provided with the rotary cleaning body which uses a turbine as a prime mover is provided with the transmission mechanism which transmits the torque of a turbine (for example, refer patent document 1).

Japanese Patent Laid-Open No. 2006-204781

1 is a perspective view showing the appearance of an electric vacuum cleaner according to an embodiment of the present invention.
2 is a plan sectional view showing an intake port according to an embodiment of the present invention.
3 is a plan sectional view showing a suction port according to an embodiment of the present invention.
Fig. 4 is a side view simply showing the planetary gear mechanism of the suction port according to the embodiment of the present invention.
5 is a longitudinal sectional view of an intake port according to an embodiment of the present invention.
6 is a plan sectional view showing another example of the inlet port according to the embodiment of the present invention.

EMBODIMENT OF THE INVENTION Hereinafter, one Embodiment of the electric vacuum cleaner which concerns on this invention is described.

First, with respect to the suction inlet, the size and weight (mass) are limited in consideration of the portability in the state of use of the electric vacuum cleaner and the ease of operation. Because of this limitation, the turbine and the electric motor which are the prime movers of the rotary cleaning body are limited in their volume (volume occupancy volume) and weight.

Therefore, in order to obtain the output of a turbine as large as possible, the inlet body of patent document 1 arranges the rotation axis of a turbine orthogonal to the rotation axis of a rotary cleaning body, and ensures the rotation radius of a turbine as large as possible.

However, the suction port of Patent Document 1 requires a reduction mechanism composed of a plurality of gears and a transmission mechanism composed of a plurality of timing belts, bevel gears, and the like, in order to transmit torque from the turbine to the rotary cleaning body. The transmission mechanism has a large mechanical loss due to a large number of frictional parts and sliding parts.

In addition, the suction inlet having the rotary cleaning body using the turbine as the prime mover utilizes a part of the suction power of the electric blower to drive the turbine, thus obtaining sufficient torque within a range that does not lower the suction work rate of the electric vacuum cleaner. It is difficult. For example, the suction inlet body provided with the rotary cleaning body which uses a turbine as a prime mover may be difficult to drive a rotary cleaning body from the carpet-cleaned surface.

In the embodiment of the present invention, a rotary cleaning body including a rotary cleaning body using a turbine as a prime mover and capable of driving the rotating cleaning body at high torque without lowering the suction work rate of the vacuum cleaner, the suction inlet body, and the vacuum cleaner. Suggest.

MEANS TO SOLVE THE PROBLEM In order to solve the said subject, the rotary cleaning body unit which concerns on embodiment of this invention contains a turbine, the planetary gear mechanism which has a drive shaft connected to the turbine, and the rotary cleaning body connected with the driven shaft of the planetary gear mechanism. It is characterized by.

Further, the inlet body according to the embodiment of the present invention is an inlet body having an air inlet, a dust inlet formed on the bottom wall, and a suction chamber communicating the air inlet and the dust inlet with each other, and tiltable with respect to the inlet body. And a connecting tube communicating with the suction chamber, and a rotary cleaning body unit housed in the suction chamber, wherein the rotary cleaning body is disposed at the dust inlet, and the turbine is connected to the connecting tube from the air inlet. Characterized in that arranged in the passage.

In addition, the electric vacuum cleaner according to the embodiment of the present invention includes a vacuum cleaner body, an electric blower housed in the vacuum cleaner body, and a suction port communicating with the electric blower.

Subsequently, an embodiment of the rotary cleaning body unit, the suction inlet body, and the electric vacuum cleaner according to the present invention will be described with reference to FIGS.

1 is a perspective view showing the appearance of an electric vacuum cleaner according to an embodiment of the present invention.

As shown in FIG. 1, the electric vacuum cleaner 1 is what is called a canister type vacuum cleaner. The vacuum cleaner 1 includes a cleaner body 2 disposed on the surface to be cleaned and a pipe part 3 detachably connected to the cleaner body 2.

The vacuum cleaner main body 2 includes a main body case 5, a pair of wheels 6 pivotably supported on both sides of the main body case 5, and a dust separation dust collecting part 7 housed in the main body case 5. And the electric blower 8 communicated with the dust separation dust collecting unit 7, the control unit 9 for controlling the driving of the electric blower 8, and the power cord 11 for inducing electric power to the electric blower 8. Equipped.

