JP2019166258A - Suction tool and vacuum cleaner - Google Patents

Abstract

To provide a suction tool 4 and a vacuum cleaner 1 capable of more surely transporting charged particles negatively electrically charged, to a surface to be cleaned.SOLUTION: A suction tool 4 comprises a case 29, a connection pipe 11, a discharge device 31, and a negative electric charge supply part 30. The case 29 forms a contour of the suction tool 4. The case 29 has a suction chamber 26 therein. The case 29 has, on a lower surface thereof, a suction hole 10 communicated to the suction chamber 26. The connection pipe 11 is provided on a rear side of the suction hole 10, and the connection pipe 11 has an inner space communicated to inside of the case 29. The discharge device 31 generates charged particles negatively electrically charged. The negative electric charge supply part 30 has a supply hole 30a on a front end of the suction chamber 26. The supply hole 30a is opened to the suction hole 10. The negative electric charge supply part 30 supplies the charged particles from the supply part 30a to the suction chamber 26.SELECTED DRAWING: Figure 10

Description

  The present invention relates to a suction tool and a vacuum cleaner.

  Patent Document 1 describes an example of a vacuum cleaner. The vacuum cleaner includes an electric blower and a suction tool. The electric blower generates an air flow. The suction tool includes an ion generator. The ion generator generates ions having a positive or negative charge toward the surface to be cleaned. The vacuum cleaner sucks the dust on the surface to be cleaned, which has been electrically neutralized, from the suction tool together with the airflow.

JP-A-5-253148

  However, in the electric vacuum cleaner of patent document 1, depending on arrangement | positioning of an ion generating part, before an ion is supplied to a to-be-cleaned surface, it may be attracted | sucked with an airflow.

  The present invention has been made to solve such problems. An object of the present invention is to provide a suction tool and a vacuum cleaner that can more reliably deliver negatively charged charged particles to a surface to be cleaned.

  The suction tool according to the present invention has an outer case, has a suction chamber inside, a case having a suction port leading to the suction chamber on a lower surface, and a rear side of the suction port, and an internal space leads to the inside of the case A connecting tube, a discharge device for generating negatively charged charged particles, a negative charge supply unit having a supply port that opens toward the suction port at the front end of the suction chamber, and supplying charged particles from the supply port to the suction chamber; .

  An electric vacuum cleaner according to the present invention includes an electric blower that generates an air flow that sucks dust from the outside, a dust collection unit that collects the dust, and the suction tool that sucks the air flow from a suction port. .

  According to the present invention, the suction tool includes a case, a connecting tube, a discharge device, and a negative charge supply unit. The case has an outer shell, has a suction chamber inside, and has a suction port communicating with the suction chamber on the lower surface. The connecting pipe is provided behind the suction port, and an internal space communicates with the inside of the case. The discharge device generates negatively charged charged particles. The negative charge supply unit has a supply port that opens toward the suction port at the front end of the suction chamber. The negative charge supply unit supplies charged particles to the suction chamber from the supply port. As a result, the suction tool can more reliably deliver negatively charged charged particles to the surface to be cleaned.

1 is a perspective view of a vacuum cleaner according to Embodiment 1. FIG. It is sectional drawing of the vacuum cleaner which concerns on Embodiment 1. FIG. 3 is a side view of the main body according to Embodiment 1. FIG. 2 is a cross-sectional view of a main body according to Embodiment 1. FIG. It is a perspective view of the suction tool which concerns on Embodiment 1. FIG. It is a bottom view of the suction tool which concerns on Embodiment 1. FIG. It is sectional drawing of the suction tool which concerns on Embodiment 1. FIG. 1 is a perspective view of a discharge device according to Embodiment 1. FIG. It is sectional drawing of the suction tool which concerns on Embodiment 1. FIG. It is sectional drawing of the suction tool which concerns on Embodiment 1. FIG. 6 is a perspective view of a discharge device according to a modification of the first embodiment. FIG. 6 is a perspective view of a discharge device according to a modification of the first embodiment. FIG. It is sectional drawing of the suction tool which concerns on Embodiment 2. 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 is a perspective view of the electric vacuum cleaner according to Embodiment 1. FIG.

  The vacuum cleaner 1 includes a main body 2, an extension pipe 3, and a suction tool 4.

  The main body 2 includes an outer case 5, a pipe part 6, a handle 7, and an operation part 8.

