JP2013188444A - Vacuum cleaner and suction port body of the same - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide a floor brush that can surely send off an ion generated while preventing enlargement.SOLUTION: A floor brush 23 includes a case body 31 that is provided with a suction port 47. The floor brush 23 includes a rotary brush 49 rotatably disposed facing the suction port 47 of the case body 31. The floor brush 23 includes a motor 61 that rotates the rotary brush 49 in the case body 31. The floor brush 23 includes an ion generator 85 in the case body 31. The floor brush 23 includes a fan 66 that is rotated by the motor 61, and that sends off a generated ion from the ion generator 85 in the case body 31.

Description

  Embodiments of the present invention relate to a suction port body of a vacuum cleaner having a case body provided with a suction port, and a vacuum cleaner including the same.

  2. Description of the Related Art Conventionally, for example, a canister type vacuum cleaner is connected to a vacuum cleaner main body containing an electric blower, a hose body connected to the vacuum cleaner main body, an extension pipe connected to the hose body, and the extension pipe. And a floor brush as a suction port body. And it is comprised so that dust may be suck | inhaled with air from the front-end | tip of a floor brush, etc. by the drive of an electric air blower, and dust will be collected by the dust collection part arrange | positioned at the cleaner body.

  In such a vacuum cleaner, in order to prevent dust from floating and adhering due to deodorization or charging, the vacuum cleaner main body is provided with an ion generator that generates negative ions, and the generated negative ions are removed. There is a thing provided with the ventilation fan for sending out in the air.

JP 2008-188422 A JP 2011-167276 A

  By the way, when the floor brush is moved back and forth on the floor surface and cleaned, dust easily adheres to the floor surface due to static electricity generated by friction between the floor brush and the floor surface. For this reason, it is conceivable that the ion generator as described above is mounted on the floor brush to electrically neutralize the dust with the generated negative ions and prevent the dust from adhering to the floor surface.

  However, the floor brush has a problem that it is not easy to take a sufficient space for arranging the blower fan, and the floor brush is enlarged even if the blower fan is arranged.

  The problem to be solved by the present invention is to provide a vacuum cleaner capable of reliably delivering ions generated while preventing an increase in size, and a suction port thereof.

  The suction port body of the vacuum cleaner of the embodiment has a case body provided with a suction port. Moreover, the suction inlet body of this electric vacuum cleaner has the rotation cleaning body arrange | positioned rotatably facing the suction inlet of a case body. Furthermore, the suction port body of this electric vacuum cleaner has a drive means that is disposed in the case body and rotates the rotary cleaning body. Moreover, the suction inlet body of this vacuum cleaner has an ion generator arrange | positioned at a case body. And the suction inlet of this vacuum cleaner has a fan which is arrange | positioned at a case body and sends out the ion which was rotated by the drive means and was generated from the ion generator.

It is a top view which shows the state which open | released the upper side of the suction inlet of the vacuum cleaner of one Embodiment. It is sectional drawing of the II equivalent position of FIG. 4 of a suction inlet same as the above. FIG. 6 is a cross-sectional view of the suction port body at the position corresponding to II-II in FIG. 4. It is a perspective view which shows a suction inlet body same as the above from the front. It is a perspective view which shows the vacuum cleaner provided with the suction inlet same as the above.

  The configuration of one embodiment will be described below with reference to FIGS.

  In FIG. 5, reference numeral 11 denotes a so-called canister-type vacuum cleaner. The vacuum cleaner 11 includes a vacuum cleaner main body 12 and a pipe portion 13 which is an air passage forming body detachably connected to the vacuum cleaner main body 12. And have.

  The vacuum cleaner main body 12 is capable of turning and running on the floor as a surface to be cleaned, an electric blower 18, a main body control unit (not shown) that controls the operation of the electric blower 18, and the electric blower 18 and main body control. The power supply unit such as a secondary battery or the like is housed, and a dust collecting unit (not shown) communicating with the suction side of the electric blower 18 is provided. In addition, a main body suction port 19 is formed in the front portion of the cleaner body 12 so as to communicate with the dust collecting portion and to which the proximal end side of the tube portion 13 is connected.