The main body case 5 has a main body connector 12 connected to the dust separation dust collecting unit 7.

The dust separation dust collecting unit 7 separates and collects dust from air including dust sucked into the electric vacuum cleaner 1 by the negative pressure generated by the electric blower 8.

The wheel 6 is a traveling wheel having a large diameter for moving the cleaner body 2.

The control unit 9 has a plurality of preset operation modes. The control unit 9 drives the electric blower 8 by alternatively selecting one arbitrary operation mode in the plurality of operation modes in response to the operation signal input from the pipe portion 3. Each operation mode is set so that the input of the electric blower 8 differs, and is associated with the operation signal input from the pipe part 3.

The power cord 11 has a power plug 14 at its free end.

The pipe part 3 inhales the air containing dust (air containing dust) from the surface to be cleaned by the negative pressure acting from the cleaner main body 2 with the operation of the electric blower 8, and the dust containing air sucked in. To the cleaner body (2). The pipe part 3 is a connection pipe 19 detachably connected to the main body connector 12 of the cleaner main body 2, the dust collecting hose 21 which communicates with the connection pipe 19, and is flexible, and dust-collecting. Hand operating tube 22 communicating with the hose 21, holding part 23 protruding from the hand operating tube 22, operating part 24 provided in the holding part 23, and hand operating tube And an extension tube 25 detachably connected to and in communication with the 22, and a suction port 26 detachably connected to and in communication with the extension tube 25.

The dust collecting hose 21 is formed to have a bent and elongate substantially cylindrical shape. One end of the dust collecting hose 21 is connected to the connecting pipe 19. The dust collecting hose 21 communicates with the inside of the cleaner body 2 via the connecting pipe 19.

One end of the hand control tube 22 is provided at the other end of the dust collecting hose 21. The hand operation pipe 22 communicates with the inside of the cleaner body 2 via the connection pipe 19 and the dust collecting hose 21.

The holding part 23 is for holding by the user of the electric vacuum cleaner 1, and for operating the electric vacuum cleaner 1. As shown in FIG. The holding part 23 protrudes from the other end of the hand control tube 22 and is curved toward one end of the hand control tube 22.

The operation unit 24 is provided with a switch corresponding to each operation mode. Specifically, the operation unit 24 includes a stop switch 24a for stopping the electric blower 8 and a start switch 24b for starting operation of the electric blower 8. The user of the electric vacuum cleaner 1 can alternatively select the operation mode of the electric blower 8 by operating the operation unit 24.

The extension pipe 25 is formed to have an elongate substantially cylindrical shape. The extension pipe 25 is comprised so that it may have a telescopic structure by superimposing a some cylindrical shape. One end of the extension pipe 25 is detachably connected to the other end of the hand control pipe 22. The extension pipe 25 communicates with the inside of the cleaner body 2 through the connection pipe 19, the hand operation pipe 22, and the dust collecting hose 21.

The inlet port 26 is detachably connected to one end of the extension pipe 25. The suction port 26 communicates with the inside of the cleaner main body 2 through the extension tube 25, the hand operation tube 22, and the dust collecting hose 21.

When the start switch 24b is operated, the electric vacuum cleaner 1 drives the electric blower 8 to apply negative pressure to the inside of the cleaner main body 2. This negative pressure acts on the suction port 26 through the dust collecting hose 21, the hand control pipe 22, and the extension pipe 25 from the main body connecting port 12. By the negative pressure acting on the suction port 26, the vacuum cleaner 1 sucks dust accumulated on the surface to be cleaned from the suction port 26 together with the air to clean the surface to be cleaned. The dust-containing air sucked into the suction port 26 is separated into air and dust by the dust separation dust collecting part 7 accommodated in the cleaner body 2. The separated dust is collected by the dust separation dust collecting part 7. On the other hand, the separated air passes through the dust separation dust collecting part 7, is sucked into the electric blower 8, and is discharged from the cleaner main body 2.

2 is a plan sectional view showing a suction inlet body and a rotary cleaning body unit according to an embodiment of the present invention.

