JP3501112B2 - Vacuum cleaner and its mouthpiece - Google Patents

Description

Detailed Description of the Invention

[0001]

TECHNICAL FIELD The present invention relates to a vacuum cleaner,
In particular, the present invention relates to a suction body provided with a rotary cleaning body that acts on a cleaning surface by being rotationally driven using a suction force as a drive source to enhance the cleaning effect.

[0002]

2. Description of the Related Art Japanese Patent Application Laid-Open No. 11-253371 discloses
11 to 13 show a suction body for an electric vacuum cleaner including a rotary brush (rotary cleaning body) having an impeller and a planetary speed reducer built therein. The planetary reducer has an internal gear with a tooth surface on the inner peripheral surface, a sun gear that rotates integrally with the impeller on the rotation axis of the impeller inside the internal gear, and between the sun gear and the internal gear. It is provided with three planetary gears that revolve (revolve) around the sun gear while rotating around the sun gear, and a carrier that transmits the revolving motion of the planetary gears as a rotary motion to the rotary shaft of the rotary cleaning body. The planetary speed reducer is arranged on the end side of the rotary brush with respect to the impeller, that is, on the upstream side in the direction of air flow. In this configuration, the rotary shaft of the impeller is fixed to the sun gear, the carrier that supports the planetary gear is fixed to the shaft fixed to the suction body, and the internal gear is fixed to the rotary brush shaft. Further, the air flowing in from the intake port formed in the suction body is introduced into the inside of the rotary brush, passes through the gap of the planetary speed reducer to reach the impeller, and after driving the impeller, is provided on the surface of the rotary brush. An air flow path is formed so as to be ejected from the created ventilation hole into the brush chamber.

[0003]

[Patent Document 1] Japanese Patent Application Laid-Open No. 11-2533
In the electric vacuum cleaner described in Japanese Patent No. 71, the air supplied to the impeller flows through a gap formed between the internal gear of the planetary speed reducer, the sun gear, the planetary gear and the carrier as a flow path. ing. In this configuration, the flow passage cross-sectional area is likely to be limited due to the presence of the carrier and each gear, and the flow rate and flow velocity of the air supplied to the impeller is likely to be limited. Further, since the shape of the air flow path becomes complicated, there are problems that the passage resistance increases and the flow velocity of the air is restricted, and noise is easily generated due to separation of the flow. In particular, when the nozzle is arranged on the upstream side of the impeller in order to increase the flow velocity of air, a structure in which the flow rate and the flow velocity are limited on the upstream side of the nozzle is not preferable.

An object of the present invention is to supply air to an impeller by suction force to generate a rotational torque, reduce the rotation of the impeller, and transmit the decelerated rotation to a rotary cleaning member to reduce the rotational torque generated in the impeller. The rotational torque generated in the impeller is increased in a structure in which the rotary cleaning body is driven to increase and the impeller and the speed reducer are provided inside the rotary cleaning body to reduce the size and improve the cleaning efficiency. And to increase the driving force of the rotary cleaning body.

[0005]

In order to achieve the above object, in the present invention, an impeller that is rotationally driven by sucked air is provided inside a base of a rotary cleaning body, and the rotation of the impeller is reduced. And a planetary speed reducer for transmitting to the rotary cleaning body. The planetary speed reducer has a sun gear fixed to the rotating shaft of the impeller,
An internal gear fixed to the casing side of the mouthpiece, a planetary gear that is engaged with the sun gear and the internal gear and can revolve around the sun gear while revolving around the sun gear, and supports and rotates the planetary gear. And a carrier fixed to the cleaning body side. Inside the base body that constitutes the rotary cleaning body
The member that forms the nozzle provided on the inside of the base.
The shaft of the scraped impeller is supported by the base body that constitutes the rotary cleaning body.
To configure. This simplifies the structure and reduces
A large impeller does not increase the road resistance unnecessarily.
Rotating torque can be generated.

In order to achieve the above object, the present invention
Then, inside the base of the rotary cleaning unit
The driven impeller and the rotation of this impeller are reduced by decelerating the rotation of the impeller.
And a planetary reduction gear that transmits to the sweeper. Planetary reducer
The sun gear fixed to the rotating shaft of the impeller and the case of the suction body.
The internal gear fixed to the single side, the sun gear and the internal gear
You can revolve around the sun gear while rotating around the sun gear.
And the planetary gears that are provided to support the planetary gears
Both are configured with a carrier fixed to the rotary cleaning body side
To be done. Provided inside the base body that constitutes the rotary cleaning body
The member that forms the nozzle is composed of a speed reducer and a rotary cleaning body.
As a transmission member that transmits rotational torque to the base body
To do. This simplifies the structure and eliminates the need for passage resistance.
The impeller produces a large rotational torque without increasing it.
Can be born.

