JP2006006383A - Electric vacuum cleaner - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To provide an electric vacuum cleaner which can prevent fine dust stored in a fine dust chamber from being adhered to a fine dust filter again by being blown up when an electric blower is operated. <P>SOLUTION: This electric vacuum cleaner is equipped with a vacuum cleaner main body 1 for which a dust collecting container 37 and the electric blower 17 for applying a suction negative pressure to the dust collecting container 37 are provided, net filters 43 and 104 which are arranged on the upstream side of the dust collecting container 37 and catch dust and dirt, and a pleat filter 48 which is arranged on the downstream side of the dust collecting container 37 and catches fine dust having passed through the net filters 43 and 104. The electric vacuum cleaner is also equipped with a vibration imparting means 49 which shakes off dust and dirt adhered to the pleat filter 48, a fine dust collecting groove 40b which is opened at an upper section and stores fine dust shaken off from the pleat filter 48, and opening/closing members 108 and 109 which open/close the upper opening end of the fine dust collecting groove 40b. In addition, for the electric vacuum cleaner, an opening/closing member opening/closing means 190 which opens the upper opening end of the fine dust collecting groove 40b by opening the opening/closing members 108 and 109 when the vibration imparting means 49 is operated, and also, closes the upper opening end of the fine dust collecting groove 40b by closing the opening/closing members 108 and 109 when the electric blower 17 is operated is provided. <P>COPYRIGHT: (C)2006,JPO&NCIPI

Description

  The present invention relates to a vacuum cleaner that forcibly drops fine dust adhering to a fine dust filter.

In a conventional vacuum cleaner, a vacuum cleaner body provided with a dust collecting portion and an electric blower that applies a suction negative pressure to the dust collecting portion, and disposed upstream of the dust collecting portion to collect dust. A main filter, a fine dust filter disposed downstream of the dust collecting portion and capturing fine dust that has passed through the main filter, a dust dropping means for dropping dust adhering to the fine dust filter, and upward One having a fine dust chamber that opens and stores fine dust dropped from the fine dust filter is known (for example, see Patent Document 1).
Japanese Patent No. 3490081

  However, since the upper end of the fine dust chamber is always open to the negative pressure chamber between the main filter and the fine dust filter, the fine dust stored in the fine dust chamber is rolled up during the operation of the electric blower, and the fine dust filter There was a problem of adhering again.

  Accordingly, an object of the present invention is to provide a vacuum cleaner that can prevent fine dust stored in the fine dust chamber from being rolled up when the electric blower is operated and reattaching to the fine dust filter. is there.

  In order to achieve this object, the invention of claim 1 is provided with a vacuum cleaner body provided with a dust collecting portion and an electric blower that applies a suction negative pressure to the dust collecting portion, and disposed upstream of the dust collecting portion. A main filter that collects dust, a fine filter that is disposed on the downstream side of the dust collection unit and that captures fine dust that has passed through the main filter, and dust that drops dust attached to the fine filter An electric vacuum cleaner comprising: a dropping means; a fine dust chamber that opens upward and stores fine dust that is dropped from the fine dust filter; and an open / close member that opens and closes an upper opening end of the fine dust chamber. When operating the dropping means, the opening / closing member is opened to open the upper opening end of the fine dust chamber, and when the electric blower is operated, the opening / closing member is closed to close the upper opening end of the fine dust chamber. Opening / closing member opening / closing means is provided. And wherein the are.

  According to this configuration, the opening / closing member opening / closing means closes the opening / closing member and closes the upper opening end of the fine dust chamber when the electric blower operates, so that the fine opening stored in the fine dust chamber is closed. It is possible to prevent dust from being rolled up when the electric blower is operated and reattaching to the fine dust filter.

Hereinafter, embodiments of the present invention will be described with reference to the drawings.
[Constitution]
In FIG. 1 (a) and FIG. 2, 1 is the vacuum cleaner main body of a vacuum cleaner. As shown in FIG. 2, the cleaner body 1 includes a lower case 2, a middle case 3 mounted on the lower case 2, and the lower case 2 and the middle case 3 so as to cover the rear part of the middle case 3. And a cover 5 attached to the front end portion of the middle case 3 so as to be vertically rotatable.

  In FIG. 1 (a), 6 is a connecting pipe provided at the front end of the cover 5, 7 is a flexible and bellows-shaped dust collecting hose with one end connected to the connecting pipe 6, and 8 is A hand operated pipe attached to the other end of the dust collecting hose 7. A suction port body 10 is connected to the hand operation pipe 8 via an extension pipe 9. Reference numeral 8 a denotes an operation panel provided on the local operation pipe 8.

  Further, the lower case 2 and the upper case 4 are partitioned into an upper fan chamber 11 and a lower cord reel chamber 12 by a partition wall portion 3a of the middle case 3 as shown in FIG. The front end of the blower chamber 11 is open to the front side, and is closed by a lattice plate (partition wall) 13 that is an end wall (front wall) attached to the open end. Moreover, the blower chamber 11 communicates with the atmosphere through a large number of exhaust holes 14 formed in the side wall 4a of the upper case 4 as shown in FIG.

  As shown in FIG. 2, a fan supporting cylinder portion 15 protruding into the blower chamber 11 is provided on the upper portion of the lattice plate 13, and a lattice portion 16 communicating with the cylinder portion 15 is provided. (See FIGS. 9 to 11). As shown in FIG. 11, flat guide side walls 15a, 15a extending in the vertical direction are provided on both sides of the cylindrical portion 15, and the cylindrical portion 15 is formed in an oval shape. Reference numeral 16 a denotes a communication air passage (suction air passage) provided in the lattice portion 16. In addition, a small-diameter cylindrical portion 13a that protrudes rearward is formed integrally with the lower portion of the lattice plate 13, and a shaft insertion hole 13b that opens concentrically with the cylindrical portion 13a is formed.