3 is a plan sectional view showing a suction inlet body and a rotary cleaning body unit according to an embodiment of the present invention.

As shown in FIG. 2 and FIG. 3, the inlet port 26 includes a suction port body 31 having a substantially rectangular box shape, a connecting pipe 32 tiltable with respect to the suction port body 31, and a suction port. The rotary cleaning body unit 33 accommodated in the main body 31 is provided.

Here, it is assumed that the advancing direction of the suction port 26 (solid arrow X in FIG. 2) is forward, and the opposite direction is backward. Further, in a state where the suction port 26 is disposed on a substantially horizontal cleaning surface such as a bottom surface, the left side (solid line arrow Y in FIGS. 2 and 3) when viewed from the rear side is opposite to the left side, and vice versa. Assume the direction to the right. In addition, it is assumed that the + Z direction of the right-hand coordinate system orthogonal to the front-rear direction and the left-right direction of the suction port 26 is upward, and the opposite direction is downward.

The suction port main body 31 has a short side in the front-rear direction on a plan view, a case body 34 having a long side in the left-right direction, and a connection pipe holding part 35 formed integrally with the rear part of the case body 34. It is provided.

The case body 34 is a hollow box-shaped body, and has the suction chamber 36 inside. In addition, the case body 34 includes a side wall having an air inlet 38 and a bottom wall having a dust suction port 39. The suction chamber 36 is opened to the outer space of the case body 34 through the dust suction port 39 and the air inlet port 38. The air inlet 38 may be disposed on a wall other than the bottom wall (sidewalls on the front, rear, left, and right sides).

The connection pipe 32 is pivotally supported by the connection pipe holding part 35 and can be tilted about the axis | shaft of the width direction of the suction port 26. As shown in FIG. In addition, the connection pipe 32 communicates with the suction chamber 36 of the case body 34. The inlet port 26 applies negative pressure to the dust inlet 39 and the air inlet 38 through a connecting tube 32 detachably connected to the extension tube 25 to suck in dust-containing air and air.

The rotary cleaning body unit 33 is accommodated in the suction chamber 36 of the case body 34. In addition, the rotary cleaning body unit 33 includes a turbine 41 driven by air sucked through the air inlet 38, a turbine shaft 42 fixed to the turbine 41, and a turbine shaft 42. A planetary gear mechanism (planetary gearing) 43 connected to and a rotary shaft C disposed at the dust inlet 39 and pivotally supported by the planetary gear mechanism 43 and substantially coaxial with respect to the axis of rotation of the turbine 41. It has the rotating cleaning body 44 which has. That is, the turbine 41, the turbine shaft 42, the planetary gear mechanism 43, and the rotary cleaning body 44 are housed in the suction chamber 36 of the suction port main body 31.

The turbine 41 is an axial turbine and includes a guide blade portion 46 fixed to the case body 34 and a rotor blade portion 47 pivotably supported by the guide blade portion 46. The turbine 41, ie, the guide blade portion 46 and the rotor blade portion 47, has a diameter approximately equal to the rotation diameter of the rotary cleaning body 44 when viewed in the rotation axis C direction.

The guide blade portion 46 includes a substantially cylindrical frame body 46a in communication with the air inlet 38, and a plurality of guide blades 46b integrally formed with the frame body 46a. The guide blade 46b guides the air introduced into the guide blade portion 46 through the air inlet 38 to the rotor blade portion 47.

The rotor blade portion 47 is integral with the rotor blade frame body 47a of the substantially cylindrical shape pivotally supported by the frame body 46a of the guide blade portion 46 and the rotor blade frame body 47a. It has a plurality of rotor blades 47b formed by. The rotor blade portion 47 receives air guided by the guide blade 46b from the rotor blade 47b and rotates around the rotation axis C. As shown in FIG.

The number and shape (cross-sectional shape of the blade) of the guide blade 46b and the rotor blade 47b are configured so that the kinetic energy of the air sucked through the air inlet 38 can be appropriately converted into rotational energy.