  The pipe portion 13 includes a hose body 21, an extension pipe 22 made of, for example, synthetic resin that can be attached to and detached from the hose body 21, and a floor brush 23 as a suction port that can be attached to and detached from the extension pipe 22. And.

  The hose body 21 includes a flexible hose portion 25, a connecting pipe portion 26 provided on the base end side (downstream side) of the hose portion 25 and connected to the main body suction port 19, and a distal end side of the hose portion 25. And a handy operating unit 27 provided on the (upstream side).

  The proximal end side (downstream side) of the extension pipe 22 is detachably connected to the hand operation unit 27. Further, the hand operating part 27 is formed with a grip part 28 that is gripped by the user so as to protrude to the base end side, and this grip part 28 is for setting the operation mode of the electric blower 18 to the main body control part. The setting button 29 is arranged. These setting buttons 29 are mounted on an electrical unit having a substrate (not shown) housed in the hand operation unit 27.

  Further, as shown in FIGS. 1 to 4, the floor brush 23 includes a case body 31 that is formed in a longitudinal shape in the left-right width direction, that is, a horizontally long shape, and an extension pipe 22 that is rotatably connected to the rear portion of the case body 31. And a connecting pipe 32 detachably connected to the distal end side (upstream side) of FIG. 5.

  The case body 31 is formed by combining a plurality of case members formed of, for example, synthetic resin, and the inside of the case body 31 is a suction chamber 41 communicating with the upstream side (front end side) of the connection pipe 32. Is divided longitudinally in the left-right width direction at the front, and a drive chamber 42 and a control chamber 43 are partitioned behind the suction chamber 41 and on both sides of the connecting pipe 32, and transmitted to one side of the drive chamber 42. The chamber 44 is partitioned longitudinally in the front-rear direction, and the ion generation chamber 45 is partitioned above the central portion of the suction chamber 41 in the left-right width direction. A plurality of wheels 46 are rotatably disposed at positions below the case body 31 such as on both sides of the front end side (upstream end side) of the connecting pipe 32. The (floor brush 23) can move (run) in the front-rear direction or the like on the surface to be cleaned. Hereinafter, the front-rear direction and the left-right direction are based on the traveling direction of the floor brush 23.

  The lower portion of the suction chamber 41 communicates with the outside of the case body 31 (floor brush 23) by a suction port 47 formed in the lower portion of the case body 31. The upper portion of the suction chamber 41 communicates with the outside of the case body 31 (floor brush 23) through dust suction ports 48 and 48 formed in the upper portion of the case body 31. Further, a rotary brush 49 as a rotary cleaning body is rotatably disposed in the suction chamber 41.

  The suction port 47 sucks dust on the surface to be cleaned together with air by the negative pressure generated by driving the electric blower 18 (FIG. 5), and is formed horizontally long across the lower portion of the suction chamber 41.

  Each dust suction port 48 sucks together dust and the like in the air located above the floor brush 23 (case body 31) with the negative pressure generated by driving the electric blower 18 (FIG. 5). The size of the suction port 47 is smaller than ½ of the length of the suction port 47, and the suction chamber 41 is formed at a position closer to the rear part in the front-rear direction and opens upward. Therefore, each dust suction port 48 communicates with the suction port 47 via the suction chamber 41. Further, each dust suction port 48 is slightly opened in a slit shape so that the degree of vacuum in the suction chamber 41 does not decrease more than necessary.

  The rotating brush 49 includes a shaft portion 51 formed in a longitudinal shape, and substantially cylindrical bearing portions 52 and 52 as receiving plates press-fitted to both ends of the shaft portion 51. I'm here.

  The shaft 51 is also referred to as a rotary brush assembly, and is formed in a substantially cylindrical shape using, for example, a metal such as aluminum or a synthetic resin, and a rotating shaft (not shown) protruding from both ends is inserted into the bearing 52 and these are inserted. It protrudes to the outside of the bearing portion 52 and is pivotally supported by a bearing (not shown) fixed to the case body 31 so as to be rotatable. In addition, a plurality of groove portions 56 are formed in the circumferential direction on both ends of the outer periphery of the shaft portion 51, and the proximal end side of the cleaning member 57 is attached to these groove portions 56.

