JP4011079B2 - Electric vacuum cleaner - Google Patents

Description

  The present invention relates to, for example, a first separation unit that separates dust and air in the middle of a suction air passage provided in a cleaner body, and a vacuum cleaner that is provided with a secondary filter downstream of the first separation.

  2. Description of the Related Art Conventionally, an electric vacuum cleaner in which a dust collecting container is detachably provided on a vacuum cleaner body is known (see Patent Document 1).

  Such a vacuum cleaner includes a vacuum cleaner body having a dust container chamber formed therein, a dust container that is detachably attached to the dust container chamber, and an electric blower provided downstream of the dust container chamber. And a pleated filter that is a secondary filter that is detachably attached to the rear opening of the dust collecting container, and a dust removing means that shakes off dust adhering to the pleated filter. Note that the pleats of the pleat filter extend in the vertical direction.

  This dust removing means is arranged so that the ring can freely rotate at a position facing the pleat filter, and provided with a protrusion abutting against the pleat filter on the ring, and the ring is rotated when the cord reel winds up the power cord. As the ring rotates, the projection moves over the pleat peaks of the pleat filter, thereby giving vibration to the pleat filter and dropping dust adhering to the pleat filter.

  However, in such a vacuum cleaner, the dust dropped from the pleat filter is dropped to the dust collecting part provided at the lower part of the rear part of the dust collecting container, but the electric blower is driven. Then, there is a problem that the dust that has fallen into the dust collecting portion is sucked and again adheres to the pleated filter.

Therefore, a dust receiving part for receiving dust dropped from the pleat filter is provided, a discharge opening for discharging the dust is formed in the dust receiving part, a closing lid for closing the discharge opening is provided, and the dust receiving part is moved over the dust receiving part. There is considered an electric vacuum cleaner provided with a sweeping member that sweeps out dust accumulated in the dust receiving portion and discharges it to the discharge opening, so that the closing member is opened when the sweeping member comes to the position of the discharge opening. Yes.
JP 2004-358135 A

  However, even in such a vacuum cleaner, when the sweeping member is stopped at the position of the discharge opening, the discharge opening remains open, and the electric blower is driven by operating the hand operation switch in this state. If it does, the problem that the dust discharged | emitted by the discharge opening will be attracted | sucked and will adhere to a pleat filter again will generate | occur | produce.

  The object of the present invention is that when the operation member is operated when the sweeping member is stopped at the position of the discharge opening, the dust discharged to the discharge opening is sucked and adheres to the secondary filter again. The object is to provide a vacuum cleaner that never happens.

In order to achieve the above object, a first aspect of the present invention provides a first separation unit that separates dust sucked from a dust suction port into dust and air, and a dust collection unit that collects the dust separated by the first separation unit. A dust part; a secondary filter disposed downstream of the first separation part; a dust removing means for dropping dust adhering to the secondary filter; a dust receiving part for receiving dust dropped by the dust removing means; An air passage wall that divides the air passage between the secondary filter and the first separation portion, or a closing lid that closes a discharge opening provided in the dust receiving portion, and the dust is moved when the sweeping member moves. A vacuum cleaner that sweeps out dust accumulated in the receiving part, and the dust thus swept out is discharged from the discharge opening where the closing lid is opened to the first separation part or upstream thereof or to the dust collecting part,
The closing lid closes the discharge opening when the sweeping member comes to the position of the discharge opening and discharges dust from the discharge opening, and then the sweep member comes to a position shifted from the discharge opening. Provided,
When the power is turned on or before the electric blower starts to be driven, the sweeping member is moved and stopped at a position shifted from the discharge opening.

  According to the present invention, when the electric blower is driven, when the electric blower is driven, the sweeping member is moved and stopped at a position shifted from the discharge opening when the electric blower is started. Is closed by the closing lid, so that dust discharged to the discharge opening is prevented from being sucked and again attached to the secondary filter.

  Hereinafter, an example which is an embodiment of a vacuum cleaner concerning this invention is described based on a drawing.

  The vacuum cleaner 10 shown in FIG. 1 has a vacuum cleaner main body 11 and a dust collecting hose 12 having one end detachably connected to a connection port 11A of the vacuum cleaner main body 11 and a hand operation tube 13 provided at the other end. And an extension pipe 14 that is detachably connected to the hand operation pipe 13 and a suction port body 15 that is detachably connected to the distal end portion of the extension pipe 14. The operation tube 13 is provided with an operation unit 13A, and the operation unit 13A is provided with a plurality of operation switches 13a.

