JP6195649B2 - Self-propelled vacuum cleaner - Google Patents

Description

  The present invention relates to a self-propelled cleaner.

A conventional self-propelled cleaner includes a dust suction port and a rotating brush provided at the dust suction port near the center of the bottom surface of the circular main body, and a side brush near the bottom outer periphery of the main body. By rotating the side brush substantially horizontally and dusting outside the outer periphery of the main body into the center side of the main body, dust near the wall surface is sucked (for example, see Patent Document 1).
In addition, another conventional self-propelled cleaner has a rectangular shape in front of the main body, and includes a rotating brush provided in the dust suction port and the dust suction port in the vicinity of the front end of the bottom surface of the main body. The rotation axis of the rotating brush and the rotation axis of the drive wheel are parallel, and the main body is moved so that the right side surface or the left side surface in front of the main body is along the wall surface. Reference 2).
In addition, another conventional self-propelled cleaner has a configuration in which a suction nozzle having a right-angled tip is accommodated in the front left of the bottom of the circular main body. By moving the main body so that the side surface of the suction nozzle protruding from the outer periphery of the main body is along the wall surface, dust near the wall surface is sucked (see, for example, Patent Document 3).

Japanese Patent No. 4838978 (paragraphs [0029]-[0033]) Japanese Translation of PCT International Publication No. 2010-526594 (paragraphs [0046]-[0053]) Japanese Patent No. 4190318 (paragraphs [0033]-[0036])

  The conventional self-propelled cleaner has a problem that the side brush does not reach a narrow space such as a corner of the floor surface, resulting in cleaning leakage. Also, in the conventional self-propelled cleaner, the direction of the rotating brush and suction nozzle relative to the moving direction of the main body is constant, and the main body moving direction is changed when cleaning a narrow space such as a corner of the floor surface. Since it is necessary to repeat moving forward and backward, there was a problem that cleaning efficiency was poor.

  The present invention has been made in order to solve the above-described problems, and provides a self-propelled cleaner with less floor leakage. The present invention also provides a self-propelled cleaner with excellent cleaning efficiency.

A self-propelled cleaner according to the present invention has a plurality of drive wheels that roll on a floor surface, a main body provided with a dust suction port on a bottom surface, and the dust suction port inside the main body. A blower and a dust collecting part for sucking air on the floor surface, and an electric circuit board having a control circuit for controlling the drive wheel and the blower, and the outer shell shape of the main body is continuous from one top part The dust suction port is formed in an elongated shape in the direction along the two planar side surfaces on the bottom surface of the main body, and the main body includes A vertical rotating brush that is driven to rotate about an axis that is horizontal with respect to the floor surface and that is arranged along the longitudinal direction of the dust suction port, and that rotates on the floor surface; rotation center portion, Ri vicinity near the dust suction port, The outer shell shape of the main body has the drive wheel, has a central part that can be moved and rotated by rolling of the drive wheel, the dust suction port, and the central part around the central part. An outer shell portion that is rotatably held, the outer shell portion has a planar side surface, and the dust suction port has a longitudinal direction parallel to or perpendicular to the planar side surface. The outer shell portion has two planar side surfaces so as to cross each other, and a first dust suction port is formed so that the longitudinal direction is parallel to one of the two planar side surfaces. A second dust suction port is formed so that the longitudinal direction is parallel to the other of the two planar side surfaces, and the outer shell portion is formed of the first dust suction port and the second dust suction port. A third dust suction port in between, and the third dust suction port has the same longitudinal angle as the two planar side surfaces. In those which are formed to cross.

  The present invention includes a control unit that controls the dust suction port angle changing unit so that the angle of the dust suction port in the longitudinal direction with respect to the rolling direction of the drive wheel is optimized. It becomes possible to reach the dust suction port at a location that could not be reached, and to reduce cleaning leakage. In addition, the present invention includes a control unit that controls the dust suction port angle changing unit so that the angle of the dust suction port in the longitudinal direction with respect to the rolling direction of the drive wheel is optimized, thereby providing a conventional self-propelled cleaning device. Like a machine, it is not necessary to repeat the change of the moving direction of the main body and the forward and backward movement, and the cleaning efficiency can be improved.

It is a bottom view of the self-propelled cleaner concerning Embodiment 1 of the present invention. It is a top view of the self-propelled cleaner concerning Embodiment 1 of the present invention. It is a left view of the self-propelled cleaner concerning Embodiment 1 of the present invention. It is sectional drawing in the Ba-Bb line | wire described in FIG. 1 of the self-propelled cleaner concerning Embodiment 1 of this invention. It is a top view including a partial cross section in the state which removed the dust collecting part cover etc. of the self-propelled cleaner concerning Embodiment 1 of the present invention. It is a top view including a partial cross section in the state which removed the dust collecting part of the self-propelled cleaner concerning Embodiment 1 of the present invention. It is sectional drawing in the Ba-Bb line | wire described in FIG. 1 in the state which removed the dust collection part, the universal connection part, etc. of the self-propelled cleaner concerning Embodiment 1 of this invention. It is sectional drawing in the Da-Db line described in FIG. 1 of the self-propelled cleaner concerning Embodiment 1 of the present invention. FIG. 6 is a plan view including a partial cross-section of the self-propelled cleaner according to Embodiment 1 of the present invention with a dust collector cover and the like removed, from which the outer shell portion is a central portion from the state shown in FIG. 5. It is a figure which shows the state rotated 45 degrees counterclockwise with respect to. FIG. 6 is a plan view including a partial cross-section of the self-propelled cleaner according to Embodiment 1 of the present invention with a dust collector cover and the like removed, from which the outer shell portion is a central portion from the state shown in FIG. 5. It is a figure which shows the state which rotated 45 degrees clockwise with respect to FIG. It is sectional drawing in the Ea-Eb line | wire described in FIG. 1 in the state which is contacting or adjoining the wall surface of the self-propelled cleaner which concerns on Embodiment 1 of this invention. It is sectional drawing in the Ba-Bb line | wire described in FIG. 1 in the state which moves on the carpet of the self-propelled cleaner which concerns on Embodiment 1 of this invention. It is a figure which shows operation | movement of the self-propelled cleaner which concerns on Embodiment 1 of this invention. It is a figure which shows operation | movement of the self-propelled cleaner which concerns on Embodiment 1 of this invention. It is a figure which shows operation | movement of the self-propelled cleaner which concerns on Embodiment 1 of this invention. It is a figure which shows operation | movement of the self-propelled cleaner which concerns on Embodiment 1 of this invention. It is a figure which shows operation | movement of the self-propelled cleaner which concerns on Embodiment 1 of this invention. It is a figure which shows operation | movement of the self-propelled cleaner which concerns on Embodiment 1 of this invention. It is a figure which shows operation | movement of the self-propelled cleaner which concerns on Embodiment 1 of this invention. It is a figure which shows operation | movement of the self-propelled cleaner which concerns on Embodiment 1 of this invention. It is a figure which shows operation | movement of the self-propelled cleaner which concerns on Embodiment 1 of this invention. It is a figure which shows operation | movement of the self-propelled cleaner which concerns on Embodiment 1 of this invention.

