JP2010269118A - Vacuum cleaner - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To solve the following problem in the prior art: even with a dust container of a vacuum cleaner projected from a dust collecting case, the rear part of the dust container abuts on the inside of the dust collecting case, so that the forming direction of an opening at the front of the projected dust container is rather closer to the vertical direction than the horizontal direction, which results in leaving dust in the dust container. <P>SOLUTION: In this vacuum cleaner, a dust collecting basket 12 can be turned toward the front of the case 10 until an angle (e-f) made between the opening surface of the dust collecting basket 12 and the horizontal direction reaches a predetermined angle within 45&deg;. <P>COPYRIGHT: (C)2011,JPO&amp;INPIT

Description

  The present invention relates to a vacuum cleaner, and more particularly to a cyclone type vacuum cleaner.

  As a conventional technique, in Patent Document 1, a dust storage chamber is disposed below the dust separation chamber, dust-containing air outside the intake cylinder in the dust separation chamber flows into the dust storage chamber, and the mass of the dust storage chamber is increased. An electric vacuum cleaner which is sucked from the lower opening of the intake cylinder through the first filter at the lower end of the intake cylinder after large sand debris is removed, and sucked into the electric blower through the second filter through the intake cylinder Are listed. Further, an outer cylinder is provided on the concentric circle of the intake cylinder, a compression plate is provided at the lower end thereof, and when the outer cylinder is lowered together with the compression plate, dust accumulated in the dust chamber is compressed by the compression plate, and the inner peripheral surface of the outer cylinder It is described that the brush bristles provided on the surface scrape off dust adhering to the filter formed on the intake cylinder.

  In Patent Document 2, a separation chamber and a dust container are arranged in parallel in a dust collection case, and air outside the inner cylinder in the separation chamber flows into the dust container from the separation chamber. There is described a vacuum cleaner that merges with air and is sucked into an electric blower through a mesh-like net filter and a pleated filter. Further, it is described that when the dust deposited on the mesh-like net filter and compressed by the intake air is thrown away, the mesh-like net filter and the pleated filter rotate around the lower end to open.

  In Patent Document 3, a dust container for collecting dust is provided inside the dust collection case, and the dust container rotates around the lower end when throwing away dust accumulated in the dust container and compressed by intake air. A vacuum cleaner is described that jumps out of the dust collection case while moving and breaks up and down.

  In Patent Document 4, a suction port for sucking contaminated air in the axial direction is formed on one side of a cylindrical cyclone body, and an air discharge port for discharging purified air in the axial direction on the other side. In the cyclone body, there is provided a rotational force applying means for rotating the air sucked in the axial direction in the tangential direction, and the contaminants separated by the centrifugal force are tangentially disposed on the discharge port side. A forward cyclone dust collector is described in which a contaminant discharge port for guiding is provided, and a dust collection box is detachably provided at one end of the contaminant discharge port.

  Patent Document 5 describes an electric vacuum cleaner provided with a cyclone dust collector that is horizontally disposed so that a rotating shaft of a swirling flow generated inside a cyclone portion extends in a substantially horizontal direction. Patent Document 5 discloses that air containing dust from the floor suction port becomes a swirling flow when passing through the flow path for half the circumference of the lid from the suction port of the cyclone dust collector, and enters the cyclone part through the opening. Then, the dust is separated from the air by the umbrella-shaped partition plate of the middle cylinder along the inner peripheral wall of the cyclone dust collector, and collected in the dust collecting section, while the air purified by the swirling flow is The air that has passed through the primary mesh filter is further purified, and then passes through the inner cylinder to the secondary filter, and the air that has entered the dust collecting portion together with the dust is collected when passing through the primary mesh filter. After the dust inside the dust part is compressed and the air purified through the primary mesh filter goes to the secondary filter, the air passing through the inside and outside of the inner cylinder is filtered by the secondary filter. The fact that I was in an electric blower It is.

  Patent Document 6 describes a dust container for a vacuum cleaner in which a swirl flow path, a bypass flow path, and a dust collection space are formed by combining two cases of an outer case and an inner case. In Patent Document 6, the inner case includes a buffer space that receives air entering from the intake port, a swirl flow passage forming portion that guides air in the buffer space in a clockwise direction, and a front side inside the swirl flow passage forming portion. A semi-columnar convex part protruding in the direction is included, and a large number of ventilation holes are formed in the peripheral surface of the semi-columnar convex part near the downstream in the turning direction. The entered air and dust flow to the downstream side while swiveling clockwise along the swirl flow path forming part, swirling around the convex part, and a part of the swirling air is formed on the convex part It is described that it flows to the back side through the vent hole.

  Further, in Patent Document 6 and Patent Document 9, by separating the dust collection space around the downstream side of the swirl flow path, dust accumulates from the outside of the dust collection space, and on the other hand, on the downstream side of the swirl flow path. The inner case has a smoothly bulging guide surface, so that almost no dust adheres to the guide surface, and even if a large amount of dust accumulates around the dust collection space, air swirls in the swirling flow path. It is also described that even if a large amount of dust is accumulated in the dust collection space, the flow of air in the swirling flow path itself is not hindered, the air swirls, and the suction force hardly decreases.

  In Patent Document 7, when the dust collection case is housed in the vacuum cleaner body, the elastic seal portion is not vertically oriented, but the upper side is inclined to the electric blower side, whereby the dust collection case is attached to the vacuum cleaner body. A vacuum cleaner having a cyclone-separated dust collecting part that makes it easy to remove the dust-tight case from the vacuum cleaner body and facilitates air-tightness is described. Further, in Patent Document 7, when the cyclone separating cylinder and the dust collecting case are integrally configured and attached to the cleaner body, the upper front-rear direction is compared with the lower front-rear direction length in consideration of removal. The draft is set to be long. Accordingly, since the filter case is also inclined with respect to the floor surface, it is described that the lower side of the filter case is longer in the front-rear direction than the upper side.

  Also in Patent Document 8, the dust collector storage chamber is formed to be inclined so that the front side wall surface becomes the upper side, and the rear side wall surface is formed substantially vertically so that the dust collector storage chamber is directed upward. There is described a vacuum cleaner that is formed so as to become wider as it is, and that guides the dust collector to be stored smoothly when the dust collector is stored.

Japanese Patent Laid-Open No. 2003-190056 JP 2007-000383 A JP 2009-000320 A JP 2000-157463 A JP 2004-105364 A JP 2007-061199 A JP 2005-95453 A JP 2009-50735 A JP 2009-18107 A

  In patent document 1, in order to compress the dust in a dust storage chamber, since a user must operate a compression board with an operation lever, a user's burden is large.

  Therefore, instead of the first filter of Patent Document 1, it is conceivable to provide the dust container of Patent Document 3 so as to open upward. However, in Patent Document 1, the air that has flowed into the dust storage chamber is the lower end of the intake cylinder. Since it is sucked from the opening, the dust accumulated in the dust container of Patent Document 3 is also sucked together with the air from the lower side of the intake cylinder, and as a result, the amount of dust deposited on the first filter in front of the electric blower increases. There is a risk that the suction power will decrease.

  In Patent Document 2, since the separation chamber and the dust container are arranged in parallel, the diameter of the separation chamber and its inner cylinder cannot be increased, and the dust is deposited in the separation chamber as the dust accumulates in the dust container. The contribution of the intake air from the inner cylinder increases, and the pressure loss of the intake air increases. As a result, the suction force may be reduced as compared with the initial state in which no dust is accumulated. Further, in Patent Document 2, since the mesh-like net filter is planar, the user may not be able to easily remove dust stuck to the mesh-like net filter.

  Therefore, it is conceivable to provide the dust container of Patent Document 3 instead of the mesh-shaped net filter of Patent Document 2, but the dust container of Patent Document 3 has a container shape. There is a risk that the shape of the. In addition, when the user holds the handle of Patent Document 2 and opens the rear part of the dust collecting case, the direction of the dust container of Patent Document 3 is the front side (handle) side for the user. There is a risk that the dust in the container is caught by the rear part of the dust container part of Patent Document 2 and is not discharged well, and the dust container itself that has popped out hits the rear part of the dust container part and the dust container itself does not fly out well. is there.

  Further, in Patent Document 3, since the rear portion of the dust container contacts the dust collection case even when the dust container protrudes from the dust collection case, the formation direction of the opening on the front side of the dust container that protrudes is more vertical than the horizontal direction. There is a risk that dust will remain in the dust container. In addition, the user must turn his / her wrist to turn the handle downward in order to face the opening on the front side of the dust container downward, which may increase the burden on the user. Moreover, in patent document 3, since the rotation axis | shaft of a dust collecting container is directly formed in the inner lower surface of a dust collecting case, there exists a possibility that intensity | strength may run short or the lower surface of a dust collecting case may bend, and an external appearance may be impaired. .

  In patent document 4, since the rotational force provision means is required in order to generate a cyclone flow, the length of the axial direction of a cyclone dust collector becomes long, As a result, the length of the front-back direction of a vacuum cleaner main body is also comprised. There is a risk of becoming longer. For example, when the dust collection box is disposed adjacent to the cyclone body in the axial direction, the length of the cyclone dust collector in the axial direction is further increased. The length will be even longer. Further, in Patent Document 4, since the flow path is enlarged from the contaminated air inlet and the flow velocity is reduced, a rotational force is applied to the contaminated air. Therefore, the rotational speed is slow, the centrifugal force is reduced, and the contaminated air is sufficiently separated. There is a fear that it cannot be done. Moreover, in patent document 4, since the space from a rotational force provision means to the cylinder part of a discharge port is long and air swirls in multiple times from a rotation force provision means to the cylinder part of a discharge port, the energy loss of air is Large and noise may be generated. Moreover, in patent document 4, since the rotational force provision means is formed with several wing | blade (fin), there exists a possibility that the energy loss of air may be large and noise may also generate | occur | produce. Further, in Patent Document 4, there is no exhaust port from the dust collection box to the outside, and exhaust from the cyclone body is only a small-diameter exhaust port corresponding to the inner cylinder, so the energy loss of exhaust air is large. . Moreover, in patent document 4, since the means to compress the dust deposited on the dust collection box is not provided, the dust storage capacity of the dust collection box is also small.

  In patent document 5, since the flow path which generate | occur | produces a swirling flow is formed in the lid | cover arrange | positioned in the front side of the front-end | tip of a middle cylinder, the length of the horizontal direction (axial direction) of a cyclone dust collector becomes long. As a result, the length of the vacuum cleaner main body in the front-rear direction may be increased. In addition, since the shape of the portion where the primary mesh filter of the middle cylinder is formed is a triangular pyramid, the primary mesh filter is moved to the downstream side in the horizontal direction (axial direction) (from the top to the bottom of the triangular pyramid). There is a risk that dust will easily adhere to the surface of the glass and the suction force will be reduced.

  In Patent Document 6, since the buffer space and the swirl flow path forming portion are formed outside the semi-columnar convex portion in the radial direction, the length of the dust collection chamber in the radial direction (vertical and horizontal directions) becomes long. As a result, the height and width of the front portion of the cleaner body may increase.

  In Patent Document 7 and Patent Document 8, the sealing mechanism between the cyclone separating cylinder and the dust collecting case is not described. Therefore, the formation direction of the elastic seal portion of the exhaust side opening of the dust collecting case (not the vertical direction, If the joint surface of the cyclone separation cylinder and the dust collection case is greatly inclined with respect to the electric blower side, the sealing member is simply interposed between the cyclone separation cylinder and the dust collection case. There is a risk that sufficient airtightness cannot be obtained.

  Therefore, an object of the present invention is to provide a vacuum cleaner that makes it easy for a user to discharge dust accumulated in a ventilation member.

  Alternatively, an object of the present invention is to provide a vacuum cleaner that improves the strength of the mechanism for attaching the dust collecting part to the case without increasing the longitudinal direction of the dust collecting part, or suppresses the case from bending. It is in.

  In the present invention, an angle formed between the opening surface of the ventilation member and the horizontal direction from the first state in which the ventilation member (for example, the dust collecting basket 12) is enclosed in the ventilation member or the case (for example, angle e−angle f). Is capable of rotating in the forward direction of the case until reaching a second state where the angle becomes a predetermined angle within 45 degrees. Alternatively, according to the present invention, the angle (for example, the angle e) formed between the opening surface of the ventilation member and the handle forming direction from the first state in which the ventilation member (for example, the dust collecting basket 12) is enclosed in the ventilation member or the case. It is characterized in that it can be rotated in the forward direction of the case until it reaches a second state in which the angle f−the angle h) becomes a predetermined angle within 45 degrees.

  Alternatively, according to the present invention, the mounting member for attaching the ventilation member (for example, the dust collecting basket 12) to the case is a rear end surface of the dust collecting unit when the dust collecting unit (for example, the dust container 5) is viewed from the side. Inclined with respect to the direction of forming or the perpendicular to the bottom surface of the cleaner body, and fixed in the case.

  According to the present invention, the ventilation member can be rotated in the forward direction of the case until reaching the second state in which the angle formed by the opening surface of the ventilation member and the horizontal direction is a predetermined angle within 45 degrees. Or the ventilation member can be rotated in the forward direction of the case until it reaches a second state in which the angle between the opening surface of the ventilation member and the direction in which the handle is formed is a predetermined angle within 45 degrees. This makes it easy for the user to discharge the dust accumulated in the ventilation member.

  Alternatively, according to the present invention, the attachment member for attaching the ventilation member to the case is in a direction perpendicular to the direction of formation of the rear end surface of the dust collection portion or the bottom surface of the cleaner body when the dust collection portion is viewed from the side. By forming it incline, the strength of the mechanism for attaching the dust collecting part to the case can be improved or the case can be prevented from bending without increasing the length of the dust collecting part in the front-rear direction.

It is sectional drawing seen from the side surface of the cleaner body of the Example of this invention. (A) is a perspective view of the dust collector of the Example of this invention, (B) is sectional drawing seen from the side of the dust collector of the Example of this invention. (A) is a perspective view of the inner cylinder and outer cylinder of the Example of this invention, (B) is a perspective view of the back side of the inner cylinder of the Example of this invention. (A) is a perspective view of the state which opened the front cover of the dust accommodating part of the Example of this invention, (B) is the perspective view of the state which opened the rear filter of the dust accommodating part of the Example of this invention. FIG. (A) is the front view which looked at the front cover of the dust accommodating part of the Example of this invention from the dust accommodating part outer side, (B) is dust accommodating the front cover of the dust accommodating part of the Example of this invention. It is the front view seen from the part inside. It is the front view seen from the dust separation part side when the front cover of the dust accommodating part of the Example of this invention is removed. It is a general-view figure of the vacuum cleaner of the Example of this invention. It is a perspective view of the vacuum cleaner main body of the Example of this invention. It is the front view which looked at the inner cylinder of Example 2 of this invention from the cylindrical part side. It is the front view which looked at the inner cylinder of Example 2 of this invention from the cylindrical part side. It is the perspective view which looked at the inner cylinder of Example 2 of this invention from the cylindrical part side. It is the top view which looked at the inner cylinder of Example 2 of this invention from the outer extension part back side. It is the perspective view which looked at the inner cylinder of Example 2 of this invention from the outer extension part back side. It is the side view which looked at the inner cylinder of Example 2 of the present invention from the upper part. It is the side view which looked at the inner cylinder of Example 2 of this invention from the right side. It is sectional drawing which looked at the inner cylinder of Example 2 of this invention from the right side. They are the perspective view which looked at the dust separation part of Example 2 of the present invention from the front, and the side view which looked from the right side. It is the side view which looked at the cleaner body of Example 3 of this invention from the right side. It is the perspective view which looked at the vacuum cleaner main body of Example 3 of this invention from the upper right side. It is the side view which looked at the cleaner body of Example 3 of this invention from the right side. It is the perspective view which looked at the vacuum cleaner main body of Example 3 of this invention from the upper right side. It is the side view which looked at the dust collector of Example 3 of this invention from the right side. It is sectional drawing which looked at the dust collector of Example 3 of this invention from the right side. It is the front view which looked at the dust accommodating part of Example 3 of this invention from the front side. It is the perspective view which looked at the dust accommodating part of Example 3 of this invention from the left rear side. It is the front view which looked at the dust accommodating part of Example 3 of this invention from the front side of the rear side wall surface of the cleaner body which opposes an axial direction other end. It is the front view which looked at the dust separation part of Example 3 of the present invention from the front side. It is the side view which looked at the dust separation part of Example 3 of the present invention from the right side, and the cross section of the front side of the cleaner body. It is the front view which looked at the dust accommodating part of Example 4 of this invention from the axial direction front end side. It is sectional drawing which looked at the dust accommodating part of Example 4 of this invention from the side surface. It is the rear view which looked at the dust accommodating part 5 of Example 4 of this invention from the rear side. It is sectional drawing which looked at the dust accommodating part of Example 4 of this invention from the side surface. It is a side view of the dust accommodating part of Example 4 of this invention. It is sectional drawing seen from the right side of the dust accommodating part of Example 4 of this invention.

  Hereinafter, Example 1, Example 2, Example 3, and Example 4 of the present invention will be described.

  The vacuum cleaner according to the first embodiment of the present invention includes a vacuum cleaner body 1 having an electric blower 28 and a dust collector 2 that is detachably attached to the vacuum cleaner body 1. A separation unit (for example, a dust separation unit 4) that swirls and separates dust from the air, and a storage unit (for example, a dust storage unit 5) that communicates with the separation unit and stores the dust, the separation unit and the storage unit, Are arranged in the axial direction, and the accommodating portion is provided with a filter (for example, a dust collecting basket 12) having a shape opened on the side communicating with the separating portion and recessed on the opposite side to the side communicating with the separating portion. The air outside the swirling flow of the part flows into the filter in the housing part, and the air inside the swirling flow of the separating part flows into the housing part and outside the filter.

  And according to Example 1 of this invention, the separation part and the accommodating part are arranged in the axial direction and communicated with each other, and the air outside the swirling flow of the separation part is in a filter having a recessed shape in the accommodating part. The air inside the swirling flow of the separation part flows into the housing part and outside the filter having a concave shape, thereby compressing the dust without bothering the user and removing the accumulated dust. The user can easily discharge, and can further suppress a decrease in suction force.