  The outer case 5 has a cylindrical shape. The pipe part 6 extends in one direction. The central axis of the pipe part 6 is provided in parallel with the central axis of the outer case 5. The handle 7 is provided at the end of the vacuum cleaner 1. The handle 7 is provided on an extension line of the central axis of the pipe portion 6. The operation unit 8 is provided on the handle 7. The operation unit 8 is configured to accept a user operation. The operation unit 8 includes, for example, a plurality of operation buttons. The user's operation includes an operation of starting the vacuum cleaner 1 and an operation of switching the operation mode of the vacuum cleaner 1. The operation mode includes two modes of “strong” and “weak”.

  The extension pipe 3 extends in one direction. The end of the extension tube 3 is detachably connected to the main body 2. The extension tube 3 includes a first attachment / detachment button 9. The first detachable button 9 is provided at the end of the extension pipe 3 on the side connected to the main body 2. The connection between the extension tube 3 and the main body 2 is released by the first attaching / detaching button 9.

  The suction tool 4 has a suction port 10 on the lower surface. The suction tool 4 includes a connecting pipe 11. The connection pipe 11 is detachably connected to the extension pipe 3. The connecting pipe 11 is provided at the end of the extension pipe 3 on the side where the main body 2 is not connected. The connection pipe 11 includes a second attach / detach button 12. The connection between the connection pipe 11 and the extension pipe 3 is released by the second attach / detach button 12.

Then, the structure inside the vacuum cleaner 1 is demonstrated using FIG.
FIG. 2 is a cross-sectional view of the electric vacuum cleaner according to the first embodiment.

  The main body 2 includes a battery unit 13, an electric blower 14, a main body control board 15, and a dust collection unit 16.

  The battery unit 13 includes a secondary battery. The secondary battery is, for example, a lithium ion battery. The battery unit 13 is connected to the electric blower 14 so that the power charged in the secondary battery can be supplied.

  The electric blower 14 is configured to generate an air flow by the supplied electric power.

  The main body control board 15 is connected to the electric blower 14 so that the operation of the electric blower 14 can be controlled. The main body control board 15 is connected to the operation unit 8 so as to receive a signal representing a user operation accepted by the operation unit 8.

  The dust collection part 16 is comprised so that the dust which flows in with the airflow which the electric blower 14 generates can be collected. The dust collection part 16 is provided in the main body 2 so that attachment or detachment is possible. The dust collection unit 16 includes a dust separation device 17, a dust collection container 18, and a filter unit 19. The dust separation device 17 has a swirling air path along the inner periphery of the dust collection unit 16. The dust separation device 17 has an inner cylinder facing upward from the center. The dust collection container 18 is provided below the dust separation device 17. The filter unit 19 is provided above the dust separation device 17.

  The main body 2 has a suction air passage 20 and an exhaust air passage 21. The suction air passage 20 is a space inside the tube portion 6. The suction air passage 20 communicates with the dust collection unit 16. The exhaust air passage 21 is a space that communicates with the downstream side of the electric blower 14.

  The tube portion 6 has a suction port 22 at the end. The suction port 22 communicates with the suction air passage 20. The tube portion 6 has a first insertion terminal 23. The first insertion terminal 23 is provided at the end of the tube portion 6 on the same side as the suction port 22. The first insertion terminal 23 is electrically connected to the battery unit 13 via the main body control board 15.

  The extension tube 3 is connected to the suction port 22 of the main body 2. When the extension pipe 3 is connected to the main body 2, the inside of the extension pipe 3 leads to the inside of the pipe portion 6. The extension pipe 3 includes a first power supply pin 24 and a second insertion terminal 25. The first power supply pin 24 is provided at the end of the extension pipe 3 on the side connected to the main body 2. When the extension pipe 3 is connected to the main body 2, the first power supply pin 24 is inserted into the first insertion terminal 23. At this time, the first power supply pin 24 is electrically connected to the first insertion terminal 23. The second insertion terminal 25 is provided at the end of the extension pipe 3 opposite to the first power supply pin 24. The second insertion terminal 25 is electrically connected to the first power supply pin 24.

  The suction tool 4 has a suction chamber 26. The suction chamber 26 is a space inside the suction tool 4. The suction port 10 leads to the suction chamber 26. The suction chamber 26 communicates with the inside of the connection pipe 11. The connection pipe 11 is connected to the end of the extension pipe 3 that is not connected to the main body 2. When the connecting pipe 11 is connected to the extension pipe 3, the inside of the connecting pipe 11 leads to the inside of the extension pipe 3.