Hereinafter, the self-propelled cleaner of the present invention will be described with reference to the drawings.
In addition, in each figure, the same code | symbol is attached | subjected to the same member and the same part. In addition, the illustration of the fine structures such as bearings and support members is omitted as appropriate. In addition, overlapping descriptions are simplified or omitted as appropriate.

Embodiment 1 FIG.
The schematic structure of the self-propelled cleaner according to the first embodiment will be described below.
(Outline structure)
FIG. 1 is a diagram illustrating a bottom view of the self-propelled cleaner according to the first embodiment.
As shown in FIG. 1, the self-propelled cleaner according to the first embodiment has a main body 1 having an outer shape surrounded by an arc having a center angle A of 270 ° and two tangent lines extending from both ends of the arc. The main body 1 has a central portion 2 and an outer shell portion 3 that are divided by a circle concentric with the arc. The outer shell portion 3 has a right angle portion 4 and an arc portion 5. The outer shell 3 is rotatable around the central portion 2 within a total range of 90 °, 45 ° clockwise and 45 ° counterclockwise from the state shown in FIG. The right angle portion 4 is supported by the outer shell portion 3 so as to be movable up and down.

  A pair of drive wheels 6 a and 6 b are provided inside the central portion 2. The drive wheels 6a and 6b protrude from the drive wheel openings 7a and 7b provided symmetrically on the bottom surface of the central portion 2 with the center line Ba-Bb interposed therebetween so that the lower surfaces are in contact with the floor surface. The drive wheels 6a and 6b are independently driven by drive wheel motors 8a and 8b, which will be described later, and the rotational force of the drive wheel motors 8a and 8b is transmitted through gear portions 9a and 9b connecting a plurality of gears. The central portion 2 is provided with a follower wheel 10 that can change its direction in the middle rear of the drive wheels 6 a and 6 b, and the main body 1 is supported by the drive wheels 6 a and 6 b and the follower wheel 10.

  The right angle portion 4 has a right suction port 11a and a left suction port 11b in front of the bottom surface, and sucks dust by a negative pressure generated by a blower 34 described later. The right suction port 11a and the left suction port 11b are arranged in parallel to the two sides of the right-angled portion 4, respectively. That is, the right suction port 11a and the left suction port 11b are disposed at an angle of 90 °. Rotating brushes 12a and 12b are provided at the right suction port 11a and the left suction port 11b, respectively. The rotary brushes 12a and 12b are constituted by rotary brush shafts 13a and 13b that are rotatably supported by bearings 14 and bristle brushes 15 planted on the rotary brush shafts 13a and 13b. The rotary brushes 12a and 12b are driven by a rotary brush motor 50 described later. The bristle brush 15 forms a plurality of rows and is implanted in a spiral shape. The length of the bristle brush 15 is set to a length that protrudes from the outer periphery of the right-angled portion 4.

  Each of the right suction port 11a and the left suction port 11b is provided with dust receivers 16a and 16b made of a sheet-like elastic member, a bristle brush row, or a cloth on the center side of the main body. The length of the dust receivers 16a and 16b in the vertical direction is set to a length at which the tip contacts the floor surface. The dust receivers 16a and 16b prevent dust removed from the floor surface by the rotating brushes 12a and 12b from passing behind the right suction port 11a and the left suction port 11b, and are sucked by the right suction port 11a and the left suction port 11b. Guide you to be.

  A tip brush 17 that rotates horizontally is provided at the tip of the right-angled portion 4. The tip brush 17 includes a tip brush shaft 18 and three bristle brushes 19 having different lengths planted at the lower end of the tip brush shaft 18. The bristle brush 19 is flocked obliquely downward at the lower end of the tip brush shaft 18 and spreads and rotates in the horizontal direction when contacting the floor surface. The bristle brush 19 that spreads in the horizontal direction in contact with the floor surface protrudes from the outer periphery of the right-angled portion 4 and scrapes off dust on the outside of the main body 1. Moreover, since the bristle brush 19 is comprised by several length, it is possible to clean the floor surface which contacts.

  The right angle portion 4 has a central suction port 20 behind the tip brush 17. The central suction port 20 is located at an intermediate portion between the right suction port 11a and the left suction port 11b, and sucks dust that could not be removed by the tip brush 17. The central suction port 20 communicates with the right suction port 11a and the left suction port 11b inside the right-angled portion 4, and sucks dust by a negative pressure generated by a blower 34 described later. A dust receiver 21 is provided behind the central suction port 20. The length of the dust receiver 21 in the vertical direction is set to a length at which the tip contacts the floor surface. The dust receiver 21 prevents the dust from passing behind the central suction port 20 and guides it to be sucked by the central suction port 20.

A pair of left and right front step detection sensors 22a and 22b that detect a concave step when the main body 1 moves forward and a pair of left and right rear step detection sensors 23a and 23b that detect a concave step when moving backward are provided on the outer periphery of the bottom surface of the arc portion 5. Provided. Each level difference detection sensor includes a light emitting unit that emits infrared light and a light receiving unit, and detects the depth of the concave step by receiving the infrared light emitted from the light emitting unit and reflected on the floor surface by the light receiving unit. A control unit (not shown) changes the moving direction of the main body 1 when a concave step having a predetermined depth or more is detected.
Each step detection sensor is not limited to a light emitting unit that emits infrared light and a light receiving unit, and may be another sensor such as a contact switch or an ultrasonic transceiver.

  The interval between the drive wheel 6a and the drive wheel 6b is set narrower than the interval between the main body rear side end of the rotary brush 12a and the main body rear side end of the rotary brush 12b. By configuring in this way, when the drive wheels 6a and 6b roll in the forward direction with the rotary brushes 12a and 12b facing forward, the floor surface of the drive wheels 6a and 6b cleaned by the rotary brushes 12a and 12b is removed. Since it passes, it can prevent that dust adheres to the drive wheels 6a and 6b.