  Or the vacuum cleaner of Example 1 of this invention is the cleaner main body 1 provided with the main body inlet 21 and the electric blower 28 which generate | occur | produces suction power, the main body inlet 21 of the cleaner main body, and the electric blower 28. A dust collecting device 2 that is detachable between the first dust collecting unit 2 and the first dust collecting unit (for example, the dust separating unit 4) that has a substantially cylindrical shape and can communicate with the main body inlet 21; A second dust collecting part (for example, a dust storage part 5) communicating with the axial end of the first dust collecting part and communicating with the electric blower 28, the first dust collecting part being a circumferential surface The inner cylinder 7 having a plurality of through-holes 33 is enclosed in a substantially cylindrical shape, and the second dust collecting portion opens on the side communicating with the first dust collecting portion and communicates with the first dust collecting portion. A ventilation member (for example, a dust collecting basket 12) having a shape recessed on the opposite side to the side is included, and the outer side of the inner cylinder 7 of the first dust collecting portion is recessed in the second dust collecting portion. It communicates with the opening of the ventilation member having the shape, and the inside of the inner cylinder 7 of the first dust collection portion communicates with the outside of the ventilation member having the recessed shape in the second dust collection portion. .

  According to the first embodiment of the present invention, the second dust collecting portion is communicated with the axial end portion of the first dust collecting portion, and the outer side of the inner cylinder 7 of the first dust collecting portion is connected to the first dust collecting portion. The inside of the inner cylinder 7 of the first dust collecting portion is connected to the outside of the venting member having the recessed shape inside the second dust collecting portion. By communicating, dust can be compressed without bothering the user, the accumulated dust can be easily discharged by the user, and a decrease in suction force can be suppressed.

  In FIG. 1, sectional drawing seen from the side surface of the cleaner body 1 of the Example of this invention is shown. It is preferable that the vacuum cleaner main body 1 is horizontally placed in the usage state of the vacuum cleaner, and the vacuum cleaner main body 1 is vertically placed in the housed state of the vacuum cleaner. When the vacuum cleaner is in use, if the main body inlet 21 side is the front (upstream side) and the main body exhaust port 30 side is the rear (downstream side), the main body inlet 21 is in the direction of gravity in the housed state of the vacuum cleaner. The main body exhaust port 30 is on the lower side in the direction of gravity action. When the cleaner body 1 is placed horizontally, the lower surface of the cleaner body 1 is parallel to the surface (for example, the floor surface) on which the cleaner body 1 is placed and is perpendicular to the direction of gravity action. Become.

  First, the structure of the cleaner body 1 will be described. The dust collector 2 that collects dust from the sucked air is detachably disposed on the front side of the cleaner body 1. When the longitudinal direction (axial direction) of the dust collector 2 is the gravity action direction (vertical arrangement), the height of the cleaner body 1 is increased. On the other hand, the closer the axial direction of the swirling flow in the dust collector 2 (the axial direction of the dust collecting device 2) is to the gravity acting direction, the greater the separation effect due to the centrifugal separation action, and the axial direction of the swirling flow in the dust collecting device 2 When the angle exceeds 45 degrees with respect to the direction of gravity action, the separation effect due to the centrifugal action is extremely reduced. Therefore, in order to reduce the height of the vacuum cleaner main body 1 and suppress a decrease in the separation effect due to the centrifugal separation action, in this embodiment, the axial direction of the dust collector 2 is 40 degrees to the gravity action direction. It is about 45 degrees. However, in order to increase the separation effect by the centrifugal separation action, the axial direction of the dust collector 2 may be smaller than 40 degrees (for example, 0 degree) with respect to the gravity action direction. Instead of disposing the dust separation unit (swivel unit) 4 on the lower side and the dust storage unit 5 on the upper side, the dust separation unit 4 may be disposed on the upper side and the dust storage unit 5 on the lower side. . In this case, the inlet pipe 3 is preferably connected to the circumferential surface of the front end portion in the axial direction of the dust separator 4.

  The dust collector 2 swirls the sucked air and communicates with the dust separator 4 that separates the dust by a centrifugal separation action (cyclone method), and the dust separator 4 accommodates the dust separated by the dust separator 4. A dust container 5 is provided. The dust separator 4 and the dust container 5 are arranged in the axial direction of the dust collector 2 and are connected and communicated with each other in the axial direction. That is, the dust separator 4 is disposed on the front side of the cleaner body 1, and the dust container 5 is disposed on the front side of the cleaner body 1 with respect to the dust separator 4. The dust separator 4 and the dust container 5 are connected so that the user can easily separate the dust separator 4 and the dust container 5. A tubular main body inlet 21 is provided at the front end of the cleaner body 1. A part of the front end face in the axial direction of the dust separator 4 is open, and the opening is connected to the inlet pipe 3. Instead of the front end surface in the axial direction of the dust separator 4, the circumferential surface of the front end in the axial direction of the dust separator 4 may be connected to the inlet pipe 3. The inlet pipe 3 is preferably formed at the center in the width direction of the cleaner body 1. The inner cylinder 7 and the recessed portion 8 are also preferably formed at the center in the width direction of the cleaner body 1.

  The dust separation unit 4 includes a hollow substantially cylindrical outer cylinder 6 and a hollow substantially cylindrical inner cylinder 7 enclosed in the outer cylinder 6 with a concentric axis with the outer cylinder 6. When the axial direction of the dust separation part 4 is inclined with respect to the gravity action direction in order to prevent the separation effect due to the centrifugal separation action from deteriorating due to the axial center of the swirling flow being shifted in the gravity action direction by gravity. The axis of the inner cylinder 7 may be shifted downward with respect to the axis of the outer cylinder 6. As shown in FIG. 3A, one end surface (front end surface) in the axial direction of the outer cylinder 6 is closed except for an opening connected to the inlet pipe 3, and the other end surface in the axial direction (rear end surface) of the outer cylinder 6. ) Is open. The outer cylinder 6 is preferably made of transparent or translucent plastic or resin so that dust accumulation can be seen by the user or a sensor provided outside the outer cylinder 6 can detect the accumulation of dust. One end face (front end face) in the axial direction of the inner cylinder 7 is closed, and the other end face (rear end face) in the axial direction of the inner cylinder 7 is open. As shown in FIG. 3A, a recessed portion 8 that is recessed inward in the axial direction of the inner cylinder 7 is formed at the center of the closed portion of one end surface in the axial direction of the inner cylinder 7. The inlet pipe 3 is opposed to the closed portion of one end surface in the axial direction of the inner cylinder 7, that is, the recessed portion 8. As shown in FIG. 3A, a part of the recessed portion 8 reaches the outer peripheral end of the inner cylinder 7. In order to reduce the pressure loss of air, it is preferable that the opening direction of the recessed part 8 is a downward direction. However, the opening direction of the recessed part 8 may be upward or lateral. As shown in FIG. 3A, at the outer peripheral end of the inner cylinder 7 of the recess 8, the recess 8 does not face straight in the radial direction of the inner cylinder 7 but is slightly inclined in the circumferential direction. As shown in FIG. 1, the depth of the recess 8 in the axial direction is about half of the axial length of the cylindrical portion of the inner cylinder 7. However, the axial depth of the recessed portion 8 may extend over substantially the entire axial length of the cylindrical portion of the inner cylinder 7. In this case, the opening of the recessed portion 8 is formed in a part of the circumferential surface of the inner cylinder 7 over almost the entire length of the cylindrical portion of the inner cylinder 7. Further, a guide tube 38 is connected to the outer peripheral end of the recess 8. The cross section of the guide tube 38 has a substantially ½ circular shape, is formed along the outer peripheral surface of the inner cylinder 7, and the outer peripheral surface of the inner cylinder 7 also forms part of the inner wall surface of the flow path. The guide tube 38 is formed on the outer peripheral surface of the inner cylinder 7 in the circumferential direction by about several centimeters. Therefore, the air that has flowed in the axial direction by the inlet pipe 3 is changed in the radial direction by the recessed portion 8 and further changed in the circumferential direction by the outer peripheral end portion of the inner cylinder 7 of the recessed portion 8. At 38, it can be changed in the circumferential direction. Moreover, it is preferable that the recessed part 8 does not have an unevenness | corrugation and is formed in a curved surface. Thereby, air can be sufficiently swirled while suppressing pressure loss. The guide tube 38 may not be provided. An outer extension 34 extending toward the outer cylinder 6 is formed on the outer periphery of the other axial end surface (rear end face) of the inner cylinder 7. That is, as shown in FIG. 3A, the other axial end surface (rear side end surface) of the inner cylinder 7 has an annular shape with the inner side of the inner cylinder 7 opened.

  As shown in FIG. 3A, a part of the outer extending portion 34 in the circumferential direction is open. With this opening, air outside the inner cylinder 7 can flow into the dust container 5. The inner cylinder 7 is made of an antibacterial metal (for example, silver, copper) or an antibacterial substance (for example, silver, copper) or a coated metal (for example, stainless steel) so as to suppress the growth of bacteria. Preferably it is configured. However, the inner cylinder 7 may be comprised with resin also including a cylindrical part. Then, as shown in FIG. 3A, the outer cylinder 34 is inserted in the axial direction from the other axial end surface of the outer cylinder 6, so that the outer peripheral end of the outer extension 34 comes into contact with the inner periphery of the outer cylinder 6. As a result, the other axial end surface of the outer cylinder 6 is closed. The outer cylinder 6 and the inner cylinder 7 are connected so that the user can easily separate the outer cylinder 6 and the inner cylinder 7. A plurality of through holes 33 are provided on the circumferential surface of the inner cylinder 7. The inner cylinder 7 has a filter function by the plurality of through holes 33. The through-hole 33 allows air to flow from the outer side of the inner cylinder 7 to the inner side of the inner cylinder 7 without large dust flowing into the inner cylinder 7. Although it depends on the suction force, garbage having a weight of 1 yen or more cannot be sucked up in the outer cylinder 6 and may remain in the outer cylinder 6. By connecting the outer cylinder 6 and the inner cylinder 7 so that the user can easily separate the outer cylinder 6 and the inner cylinder 7, the user can easily separate the outer cylinder 6 and the inner cylinder 7 from each other. The dust accumulated in the outer cylinder 6 can be easily discharged, and the hair and lint caught in the through hole 33 of the inner cylinder 7 can be easily removed.

  In order to keep the airtightness of the connecting portion between the dust separator 4 and the dust container 5, a packing 9 is provided on the other axial end surface of the inner cylinder 7. The packing 9 is not only provided on the outer extension 34, but also projects in the axial direction of the inner cylinder 7. Therefore, the inside of the inner cylinder 7 is not completely hollow, and a partially closed space exists due to the packing 9. Further, a recessed portion 39 that is recessed inward in the axial direction of the inner cylinder 7 is formed in a portion of the packing 9 that protrudes to the inner side of the inner cylinder 7. The recess 39 has a handle function. Thereby, the user can hold the dust separation part 4 or the inner cylinder 7 by inserting a finger into the recess 39. A part of the upper side of the extended portion 34 is open and communicates with the outer flow path 35 of the front lid 11. That is, the inside of the outer cylinder 6 and the outside of the cylindrical portion of the inner cylinder 7 communicates with the outer flow path 35 of the front lid 11. As shown in FIG. 3 (A), the circumferential wall surface of the opening on the upper side of the extended portion 34 has a high wall surface on the side facing the opening of the guide tube 38 in the circumferential direction. The wall surface on the opening side of the guide tube 38 is preferably low. For example, assuming that the opening direction of the guide tube 38 is the counterclockwise direction when the dust separation unit 4 is viewed from the front, the left wall surface is high among the circumferential wall surfaces of a part of the upper opening of the extension portion 34, The wall on the right side is low. That is, since a part of the upper side of the extended portion 34 is opened, the circumferential direction of the extended portion 34 is less than one round of the outer periphery of the inner cylinder 7 but is shifted in a spiral shape. Therefore, the swirling flow outside the inner cylinder 7 can collide with the wall surface in the circumferential direction of a part of the opening on the upper side of the extended portion 34 and can smoothly change the direction in the axial direction. Also easily flows to the dust container 5. On the other hand, the inner side of the inner cylinder 7 communicates with the inner flow path 36 of the front lid 11.

  The dust container 5 is provided with a hollow case 10 having an axially one end face (front end face) and an axially other end face (rear end face) that are substantially inverted triangular in cross section. One end surface in the axial direction of the case 10 is closed by a front lid 11 that can be opened and closed. A shaft 31 is provided at the lower end of the front lid 11, and the shaft 31 is supported by the lower end of the case 10. The front lid 11 can be rotated back and forth in the axial direction of the case 10 with the shaft 31 as a fulcrum. A claw projects from the upper end portion of the front lid 11 on the case 10 side. On the other hand, a button 17 (which may be a lever) that can be pressed by the user is provided on the upper front side of the case 10, and a transmission rod (rod) 18 extending to the front side of the case 10 is connected to the button 17. One end of the transmission rod 18 is connected to the button 17, and the other end of the transmission rod 18 is formed in a claw shape. The claw at the other end of the transmission rod 18 can be engaged with the claw at the upper end of the front lid 11. When the front lid 11 is closed to the case 10, it is possible to prevent the front lid 11 from being opened by engaging the claw at the other end of the transmission rod 18 and the claw at the upper end of the front lid 11. When the user presses the button 17, the transmission rod 18 slides forward (may rotate upward), and the engagement between the other end of the transmission rod 18 and the upper end of the front lid 11 is engaged. The combination is released and the front lid 11 can be opened from the case 10 by gravity. While the handle 16 is formed in a horizontal direction, the normal direction of one end surface in the axial direction of the case 10 (corresponding to the front lid 11 portion) is inclined by 45 to 50 degrees with respect to the horizontal direction. That is, when the user holds the handle 16 and lifts the dust container 5, one end surface in the axial direction of the case 10 (corresponding to the front lid 11 portion) faces downward (the direction of gravity action). Therefore, the front lid 11 can be opened from the case 10 by gravity. As will be described later, if the dust collection basket (dust collection container) 12 is urged by a spring (elastic body) to jump out to the front side of the case 10, the dust collection basket 12 pushes the rear surface of the front lid 11. Therefore, when the user presses the button 17, the front lid 11 can be smoothly opened from the case 10 by the pressing force of the dust collecting basket 12. In other words, the dust collection basket 12 is stored in the case 10 by the opening surface of the dust collection basket 12 being held by the rear surface of the front lid 11, and the stored state is maintained.

  The other axial end surface of the case 10 is closed by a filter 15 that can be opened and closed. A shaft 32 is provided at the lower end of the filter 15, and the shaft 32 is supported by the lower end of the case 10. The filter 15 can be rotated back and forth in the axial direction of the case 10 with the shaft 32 as a fulcrum. The filter 15 is formed with a filter member 79 folded in a pleat shape in a frame body having a substantially square cross-sectional shape. As shown in FIG. 4B, the wave direction of the filter member 79 is preferably the vertical direction (gravity acting direction). The filter 15 is, for example, a high-density HEPA filter (High Efficiency Particulate Air Filter). A HEPA filter is an air filter having a particle collection rate of 99.97% or more with respect to particles having a rated air volume of 0.3 μm and an initial pressure loss of 245 Pa or less. A packing 25 may be provided on the surface of the filter 15 opposite to the case 10. By the packing 25, the airtightness between the other axial end surface of the dust container 5 and the cleaner body 1 (particularly, the inlet of the intake duct 27) can be maintained. The shaft 31 and the shaft 32 may be shared. Further, the shaft 32 may be provided not at the lower end portion of the filter 15 but at the upper end portion of the filter 15.

  A dust collecting basket 12 is enclosed in the case 10. The shape of the dust collecting basket 12 may be a cage shape with one surface opened, a three-dimensional shape, a box shape, a container shape, or a dustpan shape. That is, the dust collecting basket 12 has a shape recessed on the opposite side to the opening. The cross-sectional shape of the dust collecting basket 12 may be a substantially square shape, a substantially circular shape, or a substantially triangular shape. The cross-sectional shape of the dust collecting basket 12 is preferably smaller from the opening surface toward the bottom surface. As a result, the cross-sectional area increases toward the side (opening side) where the dust is discharged, so that the user can easily discharge the dust accumulated in the dust collecting basket 12. The shape of the dust collecting basket 12 is formed by a frame body (support frame). It is preferable that a mesh member made of metal, nylon, or the like is coated or adhered to the bottom surface of the dust collecting basket 12 other than the opening surface, the top, bottom, left and right surfaces. By providing not only the bottom surface of the dust collecting basket 12 but also the top, bottom, left, and right surfaces, air flow can be secured even if dust accumulates on the bottom surface of the dust collecting basket 12, and the pressure loss of the suction air Can be reduced, and a decrease in suction force can be suppressed. This mesh member is air permeable and has a filter function of collecting dust. A disposable tissue paper may be used instead of the mesh member, or a mesh member and a tissue paper may be combined as long as they are breathable and have a filter function for collecting dust. For example, the user may wear tissue paper on the mesh member. The opening surface of the dust collecting basket 12 coincides with the opening surface of one end surface (front end surface) in the axial direction of the case 10. That is, the opening direction of the dust collecting basket 12 and the opening direction of the one end surface in the axial direction of the case 10 are the same. As shown in FIG. 6, the upper half of the outer peripheral end of the opening surface of the dust collecting basket 12 abuts on the inner peripheral surface of one end surface in the axial direction of the case 10, and the outer peripheral end of the opening surface of the dust collecting basket 12. The lower half is not in contact with the inner peripheral surface of one end surface of the case 10 in the axial direction. A shaft 14 is provided at the bottom of the dust collecting basket 12. The shaft 14 is supported in the case 10. Therefore, the dust collecting basket 12 can be rotated back and forth in the axial direction of the case 10 with the lower shaft 14 as a fulcrum. Thereby, when the front lid 11 is opened from the dust container 5, a part of the dust collecting basket 12 can be ejected from the dust container 5 by gravity. Since the formation position of the shaft 14 with respect to the case 10 is on the same side (lower side) as the formation position of the shaft 31 with respect to the case 10, the front cover 11 is obstructed when the front cover 11 is opened from the dust container 5. A part of the dust collecting basket 12 can be ejected from the dust container 5 without any trouble. Further, the shaft 14 may be provided with a helical spring in which an elastic force acts in a direction in which the dust collecting basket 12 is pushed out to the front lid 11 side. As a result, when the front lid 11 is opened from the dust container 5, a part of the dust collection basket 12 can jump out of the dust container 5 vigorously by the elastic force of the spring. The dust accumulated in 12 can be easily discharged. Further, the dust collecting basket 12 is divided into two parts in the vertical direction, that is, it is preferably composed of two structures, that is, an upper half frame (support) and a lower half frame (support). The two divided dust collecting baskets 12 are connected by a shaft 13 formed outside the bottom surface of the dust collecting basket 12. Therefore, as shown in FIG. 4 (A), the dust collecting basket 12 has the opening surface of the dust collecting basket 12 split vertically, with the middle of the bottom as a fulcrum. In particular, when a part of the dust collection basket 12 jumps out of the dust container 5, the dust collection basket 12 breaks up and down. As a result, the user can more easily discharge the dust accumulated in the dust collecting basket 12. In particular, dust stuck to the inner surface of the dust collecting basket 12 can be easily removed. However, the upper and lower divided configuration of the dust collecting basket 12 is not essential. Further, as described above, in addition to the front side of the case 10 being inclined by 40 to 45 degrees with respect to the direction of gravity action, the dust collection basket 12 jumps out of the dust container 5 by 30 degrees, so that the dust collection basket 12 Dust accumulated inside can be discharged in the direction of gravity.