[0007]

[0008]

[0009]

[0010]

[0011]

BEST MODE FOR CARRYING OUT THE INVENTION [First Embodiment] The first embodiment of the present invention will be described below.
An example of the embodiment will be described in detail with reference to the drawings.

FIG. 1 shows the appearance of the electric vacuum cleaner of this embodiment. A vacuum cleaner main body 100 having a built-in dust collecting chamber equipped with an electric blower for suction and a filter, and a hand operation unit 300 at the tip of a hose 200 connected to the dust collecting chamber of the vacuum cleaner main body 100 are connected via an extension pipe 400. The sucker body 500 is provided.
The suction body 500 includes a rotating brush that is rotationally driven by using the flow of suction air, an air turbine (hereinafter referred to as a nozzle and an impeller) incorporated in the rotating brush, and a planetary speed reducer. The rotary brush is provided in a brush chamber formed inside the suction body, and acts as a rotary cleaning body that acts on the cleaning surface by being rotationally driven to enhance the cleaning effect. The fact that the rotating brush acts on the surface to be cleaned means that the brush or blade directly contacts the surface to be cleaned or the hair such as a carpet laid on the surface to be cleaned, or the surface to be cleaned by the air flow created by the rotating brush ( This includes the effect on the surface to be cleaned).

The casing of the mouthpiece 500 is vertically divided into two parts at a position approximately at the center thereof, and is formed by a lower case 520 which forms an outer shell and an upper case 510 which is detachable from the lower case 520. ing.

In the mouthpiece 500, the universal joint 515 is fitted in the lower case 520, and the upper case 510 is fitted in the universal joint 515.
It is fixed to the lower case 520 so as to cover a part of.
A shock absorbing bumper 516 is attached to the outer periphery of the position where the upper case 510 and the lower case 520 come into contact with each other to maintain airtightness and prevent damage to furniture and the like.

FIG. 2 is a plan view of the suction body 500 with the upper case 510 removed.

The lower case 520 is provided with a suction port 521 opened on the bottom surface facing the cleaning floor surface, and rotatably accommodates a rotary brush 530 facing the suction port 521 and scraping up dust on the floor surface.

The rotating brush 530 spirally stands up a plurality of brushes 532 for scraping dust on the outer peripheral surface of the cylindrical base body 531 and one end of the cylindrical base body 531 has a bearing unit 53.
3 is fitted and supported by the bearing holding portion 522 of the lower case 520, and the other end of the tubular base body 531 is fitted and attached to the other end of the fixed shaft 541 of the planetary speed reducer 540.
The shaft holders 523 of 20 are fitted and supported. Here, the rotary brush can be configured by using not only a brush but also a soft blade-shaped one as a cleaning member (cleaning portion), and the brush and the blades can be configured individually or in a mixture of the brush and the blade. can do. In addition, the tubular substrate 53
The cleaning member (cleaning portion) may be configured by a protruding portion integrally formed with the member forming 1. In any case, the cleaning member (cleaning portion) is configured to project outward from the outer peripheral surface of the tubular base 531 (the same applies to the following embodiments).

Reference numerals 606 to 607 denote external suction ports formed of a plurality of small holes provided on the side body of the suction port main body, and the rotary brush 53.
It is an air intake for driving 0. This air intake port forms an air passage separate from the suction port 521 for guiding the air outside the suction member 500 to the air turbine.

Next, the internal structure of the rotary brush 500 will be described.

Numerals 600 to 601 are impellers that rotate by utilizing the suction force of an electric blower, 602 to 603 are nozzles for accelerating the air flowing from the outside, 540 is a planetary speed reducer, and 605 is an impeller 600 to 601. Of the nozzles 602 and 603 are held by bearings. In addition, the outer peripheral portions of the nozzles 602 and 603 and the tubular substrate 5
The inner peripheral surface of 31 is fixed, and the nozzles 602 and 603 rotate integrally with the tubular base body 531. 608-609
Is a shaft support of the cylindrical base body 531.

The arrows in the figure represent the flow of air.

In the present embodiment, as described above, since the rotating shafts of the planetary speed reducer, the nozzle and the impeller are arranged on the coaxial line in the longitudinal direction of the suction body as described above, the suction body can be made smaller and lighter. You can

At this time, since the size of the rotary brush 530 in the longitudinal direction W2 can be made larger than that in the longitudinal direction W1 of the suction body, there is an effect that the cleaning range can be widened.