  A suction chamber (not shown) in which a suction opening (dust suction port) (not shown) for sucking dust is formed on the bottom surface of the suction port body 15 is formed. The suction chamber includes an extension pipe 14 and a dust collecting hose. 12 communicates with a suction connection port 57a of a dust collection unit 50 (see FIG. 6) provided in the cleaner body 11.

  The vacuum cleaner main body 11 includes a main body case 20, a dust collection unit 50 (see FIG. 6) mounted in the main body case 20, and an electric blower 24 described later.

  As shown in FIGS. 2 to 5, a dust collection unit chamber (mounting portion) 22 is formed on the front side of the main body case 20. The dust collection unit chamber 22 has a dust separation unit 400 and a dust collection unit, which will be described later. The unit 410 is detachably mounted.

  An opening 23 is formed in the upper part of the dust collecting unit chamber 22 (see FIG. 3), and the opening 23 is closed by lid cases 21A and 21B as shown in FIG. Further, an electric blower 24 is provided on the rear side of the main body case 20, and a cylindrical connection air passage portion 25 having a front opening 25B is formed on the front side (right side in FIG. 2) of the electric blower 24. A lattice member 25K is disposed in the connection air passage portion 25, and a seal member 27 is attached to the front opening 25B. A connection opening 25b is formed in the rear wall 25A of the connection air passage 25, and the connection opening 25b communicates with the suction opening 24A of the electric blower 24.

  As shown in FIGS. 3 to 5, the dust collection unit chamber 22 is provided with a drive gear (first transmission means) 110 and a drive motor (drive means) M that rotates the drive gear Ga.

  As shown in FIGS. 6 to 8, the dust collection unit 50 includes a dust separation unit 400 and a dust collection unit 410.

  The dust separation unit 400 includes a dust separation part (first separation part) 52, a filter part 80 integrated with the dust separation part 52, and a lid case 21A provided on the filter part 80. Yes. The dust collection unit 410 includes a dust collection unit 70 and a lid case 21 </ b> B provided on the dust collection unit 70.

  The dust separator 52 includes a separation chamber 54 formed in a cylindrical shape by the outer peripheral wall 53, and a substantially conical dust separation means 55 provided in the separation chamber 54 along the axis of the separation chamber 54. A suction air passage portion 56 provided outside the right side wall 54A (see FIG. 9) of the separation chamber portion 54 and a guide air passage tube 57 for guiding air from the suction connection port 57a (see FIG. 6) to the separation chamber portion 54. And have. The suction connection port 57a communicates with the connection port 11A of the cleaner body 11 when the dust separation unit 400 is mounted in the dust collection unit chamber 22 of the cleaner body 11.

  As shown in FIG. 7, an introduction opening 53A for introducing dust separated from air into the dust collection section 70 and a discharge opening 84K (see FIG. 10), which will be described later, are provided on the upper portion of the outer peripheral wall 53 of the separation chamber section 54. An introduction hole 153B for introducing the discharged dust into the separation chamber portion 54 is formed.

  Further, as shown in FIGS. 9 and 10, a circular opening 154A and a fan-shaped opening 154B are formed on the right side wall 54A of the separation chamber 54, and a dust separating means 55 is attached to the opening 154A. A net filter NF2 is attached to the opening 154B. Further, a connection opening 54Aa is formed in the right side wall 54A, and a guide air passage tube 57 is connected to the connection opening 54Aa, and the separation chamber portion 54 and the guide air passage tube 57 communicate with each other.

  The left side surface (in FIG. 7) of the separation chamber portion 54 is opened, and a lid 58 (see FIG. 8) is detachably attached to the opening 54Ba (see FIG. 9).

  As shown in FIG. 10, the dust separating means 55 includes a disk 55a, a ring frame 55b, a plurality of connection frames 55c connecting the disks 55a and the ring frame 55b, and a net pasted around the connection frame 55c. The filter NF1. The suction air passage portion 56 communicates with the inside of the separation chamber portion 54 via the opening 154A of the right side wall 54A and the net filter NF1 of the dust separation means 55, and via the net filter NF2 of the opening 154B of the right side wall 54A. It communicates with the inside of the separation chamber 54.