  An outer channel 35 and an inner channel 36 penetrating in the axial direction are formed in the front lid 11. The outer flow path 35 is formed on the upper side of the front lid 11, and one end of the outer flow path 35 communicates with the opening of the extended part 34, particularly between the outer cylinder 6 and the inner cylinder 7 of the dust separation part 4. The other end of the outer flow path 35 communicates with the opening of the dust collecting basket 12 in the case 10. In order to prevent the dust accumulated in the dust collecting basket 12 from flowing back to the outer flow path 35 and the dust separation part 4 when the vacuum cleaner is stopped, the other end of the outer flow path 35 is the opening of the dust collecting basket 12. Of these, it is preferable to communicate with the upper half or near the upper end. However, the other end of the outer flow path 35 may communicate with the central portion of the opening of the dust collecting basket 12. Furthermore, in order to prevent the dust accumulated in the dust collecting basket 12 from flowing back to the outer flow path 35 and the dust separator 4 when the vacuum cleaner is stopped, A check valve (not shown) that covers the flow path 35 is preferably formed. The check valve rotates to the dust collecting basket 12 with the upper end as a fulcrum. However, the check valve is not an essential configuration. The cross-sectional area of the outer flow path 35 increases from one end of the outer flow path 35 toward the other end. The formation direction of the outer flow path 35 is a direction from the outer side of the front lid 11 toward the center side from one end of the outer flow path 35 to the other end. That is, the direction is from the outside of the dust collecting basket 12 toward the center side. In order to suppress the turbulence of the air flowing into the dust collecting basket 12 from the outer flow path 35, the outer flow path 35 is formed in the direction of the wall surface (upper wall surface) on the side where the outer flow path 35 of the dust collecting basket 12 communicates. Is preferred. The inner flow path 36 is formed from the center of the front lid 11 to the lower side, and one end of the inner flow path 36 communicates with the other end opening in the axial direction of the inner cylinder 7 (inside the inner cylinder 7) of the dust separator 4; The other end of the inner flow path 36 communicates with the case 10, particularly with the outside of the dust collecting basket 12. The other end of the inner flow path 36 is preferably in communication with the lower outside of the dust collecting basket 12. The inner flow path 36 is formed avoiding the outer flow path 35. Contrary to the outer flow path 35, the cross-sectional area of the inner flow path 36 is reduced from one end of the inner flow path 36 toward the other end.

  A handle 16 that can be gripped by a user extending in the horizontal direction is provided on the outside of the upper portion of the dust container 5. The user can hold the handle 16, lift the dust container 5 upward, and remove only the dust container 5 from the cleaner body 1 while leaving the dust separator 4 in the cleaner body 1. In addition, if the dust separation part 4 and the dust storage part 5 are connected, if the user holds the handle 16 and lifts the dust storage part 5 upward, the dust separation part 4 and the dust storage part 5 will be described. And, that is, the dust collector 2 itself can be removed from the cleaner body 1. As shown in FIG. 1, the axial direction other end surface (corresponding to the filter 15 portion) of the dust container 5 is preferably inclined toward the case 10 than the vertical surface (gravity acting direction). That is, it is preferable that the lower part is closer to the case 10 side than the upper part of the other axial end surface of the dust container 5. Moreover, as shown in FIG. 1, the formation direction of the axial direction one end surface (equivalent to front cover 11 part) of the dust accommodating part 5 is about 40 to 45 degrees on the case 10 side from the vertical surface (gravity acting direction). Inclined. That is, the lower part is closer to the case 10 side than the upper part of the one axial end surface of the dust container 5. As a result, the one end surface in the axial direction and the other end surface in the axial direction of the dust container 5 have an inverted C shape with respect to the vertical surface (gravity acting direction). Thereby, when a user lifts the dust accommodating part 5 upward, it becomes less caught, and the user can easily remove the dust accommodating part 5 from the cleaner body 1. Then, the user can easily remove the dust separator 4 from the cleaner body 1 by holding the recess 39 and lifting the dust separator 4 upward or obliquely upward after removing the dust container 5. As shown in FIG. 1, it is preferable that the axial direction one end surface (corresponding to the inlet pipe 3 portion) of the dust separating portion 4 is inclined toward the outer cylinder 6 rather than the vertical surface (gravity acting direction). That is, it is preferable that the lower part is closer to the outer cylinder 6 side than the upper part of the other axial end surface of the dust separator 4. As a result, when the user lifts the dust separator 4 upward or obliquely upward, there is less catching, and the user can easily remove the dust separator 4 from the cleaner body 1. Further, not only when the user removes the dust separator 4, but also when the dust separator 4 and the dust container 5 are integrated, that is, when the dust collector 2 itself is removed from the cleaner body 1. Since the one end surface in the axial direction and the other end surface in the axial direction have an inverted C shape with respect to the vertical surface (the direction of gravity action), the user is less likely to be caught when lifting the dust collector 2 upward. Can easily remove the dust collector 2 from the cleaner body 1.

  A hose joint pipe 20 is inserted into the main body inlet 21 and can hold the hose joint pipe 20. A packing 22 is provided at one end of the main body inlet 21. Thereby, the airtightness of the hose joint pipe 20 and the inlet pipe 3 can be maintained. A caster support portion 23 for supporting casters is provided at the front lower end of the vacuum cleaner body 1 (below the dust collector 2). An intake duct 27 extending in the front-rear direction of the cleaner body 1 is provided on the upper rear side in the cleaner body 1. An opening at one end in the extending direction of the intake duct 27 faces the filter 15. An auxiliary filter 26 is provided near the opening at one end of the intake duct 27. Thereby, it is possible to suppress the electric blower 28 from sucking the dust remaining outside the dust collector 2. The other end in the extending direction of the intake duct 27 is closed, and the lower portion near the other end in the extending direction of the intake duct 27, that is, the electric blower 28 side is opened. A dust removing device 24 that removes dust adhering to the filter 15 is provided at a position in contact with the filter 15 at an upper portion of one end of the intake duct 27 of the cleaner body 1. The dust removing device 24 includes a spiral spring (elastic body) on the outer periphery of the rotating body. The dust removing device 24 is rotated by a motor or by pulling out a cord reel, and a spiral spring bounces the filter member 79 of the filter 15 to shake off dust attached to the filter 15. As described above, since the wave direction of the filter 15 is the vertical direction, the dust that has been shaken off easily falls in the direction of gravity. The dust shaken off from the filter 15 accumulates in the case 10. Accordingly, clogging of the filter 15 can be suppressed, a decrease in air pressure loss can be suppressed, and a decrease in suction force can be suppressed. An electric blower 28 that generates a suction force is provided on the lower rear side in the cleaner body 1. The electric blower 28 is installed vertically so that the suction port of the electric blower 28 faces upward. An exhaust duct 40 communicating with the exhaust port of the electric blower 28 is provided on the downstream side of the electric blower 28 and on the front side of the electric blower 28. Further, a filter 29 communicating with the exhaust duct 40 is provided on the downstream side of the exhaust duct 40 and on the front side of the exhaust duct 40. The filter 29 is formed with a filter member 79 folded in a pleat shape in a frame body 78 having a substantially square cross section. The wave direction of the filter member 79 is preferably the vertical direction (gravity acting direction). The filter 15 is, for example, a high-density ULPA filter (Ultra Low Penetration Air Filter). The ULPA filter is an air filter having a particle collection rate of 99.9995% or more for particles having a rated air volume of 0.15 μm and an initial pressure loss of 245 Pa or less. The particle collection efficiency is higher than the particle collection efficiency. And the main body exhaust port 30 is provided in the rear-end surface of the cleaner body 1. FIG.

  Next, the flow of air during operation (when in use) of the vacuum cleaner will be described. The arrows in FIG. 1 indicate the flow of air. When the user turns on the power of the vacuum cleaner, the electric blower 28 operates and generates a suction force. The air sucked from the hose joint pipe 20 flows into the outer cylinder 6 through the inlet pipe 3, hits the dent portion 8, changes its direction in the radial direction, and further, the outer periphery of the inner cylinder 7 of the dent portion 8. The direction is slightly changed in the circumferential direction at the end, and the direction is further changed in the circumferential direction by the guide tube 38. As a result, air turns around the outer cylinder 6 about the axis of the outer cylinder 6. That is, it becomes a swirl flow. The heavy dust contained in the air collects outside the swirling flow by the centrifugal separation action accompanying the swirling of the air. Light dust contained in the air remains not only outside the swirl but also inside. However, in general household cleaning, most of the dust collects outside the swirling flow, and much dust does not remain inside the swirling flow. The air outside the inner cylinder 7 flows into the dust collecting basket 12 through the outer flow path 35 together with heavy dust. The dust is collected by the dust collecting basket 12, accumulated, and further compressed by the suction force. Since the dust is automatically compressed by the suction force, a lot of dust can be held without bothering the user. The air passes through the bottom surface and the top, bottom, left and right surfaces of the dust collecting basket 12 and reaches the filter 15. On the other hand, the swirling inner air flows into the inner cylinder 7 from the through hole 33 of the inner cylinder 7. Dust larger than the through hole 33 cannot pass through the through hole 33 and remains outside the inner cylinder 7. The air in the inner cylinder 7 together with light dust and small dust flows through the inner flow path 36 and flows into the lower outside of the dust collecting basket 12 in the case 10 and reaches the filter 15. The air that has passed through the dust collecting basket 12 and the air that has not passed through the dust collecting basket 12 merge before the filter 15 and pass through the filter 15. Therefore, the dust collecting basket 12 partitions (partitions) the inside of the case 10 into a space communicating with the outer flow path 35 and a space communicating with the inner flow path 36. Alternatively, the dust collection basket 12 partitions (partitions) the inside of the case 10 into a space communicating with the outer flow path 35 and a space facing the filter 15. The filter 15 collects light dust, small dust, and other dust contained in the air. Air that passes through the filter 15 and contains almost no dust flows through the auxiliary filter, flows into the intake duct 27, passes through the opening at the lower portion of the intake duct 27, and is sucked from the suction port at the upper portion of the electric blower 28. The air discharged from the discharge port on the side of the electric blower 28 reaches the filter 29 through the exhaust duct 40, and the dust remaining by the filter 29 is collected. The air that has passed through the filter 29 passes through the electric blower 28, the cord reel chamber (not shown), the gap at the bottom of the cleaner body 1, and the like, and is discharged from the body exhaust port 30 to the outside of the cleaner body 1. . In particular, since the filter 29 has a dust collection efficiency equivalent to or higher than that of a filter mounted on the air cleaner, the air discharged from the cleaner body 1 to the outside is equivalent to or higher than that of the air cleaner. Has been cleaned. FIG. 2A shows a perspective view of the dust collector 2 of the embodiment of the present invention, and FIG. 2B shows a cross-sectional view seen from the side of the dust collector 2 of the embodiment of the present invention. The user can remove the dust collector 2 from the cleaner body 1 by holding the handle 16 and lifting the dust collector 2 upward. However, the dust separator 4 may be left in the cleaner body 1 and only the dust container 5 may be removed from the cleaner body 1. As shown in FIG. 2A, the outer shape of the cross section of the dust separation portion 4 viewed from the axial direction is a substantially circular shape. The outer shape of the cross section of the dust container 5 is substantially circular at the front lid 11, but is substantially square after the front lid 11, and is also substantially square at the filter 15. As shown in FIG. 2B, the opening direction at one axial end of the case 10 and the opening direction at the other axial end of the case 10 are not in a straight line and differ by about 45 to 50 degrees. That is, the axial direction of the dust container 5 is bent slightly forward from the middle. As described above, one end surface in the axial direction of the dust collector 2 (portion of the inlet pipe 3) faces slightly downward (the direction of gravity action), and the other end surface in the axial direction of the dust collector 2 (portion of the filter 15) is also , Slightly facing downward (gravity acting direction), one end surface in the axial direction and the other end surface in the axial direction of the dust collector 2 have an inverted C shape with respect to the vertical surface (gravity acting direction). Therefore, when the dust collector 2 is lifted upward, the amount of catch is reduced, and the user can easily remove the dust collector 2 from the cleaner body 1.

  3A shows a perspective view of the inner cylinder 7 and the outer cylinder 6 of the embodiment of the present invention, and FIG. 3B shows a perspective view of the back side of the inner cylinder 7 of the embodiment of the present invention. One end surface of the outer cylinder 6 is closed except for a portion where the inlet pipe 3 is formed, and the other end surface of the outer cylinder 6 is opened. The inner cylinder 7 has an annular extending portion 34 at one end of the cylindrical portion. As shown in FIG. 3A, the outer peripheral end of the other end surface of the outer cylinder 6 abuts on the outer peripheral end of the outer extension part 34 by being inserted into the outer cylinder 6 from the cylindrical portion of the inner cylinder 7 in the axial direction. Thus, the inner cylinder 7 is formed in the outer cylinder 6. As shown in FIG. 3A, the opening direction of the inlet pipe 3 and the opening of the recessed portion 8 are opposed to each other. The opening direction of the recess 8 toward the outer peripheral end of the inner cylinder 7 is substantially downward, and the opening direction of the guide tube 38 in the circumferential direction is counterclockwise. The circumferential opening direction of the guide tube 38 may be clockwise. And the hole penetrated to an axial direction is provided in the upper part of the outward extension part 34, ie, the upper part of the outward extension part 34 is opening. The left wall surface of the opening is higher than the right wall surface. That is, the wall surface (left wall surface) of the upper opening of the extension part 34 facing the opening direction in the circumferential direction of the guide tube 38 is higher than the other wall surface (right wall surface). The surface of the extended portion 34 is spiral, and has a function of a flow path that smoothly guides air to the opening above the extended portion 34. As shown in FIG. 3 (B), the upper substantially semicircular portion in the inner cylinder 7 is provided with a recessed portion 39 that is recessed toward the inner side of the inner cylinder 7, and the lower substantially semicircular portion is formed in the inner cylinder 7. Open in. When the flow rate of air outside the inner cylinder 7 is made larger than the flow rate of air inside the inner cylinder 7 in a state where dust is not accumulated in the dust collecting basket 12, the upper portion of the extended portion 34 is higher than the opening area inside the inner cylinder 7. The opening area may be increased. The area of the recessed portion 39 may be increased as compared with the opening into the inner cylinder 7, or the area of the opening into the inner cylinder 7 may be increased as compared with the recessed portion 39. Then, the user can easily hold the dust separation part 4 or the inner cylinder 7 by putting his / her finger into the recess 39.

  When the cylindrical portion of the inner cylinder 7 is formed of a metal material having an antibacterial effect, first, a plurality of through-holes 33 having a diameter of about 0.1 mm to 0.4 mm are etched into a thin metal plate, and then both ends are formed. Join into a cylindrical shape. The through hole 33 may be punched. Examples of the metal material having an antibacterial effect include stainless steel, silver, and copper. The alloy is not limited to stainless steel, silver and copper, and may be any alloy containing silver or copper or having silver or copper surface-deposited. The thickness of the metal thin plate is 1 mm or less, and about 0.1 mm to 0.5 mm is preferable for improving workability. When the thickness of the metal thin plate is thin, it is preferable to fix both ends in the axial direction of the cylindrical metal thin plate with a resin having good moldability in order to improve the strength and roundness. Specifically, the shape of one end of the substantially circular shape of the inner cylinder 7 having the recess 8 and the guide tube 38 and the shape of the other end of the inner cylinder 7 having the annular outer extension 34 are formed. Then, a cylindrical metal thin plate is set, and then insert molding is performed by pouring resin into a mold. In the case of insert molding, the metal thin plate may not be formed into a cylindrical shape by joining both ends. Thus, only the cylindrical portion of the inner cylinder 7 in which the substantially circular one end portion of the inner cylinder 7 having the recessed portion 8 and the guide tube 38 and the other end portion of the inner cylinder 7 having the annular outer extending portion 34 are made of resin. Can be made of a metal material. Insert molding can simplify the manufacturing process.

  FIG. 4 (A) shows a perspective view of a state in which the front lid 11 of the dust container 5 of the embodiment of the present invention is opened, and FIG. 4 (B) shows the rear part of the dust container 5 of the embodiment of the present invention. The perspective view of the state which opened the filter is shown. As shown in FIG. 4A, when the front lid 11 is pivoted downward with the shaft 31 as a fulcrum, the dust collecting basket 12 is also pivoted downward with the shaft 14 as a fulcrum. At this time, the dust collecting basket 12 is divided into two parts up and down with the shaft 13 as a fulcrum. The opening of the dust collection basket 12 when it jumps out of the dust storage section 5 is wider than the opening of the dust collection basket 12 stored in the dust storage section 5. As a result, the dust stuck to the inner surface of the dust collecting basket 12 can be easily removed. When the user attaches the tissue paper along the inner surface of the dust collecting basket 12, the end of the tissue paper is sandwiched between the frame of the opening of the dust collecting basket 12 and the outer peripheral end of the front lid 11. In this case, the tissue paper can be prevented from shifting or coming off. As shown in FIG. 4B, the filter 15 is also rotated downward and opened with the shaft 32 as a fulcrum. As a result, the user can easily discharge the dust accumulated outside the dust collecting basket 12 in the case 10, and can easily remove the dust attached to the side surface of the case 10 of the filter 15.