Further, the planetary speed reducer 5 is installed in the rotating brush 530.
Since the nozzle 40, the nozzles 602 and 603, and the impellers 600 and 601 are built in, the rotating brush 530 can be easily attached and detached by removing the upper case 510, so that the brush chamber can be easily cleaned. is there.
In addition, assembling at the time of manufacturing is facilitated, and production efficiency is improved.

FIG. 3 shows a view in the vicinity of the planetary speed reducer 540 as seen in a section parallel to the rotation axis. In FIG. 3, 543 is a sun gear, 544 is engaged with the sun gear 543, and
A planetary gear that revolves while rotating around 43, 545 is an internal gear having a tooth surface on its inner peripheral surface, 546 is a casing that covers the reduction gear, and 541 is an internal gear that is fixed to the body casing side of the suction body. It is a fixed shaft for doing so and is integrally formed of the same member as the casing 546. 542 is a carrier that supports the planetary gear 544 and is fixed to the nozzle 603.

The inner peripheral surface of the cylindrical substrate 531 and the nozzle 603.
Is fixed by a ring 603a on the outer peripheral portion and is configured to rotate integrally with the shaft support tool 609 of the tubular base body 531.

The shaft support 609 is formed with an opening (air passage) 701 for introducing the air outside the suction body 500 into the inside. Although only the side of the shaft support 609 is shown in FIG. 3, an opening (air passage) is formed in the shaft support 608 as in the case of 609.

Next, the operation of the first embodiment of the present invention will be described. When the user of the cleaner operates a hand switch arranged near the hand operation unit 300, the electric blower in the electric vacuum cleaner body 100 is operated in an operation mode according to the operated switch. The suction force generated by the electric blower reaches the suction body 500 through the hose 200 and the extension pipe 400.

When the suction body is placed on the carpet, the suction port 521 is blocked by the carpet, so that most of the air is taken in by the suction ports 606, 60 on the side body of the suction body 500.
7, the air is sucked, flows through the air passage 702 formed in the outer peripheral portion of the casing 546, and further the nozzle 602,
Impellers 600, 60 after being collected and accelerated in 603
1, impellers 600 and 601 are rotated, and torque is generated.

The torque generated by the impellers 600 and 601 drives the sun gear 543 by the rotating shaft 605,
The rotation is transmitted to the planetary gear 544, and the planetary gear 544 rotates on the internal gear 545 on the outer periphery thereof. The internal gear 545 is a casing 546 that covers the entire planetary speed reducer 540.
Since the carrier 542 is fixed to the rotating shaft 60,
The rotation torque is transmitted to the nozzle 603, and rotates together with the tubular base body 531. Therefore, the nozzles 602 and 603 also rotate.

At this time, for example, if the number of teeth of the sun gear is 10,
When the number of teeth of the planetary gear is 20 and the number of teeth of the internal gear is 50, the reduction ratio becomes 1/6, and assuming that there is no loss in the planetary reducer, the drive torque of the rotating brush becomes 6 times. .

As described above, according to this embodiment, the torque generated by the impeller can be increased and the drive torque of the rotary brush can be increased.

Therefore, the dust on the carpet can be more strongly scraped up, so that the dust collecting performance is improved.

On the other hand, the air that has passed through the impellers 600 and 601 is discharged from a plurality of ventilation holes 535 provided in the cylindrical base body 531 of the rotating brush 530, as shown in FIG. The discharged air collides with the inner wall of the suction body and the cleaning surface while rotating, and blows out dust. At the same time, since suction is performed from the suction joint, a flow having a swirling component moves in the axial direction, so that it is possible to assist the transfer of dust.

Therefore, the dust on the carpet is scraped up by the brush 532 from the opening on the floor surface, efficiently carried by the exhaust airflow from the plurality of ventilation holes 535, and sucked into the cleaner body through the suction joint 515. To be done.

Here, the reason why two sets of the impeller and the nozzle are used in the suction port will be explained. The torque generated by the impeller is
It is almost determined by the amount of air flowing into the impeller and the pressure difference before and after the impeller. This pressure difference is considered to be almost the same as the difference between the atmospheric pressure and the pressure generated in the suction port. If this pressure difference is large, the torque will be large, but the suction port will stick to the cleaning surface, making it difficult to operate. If the pressure difference is too small, the torque will be small and dust cannot be sucked. Therefore, the suction port is required to have a sufficient torque that is easy to operate, maintains an appropriate suction force, and scrapes dust.

For example, when the pressure difference is 1000 Pa and the impeller and nozzle are one set, the air volume is 0.5 m ^3.
When a torque of 0.5 N · cm is generated at a speed of 1 / min, when two sets of impellers and nozzles are used, the same pressure difference is 1000 Pa and the air volume is doubled to 1.0 m ³ / min.
Therefore, the torque is doubled to generate 1 N · cm.

