JP2019166239A - Suction port body and vacuum cleaner - Google Patents

Abstract

Provided is a light-weight, well-balanced suction port body (6) that suppresses an increase in the diameter of the rotating brush (34) while obtaining torque for rotating the rotating brush (34), and a vacuum cleaner (2) including the same. A suction port body includes a case, a rotary brush, a connection pipe, a control section, and a brush drive section. The case 32 forming the outer shell of the suction port body 6 has a suction port 6a communicating with the inside on the lower surface. The rotating brush 34 is rotatably provided inside the case 32. A part of the rotating brush 34 protrudes from the suction port 6a. A connection pipe 33 whose internal space communicates with the inside of the case 32 is provided behind the suction port 6a. The control unit 37 and the brush driving unit 35 are provided on the left and right sides of the connecting pipe 33 behind the rotating brush 34. The brush driving unit 35 is a brushless motor that drives the rotary brush 34 to rotate by rotating the output shaft under the control of the control unit 37. [Selection diagram] FIG.

Description

  The present invention relates to a suction port body and a vacuum cleaner.

  Patent Document 1 describes an example of a suction port body. The suction port body includes a rotating brush. The rotating brush incorporates an outer rotor type brushless motor in the center of the left and right. The rotating brush has a good left / right weight balance.

JP 2006-223617 A

  However, in the electric vacuum cleaner of patent document 1, in order to output the torque which rotates a rotary brush, the diameter of a brushless motor becomes large. For this reason, the diameter of the rotating brush which incorporates a brushless motor becomes large.

  The present invention has been made to solve such problems. An object of the present invention is to provide a lightweight and well-balanced suction port body and a vacuum cleaner including the same, which obtain a torque for rotating the rotating brush and suppress an increase in diameter of the rotating brush.

  A suction port body according to the present invention comprises a case having an outer surface and a suction port that communicates with the inside of the suction port body, a rotary brush that is rotatably provided inside the case, and a part of which protrudes from the suction port, A connection pipe provided at the rear of the suction port, an internal space leading to the inside of the case, a control unit provided at one of the connection pipes in the left-right direction behind the rotary brush, and a brushless motor, the rotation A brush drive unit provided behind the brush in the other of the connecting pipes in the left-right direction, the rotation of the output shaft being controlled by the control unit, and the rotation brush being driven to rotate by the rotation of the output shaft.

  The vacuum cleaner according to the present invention includes a fan that generates an airflow for sucking dust from outside, a fan motor that rotationally drives the fan, a dust collecting container that collects the dust, and a suction port for the airflow. And the above-described suction port body that is sucked from.

  According to the present invention, the suction port body includes a case, a rotating brush, a connecting pipe, a control unit, and a brush driving unit. The case has an outer shell and has a suction port on the lower surface that leads to the inside. The rotating brush is rotatably provided inside the case, and a part of the rotating brush protrudes from the suction port. The connecting pipe is provided behind the suction port, and the internal space leads to the inside of the case. A control part is provided in one side of the left-right direction of a connecting pipe behind a rotation brush. The brush drive unit is a brushless motor, and is provided on the other side in the left-right direction of the connection pipe behind the rotary brush. The control unit controls the rotation of the output shaft, and the rotary brush is driven to rotate by the rotation of the output shaft. Thereby, the suction port body suppresses an increase in diameter of the rotating brush while obtaining torque for rotating the rotating brush, and is lightweight and has a good weight balance.

It is a perspective view of the vacuum cleaner unit concerning Embodiment 1. FIG. It is a perspective view of the vacuum cleaner unit concerning Embodiment 1. FIG. 3 is a front view of a main body according to Embodiment 1. FIG. 3 is a rear view of the main body according to Embodiment 1. FIG. 3 is a side view of the main body according to Embodiment 1. FIG. It is sectional drawing in the AA surface in FIG. 3 of the main body which concerns on Embodiment 1. FIG. 3 is an exploded perspective view of the battery unit according to Embodiment 1. FIG. 3 is a perspective cross-sectional view of the battery unit according to Embodiment 1. FIG. 3 is a perspective view of an extension pipe according to Embodiment 1. FIG. 3 is an exploded perspective view of a suction port body according to Embodiment 1. FIG. 3 is a perspective view of a suction port body according to Embodiment 1. FIG. 3 is a side view of the suction port body according to Embodiment 1. FIG. FIG. 3 is a bottom view of the suction port body according to Embodiment 1. It is sectional drawing in the BB surface in FIG. 13 of the suction inlet concerning Embodiment 1. FIG. It is sectional drawing in CC plane in FIG. 13 of the suction inlet concerning Embodiment 1. FIG. 3 is a top view of the suction port according to Embodiment 1. FIG. It is a perspective view of the vacuum cleaner which concerns on the modification of Embodiment 1. FIG. 5 is a configuration diagram of a transmission unit according to Embodiment 2. FIG. 10 is a table showing rotation conversion by the transmission unit according to the second embodiment. It is a figure showing the relationship between the output torque of the brush drive part which concerns on Embodiment 2, and rotational speed. It is a figure showing the relationship between the output torque and rotational speed of the rotary brush which concerns on Embodiment 2. FIG. FIG. 10 is a configuration diagram of a transmission unit according to a modification of the second embodiment. FIG. 10 is a configuration diagram of a transmission unit according to a modification of the second embodiment. FIG. 10 is a configuration diagram of a transmission unit according to a modification of the second embodiment. 6 is a configuration diagram of a transmission unit according to Embodiment 3. FIG. 6 is a configuration diagram of a transmission unit according to Embodiment 4. FIG.

  EMBODIMENT OF THE INVENTION The form for implementing this invention is demonstrated referring an accompanying drawing. In the drawings, the same or corresponding parts are denoted by the same reference numerals, and overlapping descriptions are simplified or omitted as appropriate.

Embodiment 1 FIG.
1 and 2 are perspective views of the cleaner unit according to Embodiment 1. FIG. 1 and 2, the vertical direction of the paper is the vertical direction of the vacuum cleaner. 1 and 2, the direction indicated by the arrow is the front-rear direction of the vacuum cleaner.

  The vacuum cleaner unit 1 includes a vacuum cleaner 2 and a charging stand 3.

  The electric vacuum cleaner 2 includes a main body 4, an extension pipe 5, and a suction port body 6.

  The main body 4 includes a battery unit 7, an electric blower 8, a dust collecting container 9, a housing 10, a tube part 11, a handle 12, a charging convex part 13, and a first attaching / detaching button 14.

  The battery unit 7 is provided in the upper part of the main body 4.

  The electric blower 8 is configured to receive an electric power supply from the battery unit 7 and generate an air flow.

  The dust collecting container 9 is configured to collect dust sucked together with the air flow generated by the electric blower 8. The dust collecting container 9 has a cylindrical shape. The dust collection container 9 is provided at the lower part of the main body 4. The dust collecting container 9 is detachably provided on the main body 4.

  The housing 10 has a cylindrical shape. The housing 10 houses the battery unit 7 and the electric blower 8. The housing 10 is provided coaxially with the dust collection container 9. The outer diameter of the housing 10 is the same as the outer diameter of the dust container 9.

  The pipe part 11 extends vertically. The tube portion 11 is provided on the front surface of the housing 10. The space inside the tube portion 11 communicates with the space inside the dust collection container 9. The central axis of the pipe part 11 is parallel to the central axes of the dust collecting container 9 and the housing 10. The pipe part 11 is an example of a guide part.