  FIG. 5A is a front view of the front lid 11 of the dust container 5 according to the embodiment of the present invention as viewed from the outside of the dust container, and FIG. 5B is a dust container according to the embodiment of the present invention. It is the front view which looked at the front lid 11 of 5 from the dust accommodating part inner side. The hatched portion in the figure shows the frontmost surface, not the cross section. A shaft 31 that is rotatably supported by the case 10 is provided at the lower end of the front lid 11. The front lid 11 has a substantially circular shape. A substantially circular portion outside the shaded portion shown in FIG. 5A can contact the outer peripheral end of the other end surface in the axial direction of the dust separation portion 4. A substantially circular portion inside the hatched portion shown in FIG. 5A can contact the outer peripheral end of the other axial end surface of the inner cylinder 7 of the dust separating portion 4. On the upper side of the front lid 11, that is, on the side opposite to the shaft 31, an opening of the outer flow path 35 is formed between a substantially circular portion outside the shaded portion and a substantially circular portion inside. The opening position on the front side (outside of the dust container 5) of the outer channel 35 may be the left and right sides or the lower side of the front lid 11, but the opening position on the back side (inside the dust container 5) of the outer channel 35 is the front cover. 11, the opening position on the front side of the outer flow path 35 is also preferably above the front lid 11 in order to reduce the pressure loss of the air by reducing the length of the outer flow path 35. . On the other hand, an opening of the inner flow path 36 is formed inside the inner cylinder 7. In the front view of FIG. 5A, the opening area of the inner flow path 36 is larger than the opening area of the outer flow path 35, but the upper semicircular portion in the inner cylinder 7 has a recess 39. Therefore, when the flow rate of air outside the inner cylinder 7 is made larger than the flow rate of air inside the inner cylinder 7, the substantial flow path area is that the opening of the inner flow path 36 is larger than the opening area of the outer flow path 35. The area is smaller. A portion where the opening of the outer flow path 35 between the substantially circular portion outside the shaded portion and the inner substantially circular portion is not formed is closed. A substantially circular portion outside the shaded portion shown in FIG. 5B abuts on the outer peripheral end of the axial end surface of the case 10 and a part of the outer peripheral end of the opening of the dust collecting basket 12. As shown in FIG. 5B, the opening of the outer flow path 35 is formed above the vertical center line of the front lid 11. Thereby, when the vacuum cleaner is stopped, it is possible to prevent the dust accumulated in the dust collecting basket 12 from flowing back to the outer flow path 35 and the dust separator 4. However, the opening of the outer flow path 35 may be formed in the center portion including the vertical center line of the front lid 11. Furthermore, it is preferable to form a check valve (not shown) that covers the outer flow path 35. This further prevents the dust accumulated in the dust collecting basket 12 from flowing back to the outer flow path 35 and the dust separator 4 when the vacuum cleaner is stopped. On the other hand, an opening of the inner flow path 36 is formed near the lower end of the front lid 11. However, the opening position of the inner flow path 36 may be lower than the opening position of the outer flow path 35, or may be on the left or right side or the upper side. The hatched portion on the upper side of the opening of the inner flow path 36 contacts the lower end of the outer peripheral end of the opening of the dust collecting basket 12. Then, as shown in FIG. 5B, the opening area of the outer flow path 35 is larger than the opening area of the inner flow path 36 on the back side of the front lid 11 (inside the dust container 5). Furthermore, as shown in FIGS. 5A and 5B, the opening area (FIG. 5B) of the other end (back side) of the outer flow path 35 is equal to that of one end (front side) of the outer flow path 35. It is larger than the opening area (FIG. 5A). That is, the outer flow path 35 extends from one end to the other end. On the other hand, as shown in FIGS. 5 (A) and 5 (B), the opening area (FIG. 5 (B)) of the other end (back side) of the inner flow path 36 is equal to that of one end (front side) of the inner flow path 36. It is smaller than the opening area (FIG. 5A). That is, the inner flow path 36 is narrowed from one end to the other end.

  FIG. 6 shows a front view as seen from the dust separating portion side when the front lid 11 of the dust accommodating portion 5 of the embodiment of the present invention is removed. As in FIG. 5, the hatched portion in the figure indicates the frontmost surface, not the cross section. The substantially circular shaded portion is in contact with the outer peripheral end of the front lid 11. As shown in FIG. 6, the outer peripheral end of the opening on one end surface in the axial direction of the case 10 abuts a part of the outer peripheral end of the opening of the dust collecting basket 12. As shown in FIG. 6, 80% or more of the opening on one end surface in the axial direction of the case 10 is occupied by the opening of the dust collecting basket 12. A region other than the opening of the dust collection basket 12 in the opening of the case 10 (the remaining 20% or less) faces the opening of the inner flow path 36 and communicates with the inner flow path 36.

  FIG. 7 is a schematic view of a vacuum cleaner according to an embodiment of the present invention. In addition to the vacuum cleaner main body 1, the vacuum cleaner includes a suction tool 50 having a suction port, one end communicating with the suction tool 50, a telescopic joint pipe (extension pipe) 51, and one end communicating with the other end of the joint pipe 51. An operation tube 52 having a handle 53 and an operation button / switch that are gripped by the user, and a hose 54 having one end communicating with the other end of the operation tube 52 and the other end forming the hose coupling tube 20 are provided. The hose joint pipe 20 is inserted into the main body inlet 21 of the cleaner body 1 and can be held. Further, wheels 55 are provided on both side surfaces of the cleaner body 1. And if the power supply of a vacuum cleaner is turned ON by operation to an operation button / switch from a user, the electric air blower 28 will act | operate and will generate | occur | produce suction | attraction force. The air sucked from the suction port of the suction tool 50 passes through the joint pipe 51, the operation pipe 52, the hose 54, and the hose joint pipe 20 in this order, and flows into the cleaner body 1.

  FIG. 8 is a perspective view of the cleaner body 1 according to the embodiment of the present invention. In the vicinity of the center of the upper surface of the cleaner body 1, an upper cover 56 for the dust collector 2, one end of which is rotatably supported on the cleaner body 1 by a shaft, is provided. On the rear side, a handle 37 is provided that is rotatably supported by the vacuum cleaner main body 1 by a shaft so that the user can lift the vacuum cleaner main body 1.

  According to the embodiment of the present invention, dust can be compressed without bothering the user, the user can easily discharge the dust that has been compressed and accumulated, and a reduction in suction force can be suppressed. The upper cover 56 is preferably formed in a size and position that covers the handle 16 of the dust collector 2 in a closed state. Furthermore, it is preferable that the rotation of the upper cover 56 is locked so that the upper cover 56 does not open during the operation of the cleaner body 1 or the operation of the cleaner body 1 is stopped when the upper cover 1 is opened. The upper cover 56 can prevent the user from removing the dust collector 2 during the operation of the cleaner body 1 and can improve the safety of the vacuum cleaner.

  Details of the inner cylinder 7 of the first embodiment will be described as a second embodiment.

  In the vacuum cleaner according to the second embodiment of the present invention, the dust collector 2 includes the inner cylinder 7 having a plurality of through holes 33 on the circumferential surface, and one end in the axial direction of the inner cylinder 7 is closed. The other end in the axial direction is opened and communicated with the electric blower 28 side, and one end in the axial direction of the inner cylinder 7 is formed at a position facing the outlet side opening of the inlet pipe 3 of the dust collector 2. And the one end of the axial direction of the inner cylinder 7 is comprised so that the air suck | inhaled from the inlet tube 3 of the dust collector 2 may be rotated in the circumferential direction.

  Or the vacuum cleaner of Example 2 of this invention has the function in which the obstruction | occlusion part of the axial direction end of the inner cylinder 7 rotates the air inhaled from the inlet pipe 3 of the dust collector 2 to the circumferential direction. It has a shape.

  Or the vacuum cleaner of Example 2 of this invention has the shape where the obstruction | occlusion part of the axial direction end of the inner cylinder 7 was dented inside the axial direction of the inner cylinder 7 (for example, the recessed part 8), A part of the recessed shape is characterized by opening in the circumferential surface of the inner cylinder 7.

  And according to Example 2 of this invention, by giving the turning function to the end of the inner cylinder 7, the axial length of the dust collector 2 can be shortened without increasing the width, and the vacuum cleaner can be Can be compact.

  FIG. 9 is a front view of the inner cylinder 7 according to the second embodiment of the present invention as viewed from the cylindrical portion side. The cylindrical portion of the inner cylinder 7 includes a hollow semi-columnar column portion 57 and a hollow truncated cone portion 58. The column portion 57 is located on the distal end side of the cylindrical portion of the inner cylinder 7, and the truncated cone portion 58 is located on the root side of the cylindrical portion of the inner cylinder 7. The base of the truncated cone part 58 is joined to the inner peripheral end of the outer extension 34. The frustoconical portion 58 gently smoothes the joint between the cylindrical portion 57 and the extension 34, suppresses air flow separation and turbulence, reduces the energy loss of the sucked air, and suppresses noise. it can. In the inner cylinder 7, it is preferable that the outer extending portion 34, the guide tube 38 (guide member), the columnar portion 57, and the truncated cone portion 58 are integrally formed. The cylindrical portion is not composed of the column portion 57 and the truncated cone portion 58 but may be composed of only the column portion 57 or only the truncated cone portion 58. That is, the columnar portion 57 may have a columnar shape or a truncated cone shape.

  R1 is the outer radius of the cylindrical portion 57, R2 is the outer radius of the truncated cone portion 58, R3 is the outer radius of the extension 34, and R4 is the outer radius of the guide tube 38. The outer shape of the extended portion 34 is a substantially perfect circle. The semicircle of the cylindrical portion 57 is also a substantially perfect circle. The extension part 34, the columnar part 57, and the truncated cone part 58 are formed on concentric axes and have a relationship of R1 <R2 <R3. For example, R1 is about 3 cm, R2 is about 5 cm, and R3 is about 6.5 cm. The axial center of the guide tube 38 is shifted to the left in FIG. 9 with respect to the axial center of the cylindrical portion 57, and has a relationship of R1 <R4 <R2. For example, R4 is about 4 cm. One end of the cylindrical portion 57 in the circumferential direction (lower side in FIG. 9) is terminated, and the other end (upper side in FIG. 9) is joined to the guide tube 38. The side wall of the guide tube 38 is gently curved in a semicircular shape with a radius of curvature R 4 from the other end of the column portion 57 to the front of the guide tube end portion 59. Is gently curved along the outer periphery of the cylindrical portion 57 (along the outer periphery of the truncated cone portion 58). That is, one end of the guide tube 38 is connected to the opening of the recessed portion 8, and the other end faces the direction along the outer periphery of the cylindrical portion 57 outside the cylindrical portion 57 (the direction along the outer periphery of the truncated cone portion 58). In the meantime, it is gently curved into a substantially semicircular shape so as to turn 180 °. The recess 8 itself is preferably formed in a gentle spherical shape with no step from the side wall of the recess 8 toward the center of the bottom, and the joint between the recess 8 and the guide tube 38 is also formed smoothly without a step. It is preferable. Thereby, the energy loss of the inhaled air can be reduced and noise can be suppressed.

  The cylindrical portion 57 has a thickness D1 (between the outer shape R1 and the side wall of the recessed portion 8) of about 3 mm, the inside of the thickness D1 of about 3 mm is hollow, and the space communicates with the through hole 33. To do. One end of the cylindrical portion 57 forms the inner wall of the flow path where the air flow turns approximately 180 degrees, so that the thicker one can reduce noise. Therefore, the thickness D1 of the cylindrical portion 57 is preferably about 3 mm, whereas the thickness at one end of the cylindrical portion 57 is preferably increased to about 6 mm. That is, it is preferable that the radius of curvature at one end of the cylindrical portion 57 is about 3 mm. Thereby, noise can be reduced. In addition, if the thickness D1 of the cylindrical portion 57 is also increased, dust is easily clogged. Therefore, the thickness D1 of the cylindrical portion 57 is preferably about 3 mm. The radius (R1-D1) of the recess 8 is preferably equal to or slightly larger (within 1 mm) than the inner radius of the outlet opening of the inlet pipe 3. This is because if the radius of the recess 8 is smaller than the inner diameter of the outlet opening of the inlet pipe 3, dust may be clogged, air energy loss may increase, and noise may increase.

  The through-hole 33 is preferably not formed in the truncated cone portion 58 or the guide tube 38 but formed only on the outer peripheral surface of the cylindrical portion 57. However, the through-hole 33 may be formed not only in the outer peripheral surface of the cylindrical portion 57 but also in the truncated cone portion 58 and the guide tube 38. The diameter of the through hole 33 may be about 2 mm. When the diameter of the through hole 33 is about 2 mm, the number of the through holes 33 is preferably about 100.

  When viewed from the radial direction, the guide tube end portion 59 which is a part of the guide tube 38 is substantially from the circumferential root portion 60 of the guide tube end portion 59 toward the circumferential tip 61 of the guide tube end portion 59. It has the shape of "<". As shown in FIG. 9, the guide tube end portion 59 and the cylindrical portion 57 overlap when viewed from the radial direction. By forming the terminal end (guide tube terminal portion 59) of the guide tube 38 so as to overlap with one end of the cylindrical portion 57, a sufficient turning force can be applied to the sucked air. One end opening of the outer flow path 35 (opening of the upper part of the extension part 34) is formed on the opposite side (180 degree opposite side) in the circumferential direction with respect to the guide pipe end part 59. The through hole 33 only needs to be formed at least between the guide tube terminal portion 59 and one end opening of the outer flow path 35. In order to facilitate the flow of dust into the outer flow path 35, it is preferable that the circumferential length of one end opening of the outer flow path 35 is longer. The downstream side wall surface 65 (left wall surface) of one end opening of the outer flow path 35 is higher than the upstream side wall surface 66 (right wall surface), and the downstream side wall surface 65 extends from the inner peripheral side to the outer peripheral side when viewed in the axial direction. And the outer peripheral side is longer in the circumferential direction toward the upstream side wall surface 6 than the inner peripheral side. This is because, in the unlikely event that garbage with length such as hair or lint is caught on the downstream side wall surface 65, the outer circumferential side is lengthened in the circumferential direction, and the force to guide these garbage to the inner circumferential side works. This is because the balance is gradually lost and dust is stored in the dust container 5. In order to prevent dust accumulated in the dust container 5 from spilling from the other end opening of the outer flow path 35 of the front lid 11, the one end opening of the outer flow path 35 is preferably arranged on the upper side. Therefore, when it is desired to increase the centrifugal separation distance, the position of the opening of one end of the outer flow path 35 is left as it is, and the position of forming the opening of the recess 8 and the position of forming the guide tube terminal portion 59 are outward in the clockwise direction. A position close to one end opening of the flow path 35, that is, a position on the left side in FIG.

  FIG. 10 is also a front view of the inner cylinder 7 according to the second embodiment of the present invention viewed from the cylindrical portion side. The arrows in FIG. 10 indicate the flow direction of the sucked air. The air that has flowed into the recessed portion 8 in the substantially axial direction is turned in the radial direction by the recessed portion 8 and turned in the circumferential direction by the guide tube 38, and is about a half turn between the inner tube 7 and the outer tube 6 (that is, guidance From the pipe end portion 59 to the one end opening of the outer flow path 35, it flows (swivels) in the circumferential direction and the axial direction, and most of the inflowed air flows into one end opening of the outer flow path 35 (flow 64). Therefore, the recess 8 and the guide tube 38 have a function of turning the air that has flowed in substantially the axial direction. A portion of the air flowing (swirling) in the circumferential direction and the axial direction between the inner cylinder 7 and the outer cylinder 6 (ie, from the guide tube terminal portion 59 to the opening of one end of the outer flow path 35) is a through hole. It flows into the inner cylinder 7 from 33 (flow 63). In addition, the air that has not flowed to the one end opening of the outer flow path 35 is approximately half a circumference between the guide tube 38 and the outer cylinder 6 (that is, from one end opening of the outer flow path 35 to the guide tube end portion 59) in the circumferential direction. The flow (flow 64) merges with the air coming out of the guide tube 38. In the second embodiment of the present invention, the air swirled outside the inner cylinder 7 flows into the dust container 5 that communicates with the electric blower 28 through the outer flow path 35, so there is no need to increase the centrifugal separation distance. It may be about half a circle. Therefore, the height of the inner cylinder 7 and thus the axial length of the dust separator 4 can be shortened, the axial length of the dust collector 2 can be shortened, and the cleaner body 1 can be made compact. The outer diameter of the dust separation part 4 substantially corresponds to the outer diameter of the inner cylinder 7, that is, the outer diameter 2R3 of the extended part 34. The axial length of the dust separator 4 (excluding the inlet pipe 3) substantially corresponds to the axial height H5 of the inner cylinder 7. And it has the relationship of H5 <2R3. Therefore, the axial height of the dust separator 4 is smaller than the vertical width or the horizontal width of the dust separator 4. For example, 2R3 is about 13 cm and H5 is about 7 cm. The flow rate of the air (flow 62) flowing into the one end opening of the outer flow path 35 is the flow rate V1, the flow rate of the air (flow 63) flowing into the inner cylinder 7 from the through hole 33 is the flow rate V2, and the one flow opening to the one end opening of the outer flow path 35. If the flow rate of the air (flow 64) that does not exist is the flow rate V3, the relationship is V1> V2> V3.

  The flow path width W in the radial direction is larger than the flow path width W1 at the guide pipe end portion 59 of the guide pipe 38, and the flow path width W2 at the position exiting the guide pipe 38 is widened. From the outlet to one end opening of the outer flow path 35 is constant (flow path width W2), and from one end opening of the outer flow path 35 to the guide tube end portion 59 gradually decreases from the flow path width W2 to the flow path width W3. The guide tube end portion 59 has a flow path width W3. And it has the relationship of W2> W1> W3. If W3 is too small, dust may be clogged. For example, W3 is about 1.0 cm. For example, W2 is R3-R1 and is about 4 cm. W1 is W2-W3- (the thickness in the radial direction of the guide tube end portion 59), which is slightly smaller than 3 cm.