  When using the vacuum cleaner 1, the user holds the handle 7 and directs the lower surface of the suction tool 4 to the surface to be cleaned. The operation unit 8 receives an operation for starting the user's vacuum cleaner 1. The operation unit 8 transmits a signal representing the accepted operation to the main body control board 15. The main body control board 15 activates the electric blower 14. The electric blower 14 generates an air flow. The suction chamber 26 has a negative pressure due to the airflow generated by the electric blower 14. The airflow flows into the suction chamber 26 from the suction port 10 together with dust on the surface to be cleaned. The airflow flows from the suction chamber 26 into the connection pipe 11. The airflow flows from the connection pipe 11 into the extension pipe 3. The airflow flows from the extension pipe 3 into the dust collecting unit 16. The airflow flowing into the dust collecting unit 16 forms a swirling flow in the dust separating device 17. Dust contained in the swirling flow is separated from the air flow by centrifugal force. The separated dust is collected in the dust collecting container 18. The airflow from which the dust is separated passes through the inner cylinder upward. The airflow passes through the filter unit 19. The airflow passes through the electric blower 14. The airflow is sent out through the exhaust air passage 21.

Then, the structure of the main body 2 is demonstrated using FIG. 3 and FIG.
FIG. 3 is a side view of the main body according to the first embodiment. FIG. 4 is a cross-sectional view of the main body according to the first embodiment.

  As shown in FIG. 3, the main body 2 includes a charging terminal 27. The charging terminal 27 protrudes from the side surface of the tube portion 6.

  As shown in FIG. 4, the main body 2 includes a dust collection part attaching / detaching button 28. The connection between the dust collecting unit 16 and the main body 2 is released by the dust collecting unit attaching / detaching button 28.

Then, the structure of the suction tool 4 is demonstrated using FIGS. 5-7.
FIG. 5 is a perspective view of the suction tool according to the first embodiment. 6 is a bottom view of the suction tool according to Embodiment 1. FIG. FIG. 7 is a cross-sectional view of the suction tool according to the first embodiment.

  In FIG. 5, the vertical direction of the paper surface is the vertical direction of the suction tool 4. In FIG. 5, the direction indicated by the arrow is the left-right direction of the suction tool 4. In FIG. 5, the direction indicated by the arrow is the front-rear direction of the suction tool 4.

  The suction tool 4 includes a case 29, a negative charge supply unit 30, and a discharge device 31.

  The case 29 forms an outline of the suction tool 4. The case 29 has a substantially rectangular shape when viewed from above. The longitudinal direction of the case 29 faces the left-right direction. The case 29 includes an upper case 32 and a lower case 33. The upper case 32 is provided on the lower case 33. The upper case 32 forms the upper surface of the suction tool 4. The lower case 33 forms the lower surface of the suction tool 4.

  The negative charge supply unit 30 has a rectangular tube shape that bends downward. The negative charge supply unit 30 is provided on the upper surface of the upper case 32. The negative charge supply unit 30 is provided at the center of the suction tool 4 in the left-right direction.

  The discharge device 31 is provided at the rear end of the negative charge supply unit 30. The discharge device 31 is configured to generate charged particles that are negatively charged by the supplied power. The charged particles are, for example, negative ions.

  The connecting pipe 11 includes an elbow 34, a fitting portion 35, and a second power supply pin 36. The elbow 34 is provided at one end of the connection pipe 11. The elbow 34 is supported between the upper case 32 and the lower case 33. The connecting pipe 11 can rotate around the elbow 34. The fitting part 35 is provided at the other end of the connecting pipe 11. The outer diameter of the fitting portion 35 is smaller than the inner diameter of the extension pipe 3. The fitting portion 35 is fitted to the end of the extension tube 3 on the second insertion terminal 25 side. The second power supply pin 36 is provided at the end portion on the same side as the fitting portion 35 of the connection pipe 11. When the connection pipe 11 is connected to the extension pipe 3, the second power supply pin 36 is electrically connected to the second insertion terminal 25.

  As shown in FIG. 6, the suction tool 4 includes a rotating brush 37, a drive motor 38, a safety switch 39, a motor control unit 40, and a discharge device control unit 41.

  The rotating brush 37 includes a shaft portion 42 and a plurality of cleaning bodies 43. The shaft portion 42 extends in the left-right direction of the suction tool 4. Both ends of the shaft portion 42 are held by the case 29. The shaft portion 42 is rotatable around the central axis. Each of the plurality of cleaning bodies 43 is provided on a side surface of the shaft portion 42. Each of the plurality of cleaning bodies 43 is provided in a spiral shape coaxial with the central axis of the shaft portion 42. Each of the plurality of cleaning bodies 43 is, for example, flocking.

  The drive motor 38 is provided inside the suction tool 4. The drive motor 38 has an output shaft. The drive motor 38 is electrically connected to the second power supply pin 36 so that power can be supplied. The drive motor 38 is configured such that the output shaft can be rotated by supplied electric power. A belt (not shown) is wound around the output shaft so as to transmit the rotation to the shaft portion 42.