In order to increase the torque with one set of impeller and nozzle, there is a means to increase the outer diameter of the impeller or to increase the amount of air flowing into the impeller, but in the former case, the entire suction port becomes large. However, the latter has a problem that the suction port is adsorbed to the cleaning surface because the pressure in the suction port increases as described above.

As described above, according to the present embodiment, since two sets of the impeller and the nozzle are used in the rotating brush and the planetary speed reducer is provided, it is possible to provide a small and lightweight suction port with a large torque. Further, there is an effect that a function such as wiping or polishing on the flooring can be added, which cannot be realized by the conventional method due to insufficient torque.

Further, in this embodiment, the rotation speed of the rotary brush required for dust removal is 1500 r / min, and the rotation speed of the impeller is set to 9000 r / min, which is 6 times.
Although the rotation speed of the impeller becomes high and noise is likely to occur, since the impeller is inside the rotary brush inside the suction body, it has a structure like a double cylinder that covers the impeller. Sound is less likely to be emitted to the user or the vicinity thereof, and noise generation can be suppressed.

Further, by making the upstream side of the member 541 fixed to the casing 546 and having the fixed shaft rounded, the air flowing in from the intake port can be made to flow through the reducer 54.
The loss due to bending or peeling that occurs around 0 can be reduced. Therefore, the air flowing into the nozzle 603 can be guided to the impeller 601 without obstructing the air, so that the torque can be increased.

As described above, since the impeller and the nozzle are coaxial and the outer circumference can be formed in the same cylinder, the outer diameters of the impeller and the nozzle can be effectively used to the full cylinder diameter. In addition, the air that flows in from the side is rectified in the axial direction, accelerated by the action of the nozzle, then flows into the impeller, changes the direction at almost the same speed in the impeller, and generates torque in the impeller. Since all the airflows move efficiently in the axial direction, it is possible to provide a suction port that is small and lightweight and has a quiet sound, and an electric vacuum cleaner using the suction port.

Further, as shown in FIG.
Since the position of the impeller can be moved to the intake port 607 side by incorporating the planetary speed reducer 540 inside the
The ventilation holes 535 provided in the cylindrical base 531 of the rotating brush 530 can be increased in the longitudinal direction. As a result, the ejection point from the ventilation hole 535 extends in the longitudinal direction, so that the distance over which the air flow having a swirling component moves in the axial direction with respect to the cleaning surface becomes long, further improving the dust collecting performance.

Further, since no electric parts are used in the suction body, the planetary speed reducer and the bearing parts are made of a material having water resistance (for example, gears and bearings made of polyacetal resin, shafts and carriers made of stainless steel). If configured, there is also an effect that the entire mouthpiece can be washed with water.

Since there is almost no sinking of the wheels on the flooring or tatami mat, a gap is created between the floor surface opening and the floor surface, the amount of air sucked from the floor surface opening increases, and flows through the impeller. Since the amount of air decreases, the rotation of the impeller is suppressed. Further, when the suction port 500 is lifted, the amount of air passing through the impeller becomes very small, the impeller and the rotating brush hardly rotate, and it is necessary to provide a special mechanism for stopping the rotation of the rotating brush at the time of lifting. There is no.

Further, when cleaning a corner of a room, even if one of the intake ports on the front and side of the suction port is blocked, air may flow from the intake port on the opposite side, and the rotating brush may stop. Absent. Rather, since the amount of air flowing into the intake port on one side increases, the torque generated by the impeller on one side increases, so that dust can be more scratched up.

The casing 546 has a cylindrical base 531 with respect to the sun gear 543, the planetary gear 544 and the internal gear 545.
Since it has a structure that covers the opening side of
The structure is such that noise generated at 0 does not easily leak to the outside.

Since the casing 546 has a structure covering the upstream side of the sun gear 543, the planetary gear 544 and the internal gear 545, it is possible to prevent dust mixed in the sucked air from adhering to each gear. Since the air supplied to the impeller is sucked through the external intake ports 606 and 607, the suction port 521 is used.
Although much less dust is contained in the air sucked from the external suction ports 606 and 607, which are located closer to the surface to be cleaned, the dust may be sucked. Therefore, it is preferable to give such consideration.

As described above, the casing 546 has a role of preventing dust from adhering to each gear and a role of forming a smooth air passage for guiding air to the nozzle 603 and the impeller 601 with less peeling. There is.

The carrier 542 is fixed to the nozzle 603, and the outer peripheral portion of the nozzle 603 is fixed to the cylindrical base body 531 of the rotating brush 530. Therefore, the impeller 60
The rotational torque generated at 0 and 601 is transmitted to the rotating brush 530 through the nozzle 603.