  FIG. 11 is a perspective view of the inner cylinder 7 according to the second embodiment of the present invention as viewed from the cylindrical portion side. The side wall of the guide tube end portion 59 does not end perpendicularly to the circumferential direction, but ends in a substantially “<” shape bent in two stages. Specifically, the guide tube end portion 59 is terminated at an angle close to a perpendicular to the circumferential direction from the axial tip portion to the axial intermediate portion, and to the axial base portion of the guide tube end portion 59 of the guide tube end portion. Terminates at a much greater slope than the normal to the circumferential direction. For example, if the side wall of the guide tube end portion 59 terminates perpendicularly to the circumferential direction at the position of the circumferential root portion 60 of the guide tube end portion 59, a sufficient turning force cannot be applied, and sufficient The dust cannot be separated. On the other hand, if it terminates perpendicularly to the circumferential direction at the position of the circumferential tip 61 of the guide tube end portion 59, the turning force is too strong and less air flows into the outer flow path 35 in the first turn. In some cases, dust (especially dust having a large specific gravity) is not sucked into the outer flow path 35, and dust remains in the dust separator 4. In particular, in the present invention, since the inlet side of the dust separator 4 is positioned below the gravitational direction and the outlet side is positioned above the gravitational direction, the dust is not sucked into the outer flow path 35 and the dust remains in the dust separator 4. Is remarkable. Therefore, by ending the guide tube terminal portion 59 in a substantially “<” shape, a necessary and sufficient turning force can be applied to the air flowing into the recessed portion 8. Further, since the air that has flowed into the recessed portion 8 flows toward the downstream side in the axial direction, when viewed at the guide tube end portion 59, the axial base side of the guide tube end portion 59 rather than the axial front end side. The flow rate increases (pressure increases). Thus, by making the axial base side longer in the circumferential direction than the axial front end side of the guide pipe terminal end 59, a sufficient turning force can be applied to the axial base side of the guide pipe terminal end 59 having a large flow rate. it can. In addition, instead of making the guide tube end portion 59 into a substantially “<” shape, the side wall of the guide tube end portion 59 is gradually inclined in the circumferential direction in one step from the axial front end side to the axial root side. You may do it.

  FIG. 12 is a top view of the inner cylinder 7 according to the second embodiment of the present invention as viewed from the rear side of the outer extension portion. FIG. 13: is the perspective view which looked at the inner cylinder 7 of Example 2 of this invention from the outer extension part back side. The packing 9 (seal member) is attached to the back side of the extended portion 34 by three screws 67 (attachment members). The packing 9 includes an annular lip 68 (projecting portion) located on the outer peripheral side and an annular lip 69 (projecting portion) located on the inner peripheral side. The lip 68 is provided to keep the airtightness between the inner cylinder 7 and the front lid 11 in the outer flow path 35, and the lip 69 keeps the airtightness between the inner cylinder 7 and the front lid 11 in the inner flow path 36. Is provided to do. The lip 68 and the lip 69 are formed extending from the inner peripheral side toward the outer peripheral side. Therefore, when the dust collection container 5 is attached to the dust collection separation part 4, the lip 68 and the lip 69 abut against the front lid 11 of the dust collection container 5, and elastically deform to keep the airtight. . Further, when the electric blower 28 is activated and a suction force is generated, the dust collecting / separating portion 4 is sucked into the dust collecting housing portion 5, and the lip 68 and the lip 69 are further elastically deformed to keep the airtightness. Therefore, when the electric blower 28 is operating as compared to the case where the electric blower 28 is stopped, the airtight holding force between the dust collection housing 5 and the dust collection separation unit 4 is increased. However, the lip 69 is preferably formed extending from the outer peripheral side toward the inner peripheral side. When the lip 69 is formed extending from the inner peripheral side toward the outer peripheral side, the end of the outer flow path 35 is formed. The dust from the outer flow path 35 is caught on or leaked from the inner peripheral portion 100 of the inner wall. By forming the lip 69 so as to extend from the outer peripheral side toward the inner peripheral side, it is possible to prevent dust from being caught or leaked. The packing 9 is preferably formed integrally with an elastic material such as rubber including the lip 68 and the lip 69.

  The substantially upper half of the inner peripheral side of the cylindrical portion (the inner peripheral side of the lip 69) is closed by a packing 9 having a recessed portion 39 that is recessed inward in the axial direction of the cylindrical portion, and the inner peripheral side of the cylindrical portion (the lip 69). The substantially lower half of the inner peripheral side is open without being closed by the packing 9. This opening forms an inner flow path 36. The area of the portion closed by the packing 9 may be the same as or smaller than the area of the opened portion. By making the area of the portion closed by the packing 9 smaller than the area of the opened portion, energy loss and noise of the air flowing through the inner flow path 36 can be reduced.

  FIG. 14 is a side view of the inner cylinder 7 according to the second embodiment of the present invention as viewed from above. The downstream side wall surface 65 (left wall surface) of one end opening of the outer flow path 35 is higher than the upstream side wall surface 66 (right wall surface), and is opened by a difference dH of this height. As a result, the flow outside the cylindrical portion can be smoothly changed in the axial direction along the downstream side wall surface 65, and the dust contained in the swirl flow can easily flow into the dust container 5. The inner wall surface 101 of the outer channel 35 is inclined or curved in the circumferential direction from the downstream side wall surface 65 that is the inlet of the outer channel 35 toward the other axial end surface of the inner cylinder 7 that is the outlet of the outer channel 35. Formed. Thereby, dust can flow smoothly in the outer flow path 35. In addition, since the inner wall surface 101 of the outer flow path 35 is inclined or curved, not only the axial component but also the circumferential component (swirl component) is included in the air flow that exits the outer flow path 35. Remains.

  FIG. 15 is a side view of the inner cylinder 7 according to the second embodiment of the present invention as viewed from the right side. The outward extension 34 has a lower axial height toward the outer flow path 35 (from the lower side to the upper side). The surface of the extended portion 34 is formed in a spiral shape toward the outer flow path 35 in one round. When the height of the cylindrical portion 57 is H1, and the height of the truncated cone portion 58 at the highest position is H2, the relationship is H1> H2. Further, assuming that the height of the guide tube 38 at the highest position is H3, there is a relationship of H3> H1. The through-hole 33 may be formed at least between the guide tube end portion 59 and one end opening of the outer flow path 35, but among them, the through hole 33 is more concentrated on the guide tube end portion 59 side than the outer flow path 35 side. As long as it is formed. This is because the flow rate flowing into the outer flow channel 35 is larger than the flow rate flowing into the through-hole 33 on the outer flow channel 35 side, and there is no point in forming the through-hole 33 on the outer flow channel 35 side.

  FIG. 16 is a cross-sectional view of the inner cylinder 7 according to the second embodiment of the present invention as viewed from the right side. When the depth at the deepest portion in the axial direction of the recessed portion 8 is H4, the relationship is H4 <H1. That is, the depth of the recessed portion 8 is shallower than the height of the cylindrical portion 57. When viewed three-dimensionally, the recess 8 is hemispherical, and the cross-sectional shape of the recess 8 is substantially a semicircle as shown in FIG. Therefore, the depth H4 of the recessed portion 8 is substantially equal to the outer radius R1 of the cylindrical portion 57 or the radius of the opening of the recessed portion 8. Therefore, the formation position of the recess 8 in the axial direction overlaps the formation position of the through hole 33 in the axial direction. If the depth H4 of the dent portion 8 is too deep, the flow rate of air sucked from the through-hole 33 is reduced. On the other hand, if the depth H4 of the dent portion 8 is too shallow, dust may be trapped in the dent portion 8. It is. Considering the ease of injection molding, the recess 8 is preferably hemispherical. However, the recessed portion 8 is not limited to a hemispherical shape, and may be an elliptical shape shallower or deeper than the hemispherical shape. One end of the bottom surface of the guide tube 38 is gently joined to the bottom surface of the recessed portion 8 without a step, and the other end of the bottom surface of the guide tube 38 is gently joined to the surface of the extended portion 34 without a step. The bottom surface of the guide tube 38 preferably slopes smoothly from one end of the bottom surface of the guide tube 38 to the other end of the bottom surface of the guide tube 38. Since the guide tube 38 is connected from the half of the hemispherical recess 8, the recess 8 is actually a 1/4 spherical shape except for the guide tube 38.

  Then, the air swirling outside the cylindrical portion is discharged from the outer flow path 35 (flow 62). The air that has flowed into the inside of the cylindrical portion from the through hole 33 is discharged from the inner flow path 36 while making a small turn in the space in the cylindrical portion and the space in the extended portion 34 (flow 63). The air flowing into the inside of the cylindrical portion from the through-hole 33 has a considerable energy loss as compared with the air swirling outside the cylindrical portion, but in a state where no dust is accumulated in the dust container 5 Since the flow rate of air flowing into the inside of the cylindrical portion from the hole 33 is considerably smaller than the flow rate of air swirling outside the cylindrical portion, energy loss is small as a whole.

  FIG. 17 (a) is a perspective view of the dust separator of Example 2 of the present invention as viewed from the front, and FIG. 17 (a) is the dust separator of Example 2 of the present invention as viewed from the right side. It is a side view. An arrow in FIG. 17 indicates a contact range between the axial tip portion of the cylindrical portion 57 and the outlet end portion of the inlet pipe 3. The semicircular axial tip of the cylindrical portion 57 is in contact with the outlet end of the inlet pipe 3. Due to the problem of assembly accuracy, the axial front end portion of the cylindrical portion 57 and the outlet end portion of the inlet pipe 3 may not be completely in contact with each other, and there may be a slight gap (1 mm or less). However, if there is a gap, air leaks, energy loss increases, and noise increases. Therefore, when the axial tip of the cylindrical portion 57 and the outlet end of the inlet tube 3 are hermetically sealed, packing (seal member) is provided between the axial tip of the cylindrical portion 57 and the outlet end of the inlet tube 3. ) May be interposed.

  On the other hand, as shown in the enlarged sectional view, a step is formed along the axial front end of the guide tube 38 over the entire length of the axial front end of the guide tube 38 inside the axial end surface of the outer cylinder 7. If the thickness of the axial end face of the outer cylinder 7 is D2, and the thickness of the inner peripheral side of the axial end face of the outer cylinder 7 corresponding to the axial tip of the guide tube 38 is D3, then D2> D3. Therefore, the step (D3-D2) is generated. For example, D2 is about 3 mm, and D3 is about 2 mm. Therefore, the step is about 1 mm. Therefore, the inner side of the axial end surface of the outer cylinder 7 is thinner on the inner peripheral side than the portion corresponding to the distal end portion of the guide tube 38 in the axial direction. Then, as shown in the enlarged cross-sectional view, the inner cylinder 6 and the outer cylinder 7 are combined so that the tip end portion in the axial direction of the guide tube 38 abuts on the step. Since this step has a sealing function between the inner side of the axial end surface of the outer cylinder 7 and the tip end portion of the guide tube 38 in the axial direction, this step can reduce energy loss of air or noise. The processing accuracy and assembly accuracy are poor, the electric blower 28 is operated, the inner cylinder 7 is sucked to the dust container 5 side, and the axial tip of the guide tube 38 is located on the axial end surface of the outer cylinder 6. Even in the case where it does not completely contact the inside, the step can suppress air leakage. Since the thickness of the axial tip portion of the guide tube 38 is smaller than the thickness D1 of the cylindrical tip portion 57 in the axial direction, it is difficult to form a sealing member such as a packing. Is preferably realized. The inlet pipe 3 is preferably formed integrally with the outer cylinder 6.

  On the inner peripheral surface (side wall surface) of the outer cylinder 7 and on the side close to the axial end surface (upper surface) of the outer cylinder 7 and from the outlet opening of the guide tube 38 to the inlet opening of the outer flow path 35. In the meantime, the current plate 102 (ribs, blades) is formed. The formation position of the rectifying plate 102 may be near the center between the outlet opening of the guide tube 38 and the inlet opening of the outer flow path 35, or may be closer to the outlet opening side of the guide tube 38 than the center. The rectifying plate 102 has a plate shape and is formed to extend in the circumferential direction. The length of the current plate 102 in the circumferential direction is extremely smaller than the distance from the outlet opening of the guide tube 38 to the inlet opening of the outer flow path 35. As shown in FIG. 17B, the direction in which the rectifying plate 102 is formed is the direction from the position where the rectifying plate 102 is formed toward the inlet opening of the outer flow path 35. There may be one current plate 102 or a plurality of current plates. There is a large gap between the current plate 102 and the extended portion 34, and air naturally flows through this large gap. There is also a small gap between the rectifying plate 102 and the inside of the axial end surface of the outer cylinder 7, and air flows through this large gap. Since a small gap is formed between the current plate 102 and the inner side of the axial end surface of the outer cylinder 7 to form an air flow, a flow is generated on both surfaces of the current plate 102. Generation of turbulent flow at the downstream end can be suppressed. The rectifying plate 102 can direct the swirl flow toward the inlet opening of the outer flow path 35. Therefore, the air flowing in from the guide tube 38 is guided to the outer flow path 35 without rotating in the outer cylinder 7 many times, so that energy loss of air can be reduced. Further, since it is formed not on the inner peripheral side (the outer peripheral surface of the inner cylinder 7) with a slow flow velocity but on the outer peripheral side (the inner peripheral surface of the outer cylinder 6) with a higher flow velocity, even if the shape of the rectifying plate 102 is small, the swirl flow Has the effect of turning. Since the current plate 102 can be made small, the turbulence of the air flow can be reduced, and the energy loss of the air can be reduced.

  According to the second embodiment of the present invention, the recess 8 is formed at the tip of the inner cylinder 7 to provide a turning function, whereby the axial length of the dust collector 2 can be shortened, and the cleaner body 1 Can be made compact.

  Details of the dust separator 4 and the dust container 5 of the first embodiment will be described as a third embodiment.

  In the vacuum cleaner according to the third embodiment of the present invention, the second dust collecting unit (for example, the dust container 5) is disposed at one axial end of the first dust collecting unit (for example, the dust separating unit 4). A first member having a surface along the attaching / detaching direction of the second dust collecting portion (for example, the protruding member 70) is provided, and the first dust collecting portion is the other end in the axial direction on the second dust collecting portion side. A second member having a surface facing the surface along the attaching / detaching direction of the second dust collecting portion of the first member (for example, the recessed portion 39) is provided at a position corresponding to the first member. Features. And according to this invention, when a user equips the vacuum cleaner main body 1 with a 2nd dust collection part, insertion of a 2nd dust collection part can be guided with a 1st member and a 2nd member. Therefore, it is easy for the user to attach the second dust collecting part, and the first dust collecting part and the position of the second dust collecting part with respect to the cleaner body 1 can be suppressed. The airtightness between the dust part and the second dust collection part or between the second dust collection part and the cleaner body 1 can be maintained, and the reduction in the suction work rate of the vacuum cleaner can be suppressed. Furthermore, the generation of noise due to air leakage can be suppressed.

  Alternatively, in the electric vacuum cleaner of the present invention, the second dust collector (for example, the dust container 5) is disposed at one end in the axial direction on the first dust collector (for example, the dust separator 4) side. A first member having a surface substantially perpendicular to the bottom surface of the main body 1 (for example, the protruding member 70), wherein the first dust collecting portion is a second dust collecting portion side axial second end portion; A second member (for example, a recessed portion 39) having a surface facing a substantially vertical surface of the first member is provided at a position corresponding to the first member. And according to this invention, when a user equips the vacuum cleaner main body 1 with a 2nd dust collection part, insertion of a 2nd dust collection part can be guided with a 1st member and a 2nd member. Therefore, it is easy for the user to attach the second dust collecting part, and the first dust collecting part and the position of the second dust collecting part with respect to the cleaner body 1 can be suppressed. The airtightness between the dust part and the second dust collection part or between the second dust collection part and the cleaner body 1 can be maintained, and the reduction in the suction work rate of the vacuum cleaner can be suppressed. Furthermore, the generation of noise due to air leakage can be suppressed.

  Moreover, the vacuum cleaner of the present invention includes a first dust collection unit (for example, a dust separation unit 4) and a second dust collection unit (for example, a dust storage unit 5) that are interposed in a portion that communicates with each other. A seal member (for example, packing 9), and a second seal member (for example, packing 25) interposed in a portion where the second dust collecting unit and the cleaner body 1 communicate with each other. It is characterized in that it is made of a material having a larger elastic force than that of the second seal member. And according to this invention, airtightness between the 1st dust collection part and 2nd dust collection part which are easy to separate compared with between the 2nd dust collection part and the cleaner body 1 can be maintained. The reduction in the suction work rate of the vacuum cleaner can be suppressed. Furthermore, the generation of noise due to air leakage can be suppressed.

  Moreover, the vacuum cleaner of the present invention includes a first dust collection unit (for example, a dust separation unit 4) and a second dust collection unit (for example, a dust storage unit 5) that are interposed in a portion that communicates with each other. A second dust collecting part, comprising: a sealing member (for example, packing 9); and a second sealing member (for example, packing 25) interposed in a portion where the second dust collecting part and the cleaner body 1 communicate with each other. However, the first seal member and the second seal member are supported by the cleaner body 1 to which the first dust collecting part is attached. And according to this invention, a user can remove a 2nd dust collection part from the cleaner body 1 easily, and the discharge operation of dust becomes easy. Furthermore, according to the present invention, it is possible to maintain airtightness between the first dust collecting unit and the second dust collecting unit and between the second dust collecting unit and the cleaner main body 1, and suction of the vacuum cleaner Reduction of work rate can be suppressed. Furthermore, the generation of noise due to air leakage can be suppressed.

  Moreover, the vacuum cleaner of this invention covers the wall surface part (for example, front side wall surface) of the vacuum cleaner main body 1 which opposes the axial direction one end surface of the dust collector 2 from the axial direction one end part of the dust collector 2. 2 is provided with a member (for example, a protruding member 72 and an engagement hole 82) that regulates the separation of the 2 from the main body inlet. And according to this invention, the airtightness between the vacuum cleaner main body 1 and the dust separation part 4 can be hold | maintained, and the fall of the suction work rate of a vacuum cleaner can be suppressed. Furthermore, the generation of noise due to air leakage can be suppressed.

