JP3762363B2 - Vacuum cleaner - Google Patents

Description

[0001]
BACKGROUND OF THE INVENTION
The present invention relates to a vacuum cleaner provided with a dust separation unit that separates dust from an air current by utilizing inertia of dust in sucked dust-containing air.
[0002]
[Prior art]
2. Description of the Related Art Conventionally, a cyclonic vacuum cleaner is known as a vacuum cleaner that separates dust in the air sucked by inertia separation (see, for example, Patent Document 1).
[0003]
This cyclone type vacuum cleaner includes a dust cup (dust box) having an open top, an electric blower that makes the inside of the cup have a negative pressure, and the like. An intake port is formed in the peripheral wall of the dust cup, and the intake port communicates with a suction port body for taking in dust-containing air through an intake passage.
[0004]
The dust-containing air sucked from the suction port body is sucked from the suction port into the dust cup through the suction passage. Due to the swirling flow generated in the dust cup as it is sucked into the cup, dust having a heavier mass than air is centrifuged. On the other hand, the air reverses and rises in the dust cup in the direction opposite to the direction in which the swirling flow proceeds, passes through the filter provided in the upper opening of the cup, is sucked into the electric blower, and is discharged to the outside. .
[0005]
[Patent Document 1]
JP 2001-104223 A (paragraphs 0045-0047, FIGS. 1-5)
[0006]
[Problems to be solved by the invention]
In the vacuum cleaner described in Patent Document 1, the air sucked through the intake passage is changed in direction by 90 degrees and enters the dust cup from the intake port, where it becomes a downward swirling flow, and the peripheral wall of the dust cup After that, the air reverses and rises, flows out of the dust cup, and is sucked into the electric blower. As described above, the air flow direction is changed twice in the dust cup, so that the air path loss is large. Moreover, since air swirls in the dust cup, the air path loss is even greater. Therefore, in the electric vacuum cleaner described in Patent Document 1, it is difficult to sufficiently exhibit the ability of the electric blower.
[0007]
Furthermore, in the vacuum cleaner described in Patent Document 1, when the filter that filters dust in the airflow that rises and reverses is clogged, the air path resistance increases and the suction force and the air volume decrease. Along with this, the centrifugal separation action is lowered, so that the cleaning performance is lowered. For this reason, it is desired to be able to eliminate clogging of the filter.
[0008]
On the other hand, in a normal vacuum cleaner in which a paper pack, which is a filter for filtering, is installed in the dust collection chamber, the air inlet, the paper pack, and the electric blower are substantially linear so that there is no significant change in the air flow direction. The wind path loss does not become large by being lined up. However, since a paper pack filters and collects various kinds of dust ranging from coarse dust to fine dust, if a predetermined amount of dust accumulates in this paper pack, the air volume is extremely likely to decrease.
[0009]
The problem to be solved by the present invention is that the air path loss can be reduced as compared with the case of centrifuging dust, the clogging of the filter of the dust separation part can be eliminated, and the reduction of the air volume can be easily suppressed. To get a vacuum cleaner.
[0010]
[Means for Solving the Problems]
  In order to solve the above problems, the present invention provides:A vacuum cleaner main body and suction guide means having a connecting pipe that is detachably inserted into and connected to the suction port of the main body, and this wind is introduced into the air passage from the suction port to the intake port of the electric blower. An electric vacuum cleaner provided with a dust separation part that separates air and dust flowing through a path, and a dust storage part that collects dust separated by the dust separation part, wherein the dust separation part is one end that forms an inlet An air passage forming body having a filter attached to a separation opening formed on the peripheral surface, and an opening at the other end forming an outlet opposite to the opening at the one end and forming an outlet at the other end, and A wind guide wall portion facing the outlet of the air passage formation body, and a cylindrical guide portion that guides the dust traveling straight in the air passage formation body to the dust reservoir, It is attached to the tip of the connecting pipe so as to move with the connecting pipe, and the wind Allowed the exit of the forming body is detachably fitted to the inlet of the guide portioning.