  The suction air passage section 56 communicates with a storage case 81 of the filter section 80 described later, and a dust collection case section 74 described later through a connection opening 56A formed in the right side wall section 156 (see FIG. 7). To the dust collection chamber 73.

  Air introduced from the guide air duct 57 into the separation chamber 54 through the connection opening 54Aa of the separation chamber 54 is counterclockwise as indicated by the arrows in FIGS. It is designed to rotate.

  As shown in FIGS. 11 and 12, the dust collection portion 70 includes a communication case portion 72 in which a communication passage 71 (see FIG. 7) extending in the left-right direction is formed in the upper portion, and a lower side from the right end portion of the communication case portion 72. And a dust collection case 74 having a dust collection chamber 73 (see FIG. 7) for collecting dust.

  An opening 72A is formed in the lower surface of the communication case portion 72, and the opening 72A is connected to the introduction opening 53A of the dust separation portion 52 as shown in FIG. Further, as shown in FIG. 13, a connection opening 75 is formed in the left side wall portion 74 </ b> A of the dust collection case portion 74, and a net filter NF <b> 3 is attached to the connection opening 75.

  A cover plate 170 is attached to the outer wall of the dust collecting case 74 at a position outside the net filter NF3 and at a predetermined distance from the net filter NF3. An opening 170A is formed in the lower portion of the cover plate 170, and the upper portion of the net filter NF3 is covered with the cover plate 170 from a position separated by a predetermined distance (see FIG. 7).

  The opening 170A of the cover plate 170 is connected to the connection opening 56A of the suction air passage section 56 as shown in FIG.

  Further, the dust collection case portion 74 includes a case portion 174 whose right side surface is open (see FIG. 13) and a lid body 77 (see FIG. 14) attached to the opening 76 of the case portion 174 so as to be freely opened and closed. ing.

  An arm 77M extending in the left direction as shown in FIG. 12 is formed on the bottom wall 77A of the lid 77, and a shaft 77J is provided on the arm 77M as shown in FIG. The shaft portion 77J is rotatably held by a bearing portion 78 provided at the bottom of the dust collecting case portion 74. And the opening 76 of the dust collecting case part 74 is opened and closed by the lid body 77 turning around the shaft part 77J.

  Further, a hook (not shown) is formed on the upper portion of the lid 77, and the hook 77 is locked to a locking portion (not shown) of the dust collecting case 74 so that the lid 77 is not opened. . Then, as shown in FIG. 15, when the release button 21Ba provided on the lid case 21B of the dust collecting unit 70 is operated, the hook is unlocked, and the lid body 77 is moved downward, whereby the lid body 77 is released. Opens around the shaft 77J by its own weight.

  As shown in FIG. 14, the lid 77 includes a bottom wall portion 77A, side wall portions 77B and 77C formed on both sides of the bottom wall portion 77A, and an upper wall formed on top of the side wall portions 77B and 77C. A portion 77D, and a bottom plate 77A, side walls 77B and 77C, and a cover plate 77E surrounded by the upper wall 77D. The case portion 174 and the lid body 77 are formed by dividing the dust collection case portion 74 into two vertically and the width of the side wall portion 77B of the lid body 77 is the side portion of the dust collection case portion 74. Is set to 1/2 or more of the width.

  When the dust collection unit 410 is attached to the dust collection unit chamber 22 of the cleaner body 11 to which the dust separation unit 400 is attached, the dust separation unit 52 is introduced into the opening 72A of the dust collection unit unit 410 as shown in FIG. The opening 53A is connected, and the opening 170A of the cover plate 170 of the dust collection unit 410 is connected to the connection opening 56A of the suction air passage unit 56 of the dust separation unit 400.

  The filter unit 80 has a rear surface (left side surface in FIG. 8) opened and a cylindrical storage case (air channel wall) 81, and a pleated filter body (secondary filter) rotatably mounted in the storage case 81. ) 100 and a sweeping body 300 (see FIG. 16) that rotates integrally with the pleated filter body 100. A dust separator 52 is integrally formed on the front surface (right side in FIG. 6) of the front wall (partition wall) 84 of the storage case 81. The inside of the storage case 81 is a filter chamber 181 (see FIG. 10).