  The handle 12 is provided on the upper front portion of the main body 4. The handle 12 is provided on an extension line of the central axis of the pipe part 11.

  The charging convex portion 13 is provided on the back surface of the tube portion 11. The charging convex portion 13 is provided below the dust collection container 9. The charging protrusion 13 is electrically connected to the battery unit 7.

  The first attachment / detachment button 14 is provided at the lower portion of the tube portion 11.

  The extension tube 5 has a tubular shape. The extension pipe 5 extends vertically. The extension pipe 5 has a second attach / detach button 15. The second detachable button 15 is provided on the lower front surface of the extension pipe 5. The upper end of the extension pipe 5 is detachably connected to the main body 4. The extension pipe 5 is provided coaxially with the pipe portion 11. The space inside the extension pipe 5 leads to the inside of the pipe part 11. The extension pipe 5 is released from the main body 4 by the first attaching / detaching button 14.

  The suction port body 6 is provided at the lower end of the electric vacuum cleaner 2. The suction port body 6 is detachably connected to the lower end of the extension pipe 5. The inside of the suction port body 6 leads to the inside of the extension pipe 5. The suction port body 6 has a suction port 6a. The suction port 6 a is provided on the lower surface of the suction port body 6. The suction port 6 a communicates with the inside of the suction port body 6. The suction port body 6 is released from the extension pipe 5 by the second attaching / detaching button 15.

  The charging stand 3 includes a pedestal 16 and a support column 17. The pedestal 16 is provided at the lower end of the charging stand 3. The pedestal 16 has a suction port housing portion 3d at the front. The support column 17 has a cylindrical shape. The support column 17 extends upward from the pedestal 16. The outer diameter of the support column 17 is the same as the outer diameter of the housing 10. The support column 17 has a support column recess 17a on the front side surface. The column 17 has a main body installation portion 18 at the upper end. The column 17 has a charging terminal recess 19 at the front part at the upper end. The support column 17 has a charging terminal 20. The charging terminal 20 is provided in the charging terminal recess 19.

  The vacuum cleaner 2 is detachably attached to the charging stand 3.

  As shown in FIG. 2, the electric vacuum cleaner 2 is attached to the charging stand 3 in an upright state. The main body 4 is connected to the upper end of the support column 17. The central axis of the housing 10 is connected coaxially with the central axis of the support column 17. The extension pipe 5 is fitted into the column recess 17a. The suction port body 6 is accommodated in the suction port body accommodating portion 3d. The charging terminal 20 is connected to the charging convex portion 13.

  The charging stand 3 is connected to an external power source via a power cable (not shown). The charging stand 3 supplies power to the vacuum cleaner 2 through the charging terminal 20. The battery unit 7 is charged by the electric power supplied to the vacuum cleaner 2.

  When using the electric vacuum cleaner 2, the user removes the electric vacuum cleaner 2 with the battery unit 7 charged from the charging stand 3. When using the vacuum cleaner 2, the user holds the handle 12 and directs the suction port 6 a of the suction port body 6 toward the surface to be cleaned. The user activates the vacuum cleaner 2. The vacuum cleaner 2 starts the operation of the electric blower 8 with the electric power charged in the battery unit 7. The electric blower 8 generates an air flow. The airflow flows into the suction port body 6 from the suction port 6a together with dust. The airflow flows into the extension pipe 5 from the inside of the suction port body 6. The airflow flows into the pipe portion 11 from the inside of the extension pipe 5. The airflow flows into the dust collecting container 9 from the inside of the pipe part 11. The dust collecting container 9 collects dust flowing in along with the airflow.

Subsequently, the configuration of the main body 4 will be described with reference to FIGS. 3 to 6.
FIG. 3 is a front view of the main body according to the first embodiment. FIG. 4 is a rear view of the main body according to the first embodiment. FIG. 5 is a side view of the main body according to the first embodiment. 6 is a cross-sectional view of the main body according to Embodiment 1 taken along the AA plane in FIG. 3 to 6, the vertical direction of the drawing is the vertical direction of the main body 4. 5 and 6, the left side of the drawing is the front direction of the main body 4.

  As shown in FIG. 3, the main body 4 includes an operation unit 21. The operation unit 21 is provided on the front surface of the main body 4. The operation unit 21 is, for example, an operation button.

  As shown in FIG. 4, the main body 4 includes a dust collection container attaching / detaching lever 22. The dust container attachment / detachment lever 22 is provided on the back surface of the main body 4. The dust container 9 is released from the main body 4 by the dust container attaching / detaching lever 22.

  As shown in FIG. 5, the main body 4 includes a first insertion terminal 23. The first insertion terminal 23 is provided at the front part of the lower end of the pipe part 11. The first insertion terminal 23 is electrically connected to the battery unit 7.

  As shown in FIG. 6, the electric blower 8 includes a fan 24 and a fan motor 25.

  The fan 24 is rotatably provided with the vertical direction as a rotation axis. The fan 24 is configured to generate an airflow by rotation.

  The fan motor 25 is connected to the fan 24 so that the fan 24 can be rotationally driven by the electric power charged in the battery unit 7. The fan motor 25 is a brushless motor.

  The brushless motor is a motor that switches the current flowing through the coil without using mechanical contact between the brush and the commutator. The brushless motor is a direct current motor, for example. The brushless motor detects the rotation angle of the rotor by a magnetic sensor, for example. In a brushless motor driven by an induced voltage method sensorless, the brushless motor detects the rotation angle of the rotor by an induced electromotive force generated in the coil as the rotor rotates. The brushless motor switches the current flowing through the coil by, for example, a semiconductor element according to the rotation angle of the rotor.

  The battery unit 7 includes a plurality of batteries 7a, a battery control board 7b, and a main body control board 7c.

  Each of the plurality of batteries 7a is a secondary battery. Each of the plurality of batteries 7a is, for example, a lithium ion battery. The battery control board 7b is mounted with an element that controls output voltages of the plurality of batteries 7a. The main body control board 7c is equipped with elements for controlling the operation of the fan motor 25 and the like.

  The main body control board 7c includes a plurality of connection connectors 7d. The plurality of connection connectors 7d are used when the main body control board 7c is connected to the operation unit 21, the charging terminal 20, the fan motor 25, and the like.

  The main body 4 has a first air inlet 26. The first air inlet 26 is provided at the lower end of the pipe portion 11.

  The main body 4 includes a separation device 27. The separation device 27 has an air path that guides the airflow along the circumferential direction of the dust collecting container 9. The separation device 27 is provided at the entrance of the dust collecting container 9.

  When using the vacuum cleaner 2, the user activates the vacuum cleaner 2 through the operation unit 21. The operation unit 21 transmits a control signal for activation to the main body control board 7c. The main body control board 7c starts the operation of the fan motor 25 by the electric power charged in the plurality of batteries 7a. The fan motor 25 drives the fan 24 to rotate. The fan 24 generates an air flow by rotation. The airflow generated by the fan 24 flows into the tube portion 11 from the first air inlet 26. The airflow flows into the separation device 27 from the entrance of the dust collecting container 9. The airflow is guided along the circumferential direction of the dust collecting container 9. The airflow forms a swirling flow. The dust flowing into the main body 4 together with the air current is separated from the air current by centrifugal force. Dust separated from the airflow is collected in the dust collecting container 9.