The rotating shafts 605 of the impellers 600 and 601 are supported by the nozzles 602 and 603 on the cylindrical base body 531 of the rotating brush 530. That is, the bearing that supports the rotating shaft 605 is built in the nozzle member that forms the nozzles 602 and 603.

As described above, the blades of the nozzles 602 and 603 have a role as a supporting member that pivotally supports the impellers 600 and 601 and a role as a transmitting member that transmits the rotational torque to the rotating brush 530.

Due to the structure in which the carrier 542 is fixed to the cylindrical base body 531 of the rotary brush 530, an air passage can be formed between the internal gear 545 of the planetary speed reducer 540 and the inner surface of the cylindrical base body 531 and the nozzle 603 can be formed. Since the rotational torque is transmitted to the inner surface of the cylindrical base body 531 by using the blade, the rotational torque can be satisfactorily transmitted to the rotating brush 530 with a simple structure and at low cost. Further, by using the blade of the nozzle 603, the impellers 600, 60
Since the first rotating shaft 605 is supported on the inner surface of the cylindrical base body 531, a simple and low-cost structure can be obtained. By simplifying these structures, the passage resistance is not increased more than necessary, and the rotation torque is easily improved.

(Second Embodiment) In the second embodiment, a suction brush having an air turbine and a speed reduction mechanism is formed in a rotating brush of a suction port of an electric vacuum cleaner, and two suction brushes are provided on both sides of the speed reduction mechanism. It is an electric vacuum cleaner in which the above-mentioned air turbine (hereinafter referred to as a nozzle and an impeller) is arranged. The vacuum cleaner body, the hose, the hand operation part, and the extension pipe are common to those of the electric vacuum cleaner according to the first embodiment described above, and a description thereof will be omitted.

FIG. 6 is a plan view of the suction body 500 with the upper case 510 removed. The same components as those in the first embodiment are designated by the same reference numerals, and duplicate description will be omitted.

In the cylindrical base 531 of the rotating brush 530,
The planetary speed reducer 540, the nozzle 561, and the second cylindrical base 560 containing the impeller 562 are arranged to form a double cylindrical structure.

A planetary speed reducer 540 is provided at one end of the second cylindrical base 560 and is fixed to the cylindrical base 531 of the rotary brush 530 via a carrier 542. A nozzle 561 and an impeller 562 are provided on the other end side of the nozzle 561.
It is fixed to the outer circumference. In addition, the second on-cylinder substrate 560
The outer circumference of the end of the rotary brush 530 and the end of the rotary brush 530 can rotate the rotary brush 530 via a bearing 563.

A plurality of ventilation holes 563 are provided in the second cylindrical base 560 between the planetary speed reducer 540 and the impeller 562. Considering the position of the ventilation hole 563 in the circumferential direction with the ventilation hole 535 of the rotating brush 530, a ventilation area of a certain level or more can always be secured,
For example, it is necessary to change the circumferential pitch or shift the position in the axial direction.

As described above, by forming the rotating brush into the double cylinder structure, the nozzle 60 according to the first embodiment can be obtained.
The planetary speed reducer 540 located on the upstream side of the No. 3 rotary brush 53
It can be installed at the center of 0, and two air turbines can be arranged on both sides of the planetary speed reducer 540.

Here, since the outer diameters of the nozzle 561 and the impeller 562 arranged on the second cylindrical base 560 are double cylinders, the nozzle 602 and the impeller 600 shown on the left side of the drawing of FIG. Smaller than outer diameter. However, since a large inflow area from the intake port 609 that flows into the nozzle can be obtained, the amount of air flowing into the impeller 562 increases, so that the torque can be improved and the dust collection performance can be improved.

In addition, the planetary speed reducer 540 has a rotating brush 53.
Since it is installed at the center of 0, it is possible to arrange the nozzles and impellers on both sides on the left and right end sides of the rotating brush 530, and thus the planetary speed reducer 540, the impeller 600, and the impeller 562 are long. The distance in the direction becomes longer.

Therefore, since the number and area of the ventilation holes 535 and 563 can be increased, the ejection point extends in the longitudinal direction, so that the distance in which the air flow having the swirling component with respect to the cleaning surface moves in the axial direction also becomes long. Further, there is an effect that the dust collecting performance is further improved.

By installing the planetary speed reducer 540 in the center of the rotating brush 530, the planetary speed reducer 540 is installed in the nozzle 56.
1, 602 and the impellers 562, 600 can be arranged on the downstream side, and the planetary speed reducer 540 includes an air flow path formed on the nozzle 561 and the impeller 562 sides in the rotating brush 530 and a nozzle 602. Also, since the air passages are located at the respective downstream end portions of the air flow passages formed on the impeller 600 side, the structure is such that the flow rate and flow velocity of the flowing air are not easily limited or affected. In addition, noise generated due to separation of the air flow at the planetary speed reducer 540 can be reduced.