  As shown in FIG. 16, the front wall portion 84 of the storage case 81 is formed with a connection opening 84A and a discharge opening 84K for discharging dust at the top, and the connection opening 84A is formed in the suction air passage portion 56 (see FIG. 7). It is connected. The inside of the storage case 81 and the suction air passage portion 56 communicate with each other through the connection opening 84A.

  As shown in FIG. 10, the discharge opening 84 </ b> K is closed by a closing lid 450, and the closing lid 450 is urged rearward (leftward in FIG. 10) by a spring 401. Further, the closing lid 450 can move forward (rightward) against the biasing force of the spring 401, and the discharge opening 84K is opened by moving forward. The closing lid 450 is provided with a protrusion 450A, and the protrusion 450A protrudes into the storage case 81 from the discharge opening 84K.

  The discharge opening 84 </ b> K is communicated with the introduction hole 153 </ b> B of the dust separator 52 by the communication member 403.

  Further, as shown in FIG. 16, a pair of protrusions (dust removing means) 88 spaced apart from each other are provided in the vicinity of the connection opening 84A of the front wall portion 84, and a ridge portion 104A ( It comes into contact with the protruding portion 104Ab of the peak portion with respect to the upstream side. A shaft 84J is formed at the center of the front wall 84.

  An inner peripheral wall surface of the storage case 81 serves as a dust receiving portion 86 that receives dust dropped from the pleated filter 104.

  As shown in FIG. 17, the pleated filter body 100 includes a cylindrical frame body 101, a shaft portion 101A provided at the center position of the frame body 101, and a plurality of pleats for forming radial pleats from the shaft portion 101A. Pleated bones 102 and 103, and a pleated filter 104 which is a filter formed by being attached to the pleated bones 102 and 103.

  As shown in FIG. 2, the shaft 84J of the front wall portion 84 is relatively rotatably inserted into the shaft hole 101Aa of the shaft portion 101A so that the pleat filter body 100 rotates about the shaft 84J. It has become.

  A cylindrical portion 110 having a short length as shown in FIG. 17 is formed at the rear end of the frame 101, and three small diameters having small diameters along the circumferential direction as shown in FIG. 18 are formed on the outer peripheral surface of the cylindrical portion 110. The portions 110A are formed at equal intervals. The large diameter portion 110 is between the small diameter portion 110A and the small diameter portion 110A.

  The small-diameter portion 110A and the large-diameter portion 110 are detected by a microswitch (detecting means) S1, and the microswitch S1 (not shown) is provided in the dust collection unit chamber 22 of the cleaner body 11. . In this embodiment, for example, the micro switch S1 is turned on when the large diameter portion 110 is detected, and is turned off when the small diameter portion 110A is detected.

  A gear 107 is formed on the rear end surface of the cylindrical portion 110 as shown in FIG. 17, and the gear 107 and the cylindrical portion 110 protrude outward from the storage case 81, and the gear 107 is used for collecting dust in the cleaner body 11. The pleated filter body 100 is rotated in the storage case 81 by driving the motor M so as to mesh with the drive gear Ga of the unit chamber 22.

  When the dust separation unit 400 is attached to the dust collection unit chamber 22 of the cleaner body 11, the gear 107 is engaged with the drive gear Ga. When the dust separation unit 400 is lifted from the dust collection unit chamber 22, the gear 107 is driven. Detaching from the Ga allows the dust separation unit 400 to be easily removed from the dust collection unit chamber 22.

  As shown in FIGS. 19 and 20, the sweeping body 300 is fitted to the shaft portion 101A of the pleated filter body 100 and rotates integrally with the shaft portion 101A. It has three arms 302 extending in the radial direction, and a sweeping member 303 provided at the tip of this arm 302. In FIG. 20, the two sweep members 303 are omitted.

  The tip of the sweeping member 303 is a first sliding contact portion 303A that slidably contacts the inner wall surface of the dust receiving portion 86 of the storage case 81 and scrapes up dust accumulated in the dust receiving portion 86. One side portion of the sweeping member 303 is a second sliding contact portion 303 </ b> B that slides on the front wall portion 84 of the storage case 81. Further, an inclined surface (guide inclined surface) 303C is formed on one surface of the sweeping member 303 to drop the dust scraped up by the first sliding contact portion 303A to the discharge opening 84K.