FIG. 2 is a plan view of the self-propelled cleaner according to the first embodiment. FIG. 3 is a left side view of the self-propelled cleaner according to the first embodiment.
As shown in FIGS. 2 and 3, the right angle portion 4 has a planar right side surface 24a and a left side surface 24b. The apex angle at which the right side surface 24a and the left side surface 24b intersect is 90 °, and the joint between the two surfaces is formed round.

The right side surface 24a and the left side surface 24b are provided with two right side surface proximity sensors 25a and 26a and two left side surface proximity sensors 25b and 26b that are spaced apart from each other by a predetermined distance. Each proximity sensor 25a, 26a, 25b, and 26b includes a light emitting unit that emits infrared light and a light receiving unit, and the light receiving unit receives the infrared light that is emitted and reflected from the light emitting unit. A control unit (not shown) detects the distance to the wall or obstacle from the signals of the proximity sensors. Moreover, a control part (not shown) detects the angle of the wall surface and obstacle with respect to the right side surface 24a and the left side surface 24b by comparing the distance output of two proximity sensors in the same plane.
A right proximity sensor 27a, a left proximity sensor 27b, a right rear proximity sensor 28a, a left rear proximity sensor 28b, and a rear proximity sensor 29 are provided on the left, right, left, right, and rear of the side surface of the arc portion 5. . Each proximity sensor includes a light emitting unit and a light receiving unit that emit infrared rays, and the light receiving unit receives infrared rays that are emitted from the light emitting unit and reflected. A control unit (not shown) detects the distance between the side and rear of the main body 1 and the wall surface and obstacles.
Each proximity sensor is not limited to a light emitting unit that emits infrared light and a light receiving unit, and may be another sensor such as a contact switch or an ultrasonic transmitter / receiver.

The arc part 5 has an operation display part 30 at the rear of the upper surface. The operation display unit 30 is provided with a plurality of operation buttons 31 and a display unit 32 for switching functions such as a power source and an operation mode.
In addition, a dust collector cover 33 is provided on the upper surface of the main body 1 so as to cover the right angle portion 4 and the arc portion 5. The dust collector cover 33 opens and closes by rotating around the fulcrum when the dust collector 37 described later is attached to and detached from the main body 1.

Below, the structure of the dust collection part of the self-propelled cleaner which concerns on Embodiment 1 is demonstrated.
(Dust collector structure)
4 is a cross-sectional view of the self-propelled cleaner according to the first embodiment, taken along line Ba-Bb described in FIG. 1.
As shown in FIG. 4, a blower 34 is provided at the center of the arc portion 5. The blower 34 has a fan 35 composed of a plurality of rotating blades that rotate horizontally, and generates negative pressure by rotating the fan 35. The air flows from the upper side in the axial direction of the fan 35 due to the negative pressure generated by the fan 35, and is discharged from the exhaust duct 36 provided in the radial direction of the fan 35.

  A detachable dust collecting portion 37 is provided on the upper portion of the blower 34. The dust collector 37 is configured in a cylindrical shape, and has a dust collector lid 38 provided with an opening on the blower 34 side. The dust collector lid 38 can be opened and closed with the hinge 39 as a fulcrum. The opening is provided with a filter 40 that separates dust from the dust-containing air sucked from the suction ports and allows only air to pass through. In addition, a lattice 41 is provided at the opening of the blower 34 to prevent foreign matter from entering when the dust collecting portion 37 is removed.

  A ring-shaped seal member 42 that ensures the airtightness of the dust collector 37 and the blower 34 is provided at the opening of the dust collector lid 38. The seal member 42 is made of a material in which an elastic member such as rubber or elastomer resin is blended with a fluororesin having lubricity, and has a V-shaped cross section. The opening of the dust collector lid 38 and the opening of the blower 34 are in contact with different surfaces forming the V-shape of the seal member 42. By comprising in this way, the dust collection part 37 and the air blower 34 can be slid in a horizontal direction, ensuring airtightness.

FIG. 5 is a diagram showing a plan view including a partial cross section of the self-propelled cleaner according to the first embodiment in a state in which the dust collecting unit cover 33 and the like are removed.
A suction air passage 43 and a universal coupling portion 44 communicating with the dust collecting portion 37 are connected to the right suction port 11 a, the left suction port 11 b, and the central suction port 20. The dust-containing air sucked from the right suction port 11a, the left suction port 11b, and the central suction port 20 due to the negative pressure generated by the blower 34 merges in the suction air passage 43 and is collected via the universal connection portion 44. 37 is aspirated. Dust is collected in the dust collecting portion 37 by the filter 40 from the sucked dust-containing air. Only the air filtered by the filter 40 is sucked into the blower 34. In addition, the universal connection part 44 is a bellows structure comprised by elastic members, such as rubber | gum and an elastomer resin, and ensures airtightness, when the suction air path 43 and the dust collection part 37 adjoin and separate.

FIG. 6 is a diagram illustrating a plan view including a partial cross section of the self-propelled cleaner according to the first embodiment with the dust collection part 37 removed. 7 is a cross-sectional view of the self-propelled cleaner according to the first embodiment, taken along the line Ba-Bb shown in FIG. 1, with the dust collecting portion 37 and the universal connecting portion 44 removed. FIG.
As shown in FIGS. 6 and 7, the dust collecting portion 37, the universal connecting portion 44, and the like can be separated and removed from the main body 1 by opening the dust collecting portion cover 33 (FIG. 6 shows the dust collecting portion 37. Only shows the removed state.) The dust collecting portion cover 38 can be opened with the hinge portion 39 as a fulcrum, and the filter 40 can be separated and removed. An annular seal member (not shown) is provided on the contact surface between the dust collector lid 38 and the dust collector 37 to ensure airtightness. Further, the dust collecting portion lid 38 is provided with a locking claw (not shown), and engages with the dust collecting portion 37 to keep the dust collecting portion lid 38 closed.

Below, arrangement | positioning of the electric system of the self-propelled cleaner which concerns on Embodiment 1 is demonstrated.
(Electric system layout)
As shown in FIGS. 4 and 5, an assembled battery 46 in which a plurality of cylindrical storage batteries 45 are integrated and stored in a resin case is provided at the rear of the arc portion 5. The plurality of storage batteries 45 are arranged in an arc shape along the outer shape of the arc portion 5. By arranging the storage batteries 45 in an arc shape, the main body 1 can be reduced in size.