  An electric blower 17 is disposed in the blower chamber 11 as shown in FIG. The electric blower 17 includes a front centrifugal fan unit 18 and a motor unit 19 that drives the centrifugal fan unit 18. 18 a is an air suction port of the centrifugal fan unit 18, and 19 a is an exhaust port of the motor unit 19. The centrifugal fan portion 18 is supported in the middle case 3 via an annular elastic member (buffer member) 20, and the elastic member 20 is abutted and supported on the end surface of the cylindrical portion 15. As a result, the centrifugal fan portion 18 has the air suction port 18a opened in the cylindrical portion 15 and forms a negative pressure chamber 21 as a suction air passage between the lattice portion 16 and the centrifugal fan portion 18.

  Further, as shown in FIG. 2, a support shaft 22 is disposed vertically in the cord reel chamber 12, and a terminal ring mounting plate 23 and its cover 24 (not shown) are provided at the upper end of the support shaft 22. Is fixed (see FIG. 13). The mounting plate 23 and the cover 24 are attached to the partition wall 11a of FIG. 2, and hold the upper end portion of the support shaft 22 to the partition wall 11a. The lower end portion of the support shaft 22 is attached to the bottom wall 2 a of the lower case 2.

  A cord reel 25 as shown in FIGS. 10 to 13 is attached to the support shaft 22 so as to be horizontally rotatable as shown in FIG. The cord reel 25 is urged to rotate in one direction (cord winding direction) by a rotation urging means such as a spiral spring (not shown).

  The cord reel 25 has a drum portion 26 for winding the cord, and an upper flange 27 and a lower flange 28 provided at both end portions (upper and lower end portions) of the drum 26. A large-diameter drive gear 29 in which a large number of teeth are arranged in a ring shape in the circumferential direction is provided at the peripheral edge of the upper surface of the upper flange 27. A power cord 30 that supplies driving power to the electric blower 17 is wound around the cord reel 25 by the rotation urging force of the rotation urging means described above. As shown in FIG. 1B, the power cord 30 is provided so as to be pulled out from a cord outlet 2b provided at the rear portion of the lower case 2.

  A brake device 31 as shown in FIG. 11 is attached to the attachment plate 23. The brake device 31 includes a brake arm 32 that is held on the support shaft 23a of the mounting plate 23 so as to be horizontally rotatable, a brake roller (not shown) that is attached to a free end of the brake arm 32, A spring is provided that presses the brake arm 32 and presses the brake roller against the peripheral surface of the upper flange 27.

  In the brake device 31, the brake roller is usually moved by the spring force of a spring that urges the brake arm 32 to rotate and the spring force of the rotation urging means that urges the cord reel 25 to rotate. And the upper flange 27 are bitten like a wedge so that the rotation of the cord reel 25 is locked. In the brake device 31, the power cord 30 provided so as to be able to be pulled out rearward from the lower case 2 is pulled, and the cord reel 25 is rotated against the spring force of the rotation urging means, thereby The roller is slightly moved in the direction of rotation of the cord reel 25, and the state in which the brake roller is wedged between the brake arm 32 and the upper flange 27 is released, so that the brake roller is moved to the upper flange 27. The press contact state is released. When the drawing force is released from the power cord 30, the cord reel 25 is slightly rotated in the direction of winding the power cord 30 by the rotation urging means, and the brake roller is wedge-shaped between the brake arm 32 and the upper flange 27. The cord reel 25 stops rotating and the power cord 30 is pulled out. As the structure of the brake device 31, a well-known one such as that disclosed in Japanese Patent Laid-Open No. 6-46974 can be employed.

  Further, the vacuum cleaner main body 1 is provided with a handle 33 that is attached to the front end portion of the upper case 4 so as to be movable up and down within a predetermined range, and that can be pulled upward from the upper surface of the upper case 4 by a predetermined amount. The handle 33 is formed in an inverted U shape from an upper arc-shaped grip 34 and guide portions 35 and 35 (see FIGS. 9 to 12) integrally connected downward to both ends of the grip 34. Is formed. The guide portions 35, 35 are disposed on both sides of the guide side walls 15a, 15a provided on the cylindrical portion 15 of the lattice wall 13, and are provided so as to be movable up and down.

  An inclined cam surface 35 a is formed at the lower end portion of the one guide portion 35 so as to incline toward the front upper side. The inclined cam surface 35a is engaged with the brake arm 32 from above, and when the handle 33 is pushed downward, the inclined cam surface 35a resists the spring force of a spring (not shown) around the support shaft 23a. Then, the brake roller (not shown) is moved away from the upper flange 27 by rotating to the lattice wall 13 side, and the locked state of the cord reel 25 is released. Thereby, the cord reel 25 is rotated in the direction in which the power cord 30 is wound up by the rotation urging means.

  Further, in FIG. 2, the middle case 3 has a front extending portion 3 b. A concave portion 36 is formed in the front extending portion 3b (see FIG. 1B). As shown in FIG. 2, a dust collection container 37 as a dust collection unit is fitted and placed in the recess 36. The dust collecting container 37 can be pressed by a cover 5 attached to the front end portion of the middle case 3 so as to be rotatable up and down. The dust collecting container 37 can be taken out from the recess 36 by opening the cover 5 upward. A known configuration can be adopted for this structure.

  The extending portion 3b has a vertical wall 3b1 integrally formed downward at the front end of the partition wall portion 3a. The vertical wall 3b1 has a step 3b2 positioned on the front side at an intermediate portion in the vertical direction, and a lattice plate 13 as a front wall of the upper case 4 is in contact with the step 3b2. A space S is formed between the upper part of the vertical wall 3b1 and the lower part of the lattice plate 13.