  The sweeping body 300 rotates as the pleated filter body 100 rotates, and this rotation causes the sweeping member 303 to move along the inner peripheral surface of the dust receiving portion 86 of the storage case 81 shown in FIG. Move the inner peripheral surface and the front wall 84 in sliding contact. As a result of this sliding movement, the sweeping member 303 pushes up the dust collected in the dust receiving portion 86 and pushes it up to the discharge opening 84K.

  When the sweeping member 303 moves to the position of the discharge opening 84K, the sweeping member 303 presses the protrusion 450A of the closing lid 450 and moves the closing lid 450 forward against the biasing force of the spring 401. Then, the discharge opening 84K is opened.

  When the pleat filter body 100 is rotated and the sweep member 303 is in the position shown in FIG. 16, the microswitch S1 is switched from on to off, that is, the microswitch S1 is large in the cylindrical portion 110 of the pleat filter body 100. The attachment position of the microswitch S1 and the attachment position of the sweep body 300 with respect to the pleated filter body 100 are set so as to switch from the detection of the diameter portion 110B to the detection of the small diameter portion 110A.

  When the sweeping member 303 comes to the position shown in FIG. 16, the discharge opening 84 </ b> K is closed by the closing lid 450.

  Further, when the dust separation unit 400 is mounted in the dust collection unit chamber 22 of the cleaner body 11, the storage case 81 of the dust separation unit 400 is inserted into the front opening 25 </ b> B of the connection air passage portion 25 of the cleaner body 11 via the seal member 27. The rear end face is joined, and the inside of the storage case 81 and the suction opening 24 </ b> A of the electric blower 24 are communicated with each other through the connection air passage portion 25.

FIG. 21 is a block diagram showing the configuration of the control system of this vacuum cleaner. In FIG. 21, reference numeral 200 denotes a control device that controls the electric blower 24 and the motor M based on the operation of the operation switch 13a (see FIG. 1) of the operation unit 13A and the detection signal of the micro switch S1.
[Operation]
Next, operation | movement of the vacuum cleaner comprised as mentioned above is demonstrated.

  First, as shown in FIG. 2, the dust collection unit 50 is mounted in the dust collection unit chamber 22 of the cleaner body 11, and the dust collection hose 12 is connected to the connection port 11 </ b> A of the cleaner body 11 as shown in FIG. 1. At the same time, the suction port body 15 is connected to the hand operation tube 13 via the extension tube 14.

  Then, a power plug (not shown) is connected to the outlet. When the power plug is connected to the outlet, the control device 200 drives the motor M to rotate the pleated filter body 100 of the filter unit 80. As the pleated filter body 100 rotates, the sweep body 300 rotates, and the sweep member 303 of the sweep body 300 has its first sliding contact portion 303A slidingly moved on the peripheral surface of the dust receiving portion 86. The dust accumulated in the dust receiving portion 86 is pushed up along the peripheral surface.

  Thus, the sweeping member 303 pushes up the dust along the dust receiving portion 86 to the discharge opening 84K by the rotational movement, so that the push-up can be performed with a simple structure. Further, since the sweeping body 300 is rotated by the rotation of the pleated filter body 100, only one drive source is required, and a dedicated motor for the sweeping body 300 is not necessary.

  Then, when the sweeping member 303 comes to the position of the discharge opening 84K, the second sliding contact portion 303B of the sweeping member 303 presses the projection 450A of the closing lid 450 as shown in FIG. Establish.

  On the other hand, the dust scraped up by the first sliding contact portion 303A of the sweep member 303 is dropped onto the inclined surface 303C via the side surface 303D of the sweep member 303, and the dust is further discharged to the discharge opening 84K by the inclined surface 303C. Dropped and discharged. The dust dropped into the discharge opening 84K is returned into the separation chamber portion 54 from the introduction hole 153B of the dust separation portion 52 via the communication member 403.

  Then, when the sweep member 303 comes to the position shown in FIG. 16 due to the rotation of the pleat filter body 100, the microswitch S1 shifts from detection of the large diameter portion 110B of the cylindrical portion 110 of the pleat filter body 100 to detection of the small diameter portion 110A. As a result, the driving of the motor M is stopped. Then, when the sweeping member 303 moves to the position shown in FIG. The discharge opening 84K is closed.