The turbine 41 may be an axial turbine or a radial turbine. The turbine 41 which concerns on this embodiment shown in FIG. 2 is an axial turbine. In this case, the case body 34 guides air to the guide blade part 46 through the air inlet 38 formed in the left and right side walls. As another example, the turbine 41 according to the present embodiment shown in FIG. 3 is a radial turbine. In this case, the case body 34 is directed toward the rotational axis C of the turbine 41 through the air inlet 38 opened in the rear wall (or the front wall or the upper wall) near each of the left and right ends. The driving force of the turbine 41 is obtained by introducing air at substantially right angles from the outer circumferential surface of 41.

The turbine shaft 42 is provided in the rotation shaft center (rotation shaft C) of the rotor blade part 47, and transmits the rotation of the rotor blade part 47 to the planetary gear mechanism 43.

The planetary gear mechanism 43 is a speed reduction mechanism for driving the rotary cleaning body 44 by decelerating the driving force transmitted from the turbine 41 via the turbine shaft 42, and the drive shaft and the rotary cleaning body connected to the turbine 41. It has a driven shaft connected to (44). In addition, the planetary gear mechanism 43 includes a sun gear 51 having a drive shaft connected to the turbine shaft 42, and a plurality of planet gears 52 engaged with the sun gear 51 to revolve around the sun gear 51. ), The outer gear 53 which is engaged with the planetary gear 52 and fixed to the case body 34, and the revolution of the planetary gear 52 are driven, and connected to the rotary cleaning body 44 to rotate. The planetary carrier 54 which has the driven shaft which drives the cleaning body 44 is provided.

The sun gear 51 is connected to the turbine 41 via the turbine shaft 42, and rotates in accordance with the rotation of the rotor blade portion 47.

The planetary gear 52 is disposed around the sun gear 51.

The outer gear 53 has an annular body containing the sun gear 51 and the planetary gear 52, and has an inner circumferential surface that meshes with the planetary gear 52 and an outer circumferential surface fixed to the case body 34.

The planetary carrier 54 is disposed on the side surface close to the rotary cleaning body 44 of the planetary gear mechanism 43. In addition, the planetary carrier 54 holds the gear shaft 56 together with the planetary gear cover 55 disposed on the side of the planetary gear mechanism 43 close to the turbine 41 to form the planetary gear 52 and the sun. The gear 51 and the outer gear 53 are engaged with each other. The planetary gear cover 55 has a through hole 55a in which a turbine shaft 42 is inserted at the center thereof.

The rotary cleaning body 44 includes a shaft 58 that is integrally held in the rotational motion with the planet carrier 54 of the planetary gear mechanism 43, and a cleaning body implanted in a spiral shape in the axial direction of the shaft 58. (59) is provided.

The cleaning body 59 is a brush implanted in a helical shape in the axial direction of the shaft 58, and is provided to protrude in the radial direction of the shaft 58 to constitute an outer peripheral portion of the rotary cleaning body 44. The cleaning body 59 may be obtained by combining a brush and a blade, or may include only the blade.

The inlet port 26 configured as described above includes the rotor blade portion 47, the turbine shaft 42, the sun gear 51, the planetary gear 52, the planet carrier 54, and the rotary cleaning body. The 44 is pivotally supported by the guide blade portion 46 of the turbine 41 and the outer gear 53 of the planetary gear mechanism 43. The rotary cleaning body unit 33 includes a turbine 41 (more specifically, a rotor blade portion 47), a turbine shaft 42, a drive shaft serving as a rotation center of the sun gear 51, and a planetary gear ( 52, which is the orbital center of rotation (i.e., the center of rotation of the planet carrier 54) is positioned substantially in the same straight line. This straight line is located on substantially the same straight line as the rotation axis C of the rotary cleaning body 44.

The inlet port 26 according to the present embodiment includes a turbine 41, a turbine shaft 42, and a planetary gear mechanism 43 at both ends of the rotary cleaning body 44. As a result, the suction inlet body 26 can fully secure the driving force of the rotary cleaning body 44. The suction port 26 may include the turbine 41, the turbine shaft 42, and the planetary gear mechanism 43 only at one end of the ends of the rotary cleaning body 44.

It is a side view which simply shows the planetary gear mechanism of the intake port which concerns on embodiment of this invention.