  An electric circuit board 47 is provided in the central portion 2, and electric parts such as a control circuit and a sensor are mounted on the electric circuit board 47. A plurality of main body exhaust ports 48 are provided on the rear side surface of the arc portion 5. Exhaust air discharged from the blower 34 passes through the central portion 2 and the arc portion 5, cools the electric components of the electric circuit board 47, the heating elements such as the storage battery 45, and is discharged from the main body exhaust port 48. .

The structure of each drive system of the self-propelled cleaner according to the first embodiment will be described below.
(Rotating brush drive system)
FIG. 8 is a cross-sectional view of the self-propelled cleaner according to the first embodiment, taken along line Da-Db shown in FIG. 1.
As shown in FIGS. 5 and 8, the rotating brush shafts 13a and 13b extend to the distal end side of the right-angled portion 4, and bevel gears 49a and 49b are provided at the distal ends. The bevel gears 49a and 49b are orthogonal to each other so that their gear portions mesh with each other. A rotary brush motor 50 is provided on the upper portion of the rotary brush 12a. On the rotating shaft of the rotary brush motor 50, a helical gear 51 and a bevel gear 52 are provided. The helical gear 51 transmits the rotational force of the rotary brush motor 50 to the helical gear 54 disposed on the extension of the rotary brush shaft 13 via the transmission gear 53.

  When the rotary brush motor 50 rotates, a rotational force is transmitted to the palm gear 54, and the rotary brush shaft 13a rotates. The rotating brush 12a attached to the rotating brush shaft 13a rotates in a direction from the outside of the main body 1 toward the center side when the bristle brush 15 contacts the floor surface F. When the bevel gear 49a is rotated by the rotation of the rotating brush shaft 13a, the meshing bevel gear 49b is rotated and the rotating brush shaft 13b is rotated. That is, the rotating brush shaft 13a and the rotating brush shaft 13b rotate in synchronization. The rotating brush 12b attached to the rotating brush shaft 13b rotates in the direction from the outside of the main body 1 toward the center side of the main body 1 when the bristle brush 15 contacts the floor surface F, similarly to the rotating brush 12a.

  A bevel gear 55 is provided on the tip brush shaft 18. The bevel gear 55 is disposed orthogonally so as to mesh with the bevel gear 52. When the bevel gear 52 is rotated by the rotation of the rotary brush motor 50, the bevel gear 55 to be engaged is rotated. As a result, the tip brush shaft 18 rotates and the tip brush 17 rotates horizontally with respect to the floor surface F in the clockwise direction.

(Outer shell drive system)
As shown in FIGS. 4 and 5, the outer shell portion 3 is rotatably connected to the central portion 2. The central portion 2 is disposed inside the outer shell portion 3, and a plurality of columnar rolling members 56 are provided at a connection portion with the outer shell portion 3. The rotatable angle of the outer shell portion 3 with respect to the central portion 2 is 90 °, and the outer shell portion 3 is 45 ° around the central portion 2 clockwise and counterclockwise with respect to the state shown in FIG. Rotate in the range.

  An angle adjustment motor 57 and a pinion gear 58 that transmits the rotational force of the angle adjustment motor 57 are provided at the rear of the arc portion 5. A rack gear 59 is provided in the central portion 2. The rack gear 59 meshes with the pinion gear 58, and the rotational force of the angle adjustment motor 57 is transmitted via the pinion gear 58. The control unit (not shown) rotates the outer shell 3 with respect to the central portion 2 by rotating the angle adjusting motor 57 during the operation of the main body 1.

  The arc portion 5 is provided with an angle detection sensor (not shown) that detects the position of the rack gear 59 and detects the rotation angle of the outer shell portion 3. A control unit (not shown) controls the rotation angle of the outer shell 3 based on a signal from the angle detection sensor.

FIG. 9 is a diagram showing a plan view including a partial cross section of the self-propelled cleaner according to the first embodiment with the dust collecting part cover 33 and the like removed, and is out of the state shown in FIG. It is a figure which shows the state which the shell part 3 rotated 45 degrees counterclockwise with respect to the center part 2. FIG.
In the state shown in FIG. 5, when a control unit (not shown) rotates the angle adjustment motor 57 counterclockwise, the pinion gear 58 rotates counterclockwise while rolling the gear portion of the rack gear 59 that meshes. The rack gear 59 moves to the right. As the pinion gear 58 moves, the outer shell portion 3 to which the angle adjusting motor 57 is fixed rotates counterclockwise with respect to the central portion 2. When the outer shell portion 3 rotates 45 ° counterclockwise with respect to the central portion 2, an angle detection sensor (not shown) detects this and outputs a signal to the control portion (not shown). The control unit (not shown) receives the signal and stops the angle adjustment motor 57.

  At this time, the axis Ga-Gb of the drive wheels 6a and 6b is perpendicular to the rotating brush shaft 13b. In this state, the left side surface 24b can be brought into contact with the wall surface H, and the main body 1 is moved along the wall surface H while rotating the rotary brush 12b, thereby continuously cleaning the floor surface F near the wall. Is possible. Further, since the rotating brush 12a is perpendicular to the moving direction of the main body 1, the area corresponding to the width of the rotating brush 12a can be simultaneously cleaned from the wall surface H, and the cleaning efficiency of the floor surface F near the wall can be further improved. It is possible to improve.

FIG. 10 is a diagram showing a plan view including a partial cross section of the self-propelled cleaner according to the first embodiment with the dust collecting part cover 33 and the like removed, and is out of the state shown in FIG. It is a figure which shows the state which the shell part 3 rotated 45 degrees clockwise with respect to the center part 2. FIG.
In the state shown in FIG. 5, when the control unit (not shown) rotates the angle adjustment motor 57 clockwise, the pinion gear 58 rotates clockwise and the rack gear 59 rotates while rolling the gear portion of the meshing rack gear 59. Move to the left. As the pinion gear 58 moves, the outer shell portion 3 to which the angle adjustment motor 57 is fixed rotates clockwise with respect to the central portion 2. When the outer shell 3 rotates 45 ° clockwise relative to the central portion 2, an angle detection sensor (not shown) detects this and outputs a signal to the control unit (not shown). The control unit (not shown) receives the signal and stops the angle adjustment motor 57.

  At this time, the central axis Ga-Gb of the drive wheels 6a and 6b is perpendicular to the rotating brush shaft 13a. In this state, the right side surface 24a can be brought into contact with the wall surface I, and the main body 1 is moved along the wall surface I while rotating the rotating brush 12a, thereby continuously cleaning the floor surface F near the wall. Is possible. Further, since the rotating brush 12b is perpendicular to the moving direction of the main body 1, the area corresponding to the width of the rotating brush 12b from the wall surface I can be cleaned at the same time, and the cleaning efficiency of the floor surface F near the wall can be improved. It is possible to improve.