  The dust collecting container 37 has a case main body 38. A dust collection chamber 38a that opens downward is provided at the lower portion of the case main body 38, a negative pressure chamber 38b is provided at the upper portion of the case main body 38, and an upper front end of the case main body 38 communicates with the negative pressure chamber 38b. A suction port 38c is provided. The suction port 38 c communicates with the connection pipe portion 6. A rear opening 38d for attaching a filter, which is a rear end portion of the negative pressure chamber 38b, is formed in the rear end portion of the case body 38.

  Further, the dust collecting chamber 38a has a rear wall 100 as shown in FIG. As shown in FIG. 2A, the rear wall 100 includes a lower rear wall portion 101 that extends vertically, and an upper inclined wall portion 102 that is inclined forward from the lower rear wall portion 101. An opening 103 is formed in the upper inclined wall portion 102, and a net filter 104 is attached to the opening 103.

  Further, the dust collecting container 37 includes a handle 39 integral with the case main body 38, a bottom lid 40 for opening and closing a downward opening end of the dust collecting chamber 38a, and a dust separating means 41 disposed in the negative pressure chamber 38b. As a dust separator.

  The bottom lid 40 is attached to the case body 38 so as to be openable and closable around the rear end. Further, as shown in FIGS. 2 and 2A, the rear end portion 40a of the bottom lid 40 protrudes rearward from the lower rear wall portion 101. The rear end portion 40a is a fine dust that opens upward and extends to the left and right. The collection groove 40b is formed as a fine dust chamber. The bottom cover 40 can also be attached to the case body 38 so as to be openable and closable around the front end. In this case, it becomes easy to throw away the dust collected in the fine dust collecting groove 40b. A conventionally well-known configuration can also be adopted for the opening / closing mechanism of the bottom lid 40.

  Further, at the rear of the lower rear wall portion 101, a lower support wall 105 is provided integrally with the case body 38 as shown in FIG. 2 and forms a rear opening 38d. As shown in FIG. 2A, the lower support wall 105 is formed in a substantially L-shaped cross section from a vertical wall portion 105a extending left and right and up and down, and a support wall portion 105b extending rearward from the upper end of the vertical wall portion 105a. ing.

  In addition, the lower support wall 105 includes side walls 105c and 105d and a partition wall 105e that connect the lower rear wall portion 101 and the vertical wall portion 105a as shown in FIG. 2D. And between the side walls 105c and 105d and the partition wall 105e, the fine dust inlets 106 and 107 opened up and down are formed.

  Further, the lower end openings of the fine dust inlets 106 and 107 are arranged as shown in FIG. 2B when the lower end opening of the dust collecting chamber 38a is closed by the lid 40 as shown in FIG. 2A. The lower end opening of the inlets 106 and 107 is closed by the rear end portion 40a of the lid 40 with the lower end opening facing the fine dust collecting groove (fine dust chamber) 40b.

  Opening and closing members 108 and 109 are disposed in the fine dust inlets 106 and 107 as shown in FIGS. 2B and 2D. As shown in FIG. 2D, the opening / closing member 108 is rotatably held by the lower rear wall portion 101 and the vertical wall portion 105a via coaxial support shafts 108a and 108b, and the opening / closing member 109 is connected to the lower rear wall portion 101. The vertical wall portion 105a is rotatably held via coaxial support shafts 109a and 109b.

  As shown in FIG. 2D, the support shafts 108a and 108b are provided at positions deviated toward the one end a1 side of the opening / closing member 108, and the support shafts 109a and 109b are deviated toward the one end b1 of the opening / closing member 109. Is provided.

  Therefore, the length of the opening / closing member 108 from the support shafts 108a and 108b to the one end a1 is shorter than the length from the support shafts 108a and 108b to the other end a2. Similarly, the opening / closing member 109 is formed such that the length from the support shafts 109a, 109b to the one end b1 is shorter than the length from the support shafts 109a, 109b to the other end b2.

  Further, as shown in FIG. 2B, first stopper protrusions 110 and 111 protruding into the fine dust inlets 106 and 107 are formed on the side wall 105c and the partition wall 105e, respectively. In addition, coil springs 112 and 113 are interposed between the end portions a 1 and b 1 of the opening and closing members 108 and 109 and the upper portion of the lower rear wall portion 101. The coil springs 112 and 113 rotate and bias the opening and closing members 108 and 109 in the direction in which the other ends a2 and b2 of the opening and closing members 108 and 109 abut against the stopper protrusions 110 and 111 from above.

  Further, on the rear surface of the lower rear wall portion 101, as shown in FIG. 2B, second stopper projections 114, which are positioned above the rotation centers (support shafts 108a, 109a) of the opening / closing members 108, 109, respectively. 115 is formed.

  Magnets 116 and 117 are attached to the outer ends of the support shafts 108b and 109b, respectively, as shown in FIGS. 2C and 2D.

  Further, the dust separating means 41 includes a cylindrical portion 42 having a conical diameter reduced rearward and having an opening 42a to the negative pressure chamber 38b, and a net fixed to the inner surface of the cylindrical portion 42 and covering the opening 42a. The filter 43 and the cylinder part 44 which is connected to the rear end of the cylinder part 42 and communicates with the dust collecting chamber 38a.

Further, a wave-shaped pleated filter 48 as shown in FIG. 6 is detachably fitted in the rear end portion of the negative pressure chamber 38b.
(Vibration applying means)
As shown in FIG. 2, vibration imparting means 49 as dust removing means (dust removing means) for dropping dust attached to the pleated filter 48 is disposed behind the pleated filter 48 (on the downstream side of the air flow). (See FIGS. 9, 10, 12, and 13). The vibration applying means 49 has a large-diameter gear 50 disposed between the lattice plate 13 and the pleated filter 48.