Then, the structure of the battery unit 7 is demonstrated using FIG. 7 and FIG.
7 is an exploded perspective view of the battery unit according to Embodiment 1. FIG. 8 is a perspective cross-sectional view of the battery unit according to Embodiment 1. FIG.

  As shown in FIG. 7, the battery unit 7 includes a holding body 7e, a partition 7f, a first battery case 7g, and a second battery case 7h.

  The holding body 7e includes a plurality of holding units. Each of the plurality of holding portions is made of resin. The number of holding parts is the same as the number of batteries 7a. The partition 7f is made of resin. The first battery case 7g is formed of resin. The second battery case 7h is made of resin.

  As shown in FIG. 8, the holding body 7e is provided between each of the plurality of batteries 7a and the battery control board 7b. Each of the plurality of holding portions of the holding body 7e holds each of the plurality of batteries 7a. The partition 7f is disposed between the battery control board 7b and the main body control board 7c. The first battery case 7g is arranged on one side in the direction in which the battery 7a, the control board, and the main body control board 7c are arranged. The second battery case 7h is disposed on the other side in the direction in which the battery 7a, the control board, and the main body control board 7c are arranged. The first battery case 7g and the second battery case 7h cover the battery 7a, the battery control board 7b, the main body control board 7c, the holding body 7e, and the partition 7f.

Then, the structure of the extension pipe | tube 5 is demonstrated using FIG.
FIG. 9 is a perspective view of the extension tube according to the first embodiment.

  The extension pipe 5 includes a first fitting portion 28, a first power supply pin 29, and a second insertion terminal 30. The first fitting portion 28 is provided at the end of the extension pipe 5 opposite to the second detachable button 15. The outer diameter of the first fitting portion 28 is smaller than the inner diameter of the first air inlet 26 of the main body 4. The first fitting portion 28 fits into the first air inlet 26 of the main body 4. The first power supply pin 29 is provided at the end of the extension pipe 5 on the same side as the first fitting portion 28. The first power supply pin 29 is electrically connected by being inserted into the first insertion terminal 23. The second plug-in terminal 30 is provided at the end of the extension pipe 5 opposite to the first power supply pin 29. The second plug-in terminal 30 is electrically connected to the first power supply pin 29. The extension pipe 5 has a second air inlet 31. The second intake port 31 communicates with the inside of the extension pipe 5. The second air inlet 31 is provided at the end of the extension pipe 5 on the same side as the second insertion terminal 30.

Then, the structure of the suction inlet body 6 is demonstrated using FIGS. 10-16.
FIG. 10 is an exploded perspective view of the suction port body according to the first embodiment. FIG. 11 is a perspective view of the suction port body according to the first embodiment. FIG. 12 is a side view of the suction port body according to the first embodiment. FIG. 13 is a bottom view of the suction port body according to the first embodiment. FIG. 14 is a cross-sectional view of the suction port body according to Embodiment 1 on the BB plane in FIG. 13. FIG. 15 is a cross-sectional view of the suction port body according to Embodiment 1 taken along the CC plane in FIG. 13. FIG. 16 is a top view of the suction port body according to the first embodiment.

  In FIG. 10, the vertical direction of the paper is the vertical direction of the suction port 6. In FIG. 10, the direction indicated by the arrow is the front-rear direction of the suction port body 6. In FIG. 10, the direction indicated by the arrow is the left-right direction of the suction port body 6.

  The suction port body 6 includes a case 32, a connecting pipe 33, a rotating brush 34, a brush driving unit 35, a transmission unit 36, and a control unit 37.

  The case 32 includes an upper cover 38, an upper case 39, a lower case 40, a pair of lower covers 41, and a bumper 42. The case 32 forms an outline of the suction port body 6. The upper cover 38 forms the upper surface of the case 32. The upper cover 38 has a rectangular shape when viewed from above. The upper cover 38 has a first notch 38a. The first notch 38 a is provided at the center in the longitudinal direction of the rear portion of the upper cover 38. The upper case 39 is provided below the upper cover 38. The upper case 39 has a second notch 39a. The second notch 39a is provided below the first notch 38a. The lower case 40 has a rectangular shape when viewed from above. The lower case 40 is provided below the upper case 39. Each of the pair of lower covers 41 is provided on the lower surface of the lower case 40. Each of the pair of lower covers 41 is provided at each of the left and right ends of the lower case 40. The bumper 42 is provided at the front portion of the lower case 40.

  The connecting pipe 33 has a tubular shape. The connecting pipe 33 extends in one direction. The connecting pipe 33 has a third air inlet 43. The third air inlet 43 communicates with the inside of the connection pipe 33. The third air inlet 43 is provided at the end of the connection pipe 33. The connection pipe 33 includes an elbow 44. The elbow 44 is provided at the end of the connection pipe 33 on the same side as the third intake port 43. The elbow 44 is held between the upper case 39 and the lower case 40. The elbow 44 is provided in the second notch 39a. The connection pipe 33 is held rotatably about the elbow 44.

  The rotating brush 34 has a shaft portion 45 and a plurality of cleaning bodies 46. The shaft portion 45 extends in one direction. The shaft portion 45 is held between each of the pair of lower covers 41 and the lower case 40. The shaft portion 45 is rotatably held. Each of the plurality of cleaning bodies 46 is provided on a side surface of the shaft portion 45. Each of the plurality of cleaning bodies 46 is provided in a spiral shape. Each of the plurality of cleaning bodies 46 is, for example, flocking.

  The brush drive unit 35 is a brushless motor. The brush drive unit 35 is configured to rotate the output shaft counterclockwise when viewed from the left side of the suction port body 6 when electric power is supplied.

  The transmission unit 36 includes a motor gear 47, a belt 48, and a rotating brush gear 49. The motor gear 47 is connected to the output shaft of the brush drive unit 35 so as to be driven to rotate. The belt 48 is wound around the motor gear 47 so as to circulate and move following the rotation of the motor gear 47. The rotating brush gear 49 is wound around the belt 48 so that the rotating brush gear 49 can rotate following the circulating movement of the belt 48. The diameter of the rotating brush gear 49 is larger than the diameter of the motor gear 47. The number of teeth of the rotating brush gear 49 is larger than the number of teeth of the motor gear 47. The rotating brush gear 49 is connected to the shaft portion 45 so that the rotating brush 34 can be driven.

  The control unit 37 includes a ground switch 52.

  As shown in FIG. 11, the connection pipe 33 includes a second fitting portion 50 and a second power supply pin 51.

  The second fitting portion 50 is provided at the end of the connection pipe 33 opposite to the elbow 44. The outer diameter of the second fitting portion 50 is smaller than the inner diameter of the first air inlet 26 of the main body 4. The second fitting portion 50 fits into the first air inlet 26 of the main body 4. The outer diameter of the second fitting portion 50 is smaller than the inner diameter of the second air inlet 31 of the extension pipe 5. The second fitting part 50 fits into the second air inlet 31 of the extension pipe 5.

  The second power supply pin 51 is provided at the end of the connecting pipe 33 on the same side as the second fitting portion 50. The second power supply pin 51 is electrically connected by being inserted into the first insertion terminal 23 of the main body 4. The second power supply pin 51 is electrically connected by being inserted into the second insertion terminal 30 of the extension pipe 5.