FIG. 11 is a cross-sectional view of the self-propelled cleaner according to the first embodiment, taken along line Ea-Eb described in FIG. 1, in a state where the self-propelled cleaner is in contact with or close to the wall surface.
As shown in FIG. 11, the right side surface 24 a of the main body 1 is in contact with the wall surface I. The position of the rotary brush shaft 13a and the length of the bristle brush 15 are set so that the bristle brush 15 of the rotary brush 12a protrudes outside the right side surface 24a. Further, the bristle brush 15 reaches the corner of the floor surface F in a state where the right side surface 24a is in contact with the wall surface I. By comprising in this way, it can clean reliably to the wall side.

(Driving system of driving wheels)
As shown in FIGS. 4 and 5, drive wheel motors 8a and 8b are connected to the pair of drive wheels 6a and 6b via gear portions 9a and 9b, respectively, thereby constituting an integrated drive unit. The pair of drive wheels 6a and 6b is rotatably supported by a hinge portion (not shown) provided on the rear side of the main body. The drive unit receives a force in a direction in which the drive wheels 6a and 6b protrude from the drive wheel openings 7a and 7b by a spring (not shown). When the main body 1 is lifted from the floor surface F, the drive unit receives a force from the spring, so that the amount of protrusion of the drive wheels 6a and 6b from the drive wheel openings 7a and 7b increases.

  Each drive wheel unit is provided with a drive wheel ground sensor (not shown) that detects displacement. The control unit (not shown) recognizes the contact state between the drive wheels 6a and 6b and the floor surface F by monitoring the output of the drive wheel ground sensor.

Below, operation | movement of the right-angled part of the self-propelled cleaner which concerns on Embodiment 1 is demonstrated.
(Operation of right angle part)
As shown in FIG. 4, the right angle portion 4 is supported by the outer shell portion 3 so as to be vertically movable. The outer shell portion 3 is provided with a plurality of guides 60, and the right angle portion 4 moves up and down along the guides 60. Further, the right angle portion 4 has an inclined surface at the tip of the bottom surface, and when the right angle portion 4 reaches the convex step, the inclined surface receives a force from the convex step and moves the right angle portion 4 upward.

  A displacement amount detection sensor 61 that detects the amount of vertical displacement of the right angle portion 4 is provided behind the right angle portion 4. The displacement detection sensor 61 includes an infrared light emitting unit and a light receiving unit. The control unit (not shown) detects the displacement of the right-angled portion 4 by detecting the reflected infrared light emitted to the boundary portion with the light receiving unit. The control unit (not shown) controls the drive wheels 6a and 6b so as to get over the right-angled part 4 when it gets on the convex step. In addition, when it falls to the concave step, the driving wheels 6a, 6b are stopped and then reversed so that the escape operation from the concave step is performed.

12 is a diagram illustrating a cross-sectional view of the self-propelled cleaner according to the first embodiment, taken along the line Ba-Bb illustrated in FIG. 1, in a state of moving on the carpet.
As shown in FIG. 12, when the main body 1 moves on the carpet J in which soft hairs are implanted, the driving wheels 6a and 6b and the driven wheel 10 support the weight of the main body 1 with a small contact area. Sink inside. On the other hand, since the right-angled part 4 has a large contact area with the carpet J, it does not sink into the carpet J, but is stable in contact with the surface of the carpet J. Thus, when the main body 1 moves on the carpet J, the right angle portion 4 moves upward with respect to the drive wheels 6 a and 6 b and the outer shell portion 3. With such a configuration, dust on the carpet J can be cleaned even in a state of moving on the carpet J. Further, since the rotary brushes 12a and 12b are provided at the dust suction port, the bristle brush 15 enters the carpet J, and the dust that has entered the carpet J can be scraped and cleaned.

Hereinafter, the operation of the self-propelled cleaner according to the first embodiment will be described.
(Operation of self-propelled vacuum cleaner)
13-22 is a figure which shows operation | movement of the self-propelled cleaner which concerns on Embodiment 1. FIG.
13 to 22, a broken line indicates a state before the operation of the main body 1. When the operator sets the cleaning operation of the main body 1, the control unit (not shown) operates the blower 34 and starts suction from the right suction port 11 a, the left suction port 11 b, and the central suction port 20. Further, the control unit (not shown) operates the rotary brush motor 50 to rotate the rotary brushes 12a and 12b and the tip brush 17. The control unit (not shown) drives the drive wheel motors 8a and 8b based on a predetermined operation algorithm to move the main body 1. 13 to 22 show the case where the wall surface L is on the right side with respect to the wall surface K when the floor surface F is viewed from above, but the case where the wall surface L is on the left side with respect to the wall surface K. But it is possible to operate similarly.

  FIG. 13 shows a state in which the main body 1 moves obliquely toward the wall surface K. At this time, the main body 1 is located about 30 cm away from the wall surface K, and the right side proximity sensors 25a and 26a and the left side proximity sensors 25b and 26b do not detect proximity to the wall K. Each proximity sensor may be set to detect proximity when the distance from the wall surface K is 20 cm or less.

  FIG. 14 shows a state in which the main body 1 goes straight and is close to the wall surface K up to about 10 cm. At this time, the front left side proximity sensor 25b, the rear left side proximity sensor 26b, and the front right side proximity sensor 25a detect the proximity to the wall K. The control unit (not shown) recognizes from the signals of these three proximity sensors that the front left side proximity sensor 25b is closest. Further, the control unit (not shown) recognizes that the left side surface 24b is inclined with respect to the wall surface K from the difference in distance output between the front left side surface proximity sensor 25b and the rear left side surface proximity sensor 26b. To do.

  FIG. 15 shows a state in which the main body 1 makes the left side surface 24 b contact the wall surface K. After recognizing that the left side surface 24b is inclined with respect to the wall surface K at the time of FIG. 14, the control unit (not shown) moves the main body 1 while turning in the right direction while moving the left side surface on the front side. The distance outputs of the proximity sensor 25b and the rear left side proximity sensor 26b are compared. Then, the control unit (not shown) rolls the drive wheels 6a and 6b so that the distance output difference between the proximity sensors is 0 and the proximity sensors detect contact, and the left side surface 24b is moved to the wall surface K. Contact. At this time, the left rotating brush 12b brings the bristle brush 15 into contact with the floor surface F near the wall, and scrapes off dust on the floor surface F near the wall. And dust is attracted | sucked from the left inlet 11b.