  The gear 50 is provided integrally with the boss 51 rotatably supported on the lattice plate 13 by the support shaft 51a, a plurality of arms 52 provided integrally with the boss 51 and radially, and a plurality of arms 52. An annular gear portion 53, an annular support portion 54 that is located between the boss 51 and the annular gear portion 53 and provided integrally with the arm 52, and an intersection of the arm 52 and the annular support portion 54 are shown in FIG. It has the protrusion 55 projected in this way.

Further, as shown in FIG. 8, the vibration applying means 49 includes a coil spring 56 whose base end portion is press-fitted on the outer peripheral surface of the protrusion 55, and an engagement member 57 fitted on the free end portion of the coil spring 56. (See FIGS. 2, 7, 9, 10, 12, and 13). The engagement element 57 is formed in a tapered shape that gradually decreases in diameter toward the tip, and the tip is formed in a spherical shape. Further, the engaging element 57 is shallowly engaged between the crests 48 a and 48 a of the corrugated part of the pleated filter 48.
(Rotational force transmission means 58)
Further, the gear 50 is linked to the cord reel 25 by a rotational force transmission means (power transmission means) 58 as shown in FIG. The rotational force transmitting means 58 penetrates through the cylindrical portion 13a and the shaft insertion hole 13b of the lattice plate 13, and has one end protruding into the air passage on the dust collecting chamber side and the other end on the blower chamber 11 (on the electric blower 17 side). ) Projecting on the rotary shaft 59 (see FIGS. 10 and 13), a pinion (a small-diameter gear serving as interlocking means) 60 fixed to one end of the rotary shaft 59 and meshing with the annular gear portion 53 of the gear 50, A pinion (small-diameter gear) 61 is provided as a driving rotating body that is rotatably held at the other end of the rotating shaft 59 and immovably held in the axial direction. The pinion 61 is engaged with the drive gear 29 of the cord reel 25 and interlocked with the cord reel 25. 3 and 4, 59 a is a guide convex portion extending in a direction parallel to the axis formed on the peripheral surface of the rotation shaft 59. The pinion 60 has a boss 60a that fits into the shaft insertion hole 13b (see FIGS. 3 and 5).

  Further, the rotational force transmitting means 58 has a cylindrical driven rotating body 62 which is positioned between the pinion 60 and the lattice plate 13 and is fitted to a portion where the guide convex portion 59a of the rotating shaft 59 is provided. As a result, the driven rotor 62 is held on the rotary shaft 59 so as to be movable in the axial direction and not to be relatively rotatable. Further, the rotational force transmitting means 58 has a one-way clutch 63 provided at the opposing portion of the pinion 61 and the driven rotor 62. The one-way clutch 63 includes a ratchet pawl 64 provided on the pinion 61, a ratchet pawl 65 provided on the driven rotating body 62 and engaged with the ratchet pawl 64, and a coil spring that presses the ratchet pawl 65 against the ratchet pawl 64. 66.

  In addition, when the cord reel 25 is rotated in the direction in which the power cord 30 is pulled out, the one-way clutch 63 moves on the rotating shaft 59 in a direction in which the driven rotor 62 is separated from the pinion 61 against the spring force of the coil spring 66. The ratchet pawl 64 moves over the ratchet pawl 65 so that the ratchet pawls 64 and 65 rotate relative to each other. Further, when the one-way clutch 63 rotates in the direction in which the cord reel 25 winds up the power cord 30, the ratchet claws 64 and 65 are engaged with each other so that the pinion 61 and the driven rotor 62 rotate integrally. ing.

Further, the rotational force transmitting means 58 has an annular seal member 67 that is fitted to the outer periphery of the rotation shaft 59 and is brought into contact with the lattice plate 13 to seal between the shaft insertion hole 13b and the rotation shaft 59. . The above-described coil spring 66 is interposed between the annular seal member 67 and the driven rotary body 62. The coil spring 66 presses the annular seal member 67 against the lattice plate 13, and the driven rotary body 62. The ratchet pawl 65 is pressed against the ratchet pawl 64 of the pinion 61. At this time, the annular seal member 67 indirectly presses between the shaft insertion hole 13b and the boss portion 60a of the pinion 60, thereby indirectly sealing between the rotating shaft 59 and the shaft insertion hole 13b. .
(Opening / closing member opening / closing means)
The opening / closing members 108 and 109 described above are opened and closed by the opening / closing member opening / closing means 190 as shown in FIGS. 2C and 2D to open and close the upper opening end of the fine dust collecting groove 40b. The opening / closing member opening / closing means 190 has the above-described rotational force transmission means (power transmission means) 58 and second rotational force transmission means (power transmission means) 191 that is linked to the rotational force transmission means 58.

  The second rotational force transmission means 191 includes gears 200 and 201 held by the lattice plate 13 and the middle case 3, clutch mechanisms (slip mechanisms) CL1 and CL2, and the like. Hereinafter, this structure will be described.

  At the lower part of the lattice plate 13 of the upper case 4, cylindrical bulging protrusions 13 c and 13 d that bulge backward corresponding to the upper part of the vertical wall 3 b 1 provided in the middle case 3 are formed. Recesses 13c1 and 13d1 opening forward are formed in the bulging protrusions 13c and 13d.

  Furthermore, in a space S (see FIG. 2) between the upper portion of the vertical wall 3b1 and the lower portion of the lattice plate 13, a pair of gears 200 and 201 that mesh with the pinion 60 are disposed. The gears 200 and 201 are rotatably held by the upper part of the vertical wall 3b1 and the rear end walls 13c2 and 13d2 of the bulging protrusions 13c and 13d via the rotation shafts 200a and 201a.

  Circular magnets 200b and 201b disposed in the recesses 13c1 and 13d1 are attached to the front ends of the rotary shafts 200a and 201a. The rotary shafts 200a and 201a are provided so as to be slightly movable back and forth. Further, when the gears 200 and 201 come into contact with the rear end walls 13c2 and 13d2 of the bulging protrusions 13c and 13d, the front ends of the magnets 200b and 201b are slightly projected from the front ends of the recesses 13c1 and 13d1. .