  As shown in FIG. 12, the ground switch 52 has wheels 53. The ground switch 52 protrudes downward from the lower surface of the lower case 40. The ground switch 52 is configured to be movable in the vertical direction. The ground switch 52 is pushed downward by a spring or the like. The ground switch 52 is configured to be moved upward by being pushed by the surface to be cleaned while resisting the elastic force of the spring when the suction port body 6 is grounded with the lower surface facing the surface to be cleaned. .

  As shown in FIG. 13, the lower case 40 has a pair of rear wheels 54 and a pair of front wheels 55. Each of the pair of rear wheels 54 is provided at the rear portion of the lower case 40. Each of the pair of rear wheels 54 is provided on each of the left and right sides of the connection pipe 33. Each of the pair of front wheels 55 is provided on the lower surface of the lower case 40. Each of the pair of front wheels 55 is provided at each of the left and right ends of the lower case 40. Each of the pair of front wheels 55 is provided outside the left and right sides of the suction port 6a. Each of the pair of front wheels 55 is provided in front of each of the pair of rear wheels 54. Each of the pair of front wheels 55 is provided behind the suction port 6a.

  As shown in FIG. 14, the rotating brush 34 is provided inside the case 32. Each of the plurality of cleaning bodies 46 protrudes downward from the suction port 6 a at any rotational position of the shaft portion 45.

  The connecting pipe 33 is provided behind the suction port 6a. The third air inlet 43 of the connection pipe 33 is provided in the space inside the case 32. The space inside the connecting pipe 33 communicates with the space inside the case 32.

  The suction port body 6 includes a detection unit 56. The detection unit 56 is provided inside the connection pipe 33 so that the amount of dust inside the connection pipe 33 can be detected. The detection unit 56 is, for example, a dust sensor.

  As shown in FIG. 15, the motor gear 47 is provided behind the rotating brush gear 49. The rotating shaft of the motor gear 47 is provided above the rotating shaft of the rotating brush gear 49.

  In FIG. 16, the upper cover 38 and the upper case 39 are not shown.

  The brush drive unit 35 is provided on the left side of the lower case 40. The brush drive unit 35 is provided on the left side of the elbow 44. The brush drive unit 35 is provided behind the rotating brush 34. The brush drive unit 35 is provided in front of the left rear wheel 54. The brush drive unit 35 is provided with the output shaft facing the left end of the suction port body 6. The brush drive unit 35 is electrically connected to the second power supply pin 51.

  The control unit 37 is provided on the right side of the lower case 40. The control unit 37 is provided on the right side of the elbow 44. The controller 37 is provided behind the rotating brush 34. The control unit 37 is provided in front of the right rear wheel 54.

  The control unit 37 includes a control board 57. The control board 57 mounts an element that controls the operation of the brush drive unit 35. Control of the operation of the brush drive unit 35 includes start and stop of rotation of the output shaft and control of the rotation speed of the output shaft. The rotational speed of the output shaft of the brush drive unit 35 is controlled by, for example, the magnitude of the current flowing through the coil of the brush drive unit 35 that is a brushless motor or the height of the applied voltage. The control board 57 mounts an element that detects the load of the brush drive unit 35. The load of the brush drive unit 35 is detected by, for example, the magnitude of the current flowing through the coil of the brush drive unit 35 that is a brushless motor. The control unit 37 is configured to stop the rotation of the output shaft of the brush drive unit 35 when the ground switch 52 is moving downward.

  The suction inlet 6 includes a plurality of lead wires (not shown). Some of the plurality of lead wires electrically connect the brush drive unit 35 and the control board 57. Another part of the plurality of lead wires electrically connects the detection unit 56 and the control board 57.

  The transmission unit 36 is provided at the left end of the lower case 40. The transmission unit 36 is provided on the left side of the rotating brush 34. The transmission unit 36 is provided on the left side of the brush drive unit 35. The transmission 36 is provided on the left side of the suction port 6a.

  The brush drive unit 35, the control unit 37, and the transmission unit 36 are covered from above by an upper case 39 not shown in FIG.

  Then, operation | movement of the vacuum cleaner 2 is demonstrated.

  When cleaning a surface to be cleaned such as a floor surface, the vacuum cleaner 2 is used in a state in which the main body 4, the extension pipe 5, and the suction port body 6 are connected. The second fitting portion 50 of the suction port body 6 is fitted into the second suction port 31 of the extension pipe 5. The second power supply pin 51 of the suction port body 6 is connected to the second insertion terminal 30 of the extension pipe 5. The first fitting portion 28 of the extension pipe 5 is fitted into the first air inlet 26 of the main body 4. The first power supply pin 29 of the extension pipe 5 is connected to the first insertion terminal 23 of the main body 4.

  The user activates the vacuum cleaner 2. A plurality of battery units 7 are connected from the second power supply pin 51 to the suction port 6 through the first insertion terminal 23 of the main body 4 and the first power supply pin 29 and the second insertion terminal 30 of the extension pipe 5. The battery 7a is supplied with charged electric power. The electric power supplied to the suction port body 6 is supplied to the brush drive unit 35. That is, the battery 7 a supplies power to the brush drive unit 35. The user grounds the lower surface of the suction port body 6 toward the surface to be cleaned such as the floor surface. The ground switch 52 moves upward while resisting the elastic force of the spring. The control board 57 detects the movement of the ground switch 52. The control board 57 starts rotating the output shaft of the brush drive unit 35.

  The motor gear 47 is driven to rotate by the output shaft of the brush drive unit 35. The belt 48 circulates following the rotation of the motor gear 47. The rotating brush gear 49 rotates following the circulating movement of the belt 48. Since the diameter of the rotating brush gear 49 is larger than the diameter of the motor gear 47, the transmission unit 36 converts the input rotation into rotation with a larger torque. The rotating brush gear 49 rotates the shaft portion 45 of the rotating brush 34.

  The shaft 45 is driven by the rotating brush gear 49 and rotates. Each of the plurality of cleaning bodies 46 rotates following the shaft portion 45. Each of the plurality of cleaning bodies 46 contacts the surface to be cleaned from the front toward the rear by rotation. Dust on the surface to be cleaned is swept up by each of the plurality of cleaning bodies 46. The dust that has been lifted up flows into the suction port body 6 along with the air flow generated by the electric blower 8. The suction port body 6 receives a force directed forward from the surface to be cleaned by each of the plurality of cleaning bodies 46. By this force, the user obtains a self-propelled feeling of the suction port body 6.

  The control board 57 detects the load of the brush drive unit 35. The load of the brush drive part 35 changes with the types of surfaces to be cleaned, for example. For example, when the surface to be cleaned is a carpet, the load on the brush drive unit 35 is large. For example, when the surface to be cleaned is flooring, the load on the brush drive unit 35 is small. When the load detected by the control board 57 is larger than a predetermined load threshold, the control board 57 increases the rotation speed of the output shaft of the brush drive unit 35. When the load detected by the control board 57 is smaller than a predetermined load threshold, the control board 57 reduces the rotation speed of the output shaft of the brush drive unit 35.

  The detection unit 56 detects the amount of dust flowing into the suction port body 6. When the amount of dust detected by the detection unit 56 is greater than a predetermined value, the control board 57 increases the rotation speed of the output shaft of the brush drive unit 35. When the amount of dust detected by the detection unit 56 is smaller than a predetermined value, the control board 57 decreases the rotation speed of the output shaft of the brush drive unit 35.