[0011]
  Similarly, in order to solve the above problem,The present invention comprises a vacuum cleaner main body and suction guide means having a connecting pipe that is detachably inserted into and connected to the suction port of the main body, and is located in the air path from the suction port to the intake port of the electric blower In addition, a vacuum cleaner provided with a dust separation part that separates air and dust flowing through the air passage, and a dust storage part that collects dust separated by the dust separation part, the dust separation part, An air passage having a filter formed in a cylindrical shape having an opening at one end forming an inlet and an opening at the other end facing the opening at one end, and attached to a separation opening formed on a peripheral surface And a cylindrical guide portion that has a wind-applying wall portion facing the outlet of the air passage formation body and guides dust that travels straight through the air passage formation body to the dust reservoir, and The inlet of the formed body and the tip of the connecting pipe are detachably fitted, and the front Outlet of the air path forming member is detachably fitted to the inlet of the guide portion.
[0014]
In the present invention, the dust separation unit refers to a straight-flow type inertial separation device that separates dust from air using a difference in inertial force based on the difference in kinetic energy between sucked air and dust. A centrifuge of the type is not included.
[0015]
In the present invention, the air passage forming body may be a tubular shape having a substantially constant diameter, or may be a tapered tubular shape whose diameter gradually decreases from the inlet toward the outlet. In the present invention, the filter of the air passage forming body can be a single layer or a plurality of types of filter media such as paper, cotton, cloth, glass wool, non-woven fabric, foamed synthetic resin, etc. In addition, a net can be suitably used. . Moreover, it is not hindered to provide a surface processed layer having a low coefficient of friction that suppresses the adhesion of dust to the surface and facilitates the removal of the adhered dust on the filter surface facing the inner space of the air passage forming body.
[0016]
In the present invention, since the straight separation type inertial separation is performed in the dust separation portion, the air path loss is small. Dust in the airflow passing through the separation opening of the dust separation portion and toward the air inlet of the electric blower adheres to the filter of the air passage formation body. However, in this invention, an air path formation body can be attached or detached with respect to the air path from the suction inlet of a cleaner main body to the inlet port of an electric blower. The attachment / detachment is performed without passing through the suction port or through the suction port, and more preferably, for example, the air passage forming body can be taken in and out through the suction port together with the connection pipe, or after the connection pipe is removed from the suction port, You can go in and out. By attaching and detaching the air passage forming body, it is possible to perform maintenance for eliminating clogging outside the cleaner body.
[0017]
DETAILED DESCRIPTION OF THE INVENTION
Hereinafter, a first embodiment of the present invention will be described with reference to FIGS.
[0018]
The vacuum cleaner denoted by reference numeral 10 in FIG. 1 includes a vacuum cleaner main body 20 and suction guide means 21 that guides air and dust to the main body 20. The suction guide means 21 includes a dust suction hose 22, an extension pipe 23, and a suction port body 24. The dust suction hose 22 is formed by connecting a hard synthetic resin connecting pipe 26 to one end of a flexible hose body 25 and connecting a hard synthetic resin hand operating part 27 to the other end of the hose body 25. ing. The hand operating section 27 has a handle 27A, and the handle 27A is provided with an operation switch 27B for remote operation. The extension tube 23 can be expanded and contracted, and is detachably connected to the hand operation unit 27. The suction port body 24 is detachably connected to the distal end portion of the extension pipe 23.
[0019]
The connecting pipe 26 is detachably inserted into and connected to a suction port described later of the cleaner body 20. As shown in FIG. 5 and the like, the connecting pipe 26 has a cylindrical shape and has a holder portion 26a having a smaller diameter at the tip than other portions, and a plurality of engaging portions 26b on the outer surface of the holder portion 26a. Is provided. The engaging portion 26b is made of, for example, a hemispherical convex portion. Instead of this, it is also possible to make the engaging portion 26b with a dent or a hole. These engaging portions 26b are provided at intervals in the circumferential direction of the holder portion 26a, and are provided, for example, 180 degrees apart.