  Further, the rotary shafts 200a and 201a are spring-biased backward by coil springs 202 and 203. The coil springs 202 and 203 usually move the rotating shafts 200a and 201a rearward until the magnets 200b and 201b abut against the rear end walls 13c2 and 13d2 of the bulging protrusions 13c and 13d. It is immersed in the recessed parts 13c1 and 13d1.

  The magnets 116 and 200b constitute a clutch mechanism (slip mechanism) CL1, and the magnets 117 and 201b constitute a clutch mechanism (slip mechanism) CL2.

Moreover, if the spring force of the coil springs 112 and 113 is f1, and the cord winding force of the cord reel 25 is f3, the cord winding force f3 of the cord reel 25 is set sufficiently larger than the spring force f1.
[Action]
Next, the operation of the vacuum cleaner having such a configuration will be described.

  In such a configuration, the spring force of the spring that urges the brake arm 32 (see FIGS. 11 to 13) and the spring force of the rotation urging means that urges the cord reel 25 to rotate. The rotation of the cord reel 25 is locked by the brake roller biting in a wedge shape between the brake arm 32 and the upper flange 27.

  Further, by grasping and pulling the power cord 30, the power cord 30 provided so as to be able to be pulled out rearward from the lower case 2 is pulled, and the cord reel 25 is rotated against the spring force of the rotation urging means. As a result, the brake roller (not shown) is slightly moved in the rotation direction of the cord reel 25, and the state in which the brake roller bites in between the brake arm 32 and the upper flange 27 is released. The pressure contact state with the upper flange 27 is released.

  When the cord reel 25 is rotated in the direction in which the power cord 30 is pulled out by further pulling the power cord 30 in this state, the drive gear 29 rotates the pinion 61 along with this rotation. Along with this rotation, the ratchet pawl 64 of the pinion 61 acts so as to get over the ratchet pawl 65 of the driven rotary body 62, and the driven rotary body 62 resists the spring force of the coil spring 66 (see FIG. 3). The ratchet claws 64 and 65 are rotated relative to each other on the rotation shaft 59 in a direction away from the rotation shaft 59.

  As a result, when the power cord 30 is pulled out, only the spring force generated by the rotation biasing means such as a spiral spring that biases the cord reel 25 in the direction in which the power cord 30 is wound acts on the power cord 30 as a drag force. It will be in the state. Therefore, the power cord 30 can be pulled out with a light force.

  After the power cord 30 is pulled out to some extent in this way, when the pulling force is released from the power cord 30, the cord reel 25 is slightly rotated in the direction of winding the power cord 30 by the rotation urging means, and the brake roller is braked. The arm 32 and the upper flange 27 are wedged into a wedge shape and locked, the rotation of the cord reel 25 is stopped, and the power cord 30 is pulled out. By inserting the plug 30a of the power cord 30 into an unillustrated commercial power outlet, the electric blower 17 can be supplied with driving power.

In this state, when the electric blower 17 is driven by operating the operation panel 8a of the hand operation pipe 8, the suction negative pressure of the electric blower 17 is reduced between the negative pressure chamber 21, the communication air passage 16a, the arm 52 of the gear 50, and It acts on the negative pressure chamber 38b through the pleated filter 48.
At this time, since the upper end of the fine dust collecting groove 40b of the bottom lid 40 is closed by the opening and closing members 108 and 109, the fine dust collected in the fine dust collecting groove 40b is sucked into the pleat filter 48 side. This prevents the pleat filter 48 from being clogged.

  The suction negative pressure acting on the negative pressure chamber 38b acts on the suction port 38c via the net filter 43, and acts on the suction port 38c via the net filter 104 and the dust collection chamber 38a. The suction negative pressure acting on the suction port 38 c acts on the suction port body 10 through the dust collection hose 7, the hand operation pipe 8 and the extension pipe 9.

  Thereby, air (air) containing dust is sucked into the suction port body 10, and the sucked air and dust are sucked into the suction port 38 c through the extension pipe 9, the hand operation pipe 8 and the dust collecting hose 7. After that, it flows into the cylindrical portion 42.

  A part of the sucked air passes through the net filter 43 and flows into the negative pressure chamber 38b. At this time, light dust contained in the air is captured by the net filter 43. On the other hand, most of the dust contained in the air flowing into the cylindrical portion 42 travels straight along with the remaining air due to inertial force, and then flows down into the dust collecting chamber 38 a via the cylindrical portion 44. The air flowing into the dust collecting chamber 38a becomes a swirling flow, and the dust flowing into the dust collecting chamber 38a is separated by centrifugal force (inertial force) and compressed to the bottom side of the dust collecting chamber 38a. The compressed air is passed through the net filter 104 and flows into the negative pressure chamber 38b.

  In this state, when a certain amount of dust is trapped by the net filter 43 and the amount of air passing through the net filter 43 and flowing into the negative pressure chamber 38b is reduced, the inside of the dust collection chamber 38a is passed through the cylindrical portion 44. The amount of air flowing into the air increases. This air flow separates the dust that has adhered to the net filter 43 and has become a certain amount of lump from the net filter 43, thereby eliminating the clogged state of the net filter 43. The separated dust is collected in the dust collecting chamber 38a.

  The air flowing into the negative pressure chamber 38 b passes through the pleated filter 48 toward the gear 50, and then is connected between the arms 52 of the gear 50, the communication fan 16 a and the negative pressure chamber 21 through the centrifugal fan portion of the electric blower 17. 18 is sucked into an air suction port 18 a provided in 18. When this air passes through the pleated filter 48, fine dust and larger dust are captured by the pleated filter 48. The air sucked into the centrifugal fan unit 18 flows through the motor unit 19 to cool the inside, and is exhausted into the blower chamber 11 from the exhaust port 19a, and a number of exhaust holes provided in the side wall 3a of the upper case 3. 14 is exhausted to the atmosphere outside the vacuum cleaner body 1.