The rotating shafts 605 of the impellers 600 and 562 are rotated by the nozzles 602 and 561, respectively.
The cylindrical base body 531 and the second cylindrical base body 560 are pivotally supported. The blades of the nozzles 602 and 561 are impellers 60.
It also plays a role as a support member that axially supports 0 and 562. That is, the bearing that supports the rotating shaft 605 is the nozzle 6
No. 02, 561 is incorporated in the nozzle member.

Further, since the carrier 542 is fixed to the inner surface of the cylindrical base body 531, the rotating torque can be satisfactorily transmitted to the rotating brush 530 with a simpler structure and at lower cost. Further, by using the blades of the nozzles 602 and 561 to support the rotary shaft 605 of the impellers 600 and 562 on the inner surface of the cylindrical base body 531, a simple and low-cost structure can be obtained. By simplifying these structures, the passage resistance is not increased more than necessary, and the rotation torque is easily improved.

(Third Embodiment) In the third embodiment, a rotary brush having a suction port in an electric vacuum cleaner is provided with a suction port having a built-in air turbine and a speed reducing mechanism. This is an electric vacuum cleaner in which the air turbine is arranged and the reduction mechanism is fixed at the center of the suction port. The vacuum cleaner body, the hose, the hand operation part, and the extension pipe are common to those of the electric vacuum cleaner according to the first embodiment described above, and a description thereof will be omitted.

FIG. 7 is a plan view of the suction body 500 with the upper case 510 removed. The same components as those in the first embodiment are designated by the same reference numerals, and duplicate description will be omitted.

A column 590 for fixing the planetary speed reducer 540 is projected from the upper case 510 at the center of the suction port.
It supports the outer periphery of the reducer casing 546. Rotating brushes 570 and 5 on the left and right with the planetary reducer 540 as a boundary.
71 are formed separately, and as a matter of course, a plurality of brushes 532 for scraping dust on the outer peripheral surface are attached in a spiral shape.

This support 590 and rotating brushes 570 and 57
The rotating brush is axially supported by the bearings 591 and 592 at the end of No. 1.

An impeller 600 which is rotated by a suction force is provided on the cylindrical base 572 of the rotary brush 570 shown on the left side of the drawing.
And a nozzle 602 for accelerating the air flowing from the outside
Is built in.

Reference numeral 581 denotes a rotating shaft of the impeller 600, which is held by a bearing inside a connecting ring 574 for connecting the nozzle 602 and the planetary speed reducer 540. Further, the nozzle 602, the outer peripheral portion of the connection ring 574, and the tubular base 57.
The inner peripheral surface of 2 is fixed and rotates integrally.

Similarly, the rotary brush 57 shown on the right side of the drawing.
The impeller 601 and the nozzle 603 are provided on the cylindrical base body 573 of No. 1.
And the rotary shaft 582 of the impeller 600 has a nozzle 6
Connection ring 57 for connecting to 03 and the planetary speed reducer 540
5, the nozzle 603, the outer peripheral portion of the connecting ring 575, and the inner peripheral surface of the tubular base body 573 are fixed and are rotated integrally.

A rotary shaft 583 connecting the left and right rotary shafts 581 and 582 allows both to rotate integrally. A sun gear is attached to the rotary shaft 583, and the reduced rotational force is transmitted through the planetary gear.

Further, in the left and right cylindrical bases 572 and 573, the ventilation hole 5 is provided between the impeller 600 and the connection ring 574.
A plurality of vent holes 577 are provided between the impeller 601 and the connection ring 575.

As described above, by dividing the rotary brush into two parts, the planetary speed reducer 540 located upstream of the nozzle 603 in the first embodiment can be installed in the center of the rotary brush 530. The planetary reducer 540
The air turbines can be arranged on both sides of. Furthermore, the outer diameters of the nozzle and the impeller that are different on the left and right in the second embodiment can be made the same.

Therefore, the balance of the flow rates flowing in from the left and right in the longitudinal direction of the suction port is made uniform, and the impeller and the nozzle can be configured in the same cylinder with the same outer circumference on the coaxial line. Since the cylinder can be effectively used to its full extent, the amount of air flowing into the impeller is increased, the torque is improved, and the dust collection performance is improved.