[0020]
On the outer periphery of the connecting pipe 26 near the holder portion 26a, a synthetic rubber seal packing 28 having an annular shape along the circumferential direction is attached. The packing 28 has a fin portion and is used to maintain airtightness between the inner peripheral surface of the suction port described later. Further, a clamp receiving portion 29 made of a concave portion is formed on a part of the outer peripheral surface of the connection pipe 26 and is located upstream of the seal packing 28.
[0021]
As shown in FIGS. 1 to 3, the cleaner main body 20 includes a main body case 30, a dust collection container (dust cup) 50 that is detachably attached to the main body case 30, and a lid body 40. The rear portion of the lid 40 is hinged to the front portion of the main body case 30 so as to be opened and closed in the vertical direction.
[0022]
The main body case 30 includes a rear electric part 34 and a front mounting part 35. As shown in FIG. 2, the electric blower 33 has a built-in electric blower 33, and an intake port 33 </ b> A of the electric blower 33 is mostly on the upper side of the electric drive 34. The mounting portion 35 is integrally projected forward from the lower portion of the electric portion 34 and is formed in a dish shape having a concave shape that opens upward. A dust collecting container 50 is detachably mounted on the mounting portion 35. By closing the lid body 40, the lid body 40 and the mounting portion 35 sandwich and fix the dust collecting container 50.
[0023]
As shown in FIG. 3B, the front surface of the electric motor 34 is opened, and the opening 34 </ b> A is opposed to and communicates with the air inlet 33 </ b> A of the electric blower 33. The opening 34A is provided with a filter presser 34B having radial ribs for pressing a filter 80 described later from the downstream side.
[0024]
On both side walls in the width direction of the main body case 30, oblique bulging portions 36 (only one is shown) extending from the front upper portion of the main body case 30 to the rear lower portion are integrally formed, and at the lower ends of the bulging portions 36, respectively. A rear wheel 37 is rotatably attached. Exhaust portions 38 each having a plurality of exhaust holes are provided in front portions of both bulged portions 36 and both side walls of the main body case 30. These exhaust portions 38 communicate with an exhaust port 33B (see FIG. 2) of the electric blower 33 through an exhaust air passage (not shown). The air exhausted from the exhaust port 33B of the electric blower 33 is exhausted from the exhaust part 38 through the exhaust air passage.
[0025]
The electric reel 34 of the main body case 30 is provided with a cord reel 39 that is located below the electric blower 33 and supplies electric power from a commercial AC power source to the electric blower 33 and the like. It is also possible to incorporate a battery for supplying power to the electric blower 33 or the like instead of the cord reel 39.
[0026]
The lid body 40 includes a top plate 41 formed in an approximately elliptical shape in plan view, and a peripheral wall 42 formed integrally around the top plate 41. A pipe-like suction port 43 (see FIGS. 2 and 4) to which the connection pipe 26 of the dust suction hose 22 is detachably inserted is connected to the front portion of the peripheral wall 42. The suction port 43 extends, for example, in the front-rear direction (in FIG. 2) in use, and both axial ends thereof are open.
[0027]
The lid 40 is provided around the suction port 43, and a clamp 44 is provided in the suction port 43 so as to be able to protrude and retract, and a spring 45 that biases the clamp 44 toward the center of the suction port 43. Is arranged. The clamp 44 is used to fit the clamp receiving portion 29 of the connection pipe 26 inserted into the suction port 43 and prevent the connection pipe 26 from coming off. The tip of the clamp 44 fitted to the clamp receiving portion 29 is tapered. With the contact between the taper surface of the clamp 44 and the clamp receiving portion 29, the connecting pipe 26 is slightly pushed in the insertion direction of the pipe 26 (see arrow A in FIG. 2). Further, reference numeral 46 in FIG. 1 and FIG. 2 denotes a clamp release operation part. By operating this operation part 46, the clamp 44 can be detached from the clamp receiving part 29 against the spring 45. ing.