  After cleaning is completed in this manner, the electric blower 17 is stopped by operating the operation panel 8a, and the power cord 30 is removed from an outlet (not shown), and the handle 33 is pushed downward to tilt the handle 33. The cam surface 35a rotates the brake arm 32 around the support shaft 23a against the spring force of a spring (not shown) against the lattice wall 13 side, and a brake roller (not shown) is separated from the upper flange 27. The locked state of the reel 25 is released.

  As a result, the cord reel 25 is rotated in the direction of winding the power cord 30 by the rotation biasing means (counterclockwise direction indicated by the arrow 25a in FIG. 11), and the power cord 30 is wound around the cord reel 25. To do. At this time, the ratchet claws 64 and 65 are locked to each other, and the pinion 61 and the driven rotating body 62 rotate integrally. The rotation of the driven rotating body 62 is transmitted to the pinion 60 through the rotation shaft 59, and the pinion 60 rotates in the clockwise direction (in the counterclockwise direction in FIGS. 2C and 10) as indicated by the arrow 204 in FIG. 2B. Rotated.

  As the pinion 60 rotates, the gear 200 that meshes with the pinion 60 rotates clockwise as indicated by the arrow 205 in FIG. 2C integrally with the rotation shaft 200a, and the gear 201 that meshes with the pinion 60 rotates by the rotation shaft 201a. And rotate clockwise as indicated by the arrow 206 in FIG. 2C.

  The rotation of the rotation shaft 200a is transmitted to the support shaft 108b via the magnets 116 and 200b, and the rotation of the rotation shaft 201a is transmitted to the support shaft 109b via the magnets 117 and 201b.

  Accordingly, the opening / closing member 108 is raised from the position of the broken line to the solid line position in the counterclockwise direction around the support shafts 108a, 108b in FIG. 2B, and the opening / closing member 109 is raised from the position of the broken line in FIG. The intermediate support shafts 109a and 109b are rotated up to the position of the solid line in the counterclockwise direction to be raised.

  The raising and lowering operations of the opening and closing members 108 and 109 are performed against the spring force of the coil springs 112 and 113. In addition, the standing operation of the opening and closing members 108 and 109 is performed at the beginning of the winding operation of the power cord 30 by the cord reel 25.

  In addition, when the opening and closing members 108 and 109 are raised to the position of the solid line, they come into contact with the stopper protrusions 114 and 115, respectively, and the rotation stops. Thereby, the upper end of the fine dust collecting groove 40b of the lid 40 is opened by the opening and closing members 108 and 109.

  Then, after the opening and closing members 108 and 109 come into contact with the stopper protrusions 114 and 115, the magnets 116 and 200b slip to maintain the standing state of the opening and closing member 108, and the magnets 117 and 201b slip to open and close. The standing state of the member 109 is maintained.

  On the other hand, the rotation of the driven rotating body 62 is transmitted to the gear 53 via the rotating shaft 59 and the pinion 60, and the gear 53 is rotated around the support shaft 51a. As the gear 53 rotates, the engagement element 57 moves while climbing over the peak portion 48a of the pleat filter 48 so as to bend the coil spring 56, and vibration is generated in the pleat filter 48. Due to this vibration, the dust trapped and adhered to the front side of the pleated filter 48 is knocked down and falls downward, and is collected in a fine dust collecting groove (fine dust chamber) 40b of the lid 40 that opens upward. Is done.

  Then, when the winding of the power cord 30 onto the cord reel 25 is completed, the rotation of the cord reel 25 is stopped. Thereafter, the cover 5 attached to the front end portion of the middle case 3 so as to be rotatable up and down is opened upward, and the dust collecting container 37 is taken out from the recess 36.

  At the time of taking out, the magnets 116 and 117 on the dust collecting container 37 side move upward so as to slide with respect to the magnets 200b and 201b on the cleaner body 1 side. At this time, when the magnets 116 and 117 are separated from the magnets 200b and 201b on the cleaner body 1 side, the magnets 200b and 201b on the cleaner body 1 side are immersed in the recesses 13c1 and 13d1 by the spring force of the coil springs 202 and 203. .

  Then, by opening the bottom cover 40 of the dust collecting container 37 taken out from the recess 36, the dust collected in the dust collecting chamber 38a can be discarded downward, and the fine dust collecting groove 40b of the bottom cover 40 is provided. Dust collected inside can also be thrown down.

  After the dust is discarded in this manner, the bottom cover 40 is closed, the dust collecting container 37 is disposed in the recess 36, and the magnets 116 and 117 on the dust collecting container 37 side are replaced with the magnet 200b on the cleaner body 1 side. When opposed to 201b, the magnets 200b and 201b on the cleaner body 1 side are attracted and attracted by the magnetic force to the magnets 116 and 117 on the dust collecting container 37 side against the spring force of the coil springs 202 and 203.

  2C and 2D, the diameters of the magnets 116 and 117 on the dust collecting container 37 side and the diameters of the magnets 200b and 201b on the cleaner body 1 side are the same, but the magnet on the dust collecting container 37 side is formed. The diameters 116 and 117 may be made larger than the magnets 200b and 201b on the cleaner body 1 side, and the diameters of the magnets 116 and 117 on the dust collecting container 37 side may be made larger than the diameters of the recesses 13c1 and 13d1.