  Moreover, the vacuum cleaner of this invention engages the wall surface part (for example, front side wall surface) of the vacuum cleaner main body 1 which opposes the axial direction one end part of the dust collector 2 and the axial direction one end surface of the dust collector 2. As shown in FIG. A member (for example, a protruding member 72 and an engagement hole 82) is provided. And according to this invention, the airtightness between the vacuum cleaner main body 1 and the dust separation part 4 can be hold | maintained, and the fall of the suction work rate of a vacuum cleaner can be suppressed. Furthermore, the generation of noise due to air leakage can be suppressed.

  FIG. 18: is the side view which looked at the cleaner body 1 of Example 3 of this invention from the right side. FIG. 19 is a perspective view of the cleaner body 1 according to the third embodiment of the present invention as viewed from the upper right side. In particular, a state is shown in which the user opens the upper cover 56 and leaves the dust separating portion 4 in the cleaner body 1 and pulls out only the dust accommodating portion 5 substantially upward. A dotted arrow indicates a pulling direction of the dust container 5. The direction of the dotted line arrow is perpendicular to the bottom surface of the cleaner body 1 or the surface (for example, the floor surface) on which the cleaner body 1 is placed (for example, 5 degrees).

  One end in the axial direction of the inlet pipe 3 formed integrally with the dust separation part 4 abuts on the packing 22, and the lower part of the other end in the axial direction of the dust separation part 4 is connected to the cleaner main body 1 by the engaging member 71 (fixing member). Is engaged and fixed. An engagement mechanism is realized by the lower portion of the other end in the axial direction of the dust separator 4 and the engagement member 71. Therefore, as long as the user does not operate the engaging member 71, the dust separation unit 4 is fixed to the cleaner body 1. On the other hand, in a state in which the dust container 5 is attached to the cleaner body 1, one axial end of the dust container 5 abuts against the other axial end of the dust separator 4 via the packing 9, and the dust container 5 The other end in the axial direction abuts against the cleaner body 1 via the packing 25, the upper surface of the dust container 5 is covered by the upper cover 56, and the other part of the dust container 5 is the dust separator 4. Or the vacuum cleaner body 1 is not in contact. That is, the dust container 5 is supported upward in a state where it floats on the dust separator 4 and the cleaner body 1 at one end and the other end in the axial direction. Therefore, if the user opens the upper cover 56 and holds the handle 16 and pulls the dust container 5 in the direction of the dotted arrow, only the dust container 5 remains with the dust separator 4 left in the cleaner body 1. It can be removed from the cleaner body 1. That is, the dust container 5 can be detached from the cleaner body 1 independently of the dust separator 4. Therefore, it is easy for the user to remove the dust container 5. Since most of the dust is accumulated and compressed in the dust container 5, the user removes the dust collector 2 from the cleaner body 1 and further separates the dust separator 4 and the dust container 5 to store the dust. Even if the three-stage operation of discharging the dust in the unit 5 is not performed, only the dust container 5 is removed from the cleaner body 1 while the dust separator 4 is left in the cleaner body 1, and the dust container 5 Therefore, it is easy for the user to discharge the dust. In addition, since the handle 16 is gently inclined from the rear end to the front side of the dust container 5, the user can pull out the dust container 5 in the vertical direction or slightly in the front direction from the vertical direction. Furthermore, since the dust container 5 is supported by the dust separator 4 and the cleaner body 1 only by the packing 9 and the packing 25 and the other parts of the dust container 5 are lifted from the cleaner body 1, When the air blower 28 is activated to generate a suction force, the dust storage portion 5 can be displaced by the suction force in a direction in which the packing 9 and the packing 25 are pressed against the dust separation portion 4 side and the rear wall surface side of the cleaner body 1. The airtightness between the dust separator 4 and the dust container 5 and the airtightness between the dust container 5 and the cleaner body 1 can be maintained.

  In the vicinity of the axial center of one end of the dust container 5 in the axial direction, a protruding member 70 for guiding or assisting the attachment / detachment of the dust container 5 is formed. The protruding member 70 is formed so as to protrude in the axial direction from one axial end surface of the dust container 5. The protruding member 70 is preferably made of the same material as the front lid 11 and formed integrally with the front lid 11, but may not be formed integrally. The front end surface of the projecting member 70 has a substantially front direction (for example, 0 to 5 degrees) with respect to a substantially pulling direction, that is, a substantially vertical direction or a vertical direction with respect to the bottom surface of the cleaner body 1 or the surface on which the cleaner body 1 is placed. At a predetermined angle within a range of A guide mechanism is realized by the protruding member 70 and the recessed portion 39 of the dust separating portion 4. In particular, when the user attaches the dust container 5 to the vacuum cleaner body 1, the user first holds the handle 16 of the dust container 5, and the front end surface of the protruding member 70 is located on the front side of the recess 39 of the dust separator 4. When it comes into contact with the wall surface, and then the dust container 5 is pushed in and cannot be pushed in with a normal force, the dust container 5 can be attached to the cleaner body 1 by closing the upper cover 56. Therefore, it is easy for the user to install the dust container 5. Even when the dust container 5 is not pushed to a predetermined position, the inner shape of the upper cover 56 (the shape of the surface in contact with the dust container 5) may be formed so that the upper cover 56 does not close. Good.

  FIG. 20 is a side view of the cleaner body 1 according to the third embodiment of the present invention as viewed from the right side. FIG. 21: is the perspective view which looked at the cleaner body 1 of Example 3 of this invention from the upper right side. In particular, after the dust container 5 is removed from the cleaner body 1, the dust separator 4 is pulled out substantially upward. The dotted line arrow indicates the pulling direction of the dust separator 4. The direction of the dotted line arrow is substantially perpendicular to the bottom surface of the cleaner body 1 or the surface on which the cleaner body 1 is placed.

  The engaging member 71 has a plate shape, and the rear side thereof is supported by the cleaner body 1 by a shaft. Further, a spring is attached around the shaft or on the engagement member 71 itself so as to urge the front side of the engagement member 71 toward the cleaner body 1 side. When the dust separation part 4 is mounted, the lower part of the other end in the axial direction of the dust separation part 4 engages with the front side of the engaging member 71 and is fixed so that the dust separation part 4 is not detached by the biasing force of the spring. The In the dust separator 4, the bottom surface of the dust separator 4 may be supported by the cleaner body 1 other than the lower part of the other end in the axial direction of the inlet pipe 3 and the dust separator 4.

  Then, the user releases the engagement by the engagement member 71 against the biasing force of the spring with one hand, and holds the inside or the outside of the recessed portion 39 with the other hand, and the dust separation unit 4. Can be removed from the cleaner body 1 by pulling in the direction of the dotted arrow. Therefore, the user can easily remove the dust separator 4 from the cleaner body 1. When attaching the dust separator 4 to the vacuum cleaner main body 1, the user first holds the inner side or the outer side of the recess 39 and abuts one end of the inlet pipe 3 against the packing 22, and then removes the dust separator 4. By pushing, the front side of the engaging member 71 gets over the lower part of one end in the axial direction of the dust separating portion 4 to achieve engagement, and the dust separating portion 4 can be attached to the cleaner body 1. Therefore, the user can easily attach the dust separator 4 to the cleaner body 1. The other axial end surface of the dust container 5 is formed on the rear side wall surface (the front wall surface of the electric blower 28) of the cleaner body 1 facing the other axial end of the dust container 5 over almost the front surface. When viewed from the front side of the cleaner body 1, the inlet opening (auxiliary filter 26) of the intake duct 27 is formed toward the left side. The rear side wall surface of the cleaner body 1 is formed in a substantially vertical direction with respect to the bottom surface of the cleaner body 1 or the surface on which the cleaner body 1 is placed.

  Further, above the inlet pipe 3 outside the one end surface in the axial direction of the dust separator 4, a protruding member 72 (engagement member) for hooking the tip end in the axial direction of the dust separator 4 on the inner wall on the front side of the cleaner body 1. Joint member) is formed. When the electric blower 28 is actuated, a suction force is generated, and the dust storage portion 5 tends to be displaced rearward by the suction force, and the dust separation portion 4 is also moved in the axial direction of the dust collector 2 by the suction force. As a result, the dust separation unit 4 is lifted from the cleaner body 1. That is, since the other axial end of the dust separator 4 is engaged with the engaging member 71, the displacement of the other axial end of the dust separator 4 is restricted. On the other hand, since the displacement of the one end in the axial direction of the dust separator 4 is not restricted just by the one end in the axial direction of the inlet pipe 3 being in contact with the packing 22, it is displaced or separated from the packing 22, and airtightness can be maintained. Therefore, the suction force is reduced and noise is generated. Therefore, the protruding member 72 prevents the one end in the axial direction of the inlet pipe 3 from being displaced or separated from the packing 22 and suppresses a reduction in suction force and generation of noise.

  FIG. 22 is a side view of the dust collector 2 according to the third embodiment of the present invention viewed from the right side. In particular, a state in which the dust separator 4 and the dust container 5 are separated is shown.

  A filter 15 is provided at the other axial end of the dust container 5. In the filter 15, a filter member 79 is formed in a frame body 78 having a substantially rectangular cross section. A substantially rectangular packing 25 is formed over the entire circumference of the filter 15. Therefore, the packing 25 can rotate with respect to the case 10 together with the filter 15. The packing 25 is preferably fold-folded so as to expand and contract in the front-rear direction. When viewed from the side as shown in FIG. 22, the packing 25 is disposed closer to the case 10 than the filter 15. That is, the filter 15 protrudes outside the packing 25 (on the electric blower 28 side). The formation direction of the rear end surface of the filter 15 when viewed from the side as shown in FIG. 22 is substantially perpendicular to the bottom surface of the cleaner body 1 or the surface on which the cleaner body 1 is placed. The direction along the rear side wall surface (for example, parallel). On the other hand, the formation direction of the rear end surface of the packing 25 when viewed from the side as shown in FIG. 22 is inclined by an angle b with respect to a normal to the bottom surface of the cleaner body 1 or the surface on which the cleaner body 1 is placed. . In other words, the formation direction of the rear end surface of the packing 25 is inclined at an angle b with respect to the pulling direction of the dust container 5. Therefore, the rear end surface of the packing 25 is also inclined by the angle b with respect to the rear end surface of the filter 15. The position of the lower end of the rear end surface of the packing 25 is on the front side (case 10 side) with respect to the position of the upper end of the rear end surface of the packing 25. When viewed from the side as shown in FIG. 22, the position of the upper end of the rear end surface of the packing 25 substantially coincides with the position of the upper end of the rear end surface of the filter 15. 15 is in front of the lower end position of the rear end face. For example, the angle b is a predetermined angle within a range of 5 degrees to 10 degrees. The rear wall surface of the cleaner body 1 is formed on the front side of the wall surface facing the packing 25 rather than the wall surface facing the filter 15. Further, it is preferable that the position of the wall surface facing the packing 25 with respect to the position of the wall surface facing the filter 15 of the cleaner body 1 is on the front side relative to the position of the packing 25 with respect to the position of the filter 15. Accordingly, when the user pushes in the dust container 5, the packing 25 comes into contact with the cleaner body 1 before the filter 15 comes into contact with the cleaner body 1.

  The packing 25 interposed between the dust container 5 and the cleaner body 1 is made of a material having a lower viscosity than the packing 9 interposed between the dust separator 4 and the dust container 5. Is preferred. This is because the direction in which the packing 25 is formed is substantially perpendicular to the direction in which the dust container 5 is pulled, that is, the bottom surface of the cleaner body 1 or the surface on which the cleaner body 1 is placed. Therefore, when the dust container 5 is attached to or detached from the cleaner body 1, it receives a large shearing force. If the viscosity of the packing 25 is high, the packing 25 gets stuck to the packing receiving surface 80 when attaching / detaching the dust container 5 to / from the cleaner body 1, and a large force is required for attaching / detaching. Accordingly, by making the viscosity of the packing 25 lower than that of the packing 9, the dust container 5 can be easily attached and detached from the cleaner body 1. In order to lower the viscosity of the packing 25 than the packing 9, the packing 25 is made of a material having a smaller elastic force than the packing 9. In other words, the packing 9 is made of a material having a larger elastic force than the packing 25. The dust separator 4 is in a state of being substantially fixed to the cleaner body 1, whereas the dust container 5 is in a state of floating from the cleaner body 1, and further, the position of the packing 9 is higher than the position of the packing 25. Since this is far from the electric blower 28 on the flow path, the dust separation part 4 and the dust container 5 are more easily separated from each other than the dust container 5 and the cleaner body 1. By allowing the elastic force of the packing 9 to be larger than that of the packing 25 and allowing the dust separating unit 4 and the dust container 5 to be separated by elastic deformation of the packing 9, Another effect that airtightness with the dust container 5 can be maintained is also obtained.

  The formation direction of the front end surface of the protrusion member 70 when viewed from the side as shown in FIG. 22 is inclined at an angle c with respect to the normal to the bottom surface of the cleaner body 1 or the surface on which the cleaner body 1 is placed. It is also inclined substantially at angle c with respect to the pulling direction of the dust container 5. The position of the lower end of the front end surface of the projection member 70 is on the rear side (case 10 side) with respect to the position of the upper end of the front end surface of the projection member 70. For example, the angle c is a predetermined angle within a range of 0 to 5 degrees. Therefore, the relationship of angle c ≦ angle b is established. When the angle b is increased, the angle c may be decreased. Conversely, when the angle b is decreased, the angle c may be increased. For example, if the angle b is 10 degrees, the angle c may be zero. That is, as long as the rear end surface of the packing 25 is sufficiently inclined, the front end surface of the protruding member 70 may not be inclined. The angle b may be 5 degrees, and the angle c may be 5 degrees. The front end surface of the protruding member 70 faces the front side wall surface of the recessed portion 39, but the front wall surface of the recessed portion 39 that receives the front end surface of the protruding member 70 is formed in the direction of the bottom surface of the cleaner body 1 or the cleaner. It may be substantially perpendicular to the surface on which the main body 1 is placed. In this way, by making the front end surface of the projecting member 70 and the rear end surface of the packing 25 into an inverted “C” shape, the user can easily attach and detach the dust container 5 to and from the cleaner body 1. In particular, the contact area is large with respect to the formation angle c of the protruding member 70, and the formation angle b of the highly viscous packing 25 is increased, whereby the dust container 5 can be easily attached and detached.

  Further, the lower portion of the frame body 78 of the filter 15 has a convex portion 73 protruding from the rear end surface of the filter 15. The convex portion 73 projects in a direction substantially perpendicular to the rear end surface of the filter 15. On the other hand, a recess 81 is formed in a lower part of the rear wall surface of the cleaner body 1 at a position facing the frame 78 of the filter 15, that is, at a position facing the protrusion 73 of the filter 15 (see FIG. 26). The convex portion 73 and the concave portion 81 have corresponding shapes. Therefore, the recess 81 is recessed in a direction substantially perpendicular to the rear side wall surface of the cleaner body 1. And by this convex part 73 and the recessed part 81, when the dust accommodating part 5 is mounted | worn with the cleaner body 1, the direction perpendicular | vertical with respect to the bottom face of the cleaner body 1 or the surface where the cleaner body 1 was placed A mechanism for restricting the displacement of the dust container 5 is realized. And when attaching the dust accommodating part 5 to the cleaner main body 1, before the convex part 73 of the filter 15 is fitted by the recessed part 81 of the wall surface of the cleaner main body 1, the lower end of the front end surface of the protrusion member 70 is dented. It is preferable to determine the position of the protruding member 70 and the length of the front end surface so as to contact the front side wall surface of the portion 39. Thus, when the user attaches the dust container 5 to the cleaner body 1, first, the projection member 70 is brought into contact with the recess 39, and then the dust container 5 is pushed in, so that the protrusion 73 of the filter 15 is formed. The dust container 5 is fitted into the recess 81 on the wall surface of the cleaner body 1, and the dust container 5 is attached to the cleaner body 1. Therefore, it is possible for the user to smoothly attach the dust container 5 to the cleaner body 1 and to obtain a feeling that the dust container 5 can be attached to the cleaner body 1. Further, by having the convex portion 73 of the filter 15 and the concave portion 81 of the wall surface of the cleaner body 1, the bottom surface of the cleaner body 1 or the cleaner body 1 when the dust container 5 is attached to the cleaner body 1. The dust container 5 can be prevented from being displaced in a direction perpendicular to the surface on which the dust is placed, and the dust container 5, the dust separator 4 and the vacuum cleaner body 1 can be kept airtight.

  Furthermore, the direction of formation of the inlet opening of the inlet pipe 3 when viewed from the side as shown in FIG. 22 is inclined at an angle d with respect to the normal to the bottom surface of the cleaner body 1 or the surface on which the cleaner body 1 is placed. Yes. It is also inclined substantially at an angle d with respect to the pulling direction of the dust separator 4. The position of the lower end of the inlet opening of the inlet pipe 3 is on the rear side (dust separation unit 4 side) with respect to the position of the upper end of the inlet opening of the inlet pipe 3. For example, the angle d is a predetermined angle within a range of 5 degrees to 10 degrees. Since the inlet opening which is the front end of the inlet pipe 3 formed integrally with the dust separator 4 is inclined at an angle d, the dust separator 4 can be easily attached to and detached from the cleaner body 1.

  FIG. 23 is a cross-sectional view of the dust collector 2 according to the third embodiment of the present invention as viewed from the right side. In particular, a state in which the dust separator 4 and the dust container 5 are in contact with each other is shown. The axis of the dust collector 2 is the axis of the inlet pipe 3, the axis of the outer cylinder 6, the axis of the inner cylinder 7, and the axis of the front lid 11. With respect to the direction in which the shaft is formed (axial direction), one end surface in the axial direction and the other end surface in the axial direction of the dust separator 4, one end surface in the axial direction and the other end surface in the axial direction of the front lid 11, , Formed substantially vertically.

  The axis of the dust collector 2 is inclined at an angle a with respect to a normal to the bottom surface of the cleaner body 1 or the surface on which the cleaner body 1 is placed. For example, the angle a is a predetermined angle within a range of 40 degrees to 45 degrees. However, the angle a may be smaller than 40 degrees. Therefore, the one end surface in the axial direction and the other end surface in the axial direction of the dust separator 4, the one end surface in the axial direction and the other end surface in the axial direction of the front lid 11, and the one end surface of the dust container 5 are the bottom surface of the cleaner body 1 or the cleaner body. The angle 1 is inclined with respect to the surface on which 1 is placed.