As shown in FIG. 4, the planetary gear mechanism 43 of the inlet port 26 uses the turbine shaft 42 connected to the sun gear 51 as an input shaft, and is integrally formed by the planetary carrier 54. It is a reduction mechanism which uses the retained rotary cleaning body 44 (more specifically, the shaft body 58) as an output shaft. The planetary gear mechanism 43 includes the sun gear 51, the planetary gear 52, and the outer gear 53 from the inside when viewed from the rotation shaft C.

The planetary gear 52 is disposed at each vertex position of the regular polygon around the sun gear 51, and more specifically, at each vertex position of the equilateral triangle.

The planetary gear mechanism 43 rotates the sun gear 51 in one direction (solid line arrow CW1 in FIG. 4) by the driving force of the turbine 41. In addition, the planetary gear mechanism 43 moves the plurality of planetary gears 52 in the other direction (solid line arrow CCW in FIG. 4) about each gear shaft 56 with rotation of the sun gear 51. And rotates in one direction (solid line arrow CW2 in FIG. 4) about the rotation axis C. FIG. In addition, the planetary gear mechanism 43 rotates the planet carrier 54 in one direction (solid line arrow CW2 in FIG. 4) about the rotation axis C with the revolution of the planetary gear 52. At this time, the outer gear 53 maintains rotation of the sun gear 51, the planetary gear 52, and the planetary carrier 54.

At this time, the rotary cleaning body 44 rotates integrally with the planetary carrier 54 in one direction (solid line arrow CW2 in FIG. 3).

The rotation direction of the rotary cleaning body 44 may be a direction (forward direction) for generating a forward force to the inlet port 26, or may be a direction (reverse direction) for generating a retraction force to the suction port body 26. The turbine 41 appropriately forms the guide blade 46b and the rotor blade 47b in correspondence with either the forward or reverse direction of the rotary cleaning body 44.

5 is a longitudinal sectional view showing a suction port according to an embodiment of the present invention.

As shown in FIG. 5, the suction inlet body 26 (more specifically, the case body 34 of the inlet body 31) faces the rotary cleaning body 44 to rotate the rotary cleaning body 44. Has an auxiliary air inlet 60 (second air inlet) to blow air F to assist. The auxiliary air inlet 60 is a case body of the inlet body 31 in a state where it is directed to blow the flow of air F sucked into the suction chamber 36 to the cleaning body 59 of the rotary cleaning body 44. In 34).

6 is a plan sectional view showing another example of the inlet port according to the embodiment of the present invention.

In the rotary cleaning body unit 33A, the same reference numeral is given to the same configuration as the rotary cleaning body unit 33, and overlapping description is omitted.

As shown in FIG. 6, the rotary cleaning body unit 33A accommodated in the inlet port 26 includes a turbine 41A driven by air sucked through the air inlet port 38.

The turbine 41A is an axial turbine, a guide blade 61 provided on the guide blade portion 46 and a guide blade fixed on the rotational shaft of the rotor blade portion 47 and pivotally supported by the bearing portion 61. A sub support shaft 62 is provided.

The guide blade portion support shaft 62 is formed integrally with the extended turbine shaft 42. In addition, the guide blade portion support shaft 62 is configured so as not to prevent relative rotation between the guide blade portion 46 and the rotor blade portion 47, and the retaining bulge portion so as not to be separated from the bearing portion 61. (retaining swollen portion) 62a.

Next, operation | movement of the electric vacuum cleaner 1 which concerns on this embodiment is demonstrated.

The user of the electric vacuum cleaner 1 first connects the pipe part 3, that is, the dust collecting hose 21, the extension pipe 25, and the suction port 26 to the cleaner main body 2 in an appropriate order. .

Next, the user pulls out the power cord 11 from the cleaner body 2 and connects the power plug 14 to an outlet (not shown) for supplying commercial power.

Next, the user of the electric vacuum cleaner 1 grips the holding part 23 and operates the start switch 24b.

Then, the control part 9 drives the electric blower 8 according to the operation mode set by the start switch 24b. Underpressure is generated in the vacuum cleaner body 2 and the pipe part 3 by the driving of the electric blower 8, and the electric vacuum cleaner 1 is an air inlet 38 and a dust suction port 39 of the inlet body 26. Inhale air through.