  When the electric vacuum cleaner 2 is shortened and used for cleaning the user's hand, the electric vacuum cleaner 2 is used in a state where the main body 4 and the suction port body 6 are connected. The second fitting portion 50 of the suction port body 6 is fitted to the first suction port 26 of the main body 4. The second power supply pin 51 of the suction port body 6 is connected to the first insertion terminal 23 of the main body 4. The battery unit 7 supplies power from the second power supply pin 51 to the suction port 6 through the first insertion terminal 23 of the main body 4.

  As described above, the vacuum cleaner 2 according to Embodiment 1 includes the fan 24, the fan motor 25, the dust collecting container 9, and the suction port body 6. The fan 24 generates an air flow by rotation. The fan motor 25 drives the fan 24 to rotate. The dust collecting container 9 collects dust sucked from the outside by an air flow. The suction port body 6 sucks the airflow from the suction port 6a.

  The suction port body 6 includes a case 32, a rotating brush 34, a connecting pipe 33, a control unit 37, and a brush driving unit 35. The case 32 forms an outline of the suction port body 6. The case 32 has a suction port 6a communicating with the inside on the lower surface. The rotating brush 34 is rotatably provided inside the case 32. A part of the rotating brush 34 protrudes from the suction port 6a. The connecting pipe 33 is provided behind the suction port 6a. The connection pipe 33 communicates with the interior of the case 32 in the interior space. The control unit 37 is provided on one side of the connecting pipe 33 in the left-right direction behind the rotating brush 34. The brush drive unit 35 is a brushless motor. The brush drive unit 35 is provided on the other side in the left-right direction of the connecting pipe 33 behind the rotating brush 34. The brush drive unit 35 is controlled by the control unit 37 to rotate the output shaft. The brush driving unit 35 rotationally drives the rotating brush 34 by the rotation of the output shaft.

  The brush drive unit 35 is a lightweight brushless motor. For this reason, the suction inlet body 6 becomes lightweight. The brush drive unit 35 is provided outside the rotating brush 34. For this reason, the diameter of the rotating brush 34 becomes small. Therefore, the suction port body 6 is lightweight by suppressing the increase in diameter of the rotating brush 34 while obtaining torque for rotating the rotating brush 34.

  The rotating brush 34 is prevented from increasing in diameter. For this reason, the height of the front part of the suction inlet body 6 becomes low. The suction inlet 6 becomes easy to enter a narrower gap. Thereby, the vacuum cleaner 2 becomes easy to use. The brush drive unit 35 is provided behind the rotary brush 34. For this reason, even when the diameter of the brush drive part 35 is made larger in order to obtain a larger torque, the height of the front part of the suction port body 6 does not increase.

  Each of the control unit 37 and the brush drive unit 35 is provided on each of the left and right sides of the connection pipe 33. The brush drive unit 35 is a lightweight brushless motor. For this reason, the left and right weight balance of the suction port body 6 is improved.

  In addition, the suction port body 6 includes a transmission unit 36. The transmission unit 36 converts the input rotation into a rotation having a larger torque than the rotation and outputs the converted rotation. The brush drive unit 35 inputs the rotation of the output shaft to the transmission unit. The brush drive unit 35 rotationally drives the rotary brush 34 by the rotation output from the transmission unit 36.

  The output torque of the brushless motor is small. On the other hand, the rotation speed of the brushless motor is large. The brush drive unit 35 can drive the rotating brush 34 with a larger torque by the transmission unit 36. The force which the suction inlet body 6 receives from a to-be-cleaned surface by each of the some cleaning body 46 becomes larger. The user can obtain a stronger sense of self-running of the suction port body 6. Thereby, the user can use the vacuum cleaner 2 more comfortably.

  Further, the control unit 37 detects the load of the brush drive unit 35. The control unit 37 increases the rotation speed of the output shaft of the brush drive unit 35 when the detected load is larger than a predetermined load. The control unit 37 reduces the rotation speed of the output shaft of the brush drive unit 35 when the detected load is smaller than a predetermined load.

  The control unit 37 controls the rotation speed of the rotary brush 34 by controlling the rotation speed of the output shaft in accordance with the load of the brush drive unit 35. The controller 37 does not rotate the rotating brush 34 at an unnecessarily high rotational speed. For this reason, the electric power consumed by the brush drive part 35 is reduced. The brushless motor can easily control the rotation speed by controlling the voltage applied to the coil. Thereby, the vacuum cleaner 2 can use electric power efficiently without requiring a complicated configuration for controlling the rotation speed.

  The suction port body 6 includes a detection unit 56. The detection unit 56 detects the amount of dust inside the connection pipe 33.

  Brushless motors do not generate commutation because there is no commutator. The detection unit 56 for detecting the amount of sucked dust does not erroneously detect the amount of dust sucked by wear powder.

  Further, the control unit 37 increases the rotation speed of the output shaft of the brush drive unit 35 when the amount of dust detected by the detection unit 56 is greater than a predetermined threshold value. The control unit 37 reduces the rotation speed of the output shaft of the brush drive unit 35 when the amount of dust detected by the detection unit 56 is smaller than a predetermined threshold value.

  When the amount of dust on the surface to be cleaned is small, the amount of dust sucked is small. When the amount of dust on the surface to be cleaned is large, the amount of dust sucked increases. The control unit 37 controls the rotation speed of the rotary brush 34 by controlling the rotation speed of the output shaft in accordance with the amount of dust sucked. The controller 37 does not rotate the rotating brush 34 at an unnecessarily high rotational speed. For this reason, the electric power consumed by the brush drive part 35 is reduced. The brushless motor can easily control the rotation speed by controlling the voltage applied to the coil. Thereby, the vacuum cleaner 2 can use electric power efficiently without requiring a complicated configuration for controlling the rotation speed.

  The fan motor 25 is a brushless motor.

  Brushless motors have a long life because there are no commutators to wear out. When one of the brush drive unit 35 and the fan motor 25 reaches the end of its life, the vacuum cleaner 2 reaches the end of its life. Here, both the brush drive unit 35 and the fan motor 25 are brushless motors. For this reason, the lifetime as the whole vacuum cleaner 2 becomes long.

  Moreover, the vacuum cleaner 2 includes a battery 7a which is a secondary battery. The battery 7 a supplies power to the brush drive unit 35.

  The vacuum cleaner 2 can be used continuously while the power charged in the secondary battery is available. Brushless motors are highly efficient. The vacuum cleaner 2 can be used continuously for a long time.

  The controller 37 does not rotate the rotating brush 34 at an unnecessarily high rotational speed. For this reason, the electric power consumed by the brush drive part 35 is reduced. Thereby, the time which can be continuously used for the vacuum cleaner 2 becomes longer.

The vacuum cleaner 2 includes a tube portion 11 and an extension tube 5.
The pipe part 11 guides the airflow to the dust collecting container 9. One end of the extension tube 5 is detachable from the tube portion 11. The extension pipe 5 guides the airflow to the pipe section 11. The suction port body 6 can be attached to and detached from both the other end of the extension pipe 5 and the pipe portion 11.

  The suction inlet body 6 can be used in a flexible usage pattern according to the surface to be cleaned by the user.