  Each groove portion 56 is spirally formed around the shaft portion 51 so as to be substantially parallel to each other. For example, the groove portion 56 is twisted 360 ° from one end to the other end of the shaft portion 51.

  Each cleaning member 57 includes, for example, a plurality of bristle brushes 57a in a wall shape, and is attached to the shaft portion 51 so that the bristle brushes 57a are spiral. Further, in each cleaning member 57, the front end side of the bristle brush 57a protrudes from the suction port 47 to the outside (downward).

  The drive chamber 42 is isolated from the suction chamber 41 in an airtight or substantially airtight manner. Further, the drive chamber 42 accommodates an electric motor 61 as a drive means for driving the rotary brush 49 to rotate. The electric motor 61 includes, for example, an electric motor main body 63 which is a driving means main body having a substantially cylindrical shape, and a rotating shaft 64 protruding from both ends of the electric motor main body 63. One end side of the rotating shaft 64 (the case body 31). A pulley 65, which is a rotating body, is attached to the floor brush 23 on the side opposite to the center side in the left-right width direction, and the other end side of the rotating shaft 64 (the case body 31 (floor brush 23) in the left-right width direction). A fan 66 is attached to the center side. Further, the drive chamber 42 communicates with the outside on the rear side of the floor brush 23 (case body 31) through a communication opening 67 formed in the rear portion of the case body 31, and extends to the upper portion of the suction chamber 41. The ion generation chamber 45 communicates with the air passage portion 68.

  The electric motor 61 is held in the drive chamber 42 via one and the other supports 71 and 72 attached to the outer periphery of the electric motor main body 63. Further, in the present embodiment, the electric motor 61 is driven at, for example, about 5000 revolutions / minute.

  One support 71 is formed in a cylindrical shape by a member having elasticity (flexibility) and air permeability such as a sponge, and is near the central portion in the axial direction of the electric motor 61 (the electric motor body 63 of the electric motor 61). The outer periphery is held on the inner peripheral side, and the outer peripheral side is held on the inner surface of the drive chamber 42.

  The other support 72 is formed into a cylindrical shape by a member having elasticity (flexibility) such as rubber or elastomer, and the outer periphery of the other end side of the electric motor 61 (the electric motor main body 63 of the electric motor 61) is formed. While being held on the inner peripheral side, the outer peripheral side is hermetically pressed against the inner surface of the drive chamber 42. Therefore, the other support 72 is a partition wall that partitions the drive chamber 42 in the left-right width direction on the outer periphery of the electric motor 61 (the electric motor body 63 of the electric motor 61).

  The electric motor 61 is held and fixed by the one support body 71 and the other support body 72 in a state where the motor 61 is isolated from vibration with respect to the case body 31 (the drive chamber 42 of the case body 31).

  The pulley 65 is positioned so as to protrude into the transmission chamber 44 along with one end side of the rotating shaft 64. The pulley 65 is connected to one bearing portion 52 of the rotating brush 49 as a transmission means on the outer periphery of the pulley 65. The timing belt 73 is wound around. For this reason, the rotating brush 49 is configured to rotate by the rotation of the electric motor 61. The electric motor 61 is supplied with power from the cleaner body 12 side via the connecting pipe 32.For example, the rotating brush 49 is directed forward, that is, the upper part moves from the rear side to the front side (the lower part is the front side). The direction of movement from the rear side to the rear side), in other words, the drive is controlled to rotate in a direction that assists the forward movement of the floor brush 23 (case body 31).

  Further, the fan 66 is rotated by the electric motor 61 to suck air (outside air) from the outside of the rear side of the floor brush 23 (case body 31) through the communication opening 67, and the electric motor 61 (electric motor 61) This is a blower fan (axial fan) that cools the electric motor main body 63) and sends this air to the ion generation chamber 45 through the air passage portion 68. In the present embodiment, the pulley 65 and the fan 66 are configured to rotate at the same rotational speed at the same time in the same direction. For example, the other end of the rotary shaft 64 is connected to a power transmission unit such as a gear. By connecting to the fan 66, the rotational speed and direction of rotation of the fan 66 can be arbitrarily different from that of the pulley 65.