Further, the air that has flowed in from the side is rectified in the axial direction, accelerated by the action of the nozzle, then flows into the impeller, changes its direction at almost the same speed in the impeller, and generates torque in the impeller. As a result, all the airflows move efficiently in the axial direction, so that it is possible to provide a suction port that is small and lightweight and that produces a quiet sound, and an electric vacuum cleaner using the suction port.

By installing the planetary speed reducer 540 in the center of the rotating brush 530, the planetary speed reducer 540 is installed in the nozzle 60.
3, 602 and the impellers 601 and 600, and the planetary speed reducer 540 includes an air flow path formed on the nozzle 603 and the impeller 601 inside the rotary brush 530 and a nozzle 602. Also, since the air passages are located at the respective downstream end portions of the air flow passages formed on the impeller 600 side, the structure is such that the flow rate and flow velocity of the flowing air are not easily limited or affected. In addition, noise generated due to separation of the air flow at the planetary speed reducer 540 can be reduced.

The rotating shaft 581 of the impeller 600 is the nozzle 60.
2 is pivotally supported by the tubular base body 572 of the rotary brush 570, and the rotary shaft 582 of the impeller 601 is pivotally supported by the nozzle 603 on the tubular base body 573 of the rotary brush 571. The blades of the nozzles 602 and 603 play a role as support members that axially support the impellers 600 and 601 respectively. That is, the bearings that support the rotary shafts 581 and 582 are built in the nozzle members that form the nozzles 602 and 603, respectively. As a result, a simple and low-cost structure can be obtained, the passage resistance is not increased more than necessary due to the simplification of the structure, and the rotation torque can be easily improved.

Further, since the left and right positions of the impeller and the like and the outer diameter are symmetrical, the balance is improved when the suction body is operated (for example, in the lifted state), and the usability is improved.

Further, when the suction port is lifted, the rotation of the impeller is automatically weakened or stopped, so that no noise is generated due to the high speed rotation of the rotary brush, and a special operation for stopping the rotation of the rotary brush at the time of lifting is performed. It is not necessary to install a special mechanism.

As described above, in the first, second and third embodiments, since the nozzles are arranged in the rotation axis direction of the rotary brush, the nozzles are arranged in the direction perpendicular to the rotation axis. Compared with this, the structure is such that sound is less likely to be emitted to the user or the vicinity thereof. In addition, by arranging the planetary speed reducer on the downstream side with respect to the nozzle and the impeller and forming an air flow path around the planetary speed reducer, it becomes a structure that does not easily obstruct the flow of air supplied to the impeller. ing. Further, by providing the impeller and the speed reducer inside the rotary brush, the dimension in the longitudinal direction W2 of the rotary brush can be made larger than that in the longitudinal direction W1 of the suction body, so that the range that can be cleaned by the rotary cleaning body is widened and the cleaning efficiency is improved. And the dimension of the suction body in the longitudinal direction with respect to the longitudinal direction of the rotating brush can be reduced. Note that the configuration in which the impeller and the speed reducer are provided inside the rotary brush is such that, in the axial direction of the rotary brush, the brush and / or the blade provided on the rotary brush is located closer to the center side than the both ends of the range, and A configuration in which an impeller and a speed reducer are provided inside (on the rotation center side) of a brush and / or a blade provided on a rotating brush in the radial direction of the brush. Further, by providing one speed reducer for two impellers, it is possible to reduce mechanical loss such as friction loss occurring in the gear portion of the speed reducer.

[0083]

According to the present invention, the rotation generated by the impeller is generated by supplying air to the impeller by suction force to generate a rotation torque, decelerating the rotation of the impeller and transmitting it to the rotary cleaning body. In the structure in which the rotary cleaning body is driven by increasing the torque and the impeller and the speed reducer are provided inside the rotary cleaning body to reduce the size and improve the cleaning efficiency, the flow of the air supplied to the impeller Since it has a structure that is difficult to inhibit,
A large rotating torque can be generated by the impeller, and the rotary cleaning body can be rotated with a large driving force.

[Brief description of drawings]

FIG. 1 is an external view of a vacuum cleaner according to the present invention.

FIG. 2 is a plan view of the mouthpiece according to the first embodiment of the present invention.

3 is a cross-sectional view of the suction body of FIG. 2 near the planetary deceleration.

FIG. 4 is a vertical cross-sectional view of the center of the flow path of the suction body of FIG.

FIG. 5 is a cross-sectional view around another planetary deceleration of the suction body according to the present invention.

FIG. 6 is a plan view of the mouthpiece according to the second embodiment of the present invention.

FIG. 7 is a plan view of a mouthpiece according to a third embodiment of the present invention.