  The cord winding force f3 of the cord reel 25 rotates over the peak portion 48a of the pleat filter 48 so that the spring force f1 of the coil springs 112 and 113 and the engagement element 57 bend the coil spring 56. It is sufficiently larger than the rotational power f2 to be performed. Therefore, when the rotation of the cord reel 25 is stopped when the winding of the power cord 30 is finished, the opening and closing members 108 and 109 are in an upright state.

  However, when using a vacuum cleaner, it is necessary to pull out the power cord 30 from the cord reel 25. Therefore, when the power cord 30 is pulled out against the winding force of the cord reel 25, the drive gear 29 and the cord reel 25 are rotated clockwise in FIG. 11, and the pinion 61 is moved by the drive gear 29. As shown by the arrow 61a in FIG. 10, it is rotated clockwise. At this time, the ratchet 64 is rotated in the clockwise direction in FIG. 10 together with the pinion 61 and is rotated in a direction to get over the ratchet 65.

  As a result, the ratchet 65 can rotate following the rotation direction of the ratchet 64, and the driven body 62, the rotation shaft 59, and the pinion 60 can also rotate together with the ratchet 65 in the clockwise direction in FIG.

  Therefore, when the power cord 30 is pulled out from the cord reel 25, the open / close members 108 and 109 are rotated clockwise in FIG. 2B by the spring force of the coil springs 112 and 113.

  At this time, the rotation of the support shaft 108b is transmitted to the rotation shaft 200a via the magnets 116 and 200b, and the rotation of the support shaft 109b is transmitted to the rotation shaft 201a via the magnets 117 and 201b. The rotation of the rotary shafts 200a and 201a causes the gears 205 and 206 to rotate clockwise in FIG. 2B (counterclockwise in FIG. 2C), and the pinion 60 meshing with the gears 205 and 206 is counterclockwise in FIG. 2B. The ratchet 65 is rotated in the clockwise direction (clockwise direction in FIG. 2C), and the ratchet 65 rotates following the ratchet 64.

  The rotation of the pinion 60 is transmitted to the gear 53, and the gear 53 is rotated about the support shaft 51a. As the gear 53 rotates, the engaging element 57 moves while climbing over the peak portion 48a of the pleated filter 48 so as to bend the coil spring 56.

  With this rotation, the opening and closing members 108 and 109 are further rotated in the clockwise direction in FIG. 2B and brought into contact with the stopper protrusions 110 and 111, respectively, and the open end of the fine dust collecting groove 40b is closed. To do. Such an operation of closing the opening and closing members 108 and 109 is performed only in the initial stage of pulling out the power cord 30 from the cord reel 25.

  After the opening / closing members 108 and 109 come into contact with the stopper protrusions 110 and 111, the pinion 60 does not rotate, so that the ratchet 64 rotates so as to get over the ratchet 65.

  Thereafter, when the plug 30a of the power cord 30 is inserted into a commercial power outlet (not shown), the operation panel 8a of the hand control pipe 8 is operated, and the electric blower 17 is driven, the suction negative pressure of the electric blower 17 is negative. It acts on the negative pressure chamber 38b through the chamber 21, the communication air passage 16a, the arm 52 of the gear 50, and the pleated filter 48.

  However, at this time, since the upper end of the fine dust collecting groove 40b of the bottom cover 40 is closed by the opening and closing members 108 and 109, the fine dust collected in the fine dust collecting groove 40b is directed to the pleat filter 48 side. It is prevented that the pleated filter 48 is clogged by being sucked.

  As described above, the opening / closing members 108 and 109 are substantially closed when the electric blower 17 is driven except when dust is being removed.

  As described above, the electric vacuum cleaner according to the embodiment of the present invention is provided with the dust collection part (dust collection container 37) and the electric blower 17 that applies suction negative pressure to the dust collection part (dust collection container 37). Main body (net filters 43 and 104) that are disposed upstream of the dust collecting part (dust collecting container 37) and collects dust, and the dust collecting part (dust collecting container) 37) and is attached to the fine dust filter (pleat filter 48) and the fine dust filter (pleat filter 48) that are disposed downstream of the main filter (net filters 43 and 104) and capture fine dust that has passed through the main filter. A dust dropping means (vibration applying means 49) for dropping dust, a fine dust chamber (fine dust collecting groove 40b) which opens upward and stores fine dust dropped from the fine dust filter (pleat filter 48), and Fine dust chamber (fine dust And a closing member (108, 109) for opening and closing the upper open end of Atsumarimizo 40b). Moreover, in this vacuum cleaner, when the dust drop means (vibration applying means 49) is operated, the opening and closing members (108, 109) are opened to open the upper open end of the fine dust chamber (fine dust collecting groove 40b). Opening / closing member opening / closing means 190 for closing the upper opening end of the fine dust chamber (fine dust collecting groove 40b) by closing the open / close members (108, 109) when the electric blower 17 is operated. Is provided.

  According to this configuration, the opening / closing member opening / closing means 190 closes the opening / closing member (108, 109) when the electric blower 17 is operated, thereby closing the upper opening end of the fine dust chamber (fine dust collecting groove 40b). Therefore, the fine dust stored in the fine dust chamber (fine dust collecting groove 40b) is rolled up when the electric blower 17 is operated, and is reattached to the fine dust filter (pleat filter 48). Can be prevented.

  Further, in the electric vacuum cleaner according to the embodiment of the present invention, the power transmission means (rotation) which operates the dust drop means (vibration applying means 49) in conjunction with the rotation of the cord reel 25 around which the power cord 30 is wound. Force transmission means 58), and stoppers [110, 111 (for closed position), which stop the opening and closing members (108, 109) at the open position and the closed position of the fine dust chamber (fine dust collecting groove 40b), 114, 115 (for open position)] are provided respectively. The opening / closing member opening / closing means 190 is interlocked with the rotation of the cord reel 25 and comes into contact with the opening / closing member (108, 109) after contacting the stopper [110, 111 or 114, 115]. The clutch mechanism (CL1, CL2) slips when a force of a predetermined value or more is applied.