  A drive chamber filter 75 is attached to the communication opening 67 inside the drive chamber 42. Further, the outer periphery of the electric motor main body 63 of the electric motor 61 is located opposite to the communication opening 67.

  Further, the air passage portion 68 extends in an inclined manner from a position on the other end side (connection pipe 32 side) of the drive chamber 42 to a position on one side of the ion generation chamber 45. Further, the air passage portion 68 is formed so that the air passage area gradually increases from the drive chamber 42 side, which is the upstream side of the air sent out by the fan 66, to the ion generation chamber 45 side, which is the downstream side of the air. Has been.

  The control chamber 43 includes a communication opening 77 formed in the front portion so as to communicate with the suction chamber 41. The communication opening 77 is formed in the vicinity of the other side of the suction chamber 41, that is, in the vicinity of the position opposite to the transmission chamber 44 with respect to the suction chamber 41, and faces the other bearing portion 52. In addition, a control room filter 78 is attached to the inside of the control chamber 43 at the communication opening 77. Further, in the control chamber 43, a safety device 82 which is a control means 81 for controlling the driving of the electric motor 61 and the like, and a ground detection means for detecting whether the floor brush 23 (case body 31) is placed on the floor surface. And are stored respectively. The control chamber 43 communicates with the ion generation chamber 45 through a communication air passage portion 83 extending to the upper portion of the suction chamber 41. Therefore, the control chamber 43 communicates with the drive chamber 42 (via the communication air passage portion 83 and the ion generation chamber 45).

  The control means 81 is, for example, a microcomputer and is supplied with power from the cleaner body 12 side via the connecting pipe 32. The control means 81 is electrically connected to the electric motor 61, the safety device 82, and the like.

  Further, the communication air passage portion 83 extends in an inclined manner from a position on one end side (connecting pipe 32 side) of the control chamber 43 to a position on the other side of the ion generation chamber 45. Further, the communication air passage portion 83 gradually reduces the air passage area from the ion generation chamber 45 side that is upstream of the air sent out by the fan 66 to the control chamber 43 side that is upstream of air. Is formed.

  The ion generation chamber 45 is located above the central portion of the suction chamber 41 in the left-right width direction, and is isolated from the suction chamber 41 in an airtight or substantially airtight manner. In this ion generation chamber 45, an ion generator 85 is accommodated. This ion generator 85 has an electrode 85a for generating ions I for electrically neutralizing dust by corona discharge, for example, and is electrically connected to the control means 81, and the operation is controlled by this control means 81. Has been. In addition, the ion generation chamber 45 is a plurality of ion emission holes that are formed along the front-rear direction and positioned between the dust suction ports 48 and 48 in the center in the left-right width direction on the upper side of the case body 31 toward the front. The exhaust hole 86 communicates with the outside of the case body 31. Therefore, these discharge holes 86 are configured to discharge the ions I generated by the ion generator 85 to the outside on the front side of the case body 31. The ion generator 85 may generate either negative ions or positive ions as long as the dust can be electrically neutralized. However, in general, the dust is often positively charged. A negative ion generator that generates negative ions.

  Next, the operation of the one embodiment will be described.

  As shown in FIGS. 1 to 5, when cleaning, the connecting pipe portion 26 of the hose body 21 is connected to the main body suction port 19 of the cleaner body 12, and the extension pipe is connected to the hand operating portion 27 of the hose body 21. 22 is connected, and the connecting pipe 32 of the floor brush 23 is connected to the extension pipe 22. As a result, the floor brush 23 is communicatively connected to the suction side of the electric blower 18 (through the extension pipe 22, the hose body 21, the main body suction port 19 and the dust collecting portion).

  Then, after the user sets the power supply unit to a state where power can be supplied, the user grips the grip portion 28 and operates the desired setting button 29 to set the electric blower 18 in a desired operation mode via the main body control portion. At the same time, the control means 81 drives the ion generator 85 to generate ions I by corona discharge at the electrode 85a. Therefore, when the electric blower 18 is driven, negative pressure sequentially acts on the dust collection unit, the main body suction port 19, the hose body 21, the extension pipe 22, and the floor brush 23, and the ion I generated by the ion generator 85 is generated. The ion generation chamber 45 is filled, and a part of the ion generation chamber 45 is discharged from the discharge hole 86 to the outside of the case body 31 (floor brush 23), that is, to the outside air. The discharged ions I electrically neutralize the dust adhering to the floor surface and the outer surface of the case body 31, so that the dust does not easily adhere to the floor surface and the outer surface of the case body 31 due to charging. . In addition, the user places the floor brush 23 on the surface to be cleaned and travels forward and backward, thereby sucking dust with air from the suction port 47 and generating dust and ions in the air from the dust suction ports 48 and 48. Ions I generated by the vessel 85 are sucked together with air.