  The safety switch 39 is provided on the lower surface of the suction tool 4. The safety switch 39 includes wheels. The wheel is provided at the lower end of the safety switch 39. The safety switch 39 can be moved to an upper or lower position. The safety switch 39 includes a spring. The spring is provided so as to push the safety switch 39 to a lower position by an elastic force.

  The motor control unit 40 is provided inside the suction tool 4. The motor control unit 40 is equipped with an element that controls the operation of the drive motor 38. The motor control unit 40 is configured to stop the drive motor 38 when the safety switch 39 is moving downward.

  The discharge device control unit 41 is provided inside the suction tool 4. When the suction tool 4 and the extension tube 3 are connected to the main body 2, the discharge device control unit 41 is connected to the operation unit 8 so as to receive a signal indicating the operation mode of the vacuum cleaner 1. The discharge device control unit 41 is equipped with an element that controls the operation of the discharge device 31. Control of the operation of the discharge device 31 includes control of the charge amount of the charged particles generated by the discharge device 31. The charge amount of the charged particles is, for example, the product of the number of charged particles to be generated and the average charge amount per charged particle.

  The lower case 33 includes a pair of raised cloths 33a, a pair of front wheels 33b, and a pair of rear wheels 33c. Each of the pair of raised fabrics 33 a is provided at the left and right ends of the lower case 33. Each of the pair of raised fabrics 33 a is provided at the front end of the lower case 33. Each of the pair of raised fabrics 33 a is provided on each of the left and right sides of the suction port 10. The pair of front wheels 33 b are provided at the left and right ends of the lower case 33. Each of the pair of front wheels 33 b is provided behind the suction port 10. Each of the pair of rear wheels 33 c is provided on each of the left and right sides of the connection pipe 11. Each of the pair of rear wheels 33c is provided behind each of the pair of front wheels 33b.

  In FIG. 7, the right direction of the drawing is the front direction of the suction tool 4.

  The suction chamber 26 is provided inside the case 29.

  The connecting pipe 11 is provided behind the suction port 10.

  The negative charge supply unit 30 includes a supply port 30a, an intake port 30b, and an air passage 30c. The supply port 30 a is an opening that communicates with the suction chamber 26. The supply port 30 a opens toward the suction port 10. The supply port 30 a is provided at the front end of the suction chamber 26. The intake port 30 b is an opening that opens toward a space outside the suction tool 4. The air passage 30c connects the intake port 30b and the supply port 30a.

  The rotating brush 37 is provided in the suction chamber 26. The central axis of the shaft portion 42 is provided behind the supply port 30a. Each of the plurality of cleaning bodies 43 is provided so as to protrude downward from the suction port 10 at any rotational position of the shaft portion 42. Each of the plurality of cleaning bodies 43 is provided so as to be positioned below the supply port 30a at any rotational position of the shaft portion 42.

  The discharge device 31 is provided at the end of the air passage 30c on the side of the intake port 30b. The discharge device 31 is electrically connected to the second power supply pin 36 so that power can be supplied.

  The suction tool 4 includes a detection unit 44. The detection unit 44 is provided inside the connection pipe 11 so that the amount of dust inside the connection pipe 11 can be detected. The detection unit 44 is, for example, a dust sensor. The detection unit 44 is connected to the discharge device control unit 41 so that a signal indicating the amount of dust to be detected can be transmitted.

Then, the structure of the discharge device 31 is demonstrated using FIG.
FIG. 8 is a perspective view of the discharge device according to the first embodiment. In FIG. 8, the direction indicated by the arrow is the front-rear direction of the suction tool 4.

  The discharge device 31 includes a support 45 and a discharge electrode 46. The support body 45 has a plate shape. The support body 45 is fixed to the inner surface of the negative charge supply unit 30. The discharge electrode 46 has a needle shape. The tip of the discharge electrode 46 faces the front of the suction tool 4. That is, the tip of the discharge electrode 46 faces the downstream direction of the air passage 30c. The discharge electrode 46 is supported by the support body 45. The central axis of the discharge electrode 46 passes through the center of the support 45 in the thickness direction. The discharge electrode 46 is configured such that a negative high voltage can be applied by the power supplied to the discharge device 31.

Then, operation | movement of the vacuum cleaner 1 is demonstrated using FIG. 9 and FIG.
9 and 10 are cross-sectional views of the suction tool according to Embodiment 1. FIG.