  While the motor M is being driven, that is, until the discharge opening 84K is closed by the closing lid 450, the electric blower 24 is not driven even if the switch 13a of the operation portion 13A of the hand operation tube 13 is operated. Thereby, the dust discharged into the separation chamber portion 54 of the dust separation portion 52 is prevented from being sucked from the discharge opening 84K and attached to the pleat filter 104 again.

  When the switch 13a of the operation unit 13A of the hand operation tube 13 is operated, the electric blower 24 is driven. By driving the electric blower 24, air is sucked from the suction opening 24 </ b> A of the electric blower 24, a negative pressure acts in the storage case 81 of the dust collection unit 50 through the connection air passage portion 25, and the suction air passage It acts on the inside of the dust collecting case part 74 and the separation chamber part 54 of the dust separation part 52 via the part 56. The negative pressure acts on the dust collecting hose 12, the extension pipe 14 and the suction port body 15 via the guide air duct tube 57, and dust is sucked together with air from the suction port body 15.

  The sucked dust and air are sucked into the suction connection port 57a of the dust collecting unit 50 through the extension pipe 14 and the dust collecting hose 12. Dust and air sucked into the suction connection port 57a are introduced into the separation chamber portion 54 of the dust separation portion 52 through the guide air duct 57, and rotate counterclockwise in FIG. I will do it.

  As a result of this rotation, dust and air are separated by inertia, and the air passes through the net filter NF1 (see FIG. 10) of the dust separating means 55 and the net filter NF2 of the opening 154B, and further passes through the suction air passage portion 56 to the filter portion. Suction into the 80 storage cases 81 is performed.

  On the other hand, the separated dust is introduced together with a part of the air into the communication case portion 72 of the dust collection portion 70 of the introduction opening 53A of the separation chamber portion 54 by inertial force. The introduced dust and air are sucked into the dust collection chamber 73 through the communication path 71 of the communication case portion 72, and the dust is collected in the dust collection chamber 73.

  The air sucked into the dust collection chamber 73 is sucked into the suction air passage section 56 through the net filter NF3 and the opening 170A below the cover plate 170, and further sucked into the storage case 81 of the filter section 80.

  The net filter NF3 is covered by the cover plate 170 at a position separated by a predetermined distance, and an opening 170A is formed in the lower portion of the cover plate 170, so that a large amount of air flows in the lower portion of the net filter NF3. For this reason, clogging occurs from the lower side of the net filter NF3, and more dust can be accumulated in the dust collection chamber 73.

  The air sucked into the storage case 81 passes through the pleated filter 104 of the pleated filter body 100 and is sucked into the connection air passage portion 25 of the cleaner body 11 and further sucked into the suction opening 24A of the electric blower 24.

  Air sucked into the suction opening 24A of the electric blower 24 passes through the electric blower 24 and is exhausted from the exhaust port 20H of the cleaner body 11 shown in FIG.

  When the cleaning is completed, the operation of the electric blower 24 is stopped by operating the operation switch 13a of the operation unit 13A. When driving of the electric blower 24 is stopped, the control device 200 shown in FIG. The drive gear Ga is rotated by driving the motor M, and the pleated filter body 100 is rotated.

  Due to the rotation of the pleated filter body 100, the projection 88 of the front wall portion 84 of the storage case 81 hits the protruding portion 104Ab of the peak portion 104A of the pleated filter 104, and vibration is applied to the pleated filter 104 and adheres to the pleated filter 104. Dust is shaken off. This dust accumulates in the dust receiving part 86 of the storage case 81.

  Since the protrusion 88 is provided below the center of rotation of the pleated filter body 100, a large vibration is applied to the pleated filter 104 in the lower portion of the pleated filter body 100. For this reason, dust is shaken off from the lower pleat filter 104 and falls to the dust receiving portion 86 as it is, and it does not adhere to the pleat filter 104 again during the fall, and therefore it is efficient. Dust can be dropped.