  When viewed from the side as shown in FIG. 23, the recess 39 is, from the front, the front wall surface substantially perpendicular to the bottom surface of the cleaner body 1 or the surface on which the cleaner body 1 is placed, and the axial direction of the dust separator 4. The bottom surface is substantially parallel to the other end surface, and the rear side wall surface is substantially perpendicular to the other axial end surface of the dust separator 4. When the dust container 5 is mounted, the front end surface of the projection member 70 comes into contact with the front side wall surface of the recess 39. The front end surface of the projection member 70 faces the front side wall surface of the recess 39, but the front end surface of the projection member 70 is inclined at an angle c with respect to the bottom surface of the cleaner body 1 or the surface on which the cleaner body 1 is placed. Therefore, the angle c is also inclined with respect to the front side wall surface of the recess 39. While the electric blower 28 is stopped, the front end surface of the projecting member 70 and the front side wall surface of the recessed portion 39 may be in contact with each other, or some gap may be provided without contact. When the electric blower 28 is actuated and the dust separator 4 is drawn to the dust container 5, the front side wall surface of the recess 39 abuts the front end surface of the protruding member 70, and the dust separator 4 is displaced to the dust container 5. It is preferable to prevent the packing 9 from being crushed. Instead of forming the protruding member 70 on the front lid 11 and forming the recessed portion 39 on the inner cylinder 7, the recessed portion 39 may be formed on the front lid 11 and the protruding member 70 may be formed on the inner cylinder 7. .

  FIG. 24 is a front view of the dust container 5 according to the third embodiment of the present invention as viewed from the front side. On the upper left side of the front lid 11, a transparent or translucent window 74 is formed through which the accumulated amount of compressed dust can be visually observed. A garbage disposal line is drawn on the window 74, so that the user can be notified of the timing of garbage disposal. A lower part on the back side of the outer extension part 34 is located at a position corresponding to a screw boss (protrusion on which the screw 67 is formed) projecting on the lower side on the lower side of the front end 11 in the axial direction (front face), particularly on the back side of the extension part 34. A boss receiver 75 for receiving a screw boss (projection on which the screw 67 is formed) projecting over is formed. When the dust separator 4 and the dust container 5 come into contact with each other, the screw bosses of the outer extension 34 are inserted into the boss receiver 75 of the front lid 11 so that the dust separator 4 and the dust container 5 are relative to each other. It is possible to regulate the displacement. A regulating mechanism is realized by the screw boss of the outer extension 34 and the boss receiver 75 of the front lid 11.

  A packing receiving surface 76 for receiving the lip 68 on the back side of the extended portion 34 is formed at the outermost peripheral portion of one end surface in the axial direction of the front lid 11, that is, on the position corresponding to the lip 68 on the back side of the extended portion 34. The packing receiving surface 76 preferably includes an annular portion that is wider than at least the lip 68, and the annular portion is preferably formed as a flat surface so that the lip 68 can be easily received. A packing receiving surface 77 for receiving the lip 69 on the back side of the extended portion 34 is formed at a position corresponding to the inner peripheral side of the one end surface in the axial direction of the front lid 11, that is, on the back side of the extended portion 34. The packing receiving surface 77 also includes an annular portion wider than at least the lip 69, and the annular portion is formed as a flat surface so that the lip 69 can be easily received. An outer seal mechanism (seal member) is realized by the lip 68 and the packing receiving surface 76, and an inner seal mechanism (seal member) is realized by the lip 69 and the packing receiving surface 77. The projecting member 70 is formed further on the inner peripheral side of the packing receiving surface 77. This is to correspond to the position of the recessed portion 39 formed on the inner peripheral side of the inner cylinder 7 on the back side of the outer extending portion 34. Further, the protruding member 70 includes two protruding members 70 arranged in parallel in the left-right direction. By providing a width in the left-right direction in this way, stability is increased when the front end surface of the projecting member 70 comes into contact with the front side wall surface of the recessed portion 39. However, the protruding member 70 may be configured by one protruding member 70. Further, it may be formed on the outer periphery of the packing receiving portion 77 and on the inner periphery of the packing receiving portion 76.

  FIG. 25 is a perspective view of the dust container 5 according to the third embodiment of the present invention as viewed from the left rear side. FIG. 26: is the front view which looked at the dust accommodating part 5 of Example 3 of this invention from the front side of the rear side wall surface (front wall surface of an electric blower) of the cleaner body 1 facing the other axial end. In the filter 15, a filter member 79 is formed in a frame body 78 having a substantially rectangular cross section. The convex portions 73 are formed at two places on the left and right sides of the lower portion of the frame body 78 of the filter 15. The recesses 81 are formed at two locations on the left and right sides of the lower portion of the rear wall surface of the cleaner body 1 (the front wall surface of the electric blower 28) facing the frame body 78 of the filter 15. In addition, the convex part 73 is formed in the filter 15, and the recessed part 81 is formed in the filter 15 instead of forming the recessed part 81 in the rear side wall surface of the cleaner body 1, and the convex part is formed in the rear side wall surface of the cleaner body 1. 73 may be formed.

  In FIG. 26, the auxiliary filter 26 (the inlet opening of the intake duct 27) is formed on the left side of the rear side wall surface of the cleaner body 1. On the upper side of the rear side wall surface of the cleaner body 1, a housing portion 82 that houses the dust removing device 24 is formed. A packing receiving surface 80 for receiving the packing 25 is formed at the outermost peripheral portion of the rear side wall surface of the cleaner body 1, that is, at a position corresponding to the packing 25. The packing receiving surface 80 preferably includes at least a substantially rectangular portion wider than the packing 25, and the substantially rectangular portion is preferably formed as a flat surface so that the packing 25 can be easily received. The packing receiving surface 80 is formed to protrude to the front side of the cleaner body 1 from the surface on which the auxiliary filter 26 and the accommodating portion 82 are formed. The formation direction of the packing receiving surface 80 when viewed from the side is an angle with respect to the perpendicular to the bottom surface of the cleaner body 1 or the surface on which the cleaner body 1 is placed so as to follow the formation direction of the rear end surface of the packing 25. b Inclined. Therefore, the packing receiving surface 80 is also inclined at an angle b with respect to the surface on which the auxiliary filter 26 and the accommodating portion 82 are formed. The position of the lower end of the packing receiving surface 80 is on the front side (the dust container 5 side) with respect to the position of the upper end of the packing receiving surface 80. A seal mechanism (seal member) is realized by the packing 25 and the packing receiving surface 80.

  FIG. 27 is a front view of the dust separator 4 according to the third embodiment of the present invention when viewed from the front side. The protruding member 72 is formed above the inlet pipe 3 outside the one end surface in the axial direction of the dust separating portion 4. In the left-right direction, the protruding member 72 is formed at the center of the dust separation unit 4. The protruding member 72 is formed with a width in the left-right direction. However, the projecting member 72 may be configured by a plurality of projecting members 72 arranged in parallel in the left-right direction. In addition, the dotted line in FIG. 27 shows the level | step difference formed in the inner surface of the outer cylinder 6. FIG.

  FIG. 28 is a side view of the dust separator 4 and a cross-sectional view of the front side of the cleaner body 1 according to the third embodiment of the present invention. The projecting member 72 formed on the dust separating portion 4 extends in the axial direction of the dust separating portion 4, that is, extends toward the front side wall surface of the cleaner body 1, and has a convex portion at the tip thereof. That is, the protruding member 72 has a claw shape or an L shape. On the other hand, an engagement hole 82 for receiving the protruding member 72 is formed at a position corresponding to the protruding member 72 on the front side wall surface of the cleaner body 1. An engagement mechanism (engagement member 71) or a mechanism that restricts separation is realized by the protruding member 72 and the engagement hole 82. When the user attaches the dust separator 4 to the cleaner body 1, the user first inserts the protruding member 72 into the engagement hole 82, and then attaches the inlet opening end of the inlet pipe 3 to the cleaner body 1. Then, the lower part of the other end in the axial direction of the dust separator 4 may be pressed against the engaging member 71 after coming into contact with the packing 22. When the electric blower 28 is activated, a suction force is generated, and the dust separating portion 4 tries to float up from the cleaner body 1, but the convex portion at the tip of the protruding member 72 abuts against the inner wall surface of the engagement hole 82. This prevents the one end in the axial direction of the dust separator 4 from shifting or separating from the front wall surface of the cleaner body 1. Therefore, it is possible to prevent the axial end of the inlet pipe 3 from being displaced from or separated from the packing 22, thereby suppressing a reduction in suction force and noise.

  Instead of forming the projection member 72 on the dust separator 4 and forming the engagement hole 82 on the front side wall surface of the cleaner body 1, the projection member 72 is formed on the front side wall surface of the cleaner body 1. The engagement hole 82 may be formed. The projecting member 72 may be formed on the axially one end surface of the dust separating portion 4 on the side close to the upper end or on the lower side of the inlet pipe 3. Further, instead of the projecting member 72, a pressing member for pressing the upper end surface of the tip end in the axial direction of the dust separator 4 may be formed on the front side of the cleaner body 1, or for pressing the upper end surface of the inlet pipe 3. The pressing member may be formed on the front side of the cleaner body 1.

  Details of the dust container 5 of the first embodiment will be described as a fourth embodiment.

  In the vacuum cleaner of Example 4 of the present invention, the angle formed between the opening surface of the ventilation member and the horizontal direction from the first state in which the ventilation member (for example, the dust collecting basket 12) is included in the ventilation member or the case ( For example, it is possible to rotate in the forward direction of the case until reaching a second state in which the angle e−the angle f) is a predetermined angle within 45 degrees. Alternatively, according to the present invention, the angle (for example, the angle e) formed between the opening surface of the ventilation member and the handle forming direction from the first state in which the ventilation member (for example, the dust collecting basket 12) is enclosed in the ventilation member or the case. It is characterized in that it can be rotated in the forward direction of the case until it reaches a second state in which the angle f−the angle h) becomes a predetermined angle within 45 degrees. According to the present invention, the ventilation member can be rotated in the forward direction of the case until reaching a second state in which the angle between the opening surface of the ventilation member and the horizontal direction is a predetermined angle within 45 degrees. Or the ventilation member can be rotated in the forward direction of the case until the second state where the angle formed by the opening surface of the ventilation member and the direction in which the handle is formed is a predetermined angle within 45 degrees. As a result, the user can easily discharge the dust accumulated in the ventilation member.

  Or the vacuum cleaner of Example 4 of this invention looked at the dust collection part (for example, dust storage part 5) from the side, the attachment member for attaching a ventilation member (for example, the dust collection basket 12) to a case. In some cases, the dust collector is fixed in the case so as to be inclined with respect to the direction in which the rear end face of the dust collecting part is formed or to the perpendicular to the bottom face of the cleaner body. And according to the present invention, the attachment member for attaching the ventilation member to the case is in a direction perpendicular to the direction of formation of the rear end face of the dust collector or the bottom surface of the cleaner body when the dust collector is viewed from the side. By forming it incline, the strength of the mechanism for attaching the dust collecting part to the case can be improved or the case can be prevented from bending without increasing the longitudinal direction of the dust collecting part.

  FIG. 29: is the front view which looked at the dust accommodating part of Example 4 of this invention from the axial direction front end side. In particular, a state in which the front lid 11 is removed is shown. 6 is the same as FIG. 6, but FIG. 29 shows the air flow 62 in the dust collection basket 12 and the accumulation state of the dust 83 in the dust collection basket 12.

  As shown in FIG. 26, the inlet opening of the intake duct 27 is formed closer to the left side in the left-right direction of the cleaner body 1. 5B, the outlet opening of the outer flow path 35 is formed above the vertical center line of the front lid 11, and has a symmetrical shape in the left-right direction. Also, as shown in FIG. 10, the air flow 62 swirling on the outer peripheral side of the inner cylinder 7 flows into the outer flow path 35 in the circumferential direction (turning direction) and is turned in the axial direction by the downstream side wall surface 65. However, even if it is turned in the axial direction by the downstream side wall surface 65, since the circumferential component (swirl direction) remains in the air flow 62, the air flow 62 is separated from the dust in the outer flow path 35. The other end portion in the axial direction of the portion 4 (intermediate portion of the outer flow path 35) and the one end portion in the axial direction of the front lid 11 (intermediate portion of the outer flow path 35) also face in the axial direction and the circumferential direction. The other end portion in the direction (the exit portion of the outer flow path 35) also faces the axial direction and the circumferential direction. That is, as shown in FIG. 29, the air flow 62 is directed not only in the axial direction but also in the circumferential direction in the counterclockwise direction at the inlet opening in the dust collecting basket 12. Therefore, the air flow 62 in the dust collection basket 12 is not only directly sucked into the filter 15 but also collides with the left wall surface of the dust collection basket 12 facing leftward in the circumferential direction. Collides with the bottom. The flow 62 colliding with the bottom surface of the dust collecting basket 12 further collides with the right side wall surface of the dust collecting basket 12 and swivels toward the inlet opening of the dust collecting basket 12, that is, the other axial end surface of the front lid 11. The first flow 62 that has flowed into the dust basket 12 will join. Therefore, the air that has flowed into the dust collecting basket 12 flows in the order of the front, left, back, right, and front in the dust collecting basket 12 (when the dust container 5 is viewed from the top, the clockwise direction Swirl) occurs. In particular, when a mesh member is formed on the dust collecting basket 12, the collision or turning of the air flow 62 becomes significant. However, since the bottom surface of the dust collecting basket 12 and the upper, lower, left and right side wall surfaces are opened so as to allow ventilation, a flow from the bottom surface of the dust collecting cage 12 and the upper, lower, left and right side wall surfaces to the outside of the dust collecting cage 12 also occurs. At this time, the upper right portion of the dust collecting basket 12 formed by the bottom surface, the upper wall surface, and the right wall surface of the dust collecting basket 12 has a strong swirl force of the flow 62, so that the dust contained in the air is separated by the swirling flow. Due to the action, it is blown to the outer peripheral side of the swirling flow and accumulates in the upper right part of the dust collecting basket 12. That is, the dust gradually accumulates from the upper right part of the dust collecting basket 12. Therefore, even though the inlet opening of the intake duct 27 is located on the left side, the dust 83 accumulates from the right side. Therefore, even if the dust 83 accumulates in the dust collecting basket 12, the swirl flow is generated. Since the portion corresponding to the inlet opening of the intake duct 2 is not easily blocked by the dust 83, the generation of air energy loss due to the accumulation of the dust 83 is suppressed, and the suction force associated with the accumulation of the dust 83 is suppressed. Can be suppressed. Even when the dust 83 accumulates from the upper right part of the dust collecting basket 12, the dust collecting basket 12 flows from the bottom surface of the dust collecting basket 12 and the side walls of the upper, lower, left and right sides to the outside of the dust collecting basket 12. Some dust will also adhere to the bottom surface and the top, bottom, left and right side wall surfaces.

  FIG. 30 is a cross-sectional view of the dust container of Example 4 of the present invention as viewed from the side. In particular, a state in which the front lid 11 is closed with respect to the case 10 is shown. The outer flow path 35 suddenly expands at a position in the front lid 11 past one axial end surface of the front lid 11. Furthermore, it expands abruptly even at a position in the dust collecting basket 12 past the other axial end surface (outlet opening of the outer flow path 35) of the front lid 11 of the outer flow path 35. Therefore, the air flow 62 suddenly slows and diffuses at a position in the front lid 11 past the one axial end surface of the front lid 11 and further passes the other axial end surface (exit opening) of the front lid 11. Even in the dust collecting basket 12, it suddenly becomes slow and diffuses.

  Further, the upper end and the lower end of the bottom portion 84 of the dust collecting basket are asymmetric. Specifically, the upper end of the bottom portion 84 of the dust collection basket, that is, the joint portion between the bottom surface of the dust collection basket 13 and the upper wall surface is the bottom end of the bottom portion 84 of the dust collection basket, that is, the bottom surface of the dust collection basket 13 and the lower wall surface. Compared to the joint portion, the radius of curvature is increased, so that it is gently formed. Since the axial direction of the dust collecting basket 12 is inclined at an angle a with respect to the axial direction of the filter 15, the lower end of the bottom 84 of the dust collecting basket is closest to the filter 15 in the dust collecting basket 13. On a straight line (line segment) connecting the vertical center point of the opening of the outer flow path 35 on the axial end surface of the front lid 11 and the vertical center point of the axial end surface (entrance surface) of the filter 15. In addition, the lower end of the bottom portion 84 of the dust collecting basket is substantially located. Then, the air flow 62 flowing into the dust collecting basket 12 is directed to the filter 15, but diffuses at a position where it exits the outlet opening of the outer flow path 35, and a part thereof is the upper wall surface of the dust collecting basket 12. And the other part collides with the bottom 84 of the dust collecting car 12 and swivels along the lower wall surface of the dust collecting car 12 toward the entrance opening of the dust collecting car 12. . Since the upper wall surface of the dust collecting basket 12 is formed along the direction of the flow 62 toward the filter 15, it easily flows toward the bottom 84 of the dust collecting basket, while the lower wall surface of the dust collecting basket 12 is Since it is formed facing the direction of the flow 62 toward the filter 15, the flow is likely to stop. The upper wall surface of the dust collecting basket 12 is located upstream of the lower wall surface of the dust collecting basket 12 and has a strong turning force. Therefore, the dust 83 is accumulated from the upper end of the bottom 84 of the dust collecting basket 12. Go. A protruding member 87 is provided outside the upper end of the bottom portion 84 of the dust collecting basket to restrict the dust collecting basket 12 from jumping to the front side of the case 10. The protruding member 87 is preferably formed so as to extend in the radial direction of a circle centering on the shaft 14 that is the pivot point of the dust collecting basket 12. Alternatively, the protruding member 87 preferably has a surface along its radial direction.