  As shown in FIG. 9, dust on the surface to be cleaned can be positively or negatively charged. Much of the dust generated at home is human skin, hair or fibers. Human hair such as fur and hair, glass, wool, nylon, rayon, silk, cotton, hemp, wood, human skin pieces, and glass fiber are easily positively charged by friction. That is, much of the dust generated at home is easily positively charged. The charged dust adheres to the surface to be cleaned by electrostatic force. When the charged dust flows into the vacuum cleaner 1 along with the airflow against the electrostatic force, the dust adheres to the inner surfaces of the connection pipe 11, the extension pipe 3, the pipe portion 6 and the like by the electrostatic force. sell.

  When using the vacuum cleaner 1, the user holds the handle 7 and directs the lower surface of the suction tool 4 to the surface to be cleaned. The safety switch 39 is pushed by the surface to be cleaned and moves to an upper position while resisting the elastic force of the spring. The operation unit 8 receives an operation of a user who starts the vacuum cleaner 1. The battery unit 13 supplies power to the suction tool 4 through the first insertion terminal 23, the first power supply pin 24, the second insertion terminal 25, and the second power supply pin 36.

  A negative high voltage is applied to the discharge electrode 46 by the power supplied from the battery unit 13. At this time, discharge is generated from the tip of the discharge electrode 46 into the air. This discharge generates a concentrated electric field. In the concentrated electric field, the outer electrons are separated from the air molecules. As a result, the air molecules become positive ions. The electrons detached from the air molecule are captured by another air molecule. As a result, another air molecule becomes a negative ion. Negative ions are examples of charged particles that are negatively charged. Alternatively, the detached electrons or negative ions are trapped by particles such as other molecules floating in the air. The particle is another example of a charged particle having a negative charge.

  The charged particles having a negative charge are repelled by the discharge electrode 46 to which a negative high voltage is applied. The charged particles having a negative charge are discharged into the free space inside the negative charge supply unit 30 so as to spread away from the tip of the discharge electrode 46 in the axial direction of the discharge electrode 46.

  The inside of the negative charge supply unit 30 leads to the suction chamber 26. Due to the negative pressure in the suction chamber 26, external air flows into the negative charge supply unit 30 from the intake port 30 b. The charged particles generated by the discharge device 31 move to the supply port 30 a together with the air flowing into the negative charge supply unit 30. The supply port 30 a supplies charged particles to the suction chamber 26. The charged particles supplied from the supply port 30a are sprayed from the suction port 10 onto the surface to be cleaned together with the air flowing in from the intake port 30b.

  When the safety switch 39 is moved to the upper position, the motor control unit 40 rotates the output shaft of the drive motor 38 with the electric power supplied from the battery unit 13. The output shaft of the drive motor 38 transmits rotation to the shaft portion 42 by a belt to be wound. The shaft portion 42 rotates so that the front portion is directed downward from above. The cleaning body 43 rotates following the shaft portion 42. That is, the drive motor 38 drives the rotary brush 37 to rotate. The cleaning body 43 contacts the surface to be cleaned.

  A part of the charged particles supplied from the supply port 30 a is sprayed on the cleaning body 43. The cleaning body 43 supplies negative charges charged with charged particles to the surface to be cleaned by contact.

  The user advances the suction tool 4 forward.

  As shown in FIG. 10, the positively charged dust on the surface to be cleaned is electrically neutralized by charged particles having a negative charge. The electrically neutralized dust is easily separated from the surface to be cleaned. The dust is lifted up by the cleaning body 43. The dust is sucked together with the airflow from the suction port 10 into the suction chamber 26.

  Charged dust can adhere to the cleaning body 43 due to electrostatic force. Part of the charged particles supplied from the supply port 30 a is captured by the cleaning body 43. The charged particles electrically neutralize the charged dust. The electrically neutralized dust is easily separated from the cleaning body 43. The dust is separated from the cleaning body 43 and sucked into the connection pipe 11.

  Part of the charged particles supplied from the supply port 30a is sucked into the connection pipe 11 without being electrically neutralized. The charged particles electrically neutralize charged dust adhering to the inner surfaces of the connecting pipe 11, the extension pipe 3, the pipe portion 6, and the like. The electrically neutralized dust is easily separated from the inner surfaces of the connection pipe 11, the extension pipe 3 and the pipe portion 6. The dust flows into the dust collecting part 16 without adhering to the inner walls of the connecting pipe 11, the extension pipe 3 and the pipe part 6.

  The discharge device control unit 41 controls the charge amount of the charged particles generated by the discharge device 31 by controlling a negative high voltage applied to the discharge electrode 46, for example.

  The detection unit 44 detects the amount of dust inside the connection pipe 11. The detection unit 44 transmits a signal representing the amount of detected dust to the discharge device control unit 41. When the amount of dust represented by the received signal is larger than a predetermined amount threshold, the discharge device control unit 41 increases the charge amount of the charged particles generated by the discharge device 31. When the amount of dust represented by the received signal is smaller than a predetermined amount of threshold, the discharge device control unit 41 reduces the charge amount of the charged particles generated by the discharge device 31.