[0028]
The dust collection container 50 has a container case body 53 having one surface, for example, substantially the entire rear surface located on the right side in FIG. 4 and having an intake inlet 52 on the front wall facing the opening 51, and the container case body 53. And a handle portion 54 provided on the head. The intake port 52 communicates directly with the downstream opening of the intake port 43. The handle portion 54 is provided below the intake inlet 52, for example.
[0029]
The container case body 53 includes a first dust storage portion (first dust collection portion) 55 formed at a lower portion of the case body 53, and a negative pressure chamber portion (negative pressure) formed mainly above the first dust storage portion 55. Pressure space) 56, a first dust separation portion 61 provided in the negative pressure chamber portion 56 so as to be able to be taken in and out through the suction port 43, and dust separated by the dust separation portion 61 to the first dust storage portion 55. And a guiding portion 63 for guiding.
[0030]
The bottom surface of the first dust reservoir 55 is open. A bottom plate 57 having a seal rubber 57a attached to the inner surface for airtightness when closed is attached to the bottom of the first dust reservoir 55 so as to be openable and closable around the axis J. By opening the bottom plate 57, the dust accumulated in the first dust reservoir 55 can be discarded. The closed state of the bottom plate 57 is released through a mechanism (not shown) that is interlocked with the pressing of the operation button provided on the handle portion 54.
[0031]
As shown in FIGS. 4 and 7, the first dust storage portion 55 and the negative pressure chamber portion 56 are partitioned by a standing wall 60 that is close to the opening 51 and a ceiling wall 58 that is bent from the upper end of the wall 60. . The ceiling wall 58 of the first dust reservoir 55 is formed with a vent opening 59 that allows the first dust reservoir 55 and the negative pressure chamber 56 to communicate with each other. The ventilation opening 59 is provided to face the substantially central portion of the first dust reservoir 55. As shown in FIGS. 4 and 8, a dust capturing filter F1 made of, for example, a net is attached to the ventilation opening 59.
[0032]
A connection hole 58A (see FIG. 7) is formed in the ceiling wall 58 on the upright wall 60 side. Below the connection hole 58A, a guide wall 55G (see FIGS. 4 and 8) for generating a swirling flow in the first dust reservoir 55 is provided.
[0033]
The first dust separation unit 61 includes a cylindrical air passage forming body 62 that forms a separation air passage 62 a and a guide portion 63.
[0034]
As shown in FIGS. 2 to 6, the air passage formation body 62 has a hollow frustum shape in which one end (inlet) and the other end (outlet) are opened, and a plurality of separation openings 64 are equally spaced over the entire circumference. And a dust capturing filter F2 that closes the separation opening 64.
[0035]
Specifically, the air passage forming body 62 includes a synthetic resin frame composed of a pair of large and small circular frame portions W1 and W2 and a plurality of ribs W3 connecting the frame portions W1 and W2. Each separation opening 64 is formed in a space surrounded by both frame portions W1, W2 and a rib W3. The filter F2 is made of, for example, a net and is attached in a cylindrical shape along the inner peripheral surface of the frame. Therefore, the air passage formation body 62 has a structure in which both ends in the axial direction are opened, and the inner space of the formation body 62 forms a separation air passage 62a.
[0036]
When the air passage forming body 62 is inserted and arranged in the negative pressure chamber portion 56, the central axis of the separation air passage 62a extends linearly in the axial direction of the cleaner body 20 (the front-rear direction in the present embodiment). ing. The separation air passage 62a is connected to the air inlet 33A of the electric blower 33 through the separation opening 64 of the air passage formation body 62, the negative pressure chamber portion 56 of the container case body 53, and the opening 34A of the electric portion 34 of the main body case 30 sequentially. Communicating with
[0037]
The diameter of the circular frame portion W <b> 1 at one end that forms the large-diameter inlet of the air passage forming body 62 is formed smaller than the suction port 43 and the suction opening 52. Thereby, the air path formation body 62 is made into the magnitude | size which can pass the cover body 40 suction inlet 43. FIG. The diameter of the circular frame portion W2 at the other end forming the small diameter outlet of the air passage forming body 62 is substantially equal to the inner diameter of the inlet of the guide portion 63 described later. As a result, the diameter of the air passage forming body 62 gradually decreases linearly from the entrance to the exit.