  Further, the transmission unit 36 transmits the rotation by the belt 48. The transmission unit 36 does not generate a sound of direct meshing of gears. Thereby, the sound at the time of driving | operation of the vacuum cleaner 2 becomes small.

  The brush drive unit 35 may be a brushless motor driven by an induced voltage type sensorless. The brushless motor detects the rotation angle of the rotor without using a magnetic sensor. For this reason, the lead wire which communicates the signal from a magnetic sensor among the some lead wires which connect the control part 37 and the brush drive part 35 becomes unnecessary. That is, the number of lead wires can be reduced. Thereby, the manufacturability of the suction port body 6 is improved.

  The brush drive unit 35 may be an inner rotor type brushless motor. The brush drive unit 35 is configured more compactly.

The number of phases of the brush drive unit 35 is preferably three or more. In particular, in the case of a brushless motor driven by an induced voltage type sensorless, it is easy to detect the rotation angle of the rotor. The number of coils of the brush drive unit 35 is preferably three or more. The number of poles of the brush drive unit 35 is preferably two or more. The brush drive unit 35 may be an 8-pole 3-phase 6-coil brushless motor. In this case, the cogging torque of the brushless motor is reduced.

  The detection unit 56 may be provided in a space inside the case 32. At this time, the detection unit 56 detects the amount of dust inside the case 32. The detection unit 56 may be provided inside the extension tube 5 or the main body 4.

  The transmission unit 36 may transmit rotation with a pulley instead of the gear. The transmission unit 36 may transmit rotation using a chain instead of the belt. The transmission unit 36 may transmit rotation using a gear, a pulley, a belt, a chain, and the like together.

Subsequently, a modification of the first embodiment will be described with reference to FIG.
FIG. 17 is a perspective view of a vacuum cleaner according to a modification of the first embodiment.

  The vacuum cleaner 2 is a canister type.

  The main body 4 includes a connection portion 4a. The space inside the connecting portion 4a leads to the inside of the dust collecting container 9. The connection part 4a is an example of a guide part. The main body 4 moves on the surface to be cleaned. The main body 4 has moving wheels.

  The extension pipe 5 has a hose 5a and a pipe 5b. The hose 5a is flexible due to the bellows. The hose 5 a constitutes an end portion of the extension pipe 5 on the side connected to the suction port body 6. The pipe 5b has a tubular shape. The pipe 5 b constitutes an end portion of the extension pipe 5 on the side connected to the main body 4. The pipe 5 b is connected to the connection portion 4 a of the main body 4.

  The handle 12 is provided on the pipe 5b. The operation unit 21 is provided in the pipe 5b.

  The suction port 6 can also be used in the canister type vacuum cleaner 2.

Embodiment 2. FIG.
In this embodiment, differences from the example disclosed in Embodiment 1 will be described in detail. For features not described in the present embodiment, any of the features disclosed in the first embodiment may be employed.

The configuration of the transmission unit 36 will be described with reference to FIG.
FIG. 18 is a configuration diagram of the transmission unit according to the second embodiment.

  The transmission unit 36 includes a motor gear 47, an intermediate gear 58, a first belt 48 a, a second belt 48 b, and a rotating brush gear 49. The intermediate gear 58 includes a large diameter gear 58a and a small diameter gear 58b. The large diameter gear 58a is provided coaxially with the small diameter gear 58b. The first belt 48 a is wound around the motor gear 47 so that it can circulate and follow the rotation of the motor gear 47. The first belt 48a is wound around the large-diameter gear 58a so as to be able to rotate following the circulating movement of the first belt 48a. The small diameter gear 58b is formed integrally with the large diameter gear 58a. The second belt 48b is wound around the small diameter gear 58b so that it can circulate and follow the rotation of the small diameter gear 58b. The second belt 48b is wound around the rotating brush gear 49 so that the rotating brush gear 49 can rotate following the circulating movement of the second belt 48b.

  The diameter of the large diameter gear 58 a is larger than the diameter of the motor gear 47. The diameter of the small diameter gear 58b is smaller than the diameter of the large diameter gear 58a. The diameter of the rotating brush gear 49 is larger than the diameter of the small diameter gear 58b.

  The number of teeth of the large diameter gear 58 a is larger than the number of teeth of the motor gear 47. The number of teeth of the small diameter gear 58b is smaller than the number of teeth of the large diameter gear 58a. The number of teeth of the rotating brush gear 49 is larger than the number of teeth of the small diameter gear 58b.

  The reduction ratio of the intermediate gear 58 is the reduction ratio between the large diameter gear 58a and the small diameter gear 58b. That is, the ratio of the number of teeth or the diameter of the large diameter gear 58a and the small diameter gear 58b.

Subsequently, rotation conversion by the transmission unit 36 will be described with reference to FIGS. 19 to 21.
FIG. 19 is a table showing rotation conversion by the transmission unit according to the second embodiment. FIG. 20 is a diagram illustrating the relationship between the output torque and the rotation speed of the brush drive unit according to the second embodiment. FIG. 21 is a diagram illustrating the relationship between the output torque and the rotation speed of the rotating brush according to the second embodiment.

  In FIG. 19, the rotation speed and output torque of a general brushless motor and commutator motor are shown. The rotation speed of the brushless motor at no load is 30363 rpm. The output torque of the brushless motor when locked is 58 mNm. The rotation speed of the commutator motor at no load is 10800 rpm. The output torque of the commutator motor when locked is 92 mNm.

  In this example, the motor gear 47 has 12 teeth. The number of teeth of the rotating brush gear 49 is 33. The reduction ratio of the intermediate gear 58 is 0.37 or more and 0.62 or less. The overall reduction ratio is a reduction ratio between the brush drive unit 35 and the rotating brush 34. When the intermediate gear 58 is not used, the overall reduction ratio is 0.36.

  When the intermediate gear 58 is not used, the rotational speed of the rotating brush 34 driven by the brushless motor is 11041 rpm. In this case, the output torque of the rotating brush 34 driven by the brush drive unit 35 is 160 mNm.

  When the intermediate gear 58 having a reduction ratio of 0.62 is used, the rotational speed of the rotating brush 34 driven by the brushless motor is 6845 rpm. In this case, the output torque of the rotating brush 34 is 257 mNm. At this time, the overall reduction ratio is 0.23.

  When the intermediate gear 58 having a reduction ratio of 0.37 is used, the rotational speed of the rotating brush 34 driven by the brushless motor is 4085 rpm. In this case, the output torque of the rotating brush 34 is 431 mNm. At this time, the overall reduction ratio is 0.13.

  When the intermediate gear 58 is not used, the rotational speed of the rotating brush 34 driven by the commutator motor instead of the brushless motor is 3927 rpm. In this case, the output torque of the rotating brush 34 is 253 mNm.

  In FIG. 20, the rotation speed and output torque of a general brushless motor and commutator motor are shown. The horizontal axis represents the output torque of the motor. The vertical axis represents the rotational speed of the motor.

  A round marker represents a brushless motor. The triangular marker represents the commutator motor.

  The rotation speed of the brushless motor at no load is larger than the rotation speed of the commutator motor at no load. On the other hand, the output torque when the brushless motor is locked is smaller than the output torque when the commutator motor is locked.

  In FIG. 21, the rotational speed and output torque of the rotating brush 34 are shown. The horizontal axis represents the output torque of the rotating brush 34. The vertical axis represents the rotational speed of the rotating brush 34.