  The operation unit 8 receives a user's operation for switching the operation mode. The operation unit 8 transmits a signal representing the accepted operation mode to the discharge device control unit 41. When a signal representing the “strong” operation mode is received, the discharge device control unit 41 increases the amount of charge of the charged particles generated by the discharge device 31. When a signal representing the “weak” operation mode is received, the discharge device control unit 41 reduces the charge amount of the charged particles generated by the discharge device 31.

  As described above, the vacuum cleaner 1 according to the first embodiment includes the electric blower 14, the dust collection unit 16, and the suction tool 4. The electric blower 14 generates an air flow that sucks dust from the outside. The dust collection unit 16 collects dust. The suction tool 4 sucks the airflow from the suction port.

  The suction tool 4 includes a case 29, a connection tube 11, a discharge device 31, and a negative charge supply unit 30. The case 29 forms an outline of the suction tool 4. The case 29 has a suction chamber 26 inside. The case 29 has a suction port 10 communicating with the suction chamber 26 on the lower surface. It is provided behind the connection pipe 11 and the suction port 10. The connection pipe 11 has an internal space that communicates with the inside of the case 29. The discharge device 31 generates charged particles having a negative charge. The negative charge supply unit 30 has a supply port 30 a at the front end of the suction chamber 26. The supply port 30 a opens toward the suction port 10. The negative charge supply unit 30 supplies charged particles to the suction chamber 26 from the supply port 30a.

  The charged particles supplied to the suction chamber 26 from the supply port 30a pass over the surface to be cleaned together with the airflow. Thereby, the suction tool 4 can more reliably deliver the charged particles having a negative charge to the surface to be cleaned.

  The supply port 30 a is provided in the uppermost stream of the airflow passing from the suction port 10 to the dust collection unit 16. Thereby, the inner surface of the whole part, such as the connection pipe 11, the extension pipe 3, and the pipe part 6 through which the airflow containing the dust of the vacuum cleaner 1 passes, is electrically neutralized. As a result, the suction tool 4 prevents charged dust from adhering to the inner surface due to electrostatic force.

  The suction tool 4 can selectively supply negatively charged charged particles to the surface to be cleaned. The suction tool 4 can control the amount of charge supplied to the surface to be cleaned by controlling the high voltage applied to the discharge electrode 46.

  Further, the negative charge supply unit 30 is provided on the upper surface of the case 29.

  The negative charge supply unit 30 does not protrude forward or sideward. Thereby, the suction tool 4 becomes compact.

  Further, the negative charge supply unit 30 has an air passage 30c. The air passage 30c connects the external space and the supply port 30a. The negative charge supply unit 30 houses the discharge device 31 in the air passage 30c.

  The charged particles are sprayed onto the surface to be cleaned together with the airflow passing through the air passage 30c. Thereby, the suction tool 4 can more reliably deliver the charged particles having a negative charge to the surface to be cleaned.

  The suction tool 4 includes a rotating brush 37. The rotating brush 37 is rotatably provided inside the suction chamber 26. A part of the rotating brush 37 protrudes from the suction port 10.

  The rotating brush 37 is electrically neutralized by charged particles. As a result, the suction tool 4 prevents charged dust from adhering to the rotating brush 37.

  The rotating brush 37 is provided below the supply port 30a.

  The charged particles supplied from the supply port 30 a are sprayed on the rotating brush 37. The rotating brush 37 supplies negative charges charged with charged particles to the surface to be cleaned by contact. Thereby, the suction tool 4 can more reliably deliver the charged particles having a negative charge to the surface to be cleaned.

  Further, the suction tool 4 includes a drive motor 38. The drive motor 38 rotates the rotary brush 37.

  The rotating brush 37 is stably rotated by the drive motor 38. Thereby, the suction tool 4 can more reliably deliver the charged particles having a negative charge to the surface to be cleaned.

  The suction tool 4 includes a detection unit 44 and a discharge device control unit 41. The detection unit 44 detects the amount of dust inside the connection pipe 11. When the amount of dust detected by the detection unit 44 is larger than a predetermined amount, the discharge device control unit 41 increases the charge amount of the charged particles generated by the discharge device 31. When the amount of dust detected by the detection unit 44 is smaller than a predetermined amount, the discharge device control unit 41 reduces the charge amount of the charged particles generated by the discharge device 31.

  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 discharge device control unit 41 controls the charge amount of the charged particles generated by the discharge device 31 according to the amount of dust sucked. The discharge device control unit 41 does not cause the discharge device 31 to generate charged particles unnecessarily. Thereby, the electric power consumed by the discharge device 31 decreases. The suction tool 4 can use electric power efficiently.