Next, the user of the electric vacuum cleaner 1 arrange | positions the suction inlet body 26 on the to-be-cleaned surface, and reciprocates back and forth between the hand control pipe 22 and the extension pipe 25 in the state which hold | gripped the holding part 23. FIG. Let's do it.

Then, the suction port 26 sucks dust on the surface to be cleaned together with air (air containing dust) while reciprocating back and forth on the surface to be cleaned through the dust suction port 39. The dust containing air sucked in through the dust suction port 39 is guided to the cleaner main body 2 through the connection pipe 32.

At this time, the suction port 26 also sucks air through the air inlet 38. The air sucked in through the air inlet 38 is guided to the rotor blade portion 47 by the guide blade portion 46 of the turbines 41 and 41A, and passes while rotating the rotor blade portion 47, and suction In the chamber 36, the dust-containing air sucked through the dust suction port 39 joins to reach the connection pipe 32. Rotation of the rotor blade part 47 is input to the planetary gear mechanism 43 via the turbine shaft 42 to drive the rotary cleaning body 44. By driving the rotary cleaning body 44, the inlet port 26 cleans dust on the surface to be cleaned and polishes the surface to be cleaned. The dust cleaned by the rotary cleaning member 44 is sucked into the suction port body 26 through the dust suction port 39. At this time, the flow of air F sucked into the suction chamber 36 through the auxiliary air inlet 60 is blown to the cleaning body 59 of the rotary cleaning body 44, and assists rotation of the rotary cleaning body 44. do.

The dust-containing air sucked into the suction port 26 passes through the extension pipe 25, the hand control pipe 22, and the dust collecting hose 21 sequentially, and is then guided to the cleaner body 2.

The dust-containing air guided to the cleaner body 2 is sucked into the dust separation dust collecting unit 7 and separated into dust and air. The separated dust is collected by the dust separating dust collecting part 7. On the other hand, the separated air passes through the dust separation dust collecting unit 7 and is sucked into the electric blower 8 and is discharged from the cleaner main body 2.

As described above, the electric vacuum cleaner 1 collects dust sucked from the suction port body 26.

In the rotary cleaning body unit 33, the rotary cleaning body unit 33A, the suction inlet body 26, and the electric vacuum cleaner 1 which concern on this embodiment, the rotation diameter of the rotary cleaning body 44 is turbine 41, 41A. Drive shafts which are configured to be substantially the same as the diameter of the turbine 41, 41A (more specifically, the rotor blade portion 47), the turbine shaft 42, and the rotation center of the sun gear 51, The driven shaft which is the revolving center of the planetary gear 52 (that is, the rotating center of the planet carrier 54), and the rotating center of the rotary cleaning body 44 can be arrange | positioned substantially in the same straight line (rotation axis C), When transmitting torque from the turbines 41 and 41A to the rotary cleaning body 44, it is possible to reduce as few as possible the elements that cause mechanical loss due to friction and sliding movement. Specifically, this mechanical loss substantially depends on the mechanical loss of the planetary gear mechanism 43, and can easily reduce the loss of the entire mechanism for driving the rotary cleaning body 44.

Moreover, in the rotary cleaning body units 33 and 33A, the suction inlet 26, and the electric vacuum cleaner 1 which concern on this embodiment, the torque generate | occur | produced by the turbines 41 and 41A produces the rotary cleaning body 44. Direct drive is provided with a planetary gear mechanism 43 having a relatively large reduction ratio compared to a reducer consisting of a flat gear or a bevel gear that can be built in the same capacity (volume), even if it is insufficient, so that the coefficient of friction is as if carpet is laid. The torque which can reliably drive the rotary cleaning body 44 also can be obtained also in the high cleaning surface.

Moreover, the rotary cleaning body unit 33A which concerns on this embodiment comprises the turbine 41, the turbine shaft 42, the planetary gear mechanism 43, and the rotary cleaning body 44 as a single module, and convenience of handling. And assembling of the inlet body 26 is improved.