  FIG. 16 shows a state in which the rolling directions of the drive wheels 6a and 6b are parallel to the wall surface K. The control unit (not shown) moves the main body 1 along the wall surface K in the state of FIG. 15, that is, the left side surface 24b is in contact with the wall surface K. The central portion 2 and the outer shell portion 3 are rotated so as to be parallel to the wall surface K.

  At this time, the control unit (not shown) rolls the right drive wheel 6a in the negative direction (rolls in the backward direction) and rolls the left drive wheel 6b in the positive direction (rolls in the forward direction). As a result, the central part 2 is rotated clockwise. At the same time, the angle adjusting motor 57 is rotated counterclockwise, and the outer shell 3 is rotated counterclockwise with respect to the central portion 2. Here, the rolling direction of the drive wheels 6a, 6b is changed while the left side surface 24b is in contact with the wall surface K by making the central part 2 and the outer shell part 3 rotate at the same speed. can do.

  FIG. 17 shows a state in which the main body 1 moves along the wall surface K and reaches the corner M. The control unit (not shown) is in the state shown in FIG. 16, that is, in a state where the left side surface 24b is in contact with the wall surface K and the rolling direction of the drive wheels 6a and 6b is parallel to the wall surface K. Roll 6b. The main body 1 moves along the wall surface K while bringing the left side surface 24b into contact with the wall surface K. By moving in this way, the main body 1 can scrape and collect the dust on the floor surface F near the wall.

  When the main body 1 approaches the wall L, the front right side proximity sensor 25a and the rear right side proximity sensor 26a simultaneously detect the proximity to the wall L. At this time, the control unit (not shown) recognizes the angle of the right side surface 24a with respect to the wall surface L by comparing the distance outputs of the front right side proximity sensor 25a and the rear right side proximity sensor 26a. The control unit (not shown) can recognize that the wall surface L is perpendicular to the wall surface K when both proximity sensors have the same distance output. When recognizing that the wall surface L is not perpendicular to the wall surface K, the control unit (not shown) outputs a signal that warns that there is a possibility of cleaning leakage. Further, the operation algorithm is switched according to the angle between the wall surface K and the wall surface L, and the cleaning is continued.

  When the main body 1 reaches the corner M, the control unit (not shown) stops driving the drive wheels 6a and 6b with the right side surface 24a in contact with the wall surface L. Then, staying at the corner M for a predetermined time, the rotating brushes 12a and 12b and the tip brush 17 are rotated to clean the corner M. At this time, the dust on the wall surface K side is scraped out by the rotating brush 12b and sucked from the left suction port 11b. Further, the dust on the wall L side is scraped out by the rotating brush 12a and sucked from the right suction port 11a. Further, dust accumulated at the corner formed by the wall surface K and the wall surface L is scraped by the tip brush 17 and is sucked by the right suction port 11a, the left suction port 11b, and the central suction port 20.

  FIG. 18 shows a state in which the rolling directions of the drive wheels 6 a and 6 b are parallel to the wall surface L. In the state where the right side surface 24a is in contact with the wall surface L, the control unit (not shown) moves the main body 1 along the wall surface L so that the rolling directions of the drive wheels 6a and 6b are parallel to the wall surface L. The center part 2 and the outer shell part 3 are rotated so that

  At this time, the control unit (not shown) rolls the right driving wheel 6a in the positive direction (rolls in the forward direction) and rolls the left driving wheel 6 ′ in the negative direction (rolls in the backward direction). ) To rotate the central part 2 counterclockwise. At the same time, the angle adjusting motor 57 is rotated clockwise, and the outer shell 3 is rotated clockwise with respect to the central portion 2. Here, the rolling direction of the drive wheels 6a and 6b is changed while the right side surface 24a is in contact with the wall surface L by making the central part 2 and the outer shell part 3 have the same rotational speed. can do. That is, the rolling direction of the drive wheels 6a and 6b can be changed from the wall surface K to the wall surface L while the main body 1 is held at the corner M.

  FIG. 19 shows a state in which the main body 1 has moved along the wall surface L in a direction away from the corner M. The control unit (not shown) is in the state shown in FIG. 18, that is, in a state where the right side surface 24a is in contact with the wall surface L and the rolling direction of the driving wheels 6a, 6b is parallel to the wall surface L. Roll 6b. The main body 1 moves along the wall surface L while bringing the right side surface 24a into contact with the wall surface L. By moving in this way, the main body 1 can scrape and collect the dust on the floor surface F near the wall. At this time, since the rotating brushes 12a and 12b are located rearward with respect to the drive wheels 6a and 6b, the drive wheels 6a and 6b move on a floor surface that has not been cleaned. Therefore, the control unit (not shown) temporarily stops the main body 1 after moving the main body 1 from the corner portion M along the wall surface L by about 50 cm, and the rotating brushes 12a and 12b are driven by the driving wheels 6a and 6b according to the following procedure. The positional relationship between the rotary brushes 12a and 12b and the drive wheels 6a and 6b is changed so as to be positioned forward with respect to.

  FIG. 20 shows a state in which the main body 1 moves along the wall surface L and returns to the corner M side. In the state shown in FIG. 19, the control unit (not shown) moves the main body 1 toward the corner M to a position where the outer shell 3 sufficiently passes through the range cleaned by the left rotating brush 12 b. This is an operation for preventing the occurrence of the floor surface F that causes cleaning leakage due to a change in the positional relationship between the rotating brushes 12a and 12b and the drive wheels 6a and 6b.

  FIG. 21 shows a state in which the positional relationship between the rotating brushes 12a and 12b and the driving wheels 6a and 6b is changed so that the rotating brushes 12a and 12b are positioned in front of the driving wheels 6a and 6b. The control unit (not shown) is counterclockwise with respect to the central portion 2 from the state shown in FIG. 20, that is, the outer shell portion 3 is rotated 45 ° clockwise relative to the central portion 2. The outer shell 3 is rotated until it is rotated 45 ° around. At the same time, the right driving wheel 6a rolls in the positive direction (rolls in the forward direction), and the left driving wheel 6b rolls in the negative direction (rolls in the backward direction). Rotate 180 ° counterclockwise. With this operation, the rotating brushes 12a and 12b can be disposed on the front side of the drive wheels 6a and 6b, that is, on the side away from the corner M, at the same place as the position of the main body 1 in FIG. Further, it is possible to cope with cleaning at the next corner that appears after further movement along the wall surface L. The rotation of the outer shell 3 and the central rotation of the central portion 2 may not be simultaneous, but simultaneous rotation is necessary for changing the positional relationship between the rotating brushes 12a and 12b and the drive wheels 6a and 6b. This is preferable because it saves time.