  The round marker represents the rotating brush 34 driven by a brushless motor when the intermediate gear 58 is not used. The triangular marker represents the rotating brush 34 driven by a brushless motor when using an intermediate gear 58 with a reduction ratio of 0.62. The square marker represents the rotating brush 34 driven by the brushless motor when the intermediate gear 58 having a reduction ratio of 0.37 is used. The inverted triangular marker represents the rotating brush 34 driven by the commutator motor when the intermediate gear 58 is not used.

  If the reduction ratio of the intermediate gear 58 is 0.37 or more, the rotational speed of the rotating brush 34 at no load is 4000 rpm or more. If the reduction ratio of the intermediate gear 58 is 0.62 or less, the output torque of the rotating brush 34 at the time of locking is 253 mNm or more.

  When the electric vacuum cleaner 2 is used, the motor gear 47 is driven by the output shaft of the brush drive unit 35 and rotates. The first belt 48 a circulates following the rotation of the motor gear 47. The large diameter gear 58a rotates following the circulating movement of the first belt 48a. The reduction ratio of the intermediate gear 58 is not less than 0.37 and not more than 0.62. The small diameter gear 58b rotates integrally with the large diameter gear 58a. The second belt 48b circulates following the rotation of the small diameter gear 58b. The rotating brush gear 49 rotates following the circulating movement of the second belt 48b. The rotating brush gear 49 rotates the shaft portion 45 of the rotating brush 34.

  As described above, the transmission unit 36 converts the rotational torque input from the brush drive unit 35. The rotation speed of the rotating brush 34 at no load is 4000 rpm or more. The output torque of the rotating brush 34 when locked is 253 mNm or more.

  When the rotational speed of the rotating brush 34 is 4000 rpm or more, the frequency with which the rotating brush 34 comes into contact with the surface to be cleaned is more than the frequency with which the commutator motor is driven. For this reason, the dust on the surface to be cleaned is more easily swept up. When the output torque of the rotary brush 34 is 253 mNm or more, the magnitude of the forward force that the suction port body 6 receives from the surface to be cleaned is greater than the magnitude of the force when driven by the commutator motor. . For this reason, the user can easily obtain a sense of self-running of the suction port body 6. Therefore, the user can use the vacuum cleaner 2 more comfortably.

Subsequently, a modification of the second embodiment will be described with reference to FIG.
FIG. 22 is a configuration diagram of a transmission unit according to a modification of the second embodiment.

  The transmission unit 36 includes a motor gear 47, an intermediate gear 58, a belt 48, and a rotating brush gear 49. The large-diameter gear 58a meshes directly with the motor gear 47 so that it can rotate following the rotation of the motor gear 47. The belt 48 is wound around the small diameter gear 58b so that the belt 48 can circulate and move following the rotation of the small diameter gear 58b. The rotating brush gear 49 is wound around the belt 48 so that the rotating brush gear 49 can rotate following the circulating movement of the belt 48.

  The brush drive unit 35 is configured to rotate the output shaft clockwise as viewed from the left side of the suction port body 6 when electric power is supplied.

  In the transmission 36, the motor gear 47 and the large diameter gear 58a are directly meshed with each other. Thereby, the distance between the rotating shafts of a gear becomes small. For this reason, the speed change part 36 becomes compact. Therefore, the suction inlet body 6 becomes compact.

Subsequently, another modification of the second embodiment will be described with reference to FIG.
FIG. 23 is a configuration diagram of a transmission unit according to a modification of the second embodiment.

  The transmission unit 36 includes a motor gear 47, a reverse gear 59, an intermediate gear 58, a belt 48, and a rotating brush gear 49. The reversing gear 59 meshes directly with the motor gear 47 so that it can rotate following the rotation of the motor gear 47. The large-diameter gear 58a meshes directly with the reversing gear 59 so as to be able to rotate following the rotation of the reversing gear 59. The belt 48 is wound around the small diameter gear 58b so that the belt 48 can circulate and move following the rotation of the small diameter gear 58b. The rotating brush gear 49 is wound around the belt 48 so that the rotating brush gear 49 can rotate following the circulating movement of the belt 48.

  The brush drive unit 35 is configured to rotate the output shaft counterclockwise when viewed from the left side of the suction port body 6 when electric power is supplied.

  By using the reversing gear 59, the direction of rotation caused by the meshing of the gears can be reversed.

Subsequently, another modification of the second embodiment will be described with reference to FIG.
FIG. 24 is a configuration diagram of a transmission unit according to a modification of the second embodiment.

  The transmission unit 36 includes a motor gear 47, an intermediate gear 58, a belt 48, and a rotating brush gear 49. The belt 48 is wound around the motor gear 47 so as to circulate and move following the rotation of the motor gear 47. The large-diameter gear 58a is wound around the belt 48 so that the large-diameter gear 58a can rotate following the circulating movement of the belt 48. The rotating brush gear 49 meshes directly with the small diameter gear 58b so as to be able to rotate following the rotation of the small diameter gear 58b.

  The large diameter gear 58a is provided on the opposite side of the rotating brush 34 with respect to the small diameter gear 58b. That is, the large diameter gear 58a is provided on the left side of the small diameter gear 58b.

  The brush drive unit 35 is configured to rotate the output shaft clockwise as viewed from the left side of the suction port body 6 when electric power is supplied.

  In the transmission unit 36, the small diameter gear 58b and the rotating brush gear 49 are directly meshed with each other. Thereby, the distance between the rotating shafts of a gear becomes small. For this reason, the speed change part 36 becomes compact. Therefore, the suction inlet body 6 becomes compact.

  Since the large-diameter gear 58a is provided on the opposite side of the rotating brush 34 with respect to the small-diameter gear 58b, the large-diameter gear 58a contacts the rotating brush 34 and does not interfere.

Embodiment 3 FIG.
In this embodiment, differences from the example disclosed in Embodiment 1 or Embodiment 2 will be described in detail. As features not described in the present embodiment, any of the features disclosed in the first embodiment or the second embodiment may be employed.

The configuration of the transmission unit 36 will be described with reference to FIG.
FIG. 25 is a configuration diagram of a transmission unit according to the third embodiment.

  The transmission unit 36 includes a motor gear 47, an intermediate gear 58, and a rotating brush gear 49. The large diameter gear 58a meshes directly with the motor gear 47 so that it can rotate following the circulating movement of the motor gear 47. The rotating brush gear 49 meshes directly with the small diameter gear 58b so as to be able to rotate following the rotation of the small diameter gear 58b.

  The large diameter gear 58a is provided on the opposite side of the rotating brush with respect to the small diameter gear 58b. That is, the large diameter gear 58a is provided on the left side of the small diameter gear 58b.

  The brush drive unit 35 is configured to rotate the output shaft clockwise as viewed from the left side of the suction port body 6 when electric power is supplied.

  As described above, the transmission unit 36 converts the input rotation and outputs it by directly meshing the motor gear 47, the large diameter gear 58a, the small diameter gear 58b, and the rotating brush gear 49 with different numbers of teeth.

  The transmission unit 36 does not use a belt to transmit rotation. In the transmission 36, the motor gear 47 and the large diameter gear 58a are directly meshed with each other. In the transmission unit 36, the small diameter gear 58b and the rotating brush gear 49 are directly meshed with each other. Thereby, the distance between the rotating shafts of the plurality of gears becomes smaller. Therefore, the transmission unit 36 becomes more compact.