Therefore, according to the electric vacuum cleaner 1, the suction inlet body 26, and the rotary cleaning body units 33 and 33A which concern on this embodiment, the rotary cleaning body 44 which uses the turbine 41 and 41A as a prime mover is provided. Thus, the rotary cleaning body 44 can be driven at a high torque without lowering the suction work rate of the electric vacuum cleaner 1.

While some embodiments of the inventions have been described, these embodiments have been presented by way of example only, and are not intended to limit the scope of the inventions. Indeed, the novel apparatuses and units disclosed herein may be embodied in a variety of other forms, and various omissions, substitutions, and changes in the apparatuses and units disclosed herein may be made without departing from the spirit of the inventions. I can do it. The accompanying claims and their equivalents are intended to cover such forms or modifications as would fall within the scope and spirit of the invention.

1: electric vacuum cleaner
2: cleaner body
3: pipe part
5: body case
6: wheel
7: Dust separation dust collector
8: electric blower
9:
11: power cord
12: main body connector
14: Power plug
19: connector
21: Dust Hose
22: operator
23: holding part
24: control panel
24a: stop switch
24b: start switch
25: extension tube
26: suction port
31: inlet body
32: connector
33: rotary cleaning unit
34: case body
35: connector holder
36: suction chamber
38: air inlet
39: dust intake
41, 41A: turbine
42: turbine shaft
43: planetary gear mechanism
44: rotary cleaning body
46: guide blade portion
46a: frame
46b: guide blade
47: rotor blade part
47a: rotor blade frame
47b: rotor blade
51: sun gear
52: planetary gear
53: outer gear
54: planetary carrier
55: planetary gear cover
55a: through hole
56: gear shaft
58: shaft
59: cleaning body
60: auxiliary air inlet
61: bearing part
62: guide blade support shaft
62a: retaining bulge

Claims (12)

As a rotary cleaning body unit,
Turbine,
A planetary gear mechanism having a drive shaft connected to the turbine,
And a rotary cleaning body connected to the driven shaft of the planetary gear mechanism. The method of claim 1,
A rotary cleaning body unit, wherein the rotary shaft of the turbine, the drive shaft and the driven shaft of the planetary gear mechanism, and the rotary shaft of the rotary cleaning body are arranged substantially coaxially. The method according to claim 1 or 2,
The planetary gear mechanism,
A sun gear connected to the turbine,
A planetary gear meshing with the sun gear to revolve around the sun gear,
An outer gear meshed with the planetary gear,
And a planetary carrier connected to the rotary cleaning body and driven by the revolution of the planetary gear. 4. The method according to any one of claims 1 to 3,
The turbine and the planetary gear mechanism are provided in pairs at both ends of the rotary cleaning body. 5. The method according to any one of claims 1 to 4,
The turbine,
A rotor blade portion having a plurality of rotor blades,
And a guide blade portion having a plurality of guide blades for inducing air to the rotor blade portion. The method of claim 5,
A bearing portion provided in the guide blade portion;
And a guide blade portion support shaft fixed on the rotation shaft of the rotor blade portion and pivotally supported by the bearing portion. As the intake sphere,
An inlet body having an air inlet, a dust inlet formed on the bottom wall, and a suction chamber communicating the air inlet and the dust inlet with each other;
A connection tube tiltable with respect to the suction inlet and in communication with the suction chamber,
A rotary cleaning body unit according to any one of claims 1 to 6, housed in the suction chamber,
The rotary cleaning body is disposed in the dust inlet, the turbine is disposed in the passage from the air inlet to the connecting pipe. The method of claim 7, wherein
The outer inlet gear of the planetary gear mechanism is fixed to the inlet body. 9. The method according to claim 7 or 8,
The air inlet is disposed on the side walls on the left and right with respect to the traveling direction of the inlet body. 9. The method according to claim 7 or 8,
The air inlet is disposed in the upper wall of the inlet body, the inlet body. The method according to any one of claims 7 to 10,
The suction inlet body has a second air inlet that faces the rotary cleaning body and blows air to assist rotation of the rotary cleaning body. As an electric vacuum cleaner,
With the cleaner body,
An electric blower accommodated in the cleaner body,
An electric vacuum cleaner comprising a suction port according to any one of claims 7 to 11 in communication with the electric blower.

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