[Explanation of symbols]

500 ... Suction body, 520 ... Lower case, 510 ... Upper case, 530 ... Rotating brush, 531 ... Cylindrical base, 540 ...
Planetary reducer, 600, 601 ... Impeller, 602, 603
... Nozzle, 515 ... Suction joint, 535 ... Vent hole, 60
6, 607 ... Intake port, 541 ... Fixed shaft.

─────────────────────────────────────────────────── ─── Continuation of the front page (72) Inventor Shigehiko Suzuki 1-1-1, Higashitaga-cho, Hitachi-shi, Ibaraki Hitachi Taga Electronics Co., Ltd. (72) Inventor Kenichi Tomita 1-1-1, Higashitaga-cho, Hitachi-shi, Ibaraki No. 1 In Hitachi Taga Electronics Co., Ltd. (72) Inventor Susumu Sato 1-1-1 Higashi Taga-cho, Hitachi City, Ibaraki Hitachi Taga Electronics Co., Ltd. (56) Reference JP-A-11-253371 (JP, A) Kaihei 11-99105 (JP, A) JP 2000-245662 (JP, A) (58) Fields investigated (Int. Cl. ⁷ , DB name) A47L 9/04

Claims (4)

(57) [Claims] 1. An electric blower for generating a suction force, a suction body having a suction port facing a surface to be cleaned, and a suction port of the electric blower formed inside the suction port communicating with the suction port. An air passage, a dust collecting portion which is provided in the middle of the air passage and accommodates dust sucked through the suction port, and a cylindrical base body and an outer peripheral surface of the base body which are provided inside the suction body. A rotary cleaning body having a cleaning member provided so as to project, and a first intake passage for sucking air from the outside of the suction body to the inside of the suction body through the suction port, separately from the outside of the suction body. An opening formed in the casing of the suction body so as to constitute a second intake passage for sucking air into the nozzle; a nozzle provided inside the base body to increase the flow velocity of the air sucked from the opening; Provided inside the base An impeller rotationally driven by air from the nozzle; and a speed reducer provided inside the base so as to reduce the speed of the impeller and transmit the rotation to the rotary cleaning body. An electric vacuum cleaner in which a shaft of a vehicle is supported on the base by a member forming the nozzle. 2. A rotation having a casing having a suction port facing a surface to be cleaned, a cylindrical base provided inside the casing, and a cleaning member provided so as to project from an outer peripheral surface of the base. In addition to the cleaning body and the first intake passage for sucking air from the outside of the casing through the suction port to the inside of the casing, a second intake passage for sucking air from the outside of the casing to the inside is formed. An opening formed in the casing, a nozzle provided inside the base body to increase a flow rate of air sucked from the opening, and an impeller provided inside the base body and rotationally driven by air from the nozzle. And a speed reducer provided inside the base body so as to reduce the rotation of the impeller and transmit the rotation to the rotary cleaning body. The shaft of the impeller forms the nozzle. A suction body for an electric vacuum cleaner, which is supported by the base member by a member. 3. An electric blower for generating a suction force, a suction body having a suction port facing a surface to be cleaned, a suction body formed between the inside of the suction body communicating with the suction port and the suction side of the electric blower. An air passage, a dust collecting portion which is provided in the middle of the air passage and accommodates dust sucked through the suction port, and a cylindrical base body and an outer peripheral surface of the base body which are provided inside the suction body. A rotary cleaning body having a cleaning member provided so as to project, and a first intake passage for sucking air from the outside of the suction body to the inside of the suction body through the suction port, separately from the outside of the suction body. An opening formed in the casing of the suction body so as to constitute a second intake passage for sucking air into the nozzle; a nozzle provided inside the base body to increase the flow velocity of the air sucked from the opening; Provided inside the base An impeller rotationally driven by air from the nozzle; and a speed reducer provided inside the base so as to decelerate the rotation of the impeller and transmit the rotation to the rotary cleaning body. An electric vacuum cleaner in which a member that forms a member is a transmission member that transmits a rotational torque from the speed reducer to the base body. 4. A rotary having a casing having a suction port facing a surface to be cleaned, a cylindrical base member provided inside the casing, and a cleaning member provided so as to project from an outer peripheral surface of the base member. In addition to the cleaning body and the first intake passage for sucking air from the outside of the casing through the suction port to the inside of the casing, a second intake passage for sucking air from the outside of the casing to the inside is formed. An opening formed in the casing, a nozzle provided inside the base body to increase a flow rate of air sucked from the opening, and an impeller provided inside the base body and rotationally driven by air from the nozzle. And a speed reducer provided inside the base so as to reduce the speed of rotation of the impeller and transmit the speed to the rotary cleaning body. The member forming the nozzle is the speed reducer. Vacuum cleaner as a transmission member for transmitting rotational torque from the base body to the base body.