Embodiment 4 FIG.
In the present embodiment, differences from any of the examples disclosed in the first to third embodiments will be described in detail. As features not described in the present embodiment, any of the features disclosed in the first to third embodiments may be employed.

The configuration of the transmission unit 36 will be described with reference to FIG.
FIG. 26 is a configuration diagram of a transmission unit according to the fourth embodiment. In FIG. 26, the speed change part 36 of the suction inlet body 6 in a state where the lower surface faces the horizontal plane is shown.

  The transmission unit 36 includes a motor gear 47, an intermediate gear 58, a first belt 48 a, a second belt 48 b, and a rotating brush gear 49. The first belt 48 a is wound around the motor gear 47 so that it can circulate and follow the rotation of the motor gear 47. The first belt 48a is wound around the large-diameter gear 58a so as to be able to rotate following the circulating movement of the first belt 48a. The small diameter gear 58b is formed integrally with the large diameter gear 58a. The second belt 48b is wound around the small diameter gear 58b so that it can circulate and follow the rotation of the small diameter gear 58b. The second belt 48b is wound around the rotating brush gear 49 so that the rotating brush gear 49 can rotate following the circulating movement of the second belt 48b.

  The outer diameter of the brush drive unit 35 is smaller than the outer diameter of the rotating brush 34.

  The upper limit of the rotating brush 34 is the highest position among the positions of the upper ends of the cleaning body 46 at all the rotational positions of the shaft portion 45. The lower limit of the rotating brush 34 is the lowest position among the positions of the lower ends of the cleaning body 46 at all the rotation positions of the shaft portion 45.

  The first plane U passes through the upper limit of the rotating brush 34. The first plane U is perpendicular to the vertical direction. The second plane L passes through the lower limit of the rotating brush 34. The second plane L is parallel to the first plane.

  The brush drive unit 35 is provided below the first plane U. The brush drive unit 35 is provided above the second plane L.

  The diameter of the large diameter gear 58 a is smaller than the outer diameter of the rotating brush 34. The outer diameter of the rotating brush gear 49 is smaller than the outer diameter of the rotating brush 34.

  The transmission unit 36 is provided below the first plane U. The transmission unit 36 is provided above the second plane L.

  As described above, the brush drive unit 35 is provided below the first plane U and above the second plane L. The transmission unit 36 is provided below the first plane U and above the second plane L.

  The transmission unit 36 and the brush drive unit 35 do not exceed the upper limit of the rotating brush 34. For this reason, the height of the suction inlet 6 becomes low. The suction port body 6 is easy to enter to the back by a narrower gap. The transmission unit 36 and the brush drive unit 35 do not exceed the lower limit of the rotating brush 34. For this reason, the transmission unit 36 and the brush drive unit 35 do not contact the surface to be cleaned. Thereby, the vacuum cleaner 2 becomes easy to use.

  DESCRIPTION OF SYMBOLS 1 Vacuum cleaner unit, 2 Vacuum cleaner, 3 Charging stand, 3d Suction port housing part, 4 Main body, 4a Connection part, 5 Extension pipe, 5a Hose, 5b Pipe, 6 Suction port body, 6a Suction port, 7 Battery unit 7a battery, 7b battery control board, 7c main body control board, 7d connection connector, 7e holder, 7f partition, 7g first battery case, 7h second battery case, 8 electric blower, 9 dust collecting container, 10 housing , 11 tube portion, 12 handle, 13 charging convex portion, 14 first attaching / detaching button, 15 second attaching / detaching button, 16 base, 17 strut, 17a strut concave portion, 18 main body installation portion, 19 charging terminal concave portion, 20 charging terminal, Operation unit, 22 Dust collection container attaching / detaching lever, 23 First insertion terminal, 24 Fan, 25 Fan mode 26, first intake port, 27 separator, 28 first fitting portion, 29 first power supply pin, 30 second plug terminal, 31 second intake port, 32 case, 33 connecting pipe, 34 rotating brush, 35 brush drive unit, 36 transmission unit, 37 control unit, 38 upper cover, 38a first notch, 39 upper case, 39a second notch, 40 lower case, 41 lower cover, 42 bumper, 43 third intake port, 44 elbow, 45 shaft portion, 46 cleaning body, 47 motor gear, 48 belt, 48a first belt, 48b second belt, 49 rotating brush gear, 50 second fitting portion, 51 second power supply pin, 52 ground switch, 53 wheels, 54 rear wheels, 55 front wheels, 56 detection unit, 57 control board, 58 intermediate gear, 5 a large diameter gear, 58b small-diameter gear, 59 reversing gear

Claims (12)

A case having an outer shell and a suction port on the lower surface leading to the inside;
A rotating brush that is rotatably provided in the case and partially protrudes from the suction port;
A connecting pipe which is provided behind the suction port and whose internal space leads to the inside of the case;
A controller provided on one side of the connecting pipe in the left-right direction behind the rotating brush;
A brushless motor, which is provided on the other side of the connecting pipe in the left-right direction behind the rotating brush, and whose rotation is controlled by the control unit, and which rotates the rotating brush by the rotation of the output shaft. And
A suction port body comprising: A transmission that converts the input rotation to rotation with a torque larger than the rotation and outputs the rotation,
The suction port body according to claim 1, wherein the brush drive unit inputs rotation of the output shaft to the transmission unit and rotationally drives the rotary brush by rotation output from the transmission unit.   The transmission unit converts and outputs an input rotation so that the rotation speed of the rotating brush when no load is 4000 rpm or more and the output torque of the rotating brush when locked is 253 mNm or more. The suction inlet according to claim 2.   The suction port body according to claim 2 or 3, wherein the transmission unit converts and outputs an input rotation when a plurality of gears having different numbers of teeth are directly meshed with each other. The brush drive unit is provided below the first plane that passes through the upper limit of the rotating brush and is perpendicular to the vertical direction, and above the second plane that passes through the lower limit of the rotating brush and is parallel to the first plane,
The suction port body according to any one of claims 2 to 4, wherein the transmission unit is provided below the first plane and above the second plane.   The suction port body according to any one of claims 1 to 5, wherein the control unit detects a load of the brush drive unit and varies a rotation speed according to the detected load. The suction port body according to any one of claims 1 to 6, further comprising a detection unit that detects an amount of dust inside the case or the connection pipe.   The suction port body according to claim 7, wherein the control unit varies a rotation speed in accordance with an amount of dust detected by the detection unit. A fan that generates airflow by rotation,
A fan motor for rotating the fan;
A dust collection container for collecting dust sucked from the outside by the airflow;
The suction port body according to any one of claims 1 to 8, wherein the air flow is sucked from a suction port;
Electric vacuum cleaner.   The vacuum cleaner according to claim 9, wherein the fan motor is a brushless motor. The vacuum cleaner according to claim 9 or 10, further comprising a secondary battery that supplies electric power to the brush drive unit. A guide for guiding the airflow to the dust collecting container;
One end is detachable from the guide part, and an extension pipe for guiding the airflow to the guide part;
With
The vacuum cleaner according to any one of claims 9 to 11, wherein the suction port body is attachable to and detachable from both the other end of the extension pipe and the guide portion.

Images