  The dust sucked into the floor brush 23 together with the air is sucked into the dust collecting portion through the connection pipe 32, the extension pipe 22, the hose body 21, and the main body suction port 19. At this time, dust adhering to each part such as the rotating brush 49, the connecting tube 32, the extension tube 22, the hose body 21, and the main body inlet 19 is electrically neutralized by the sucked ions I, so that these rotating brushes 49, particularly fine dust (fine dust) is easily peeled off to the connection pipe 32, the extension pipe 22, the hose body 21, and the like. The dust sucked into the dust collecting part is separated from the air and collected by the dust collecting part. In addition, the air separated from the dust is sucked into the electric blower 18, and after cooling the electric blower 18, the air is exhausted to become exhaust air and exhausted to the outside of the cleaner body 12.

  In this cleaning, the user rotates the rotating brush 49 by operating the setting button 29 as necessary, for example, when the type of the surface to be cleaned is flooring. Specifically, when the control means 81 drives the electric motor 61, the rotary brush 49 connected via the timing belt 73 to the pulley 65 connected to one end of the rotary shaft 64 of the electric motor 61 is in the suction chamber 41. Rotate forward. Further, the drive of the electric motor 61 causes the fan 66 connected to the other end side of the rotating shaft 64 to rotate.

  The rotary brush 49 sweeps out dust on the floor surface by each bristle brush 57a of each cleaning member 57. Further, the fan 66 generates a negative pressure by rotation, and sucks air outside the case body 31 (floor brush 23) from the communication opening 67. The sucked air is blown to the electric motor 61 (the electric motor main body 63 of the electric motor 61) through the driving chamber filter 75 to cool the electric motor 61 (the electric motor main body 63 of the electric motor 61), and the air passage portion 68 by the fan 66. To the ion generation chamber 45. Therefore, the ion I filled in the ion generation chamber 45 is forced from the discharge hole 86 to the outside of the case body 31 (floor brush 23) together with the air in the ion generation chamber 45 by the sent air. And it is sent out continuously. Further, a part of the ions I in the ion generation chamber 45 is sent out to the control chamber 43 through the communication air passage portion 83 and fills the control chamber 43 to the control means 81 and the safety device 82. Suppresses the adhesion of dust. Furthermore, the control tube filter 78 passes through the communication opening 77 to the suction chamber 41, and the negative pressure generated by the drive of the electric blower 18 causes the inside of the suction chamber 41 to extend along the longitudinal direction in the central connection pipe. It flows to 32. At this time, the ions I electrically neutralize the dust adhering to the inner wall of the suction chamber 41 and the rotary brush 49, and easily peel off from the inner wall of the suction chamber 41 and the rotary brush 49.

  Similarly, some of the ions I in the outside air sucked into the suction chamber 41 together with air from the dust suction ports 48 and 48 are moved upward in the suction chamber 41 from behind the rotary brush 49 along with the rotation of the rotary brush 49. Then, it is carried to the lower rear via the front, and the dust adhering to the suction chamber 41 and the rotating brush 49 is electrically neutralized to be easily separated from the inner wall of the suction chamber 41 and the rotating brush 49, and then to the connection pipe 32. And flow.

  When cleaning is completed, the user operates the setting button 29 so that the main body control unit stops the electric blower 18 and the control unit 81 stops the ion generator 85. When the electric motor 61 (the rotating brush 49 and the fan 66) is driven, the control unit 81 also stops the electric motor 61 (the rotating brush 49 and the fan 66).