  Moreover, the discharge device control part 41 controls the electric charge amount of the charged particle which the discharge device 31 produces | generates based on the operation mode switched by a user.

  Thereby, the vacuum cleaner 1 can operate the discharge device 31 flexibly according to a use condition of a user.

  Further, the negative charge supply unit 30 may include a filter in the intake port 30b. The filter suppresses dust from entering the discharge device 31 to which a high voltage is applied.

  The detection unit 44 may be provided in the suction chamber 26. At this time, the detection unit 44 detects the amount of dust inside the case 29. The detection unit 44 may be provided inside the extension pipe 3 or the main body 2. At this time, the detection unit 44 detects the amount of dust sucked.

  The operation mode may include three or more modes. The operation mode may include a continuous numerical value. At this time, the numerical value corresponds to the charge amount of the charged particles generated by the discharge device 31.

Subsequently, a discharge device 31 according to a modification of the first embodiment will be described with reference to FIG.
FIG. 11 is a perspective view of a discharge device according to a modification of the first embodiment. In FIG. 11, the direction indicated by the arrow is the front-rear direction of the suction tool 4.

  The discharge device 31 includes a support 45, a discharge electrode 46, and a counter electrode 47. The support body 45 has a plate shape. The support body 45 is fixed to the inner surface of the negative charge supply unit 30. The discharge electrode 46 has a needle shape. The tip of the discharge electrode 46 faces the front of the suction tool 4. That is, the tip of the discharge electrode 46 faces the downstream direction of the air passage 30c. The discharge electrode 46 is supported by the support body 45. The central axis of the discharge electrode 46 passes through the center of the support 45 in the thickness direction. The discharge electrode 46 is configured such that a negative high voltage can be applied by the power supplied to the discharge device 31. The counter electrode 47 is provided at a position spaced forward from the tip of the discharge electrode 46. That is, the counter electrode 47 is provided on the downstream side of the air passage 30 c from the discharge electrode 46. The counter electrode 47 has a hole through which the central axis of the discharge electrode 46 passes. The counter electrode 47 is configured such that a positive high voltage can be applied by power supplied to the discharge device 31.

  In this modification, the discharge intensity from the tip of the discharge electrode 46 is increased. The charged particles having a negative charge are accelerated forward by the electric field between the discharge electrode 46 and the counter electrode 47. Thereby, the discharge device 31 can efficiently discharge the charged particles to the front of the suction tool 4.

Next, a discharge device 31 according to another modification of the first embodiment will be described with reference to FIG.
FIG. 12 is a perspective view of a discharge device according to a modification of the first embodiment. In FIG. 12, the direction indicated by the arrow is the front-rear direction of the suction tool 4.

  The discharge device 31 includes a support 45, a discharge electrode 46, and a counter electrode 47. The support body 45 has a plate shape. The support body 45 has a notch. The support body 45 is fixed to the inner surface of the negative charge supply unit 30. The discharge electrode 46 has a needle shape. The tip of the discharge electrode 46 faces the front of the suction tool 4. That is, the tip of the discharge electrode 46 faces the downstream direction of the air passage 30c. The discharge electrode 46 is supported by the support body 45. The discharge electrode 46 is provided in the notch of the support body 45. The central axis of the discharge electrode 46 passes through the center of the support 45 in the thickness direction. The discharge electrode 46 is configured such that a negative high voltage can be applied by the power supplied to the discharge device 31. The counter electrode 47 is provided in front of the tip of the discharge electrode 46. That is, the counter electrode 47 is provided on the downstream side of the air passage 30 c from the discharge electrode 46. The counter electrode 47 is provided at the front end of the support body 45. The counter electrode 47 is provided on the left and right sides of the cutout of the support body 45. The counter electrode 47 is configured such that a positive high voltage can be applied by power supplied to the discharge device 31.

  In this modification, the discharge intensity from the tip of the discharge electrode 46 is increased. The charged particles having a negative charge are accelerated forward by the electric field between the discharge electrode 46 and the counter electrode 47. The counter electrode 47 does not hinder the movement of the charged particles from the tip of the discharge electrode 46 toward the front. Thereby, the discharge device 31 can efficiently discharge the charged particles to the front of the suction tool 4.

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 structure of the suction tool 4 is demonstrated using FIG.
FIG. 13 is a cross-sectional view of the suction tool according to the second embodiment.

  The upper case 32 has a flat surface 32a and an inclined surface 32b. The normal direction of the flat surface 32a faces upward. The inclined surface 32b extends forward and downward from the flat surface 32a. The inclined surface 32b curves upward and forward.