  On the other hand, the sweeping body 300 rotates together with the pleated filter body 100, and the first sliding contact portion 303A of the sweeping member 303 of the sweeping body 300 slides on the inner peripheral surface of the dust receiving portion 86 of the storage case 81. I will do it. By this sliding movement, the dust accumulated in the dust receiving portion 86 is pushed up along the peripheral surface of the dust receiving portion 86 while being scraped up, and the sweep member 303 is moved to the position of the discharge opening 84K. Then, the discharge opening 84K is opened as described above (see FIG. 22), and the pushed up dust is discharged to the discharge opening 84K, and inside the separation chamber portion 54 of the dust separation portion 52 via the communication member 403. Returned to

  Then, for example, when the pleated filter body 100 rotates once and the sweep member 303 comes to the position shown in FIG. 16, the microswitch S1 detects the small diameter portion 110A from the detection of the large diameter portion 110B of the cylindrical portion 110 of the pleated filter body 100. , Thereby stopping the driving of the motor M and stopping the rotation of the pleated filter body 100. As described above, the discharge opening 84K is closed by the closing lid 450.

  When the operation switch 13a is operated again, the control device 200 drives the motor M to rotate the pleated filter body 100 of the filter unit 80 as described above. Then, the sweeping body 300 is rotated by the rotation of the pleated filter body 100. Due to the rotation of the sweeping body 300, the dust accumulated in the dust receiving portion 86 is pushed up as described above, the discharge opening 84K is opened, and the dust is discharged from the discharge opening 84K. When the output member 303 comes to the position shown in FIG. 16, which is a position shifted from the discharge opening 84K, the driving of the motor M is stopped by the detection of the microswitch S1, the rotation of the pleated filter body 100 is stopped, and the discharge opening 84K is closed. And the electric blower 24 is driven and cleaning is performed.

  Thus, before the electric blower 24 is driven, the motor M is driven, the pleated filter body 100 and the sweep body 300 are rotated, and the sweep member 303 passes through the discharge opening 84K and is displaced from the discharge opening 84K. Therefore, even if the discharge opening 84K is opened, the discharge opening 84K is reliably closed by the closing lid 450, and when the electric blower 24 is driven, the separation chamber of the dust separation unit 52 is driven. The problem of sucking the dust returned to the portion 54 from the discharge opening 84K is prevented.

  Further, when the sweep member 303 of the sweeper 300 opens the discharge opening 84K, if the power plug is pulled out from the outlet, the driving of the motor M is stopped and the discharge opening 84K remains open. Thus, when the power plug is connected to the outlet, the motor M is driven to rotate the pleated filter body 100, and when the sweeping member 303 reaches the position shown in FIG. Since the outlet member 303 is stopped at the position shown in FIG. 16, the discharge opening 84 </ b> K is closed by the closing lid 450, and thereafter the electric blower 24 is driven, so that the separation chamber portion 54 of the dust separation portion 52. The problem of sucking the dust returned to the discharge opening 84K is prevented.

  Further, since the dust accumulated in the dust receiving portion 86 is returned to the separation chamber portion 54 of the dust separation portion 52 from the discharge opening 84K through the communication member 403 by the rotational movement of the sweep member 303, the pleat filter The dust collecting unit 410 may not be provided with a dedicated dust collecting unit for 104.

  When clogging occurs in the pleat filter 104 due to long-term use, the dust separation unit 400 is removed from the cleaner body 11 and the pleat filter 104 is cleaned.

  The dust separation unit 400 is first removed after the dust collecting unit 410 is removed from the cleaner body 11 so that the drive gear Ga is positioned below the rotational center position of the gear 107 of the pleated filter body 100. By setting, the gear 107 of the pleated filter body 100 is disengaged from the drive gear Ga simply by lifting the dust separation unit 400 upward without disturbing the drive gear Ga. For this reason, the dust separation unit 400 can be easily removed from the dust collection unit chamber 22 of the cleaner body 11.

  Further, when the dust separation unit 400 is attached, if the dust separation unit 400 is inserted from above the dust collection unit chamber 22, the gear 107 of the pleat filter body 100 meshes with the drive gear Ga without causing the drive gear Ga to get in the way. The dust separation unit 400 can be easily attached to the dust collection unit chamber 22.

  In the above embodiment, the motor M is driven when the power plug is connected to the outlet, and then the electric blower 24 is driven without driving the motor M when the operation switch 13a is operated. The motor M may be driven before the electric blower 24 is driven.