  According to the embodiment described above, the electric motor 61 for rotating the fan 66 is rotated by rotating the fan 66 that sends out the ions I generated by the ion generator 85 by the electric motor 61 that rotates the rotary brush 49. The generated ions I can be reliably sent out without being separately arranged in the case body 31 and increasing the size of the floor brush 23 (case body 31).

  In particular, when the rotary brush 49 is rotationally driven by the electric motor 61, static electricity is likely to be generated on the floor surface and the cleaning member 57 due to friction between each cleaning member 57 (the bristle brush 57a of each cleaning member 57) and the floor surface. The rotary brush 49 is sent out from the ion generation chamber 45 to the outside of the case body 31 (floor brush 23) by rotating the rotary brush 49 at a timing when the rotary brush 49 is rotated by the electric motor 61. The static electricity generated by the rotational drive of can be effectively neutralized by the ions I.

  In addition, since the electric motor 61 (the electric motor body 63 of the electric motor 61) is cooled by the air sucked by the rotation of the fan 66, a reduction in efficiency due to heat generated by the electric motor 61 can be reliably suppressed with a simple configuration.

  In particular, the rotary brush 49 used in the vacuum cleaner 11 is driven to rotate at a high speed of about 5000 rotations / minute by the electric motor 61. Therefore, by rotating the fan 66 using the rotation of the electric motor 61, the ion I The airflow for cooling the electric motor 61 can be secured sufficiently.

  Further, a part of the ions I generated by the ion generator 85 is sent to the inside of the case body 31, in this embodiment, the control chamber 43 by the air sent to the ion generation chamber 45 by the rotation of the fan 66. Thus, even when dust (fine dust) is sucked into the control chamber 43 or the like from a slight gap of the case body 31 due to, for example, negative pressure generated by driving the electric blower 18, the control means in the control chamber 43 The adhesion of dust (fine dust) to 81 and the safety device 82 can be suppressed.

  Then, by communicating the control chamber 43 and the suction chamber 41 through the communication opening 77, the ions I sent into the control chamber 43 can be reliably sent out from the communication opening 77 to the suction chamber 41. By arranging the communication opening 77 in the vicinity of the other side of the suction chamber 41, when the ions I in the suction chamber 41 are sucked into the connecting pipe 32 by the negative pressure generated by driving the electric blower 18, the ions I Can be efficiently applied to a wider range along the suction chamber 41 and the rotating brush 49.

  In the above-described embodiment, it is also possible to form the various air passages communicating with the drive chamber 42 in the case body 31 so that the ions 66 are sent out to a desired location in the case body 31 by the fan 66. Good.

  Further, the vacuum cleaner 11 is not limited to a canister type, for example, an upright type in which a floor brush 23 is connected to the lower part of a vacuum cleaner body 12 that is vertically long, and a floor brush 23 is directly attached to the vacuum cleaner body 12. A handy type that is connected and cleaned while carrying the cleaner body 12 can also be used.

  Furthermore, although one embodiment of the present invention has been described, this embodiment is presented as an example and is not intended to limit the scope of the invention. The novel embodiment can be implemented in various other forms, and various omissions, replacements, and changes can be made without departing from the scope of the invention. This embodiment and its modifications are included in the scope and gist of the invention, and are included in the invention described in the claims and the equivalents thereof.

11 Vacuum cleaner
12 Vacuum cleaner body
18 Electric blower
23 Floor brush as inlet
31 Case body
47 Air inlet
49 Rotating brush as rotating cleaning body
61 Electric motors as driving means
66 fans
85 Ion generator

Claims (4)

A case body with a suction port;
A rotating cleaning body that is rotatably arranged facing the suction port of the case body,
A driving means disposed on the case body for rotating the rotary cleaning body;
An ion generator disposed in the case body;
A suction port body for a vacuum cleaner, comprising: a fan disposed on the case body and rotated by the driving means to send out ions generated from the ion generator. The suction port body for an electric vacuum cleaner according to claim 1, wherein the fan cools the driving means by rotation. The suction port body of the vacuum cleaner according to claim 1 or 2, wherein the fan sends a part of ions generated from the ion generator into the case body. A vacuum cleaner body containing an electric blower,
A vacuum cleaner comprising: a suction port body according to any one of claims 1 to 3 communicating with a suction side of the electric blower.

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