  FIG. 22 shows a state in which the main body 1 has moved along the wall surface L in a direction away from the corner M. The control unit (not shown) is in the state shown in FIG. 21, that is, in a state where the left side surface 24b is in contact with the wall surface L and the rolling direction of the driving wheels 6a and 6b is parallel to the wall surface L. Roll 6b. The main body 1 moves along the wall surface L in the direction away from the corner M while bringing the left side surface 24b into contact with the wall surface L. By moving in this way, the main body 1 can scrape and collect the dust on the floor surface F near the wall.

  The self-propelled cleaner according to the first embodiment is operated so that the right side surface 24a and the left side surface 24b are in contact with the wall surface when cleaning the floor surface F near the wall, but is several mm from the wall surface. You may operate | move in the state which released | separated and was made close proximity. By operating in this way, the floor surface F near the wall can be cleaned without damaging the wall surface.

  Moreover, you may provide the buffer member with high sliding performance comprised with raw materials, such as a fluororesin, in each of the right side surface 24a and the left side surface 24b. With this configuration, it is possible to prevent the wall surface from being damaged when the right side surface 24a and the left side surface 24b are brought into contact with the wall surface.

  In addition, the self-propelled cleaner according to the first embodiment includes a plurality of dust suction ports at right angles of the outer shell, but is not limited to such a form. For example, it goes without saying that the same effect as that of the self-propelled cleaner according to the first embodiment can be obtained even if the outer shell portion has one dust suction port. As in the self-propelled cleaner according to the first embodiment, the outer shell 3 is provided with a side surface parallel to the wall surface or a corner portion corresponding to the wall surface crossing angle of the corner floor surface. Since the suction port can be brought close to the floor surface or the corner floor surface, cleaning leakage can be further reduced. Moreover, since a plurality of dust inlets having different longitudinal directions are provided as in the self-propelled cleaner according to the first embodiment, a plurality of locations can be cleaned at the same time, thereby further improving the cleaning efficiency. It becomes possible.

  Further, the self-propelled cleaner according to the first embodiment is such that the outer shell portion rotates within a range of ± 45 ° with respect to the central portion, but is not limited to such a form. For example, it goes without saying that the same effect as that of the self-propelled cleaner according to the first embodiment can be obtained even when the outer shell portion is rotated 360 ° with respect to the central portion. Like the self-propelled cleaner according to the first embodiment, by limiting the range in which the outer shell portion rotates, a storage battery or the like can be provided behind the dust collecting portion, and the self-propelled cleaner is downsized. It becomes possible to do.

  In addition, the self-propelled cleaner according to the first embodiment includes two drive wheels on a straight line passing through the center of rotation at the center, but is not limited to such a form. For example, it is needless to say that the same effect as that of the self-propelled cleaner according to the first embodiment can be obtained even if a mechanism that rotates the central part apart from the drive wheel that moves in the central part is provided. Like the self-propelled cleaner according to the first embodiment, a mechanism for moving the central portion and a mechanism for rotating the central portion by providing two drive wheels on a straight line passing through the rotation center of the central portion The self-propelled cleaner can be reduced in size.

  In addition, the self-propelled cleaner according to the first embodiment is provided with a rotating brush and a dust receiver at the dust suction port, but is not limited to such a form. For example, it is needless to say that the same effect as that of the first embodiment can be obtained even if the dust suction port has nothing, only one of the rotating brush and the dust receiver, or other members. Yes. As in the self-propelled cleaner according to the first embodiment, by providing the dust suction port with the rotating brush and the dust receiver, the dust on the floor surface, particularly the dust on the floor surface near the wall can be reliably cleaned. Can be further reduced. Further, as in the self-propelled cleaner according to the first embodiment, by providing the dust suction port with the rotating brush, the carpet can be cleaned, and cleaning leakage can be further reduced.

  Further, the self-propelled cleaner according to the first embodiment is supported by the right-angled portion so as to be vertically movable on the outer shell portion, but is not limited to such a configuration. For example, it goes without saying that the same effect as in the first embodiment can be obtained even when the right-angled portion is fixed or the bottom surface of the right-angled portion is inclined so that the front becomes higher. Like the self-propelled cleaner according to the first embodiment, it is possible to surely get over the convex step by moving the right-angled portion up and down. Moreover, like the self-propelled cleaner according to the first embodiment, by moving the right-angled portion up and down, it is possible to clean the carpet, and it is possible to further reduce cleaning leakage.

  In addition, the self-propelled cleaner according to the first embodiment is configured such that the bristle brush 19 of the tip brush 17 is composed of three bristle brushes having different lengths planted on the lower end portion of the tip brush shaft 18. However, the bristle brush 19 may be constituted by a single bristle brush. In that case, the bristle brush 19 is planted at the lower end portion of the tip brush shaft 18 so that the tip side of the bristle brush spreads, and the length of the outer bristle brush is longer than the length of the inner bristle brush. Good to be done. With such a configuration, the dust scraping effect on the floor surface F is improved, and the hair, yarn, and the like are prevented from being entangled with the bristle brush 19.

In addition, the self-propelled cleaner according to the first embodiment includes the driven wheel 10 on the bottom surface of the main body 1, but the driven wheel 10 may not be provided. In that case, since the bristle brush 15 of the rotating brushes 12a and 12b contacts the floor surface F and supports the front of the main body 1, the main body 1 is supported horizontally with respect to the floor surface F.
Further, instead of the driven wheel 10, a cushion member having high slidability may be provided. In that case, when the front of the main body 1 is lifted, the cushion member is brought into contact with the floor surface F and the bottom surface of the main body 1 is prevented from being damaged.

  Further, the self-propelled cleaner according to the first embodiment is configured such that the air blower 34 and the dust collecting portion 37 are horizontal in a state where the air passage between the air blower 34 and the dust collecting portion 37 is secured by the seal member 42. Although configured to be slidable in the direction, both the blower 34 and the dust collecting portion 37 may be provided in the outer shell portion 3. In that case, when the outer shell portion 3 rotates with respect to the central portion 2, the exhaust duct 36 of the blower 34 is configured not to interfere with the drive wheel motors 8a, 8b and the like.