  Moreover, in the said Example, although the dust discharged | emitted from the discharge opening 84K is returned in the separation chamber part 54 of the dust separation part 52, it is not restricted to this, For example, the guide wind path pipe | tube upstream of the dust separation part 52 You may return to 57 or a dust collection part. Moreover, although what was applied to the inertia separation type vacuum cleaner was demonstrated, you may apply to the normal vacuum cleaner which uses a paper filter, for example.

  In the above embodiment, the pleated filter body 100 is rotated to remove dust adhering to the pleated filter 104. However, the present invention is not limited to this. It may be one that drops.

  In the above embodiment, the canister type vacuum cleaner has been described. However, the present invention can also be applied to an upright type vacuum cleaner or a vacuum cleaner in which a dust separation unit is attached to a hand control tube.

It is the perspective view which showed the external appearance of the electric vacuum cleaner which concerns on this invention. It is the longitudinal cross-sectional view which showed the structure of the cleaner body shown in FIG. It is the perspective view which showed the cleaner body which removed the dust collection unit. It is a longitudinal cross-sectional perspective view of the cleaner body shown in FIG. It is a longitudinal cross-sectional view of the cleaner body which removed the dust collection unit. It is the perspective view which showed the external appearance of the dust collection unit. It is a cross-sectional view of the dust collection unit shown in FIG. It is the perspective view seen from the other direction of the dust collection unit shown in FIG. It is the perspective view which showed the external appearance of the dust separation unit. It is the conceptual diagram which showed the front wall part of the storage case, the dust separation part, and the duct. It is the perspective view which showed the external appearance of the dust collection unit. It is the perspective view which looked at the dust collection unit of FIG. 11 from the other direction. It is the perspective view which showed the dust collection part unit which removed the cover body. It is the perspective view which showed the cover body. It is a top view of the dust collection unit of FIG. It is explanatory drawing which showed the storage case and the sweeping body. It is the side view which showed the pleated filter body. It is explanatory drawing which showed the shape of the cylindrical part of the pleat filter body shown in FIG. It is the front view which showed the sweeping body. It is a perspective view of the sweeping body shown in FIG. It is the block diagram which showed the structure of the control system of a vacuum cleaner. It is explanatory drawing which showed the state by which the discharge opening was opened by the sweep member. It is the perspective view which showed the dust separation part.

Explanation of symbols

52 Dust separator (first separator)
54 Separation chamber 80 Filter 81 Storage case (wind channel wall)
84 Front wall (partition wall)
84K Discharge opening 86 Dust receiving part 104 Pleated filter (secondary filter)
181 Filter chamber 300 Sweep body 303 Sweep member 450 Closure lid M Motor

Claims (3)

A first separation unit that separates dust sucked from the dust suction port into dust and air, a dust collection unit that collects dust separated by the first separation unit, and a downstream of the first separation unit. Secondary filter, dust removing means for dropping dust adhering to the secondary filter, a dust receiving part for receiving the dust dropped by the dust removing means, and an air path between the secondary filter and the first separating part And a closing lid that closes a discharge opening provided in the dust receiving portion, and sweeping out the dust accumulated in the dust receiving portion by moving the sweeping member. An electric vacuum cleaner in which dust is discharged from the discharge opening in which the closing lid is opened to the first separation part or upstream thereof or to the dust collection part,
The closing lid closes the discharge opening when the sweeping member comes to the position of the discharge opening and discharges dust from the discharge opening, and then the sweep member comes to a position shifted from the discharge opening. Provided,
An electric vacuum cleaner, wherein when the power is turned on or before the electric blower starts to be driven, the sweeping member is moved and stopped at a position shifted from the discharge opening.   3. The vacuum cleaner according to claim 2, wherein the sweeping member is stopped at a position shifted from the discharge opening after passing through the discharge opening. When the secondary filter rotates, dust is dropped by the dust removing means, and the dust receiving portion is configured by a cylindrical tube portion surrounding the secondary filter,
The sweeping member rotates integrally with the secondary filter to sweep out dust on the inner peripheral surface of the cylindrical portion,
The electric vacuum cleaner according to claim 1 or 2, wherein the movement of the sweeping member is stopped based on an output of a detection unit that detects a position of the sweeping member.

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