  The enlarged view of FIG. 30 shows a structure for supporting the dust collecting basket 12 to the case 10. FIG. 31 is a rear view of the dust container 5 according to the fourth embodiment of the present invention as viewed from the rear side. In particular, a state in which the filter 15 is opened with respect to the case 10 is shown. As shown in the enlarged view of FIG. 30, the dust collecting basket 12 is attached to the inside of the case 10 by an attachment member 85. Thereby, it can suppress that the external appearance of case 10 is impaired. As shown in FIG. 31, the attachment member 85 has a substantially square shape, and has a certain width in the front-rear direction and the left-right direction. Protrusions 86 are formed at both ends of the mounting member 85 in the left-right direction. The mounting member 85 is fixed to the case 10 by fitting the protruding portion 86 into a part of the case 10 (a portion formed extending obliquely from the lower surface of the case 10 into the case 10). The shaft 14 is supported on the front side of the mounting member 85. The shaft 14 may be provided with a helical spring in which an elastic force acts in a direction in which the dust collecting basket 12 is pushed out to the front lid 11 side. When the dust collection basket 12 jumps out to the front side, the mounting member 85 remains on the case 10 side, and only the dust collection basket 12 is displaced forward with the shaft 14 as a fulcrum. Here, the attachment member 85 is perpendicular to the bottom surface of the cleaner body 1 or the surface on which the cleaner body 1 is placed and to the bottom surface of the cleaner body 1 or the surface on which the cleaner body 1 is placed. It forms in the diagonal direction with respect to the direction or the formation direction of the axial direction other end surface of the dust container 5 or the case 10. The attachment member 85 may be formed in a direction substantially perpendicular to the formation direction of the one end surface in the axial direction of the dust container 5 or the case 10. The dust container 5 and the case 19 have a substantially inverted triangular shape or a substantially fan shape when viewed from the side, that is, the lower side is shorter than the upper side. In such a dust container 5, when the mounting member is formed in the horizontal direction as in Patent Document 3, the lower side of the dust container 5 becomes long, and the axial length of the dust collector 2 becomes long. The length of the vacuum cleaner body 1 in the front-rear direction is also increased. If the mounting member 85 itself is shortened, the strength for fixing the mounting member 85 to the case 10 is insufficient. In particular, when a helical spring is formed on the shaft 14, the elastic force of the helical spring reacts with the attachment member 85, so that the attachment member 85 is easily bent or damaged. Even when the dust-collecting basket 12 is protruded, the load of the dust-collecting basket 12 is applied to the mounting member 85, so that it is easily bent or damaged. Therefore, in order to lengthen the attachment member 85 (1/2 or more of the axial length of the dust collecting basket 12) and shorten the lower side of the dust container 5, the attachment member 85 is attached to the bottom surface of the cleaner body 1 or The direction parallel to the surface on which the cleaner body 1 is placed and the direction perpendicular to the bottom surface of the cleaner body 1 or the surface on which the cleaner body 1 is placed, or the axis of the dust container 5 or the case 10 It forms in the diagonal direction with respect to the formation direction of a direction other end surface. In FIG. 31, the user can remove the dust collecting basket 12 together with the mounting member 85 from the case 10 by pressing a portion of the mounting member 85 that is indicated as “push”.

  FIG. 32 is a cross-sectional view of the dust container of Example 4 of the present invention as viewed from the side. In particular, a state in which the front lid 11 is opened with respect to the case 10 and the dust collecting basket 12 has protruded forward in the case 10 is shown. As shown in FIG. 23, the axis is inclined at an angle a with respect to the vertical direction, and the forming direction of the axial one end face and the axial other end face of the front lid 11 and the forming direction of the axial one end face of the case 10 are It is substantially perpendicular to the axial direction. Therefore, the forming direction of the one end face in the axial direction and the other end face in the axial direction of the front lid 11 and the forming direction of the one end face in the axial direction of the case 10 are inclined approximately (180-a) degrees with respect to the vertical direction (gravity acting direction). It is inclined substantially at angle a with respect to the horizontal direction (direction perpendicular to the direction of gravity action). Therefore, the forming direction of the one axial end surface of the case 10 is inclined by the angle e with respect to the horizontal direction, and this angle e is substantially equal to the angle a. Therefore, for example, the angle e is also a predetermined angle within a range of 40 degrees to 45 degrees, similarly to the angle a. The front lid 11 rotates from the front to the bottom with the shaft 31 as a fulcrum with respect to the case 10, but as shown in FIG. 32, the formation direction of the one end surface in the axial direction and the other end surface in the axial direction of the front lid 11 is at least approximately. Opening is possible until the vertical direction is reached. The front lid 11 can be opened at least at an angle (e + 90) degrees with respect to the forming direction of the one axial end surface of the case 10. The front lid 11 preferably opens more than an angle (e + 90) degrees with respect to the forming direction of the one axial end surface of the case 10. The angle of the surface formation direction with respect to the horizontal direction is the same as the angle of the surface normal direction with respect to the vertical direction.

  The dust collecting basket 12 has an upper half 88 of the dust collecting basket and a lower half 89 of the dust collecting basket with the shaft 13 formed outside the middle 84 of the dust collecting basket as it protrudes from the case 10 as a fulcrum. The upper half 88 of the dust collection basket and the lower half 89 of the dust collection basket are relatively opened by an angle g. For example, the angle g is about 11.5 degrees. A protruding member 87 (a part of the dust collecting basket 12) formed on the outside of the upper half 88 of the dust collecting basket abuts on the inner side of the opening on the one end surface in the axial direction of the case 10, and the jumping out of the dust collecting basket 12 is restricted. Is done. With this restriction, the front end surface of the lower half portion 89 of the dust collecting basket is opened at an angle f at the maximum with respect to the one axial end surface of the case 10. For example, the angle f is about 33 degrees. The front end face (opening face) and the bottom face of the dust collecting basket 12 are substantially parallel. The front end surface of the upper half 88 of the dust collecting basket is opened at an angle (fg) at the maximum with respect to the one end surface in the axial direction of the case 10. Further, the front end surface of the lower half portion 89 of the dust collecting basket is opened until the angle (ef) is obtained with respect to the horizontal direction. For example, if the angle e is 40 degrees and the angle f is 33 degrees, the angle (ef) is about 7 degrees. That is, the front end surface of the lower half 89 of the dust collecting basket is close to about 7 degrees with respect to the horizontal direction, and the front end surface of the upper half 88 of the dust collecting basket is also (11. 5 + 7) = 1. Therefore, the front end surface of the upper half 88 of the dust collection basket and the front end surface of the lower half 89 of the dust collection basket are close to the horizontal direction, that is, in the horizontal direction more than 45 degrees between the horizontal direction and the vertical direction. In other words, the normal direction of the front end face of the upper half 88 of the dust collecting basket and the front end face of the lower half 89 of the dust collecting basket is close to the vertical direction (gravity acting direction), that is, the horizontal direction Since it is closer to the vertical direction than 45 degrees, which is the middle of the vertical direction, the dust 83 deposited on the dust collecting basket 12 is likely to fall.

  The handle 16 is gently inclined from the rear end to the front side of the dust container 5. The user has the front side of the handle 16 in order to operate a button 17 formed in front of the handle 16 in order to open the front lid 11. Although it depends on the position of the center of gravity of the dust container 5, if the user has the front side of the handle 16, the front side of the handle 16 is inclined so that the entire dust container 5 is inclined slightly upward with respect to the horizontal direction. become. Assuming that the formation direction (tangential direction) on the front side of the handle 16 is inclined at an angle h with respect to the horizontal direction, the entire dust container 5 is at an angle h upward with respect to the horizontal direction. For example, the angle h is about 12 degrees. Even when the user holds the front side of the handle 16 and discharges the dust 83 in the dust collecting basket 12, the front end surface of the lower half 89 of the dust collecting basket is at an angle (ef−h + h) with respect to the horizontal direction. For example, close to 19 degrees, and the front end surface of the upper half 88 of the dust collecting basket is also close to an angle (e−f + g + h), for example, about 30.5 degrees with respect to the horizontal direction. Therefore, even when the user holds the front side of the handle 16 and discharges the dust 83 in the dust collecting basket 12, the front end face of the upper half 88 of the dust collecting basket and the front end face of the lower half 89 of the dust collecting basket. Is closer to the horizontal direction, that is, closer to the horizontal direction than 45 degrees between the horizontal direction and the vertical direction, so that the dust 83 accumulated in the dust collecting basket 12 can easily fall. However, it is not essential that the handle 16 is gently inclined from the rear end to the front side of the dust container 5, and the handle 16 may be formed straight in the horizontal direction.

  FIG. 33 is a side view of the dust container of Embodiment 4 of the present invention. On the upper left side of the front lid 11, a transparent or translucent window 74 is formed through which the accumulated amount of compressed dust can be visually observed. In particular, when the case 10 is opaque, the user cannot visually check the amount of accumulated dust 83, so the window 74 is necessary. A garbage disposal line 90 is drawn on the window 74, so that the user can be notified of the timing of garbage disposal. The direction in which the dust disposal line 90 is formed is substantially perpendicular to the direction in which the dust 83 is deposited in the dust collecting basket 12, that is, substantially perpendicular to the suction direction to the filter 15, that is, approximately horizontal. The vertical direction. The dust disposal line 90 is formed at a position where the dust 83 accumulated in the dust collecting basket 12 does not spill from the opening at one end of the front lid 11 in the axial direction, for example, the lower end of the opening at one end of the front lid 11 in the axial direction. Is a position corresponding to. Even if the outer flow path 35 is blocked by dust, the suction force does not decrease so much because the inner flow path 36 is open. Therefore, the number of times that the dust is deposited in the dust collecting basket 12 as much as possible and the user discharges the dust by setting the dust disposal line 90 to a position where the dust 83 does not spill from the opening of the front lid 11. And the burden on the user can be reduced. However, when priority is given to maintaining the suction force, the waste disposal line 90 may be formed at the rear side and the lower side. The window 74 may be formed on the right side instead of being formed on the left side of the front lid 11, and may be formed on the case 10 instead of being formed on the front lid 11.

  FIG. 34 is a cross-sectional view seen from the right side of the dust container of the fourth embodiment of the present invention. FIG. 34A shows a fully opened state of the dust collection basket 12, and FIG. 34A shows a half-opened state of the dust collection basket 12. As described above, the protruding member 87 comes into contact with the inside of the opening on the one end surface in the axial direction of the case 10 to restrict the dust collecting basket 12 from jumping out, so that the fully opened state as shown in FIG.

  As shown in the enlarged view of FIG. 34 (a), a protrusion 91 and a protrusion 92 for maintaining the dust collection basket 12 in a half-open state are provided on the upper front side of the upper half 88 of the dust collection basket. Both the projecting member 91 and the projecting member 92 have a triangular shape. The projecting member 91 and the projecting member 92 are linearly formed in the front-rear direction, the projecting member 91 is formed on the front side, the projecting member 92 is formed on the rear side, and a gap is provided between the projecting member 91 and the projecting member 92. (Concave). The heights of the vertices of the protruding member 91 and the protruding member 92 are preferably the same or lower with respect to the upper surface of the upper half 88 of the dust collecting basket. In FIG. 34A, the inclination angle of the left side (front side surface) of the protrusion member 91 is preferably larger than the inclination angle of the right side (rear side surface) of the protrusion member 92. The inclination angle of the left side (front side surface) of the protruding member 92 is larger than the inclination angle of the right side of the protruding member 92. The inclination angle of the left side of the protruding member 92 is preferably close to 90 degrees (80 to 90 degrees) with respect to the bottom side. The inclination angle of the right side (rear side surface) of the protruding member 91 is larger than the inclination angle of the left side of the protruding member 91.

  When the dust collection basket 12 jumps out to the front of the case 10, there is a depression due to the weight of the dust collection basket 12 or the urging force of the spring, and therefore an end portion 93 that protrudes inside the axial end face opening of the case 10. However, the left side of the projecting member 91 slides, jumps over the gap between the projecting member 91 and the projecting member 92, and slides on the right side of the projecting member 92. Therefore, the dust collecting basket 12 is fully opened without being half opened as shown in FIG. On the other hand, when the dust collecting basket 12 is accommodated in the case 10 by a user's operation, the end 93 jumps over the gap between the protruding member 91 and the protruding member 92 when the user's pushing force is strong. However, when the pressing force of the user is weak, the end portion 93 slides on the right side of the protruding member 92, climbs over the apex of the protruding member 92, slides on the left side of the protruding member 92, and the protruding member 91 and the protruding member Will fall into the gap between the two. At this time, if the user removes the force pushing the dust collecting basket 12, the end portion 93 comes into contact with the left side of the projecting member 92, and the jumping (turning) of the dust collecting basket 12 to the front of the case 10 is restricted. In a half-open state. Then, from the half-opened state, the user abuts the front lid 11 against the front surface of the dust collecting basket 12 and applies a pressing force to one end surface in the axial direction of the front lid 11, so that the other axial end surface of the front lid 11 is collected. The front surface of the dust basket 12 is pushed, the end 93 slides on the right side of the projection member 91, climbs over the top of the projection member 91, slides on the left side of the projection member 91, and the dust collection basket 12 enters the storage state. The lid 11 is fully closed. However, since the left side of the protruding member 91 is also inclined, even if the front lid 11 is in an open state or the user is not holding the dust collecting basket 12, the front opening of the dust collecting basket 12 is directed upward. If directed, the end 93 abuts on the left side of the protruding member 91, and the stored state of the dust collecting basket 12 can be maintained. As a result, the user can easily store the dust collecting basket 12 in the case 10 and the front lid 11 can be easily closed.

  In the half-open state, the user sets the tissue paper inside the dust collection basket 12 with the front opening of the dust collection basket 12 facing upward, and pushes the bottom surface of the dust collection basket 12 from above the tissue paper to collect the dust. If the dust basket 12 is pushed into the case 10, the dust collection basket 12 can be stored in the case 10 with the front lid 11 opened. The user can then close the front lid 11. As a result, when the user moves the dust collecting basket 12 into the case 10, the user pushes the tissue paper to the bottom surface of the dust collecting basket 12. It can be securely attached to the left and right side wall surfaces. If the tissue paper can be mounted in close contact with the bottom surface of the dust collecting basket 12 and the upper, lower, left and right side wall surfaces, it is possible to prevent the tissue paper from being damaged when dust is collected.

  The present invention is applicable to a vacuum cleaner.

DESCRIPTION OF SYMBOLS 1 Vacuum cleaner main body 2 Dust collector 3 Inlet pipe 4 Dust separation part 5 Dust accommodating part 6 Outer cylinder 7 Inner cylinder 8 Recessed part 9, 22, 25 Packing 10 Case 11 Front cover 12 Dust collection basket 13, 14, 31, 32 Shafts 15, 29 Filters 16, 37, 53 Handle 17 Button 18 Transmission rod 20 Hose joint pipe 21 Main body inlet 23 Caster support 24 Dust remover 26 Auxiliary filter 27 Inlet duct 28 Electric blower 30 Main body outlet 33 Through hole 34 Extension 35 Outer channel 36 Inner channel 38 Guide tube 39 Recess 40 Exhaust duct 50 Suction tool 51 Joint tube 52 Operation tube 54 Hose 55 Wheel 56 Upper cover 57 Column portion 58 Frustum portion 59 Guide tube end portion 60 Circumferential direction base Portion 61 Circumferential tip 62, 63, 64 Flow 65 Downstream side wall surface 66 Upstream side wall surface 67 Screw 68, 69 Lip 70, 72, 87, 1,92 Projection member 71 Engagement member 73 Protrusion 74 Window 75 Boss receiver 76, 77, 80 Packing receiving surface 78 Frame 79 Filter member 81 Recess 82 Engagement hole 83 Dust 84 Dust collection basket bottom 85 Mounting member 86 Projection Part 88 Upper half part of dust collecting basket 89 Lower half part of dust collecting basket 90 Waste disposal line 93 End part 100 Part 101 Inner wall surface 102 of outer flow path

Claims (6)

A vacuum cleaner comprising a main body inlet and an electric blower that generates a suction force, and a dust collector detachable between the main body inlet of the cleaner main body and the electric blower In
The dust collecting apparatus includes a dust collecting portion including a case, a handle formed on an upper portion of the case, and a ventilation member formed by a member having one surface opened and the other surface being permeable.
The lower part of the ventilation member is rotatably supported by the case, and the opening of the ventilation member communicates with the main body inlet.
From the first state in which the ventilation member is included in the ventilation member or the case to the second state in which the angle between the opening surface of the ventilation member and the horizontal direction is a predetermined angle within 45 degrees A vacuum cleaner characterized by being rotatable in the forward direction of the case. The vacuum cleaner of claim 1,
The vacuum cleaner characterized in that when the dust collecting part is viewed from the side, the lower side of the case is shorter than the upper side, and the front end surface of the case is inclined with respect to the vertical direction. The vacuum cleaner of claim 2,
The dust collection part has an attachment member for attaching the lower part of the ventilation member to the case,
The vacuum cleaner according to claim 1, wherein the attachment member is fixed in the case while being inclined with respect to a vertical direction. In the vacuum cleaner in any one of Claim 1 to 3,
The dust collecting portion includes a closing member that is rotatably supported by the case and closes a front end surface of the case.
The ventilation member is in a first state when an opening surface of the ventilation member is pressed by the closing member, and is in a second state when a part of the ventilation member is in contact with the case. Electric vacuum cleaner. A vacuum cleaner comprising a main body inlet and an electric blower that generates a suction force, and a dust collector detachable between the main body inlet of the cleaner main body and the electric blower In
The dust collecting apparatus includes a dust collecting portion including a case, a handle formed on an upper portion of the case, and a ventilation member formed by a member having one surface opened and the other surface being permeable.
The lower part of the ventilation member is rotatably supported by the case, and the opening of the ventilation member communicates with the main body inlet.
The ventilation member has a second state in which an angle formed between the opening surface of the ventilation member and the forming direction of the handle is a predetermined angle within 45 degrees from the first state enclosed in the ventilation member or the case. A vacuum cleaner characterized in that it can be rotated in the forward direction of the case up to. A vacuum cleaner comprising a main body inlet and an electric blower that generates a suction force, and a dust collector detachable between the main body inlet of the cleaner main body and the electric blower In
The dust collector includes a case in which the lower side is shorter than the upper side when the dust collecting unit is viewed from the side, and a member that is open on one side and the other side can be ventilated, and the ventilation member included in the case and the ventilation A dust collecting portion having an attachment member for attaching the member to the case;
The lower part of the ventilation member is rotatably supported by the case, and the opening of the ventilation member communicates with the main body inlet.
The mounting member is fixed in the case while being inclined with respect to a direction in which a rear end surface of the dust collecting part is formed or a perpendicular to a bottom surface of the cleaner body when the dust collecting part is viewed from a side surface. An electric vacuum cleaner.

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