[0038]
The direction in which the axial line of the air passage forming body 62 arranged in the dust collecting container 50 extends through the suction port 43 and the direction in which the axial line of the suction port 43 extends are substantially straight, and on the extension of these axes. The air inlet 33A of the electric blower 33 is provided so as to face each other (see FIGS. 2 and 4). Thus, the suction port 43, the opening 51 of the container case body 53, and the suction port 33A of the electric blower 33 are sequentially arranged along the axial direction of the cleaner body 20 (the front-rear direction in this embodiment). Yes.
[0039]
As shown in FIG. 4 and the like, the guide portion 63 has a cylindrical shape and is provided continuously to the circular frame portion W2 of the air passage forming body 62. Specifically, the guide portion 63 is curved from an inlet 63A fitted to the outer periphery of the circular frame portion W2, an inclined wall portion 63B extending obliquely downward from an upper portion of the inlet 63A, and one end of the inclined wall portion 63B. In addition, it has an air blowing wall portion 63C that extends downward and faces the inlet 63A. Furthermore, the lower part of the guide part 63 extends in the vertical direction, for example, and is connected to the connection hole 58A. By this connection, the guide portion 63 communicates the separation air passage 62a with the first dust storage portion 55.
[0040]
The air passage forming body 62 is attached to the distal end portion of the connection pipe 26 so as to be movable together with the connection pipe 26 and is detachable.
[0041]
Specifically, the circular frame portion W1 that forms the upstream inlet of the air passage forming body 62 is formed in a size that can be fitted to the outer peripheral surface of the holder portion 26a. The circular frame portion W1 is provided with a plurality of, for example, a pair of engaging portion receivers 65 corresponding to the engaging portions 34. As shown in FIG. 6, the engaging portion receiver 65 is made of a hole or a groove provided in the flexible deformation plate portion 66 between a pair of cuts 68 provided in the circular frame portion W1. The engaging portion receiving portion 65 is made of a convex portion when the engaging portion 34 is made of a hole or a groove.
[0042]
By fitting the engagement portion receiver 65 and the engagement portion 34, the attachment state of the air path forming body 62 to the connection pipe 26 is maintained. FIG. 5 shows a state in which the air passage forming body 62 is fitted and attached to the distal end portion of the connecting pipe 26. As described above, the flexible deformation plate portion 66 having the engagement portion receiver 65 can be elastically deformed. For this reason, by strongly pulling the air passage forming body 62, the engagement between the engagement portion 34 and the engagement portion receiver 65 can be released with the elastic deformation of the flexible deformation plate portion 66. On the contrary, when the air passage forming body 62 in a state where the circular frame portion W1 is shallowly fitted into the holder portion 26a of the connecting pipe 26 is strongly pressed, the engaging portion is accompanied by elastic deformation of the flexible deformable plate portion 66. 34 and the engaging portion receiver 65 can be engaged with each other. In FIG. 5A and FIG. 6, reference numeral 67 denotes a rib on the inner peripheral surface of the circular frame W1.
[0043]
The standing wall 60 is provided slightly inside (front side) of the opening 51 of the container case body 53 to give the opening 51 a predetermined depth H (see FIG. 4). A filter 80 (to be described later) that forms the second dust separation portion is detachably mounted in the opening 51 using this depth H.
[0044]
As shown in FIGS. 4, 7, and 8, a support wall 71 that supports a filter 80, which will be described later, from the lower side is integrally provided on the outside of the lower end portion of the standing wall 60. A second dust reservoir 72 is formed between the outside and the outside. The second dust storage unit 72 is provided to store dust finer than the dust stored in the first dust storage unit 55 independently of the first dust storage unit 55. Both the upper and lower ends of the second dust reservoir 72 are opened, and the second dust reservoir 72 is partitioned into a plurality of regions by a plurality of support ribs 73. The support rib 73 supports the filter 80 from below.