  According to this configuration, the opening / closing member (108, 109) can be opened / closed by the rotation of the cord reel 25, and the opening / closing member (108, 109) is in contact with the stopper [110, 111, 114, 115] to become a fine dust chamber. After opening or closing the (fine dust collecting groove 40b), when a force of a predetermined value or more acts in the contact direction from the opening / closing member (108, 109) to the stopper [110, 111, or 114, 115], the clutch Since the mechanism (CL1, CL2) slips, even if the cord reel 25 rotates after the opening / closing member (108, 109) contacts the stopper [110, 111, or 114, 115], the opening / closing member (108, 109) can be held in the open or closed position without difficulty.

  Further, in the embodiment described above, the example in which the opening and closing members 108 and 109 are interlocked with the cord reel 25 and the fine dust collecting grooves 40b are opened and closed by the opening and closing members 108 and 109 is shown. It is not limited to.

  For example, the support shafts 108a and 109a can be rotationally driven by an actuator (rotation drive means) such as a drive motor or a solenoid, and the support shafts 108a and 109a are rotationally driven by this actuator, whereby the opening and closing members 108, 109 may be rotated integrally with the support shafts 108a and 109a, and the opening and closing members 108 and 109 may be used to open and close the fine dust collecting groove 40b.

  In this case, a battery (not shown) is provided in the cleaner body, a manual opening / closing member opening switch and an opening / closing member closing switch are provided, and the opening / closing member opening switch or the opening / closing member closing switch is turned on to operate the battery from the battery. The opening / closing members 108 and 109 can be opened and closed by supplying the electric power.

  Further, a sensor for detecting the start of winding of the power cord 30 onto the cord reel 25 is provided, and a predetermined time (for example, 5 to 10 seconds) after the opening and closing members 108 and 109 are opened by the actuator by the output from the sensor. A control circuit that closes the opening and closing members 108 and 109 with an actuator after the passage of time can also be provided.

(A) is a schematic perspective view of the vacuum cleaner which concerns on this invention, (b) is an expansion perspective view of the state which removed the dust collecting container and cover of the cleaner main body of (a). It is sectional drawing of the cleaner main body of Fig.1 (a). FIG. 3 is an enlarged explanatory view of main parts of FIG. 2. It is explanatory drawing which looked at the opening-and-closing member from back (right side in FIG. 2A) in the state which abbreviate | omitted a part of FIG. 2A. It is a partial perspective view of the opening-and-closing member opening-and-closing means which opens and closes the opening-and-closing member of FIG. 2B. It is sectional drawing which follows the B1-B1 line | wire of FIG. 2A. It is the principal part perspective view which abbreviate | omitted a part of FIG. 2D and looked at the rear lower part of the dust collecting container from diagonally upward. FIG. 3 is an enlarged explanatory view of a rotational force transmission unit in FIG. 2. It is sectional drawing which follows the A1-A1 line | wire of FIG. It is sectional drawing which follows the A2-A2 line | wire of FIG. FIG. 3 is a perspective view of the pleated filter of FIG. 2. It is a partial expansion perspective view which shows the relationship between the pleat filter of FIG. 2 and the engagement element of a vibration provision means (dust removal means). It is a partial expanded sectional view which shows the relationship between the pleat filter of FIG. 2 and the engagement element of a vibration provision means. It is the perspective view which looked at the vibration provision means to the pleat filter of FIG. 2 from the diagonal front side. It is a perspective view which shows the relationship between the vibration provision means of FIG. 2, and a cord reel. It is the perspective view which looked at the relationship between the vibration provision means of FIG. 10, and a cord reel from the rear side. It is the perspective view which looked at the relationship between the vibration provision means of FIG. 10, and a cord reel from the diagonally rear side. It is a disassembled perspective view of the vibration provision means of FIG. 10, a cord reel, etc.

Explanation of symbols

DESCRIPTION OF SYMBOLS 1 ... Electric vacuum cleaner 17 ... Electric blower 25 ... Cord reel 37 ... Dust collection container (dust collection part)
40b ... Fine dust collecting groove (fine dust chamber)
43 ... Net filter (main filter)
48 ... pleat filter (fine dust filter)
49 ... Vibration applying means (dust removing means)
104 ... Net filter (main filter)
108, 109 ... Opening / closing member 110, 111 ... Stopper (for closed position)
114, 115 ... stopper (for open position)
190: Opening / closing member opening / closing means CL1, CL2 ... Clutch mechanism

Claims (2)

A vacuum cleaner body provided with a dust collector and an electric blower that applies a suction negative pressure to the dust collector, a main filter that is disposed upstream of the dust collector and collects dust, and the dust collector A fine dust filter that is disposed downstream of the main part and captures fine dust that has passed through the main filter, dust removing means that drops dust attached to the fine dust filter, and an opening that opens upward from the fine dust filter. A vacuum cleaner comprising a fine dust chamber for storing fine dust to be dropped,
An opening / closing member for opening and closing the upper opening end of the fine dust chamber is provided, and when the dust dropping means is operated, the opening / closing member is opened to open the upper opening end of the fine dust chamber, and the electric blower is operated. An electric vacuum cleaner comprising: an opening / closing member opening / closing means for closing the opening / closing member to close the upper opening end of the fine dust chamber. 2. The vacuum cleaner according to claim 1, further comprising power transmission means for operating the dust drop means in conjunction with rotation of a cord reel on which a power cord is wound, and opening and closing the opening and closing member. A stopper for stopping at each of the position and the closed position is provided, and the opening / closing member opening / closing means is interlocked with the rotation of the cord reel and has a force greater than a predetermined value in the contact direction after the opening / closing member contacts the stopper. A vacuum cleaner characterized by having a clutch mechanism that slips when an action occurs.

Images