  In addition, the self-propelled cleaner according to the first embodiment is configured such that the right angle portion 4 is movable up and down along the plurality of guides 60 provided in the outer shell portion 3. However, it may be configured to be rotatable in the vertical direction around a part of the right-angled portion 4.

  As described above, the self-propelled cleaner according to the first embodiment controls the dust suction port angle changing means so that the angle of the dust suction port in the longitudinal direction with respect to the rolling direction of the drive wheel is optimized. By providing the means, it becomes possible to reach the dust suction port into a narrow space such as a corner of the floor surface, and the cleaning leakage can be reduced. Further, the self-propelled cleaner according to the first embodiment includes control means for controlling the dust suction port angle changing means so that the angle of the dust suction port in the longitudinal direction with respect to the rolling direction of the drive wheel is optimized. Accordingly, when cleaning a narrow space such as a corner of the floor surface, it is not necessary to repeat the change of the moving direction of the main body and the forward and backward movement, and the cleaning efficiency can be improved.

  DESCRIPTION OF SYMBOLS 1 Main body, 2 Center part, 3 Outer shell part, 4 Right angle part, 5 Arc part, 6 Driving wheel, 10 Driven wheel, 11a Right suction port, 11b Left suction port, 12 Rotating brush, 16 Dust receptacle, 17 Tip brush, 20 Central suction port, 21 Dust receiver.

Claims (15)

A main body having a plurality of driving wheels that roll on the floor surface, and a dust suction port provided on the bottom surface;
A blower and a dust collecting unit that sucks air on the floor surface from the dust suction port inside the main body;
An electric circuit board having a control circuit for controlling the driving wheel and the blower,
The outer shell shape of the body has two planar side surfaces continuous from one top,
Each of the dust suction ports is formed in an elongated shape in the direction along the two planar side surfaces on the bottom surface of the main body,
The main body is vertically driven to rotate on the floor surface while being driven by the rotation centering on an axis disposed along the longitudinal direction of the dust suction port while being operated with the blower. Comprising a rotating brush, the vertical rotating brush has a rotation center in the vicinity of the dust inlet,
The outer shell shape of the main body is
A central portion having the drive wheel, and movable and pivotable by rolling of the drive wheel;
An outer shell portion that has the dust suction port and is rotatably held around the central portion at the central portion;
The outer shell portion has a planar side surface;
The dust suction port is formed such that the longitudinal direction is parallel or perpendicular to the planar side surface,
The outer shell portion has two planar side surfaces so as to cross each other, and a first dust suction port is formed so that a longitudinal direction is parallel to one of the two planar side surfaces, A second dust suction port is formed so that the longitudinal direction is parallel to the other of the two planar side surfaces;
The outer shell portion has a third dust suction port between the first dust suction port and the second dust suction port,
The third dust suction port is formed such that the longitudinal direction intersects with the two planar side surfaces at the same angle.
This is a self-propelled vacuum cleaner.   The drive wheels pass through the top and are arranged at positions on both sides of a center line that bisects the main body, and the rolling direction and rolling amount are controlled by the control circuit independently of each other. The self-propelled cleaner according to claim 1, wherein When the control circuit is not in contact with or close to the wall surface, a top portion formed by the two planar side surfaces is disposed on a center line passing through the center of the main body and parallel to the rolling direction of the drive wheel. The rotation angle of the outer shell portion is set so that the rotation angle of the outer shell portion is set so that the planar side surface is parallel or perpendicular to the wall surface in a state where it is in contact with or close to the wall surface.
The self-propelled cleaner according to claim 1 or 2. The angle of the top formed by the two planar side faces is 90 °;
The control circuit rotates the outer shell portion in a range of ± 45 ° with respect to a state in which the top portion is arranged on a center line passing through the center of the main body and parallel to the rolling direction of the drive wheel.
The self-propelled cleaner as described in any one of Claims 1-3 characterized by the above-mentioned. The center of rotation of the central part and the center of rotation of the outer shell part are the same,
The control circuit rotates the central part at the same time, and simultaneously rotates the outer shell part by the same angle in the opposite direction at the same speed with respect to the central part of the central part, and the moving direction of the main body Convert
The self-propelled cleaner as described in any one of Claims 1-4 characterized by the above-mentioned. The driving wheel is two points on a straight line that passes through the center of rotation of the central part and is perpendicular to the rolling direction of the driving wheel, and is separated from the center of rotation by the same distance in the opposite direction. Placed at two points,
The self-propelled cleaner as described in any one of Claims 1-5 characterized by the above-mentioned. A main body having a plurality of driving wheels that roll on the floor surface, and a dust suction port provided on the bottom surface;
A blower and a dust collecting unit that sucks air on the floor surface from the dust suction port inside the main body;
An electric circuit board having a control circuit for controlling the driving wheel and the blower,
The outer shell shape of the body has two planar side surfaces continuous from one top,
Each of the dust suction ports is formed in an elongated shape in the direction along the two planar side surfaces on the bottom surface of the main body,
The main body is vertically driven to rotate on the floor surface while being driven by the rotation centering on an axis disposed along the longitudinal direction of the dust suction port while being operated with the blower. Comprising a rotating brush, the vertical rotating brush has a rotation center in the vicinity of the dust inlet,
A self-propelled cleaner having a rotating shaft in the vertical direction and rotating in a horizontal direction with respect to the floor surface between the dust suction ports. The first dust suction port and the second dust suction port have a vertical rotating brush,
The self-propelled cleaner as described in any one of Claims 1-6 characterized by the above-mentioned. The vertical rotating brush protrudes from the outer periphery of the main body,
The self-propelled cleaner according to claim 8. The vertical rotating brush and the horizontal rotating brush are driven by one driving source.
Self-propelled cleaner according to claim 7, characterized in that. The dust suction port is movable in the vertical direction with respect to the drive wheel.
The self-propelled cleaner as described in any one of Claims 1-10 characterized by the above-mentioned. The dust inlet has a dust receiver,
The self-propelled cleaner according to any one of claims 1 to 11, wherein The main body includes a sensor for detecting a distance between the side surface and the wall surface and / or an angle between the side surface and the wall surface.
The self-propelled cleaner according to any one of claims 1 to 12, wherein A heat generating member is disposed in the exhaust path of the main body.
The self-propelled cleaner according to any one of claims 1 to 13, wherein The main body has a plurality of storage batteries built in along the outer shape of the main body.
The self-propelled cleaner as described in any one of Claims 1-14 characterized by the above-mentioned.

Images