  The negative charge supply unit 30 has a rectangular tube shape with the vertical direction as an axis. The negative charge supply unit 30 is provided on the inclined surface 32b. The negative charge supply unit 30 protrudes upward from the inclined surface 32b. The plane P includes a flat surface 32a. The negative charge supply unit 30 does not protrude upward from the plane P. The negative charge supply unit 30 is provided at the center of the suction tool 4 in the left-right direction. The intake port 30 b is provided at the rear portion of the negative charge supply unit 30.

  The discharge device 31 is provided in the air path 30c. The tip of the discharge electrode 46 faces downward of the suction tool 4. That is, the tip of the discharge electrode 46 faces the downstream direction of the air passage 30c.

  As described above, the case 29 of the suction tool 4 according to Embodiment 2 has the flat surface 32a and the inclined surface 32b on the upper surface. The normal direction of the flat surface 32a faces upward. The inclined surface 32b extends forward and downward from the flat surface 32a. The negative charge supply unit 30 is provided on the inclined surface 32b. The negative charge supply unit 30 does not protrude upward from the plane P including the flat surface 32a.

  The negative charge supply unit 30 does not exceed the height of the flat surface 32a. Thereby, the height of the suction tool 4 becomes low. Therefore, the suction tool 4 becomes easy to enter a narrow gap. Therefore, the vacuum cleaner 1 is easy to use.

  The intake port 30b may be provided on at least one of the side surface and the upper surface of the negative charge supply unit 30.

  DESCRIPTION OF SYMBOLS 1 Vacuum cleaner, 2 Main body, 3 Extension pipe, 4 Suction tool, 5 Outer case, 6 Pipe part, 7 Handle, 8 Operation part, 9 First attachment / detachment button, 10 Suction port, 11 Connection pipe, 12 Second attachment / detachment button , 13 Battery section, 14 Electric blower, 15 Main body control board, 16 Dust collection section, 17 Dust separator, 18 Dust collection container, 19 Filter section, 20 Suction air path, 21 Exhaust air path, 22 Suction port, 23 First Plug terminal, 24 1st power supply pin, 25 2nd plug terminal, 26 Suction chamber, 27 Charging terminal, 28 Dust collection part attaching / detaching button, 29 Case, 30 Negative charge supply part, 30a Supply port, 30b Inlet, 30c Air path, 31 Discharge device, 32 Upper case, 32a Flat surface, 32b Inclined surface, 33 Lower case, 33a Brushed fabric, 3 b front wheel, 33c rear wheel, 34 elbow, 35 fitting part, 36 second power supply pin, 37 rotating brush, 38 drive motor, 39 safety switch, 40 motor control part, 41 discharge device control part, 42 shaft part, 43 cleaning body, 44 detector, 45 support body, 46 discharge electrode, 47 counter electrode

Claims (10)

A case having an outer shell, having a suction chamber inside, and having a suction port leading to the suction chamber on the lower surface;
A connecting pipe that is provided behind the suction port and in which an internal space leads to the inside of the case;
A discharge device that generates negatively charged charged particles;
A supply port that opens toward the suction port at a front end of the suction chamber, and a negative charge supply unit that supplies the charged particles from the supply port to the suction chamber;
A suction tool comprising:   The suction tool according to claim 1, wherein the negative charge supply unit is provided on an upper surface of the case. The case has a flat surface with a normal direction facing upward, and an inclined surface extending forward and downward from the flat surface on the upper surface,
The suction device according to claim 1, wherein the negative charge supply unit is provided on the inclined surface and does not protrude upward from a plane including the flat surface.   The suction device according to any one of claims 1 to 3, wherein the negative charge supply unit includes an air passage connecting an external space and the supply port, and the discharge device is accommodated in the air passage. . The suction tool according to any one of claims 1 to 4, further comprising a rotating brush that is rotatably provided inside the suction chamber and partially protrudes from the suction port.   The suction tool according to claim 5, wherein the rotating brush is provided below the supply port. The suction tool according to claim 5, further comprising a drive motor that rotationally drives the rotary brush. A detection unit for detecting the amount of dust inside the case or the connection pipe;
A discharge device control unit that varies a voltage applied to the discharge device according to the amount of dust detected by the detection unit;
The suction tool according to any one of claims 1 to 7, further comprising: The suction device according to any one of claims 1 to 7, further comprising: a discharge device control unit that controls a voltage applied to the discharge device based on an operation mode switched by a user. An electric blower that generates an air flow that sucks dust from the outside;
A dust collecting part for collecting the dust;
The suction tool according to any one of claims 1 to 9, wherein the airflow is sucked from a suction port;
Electric vacuum cleaner.

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