[0045]
The lower end opening of the second dust storage part 72 is arranged in the lower end opening of the first dust storage part 55 and is closed by the bottom plate 57 that opens and closes the first dust storage part 55. Thereby, by opening one bottom plate 57, the dust accumulated in the first and second dust reservoirs 55 and 72 can be discarded at the same time, which is convenient. By closing the lower end opening of the second dust reservoir 72 with the bottom plate 57, the second dust reservoir 72 is formed in a concave shape so that the airflow passes therethrough and the influence of the turbulent flow hardly affects the dust reservoir 72. Specifically, it becomes a dead end structure.
[0046]
The depth of fitting of the filter 80 into the opening 51 portion of the container case body 53 is determined by the regulating means provided in the container case body 53, for example, the stepped portion 53A formed on the ceiling portion of the container case body 53 and the standing as shown in FIG. The restriction is made by the corner portion 53B formed by the wall 60 and the rib 73, and the restriction allows the filter 80 to be mounted upright, preferably tilted forward at an angle close to vertical, for example.
[0047]
The upper part of the filter 80 attached to the container case body 53 faces the negative pressure chamber part 56, and the lower part is opposed to the upright wall 60 in the vicinity. As a result, a gap G is formed between the lower portion of the filter 80 and the upright wall 60, which is much narrower than the upper negative pressure chamber portion 56 and has a small air passage cross-sectional area. The lower end of the gap G communicates with the second dust reservoir 72 located below the gap G.
[0048]
The filter 80 includes a filter frame 81 and a filter element 82 that is attached by closing the entire inside of the frame 81. The filter element 82 is formed by matting the filter medium. In particular, in this embodiment, a pleated filter element bent into a corrugated shape is used to expand the filtration area. The mesh of the filter element 82 is finer than that of the filters F1 and F2 in the previous stage.
[0049]
Next, operation | movement of the vacuum cleaner 10 comprised as mentioned above is demonstrated.
[0050]
  After the dust collecting container 50 is placed on the placing portion 35 of the main body case 30 as shown in FIG. 3 (A), the lid 40 is closed and then the connecting pipe 26 of the dust suction hose 22 as shown in FIG. The suction port 43 of the lid 40 provided at the front end of the vacuum cleaner body 20InInsert and connect.
[0051]
In this case, a tapered air passage forming body 62 is attached to the distal end portion of the connecting pipe 26 to be inserted. Therefore, the air passage forming body 62 substantially passes through the suction port 43 with the insertion, and the small-diameter circular frame portion W2 of the forming body 62 is fitted and connected to the inside of the inlet 63A of the guide portion 63. The
[0052]
In addition, these fitting parts can be formed in a taper shape. When this configuration is adopted, the circular frame portion W2 is prevented from being caught on the opening edge of the inlet 63A, and smooth insertion is performed. For this reason, it is preferable at the point which can insert the air path formation body 62 to an appropriate set position easily.
[0053]
FIG. 2 shows a state where the first dust separator 61 is assembled by completing the insertion of the connecting pipe 26 and setting the air passage forming body 62 at a predetermined position. In this state, the clamp 44 pressed by the spring 45 enters the clamp receiving portion 29 of the connection pipe 26 to prevent the connection pipe 26 from coming off. At the same time, the circular frame portion W2 reaches the back of the inlet 63A of the guide portion 63 by the movement of the air passage forming body 62 in the direction of arrow A in FIG. 2 accompanying the engagement between the clamp 44 and the clamp receiving portion 29. It is pushed. For this reason, when a ring-shaped rubber packing is provided on the front end surface of the circular frame portion W2 or the back end surface of the inlet 63A, the packing can be compressed to achieve a high degree of airtightness. Further, when the connection pipe 26 is completely inserted, the seal packing 28 comes into contact with the inner peripheral surface of the suction port 24 at a position downstream of the clamp 44 to ensure airtightness at the suction port portion.
[0054]
As described above, the suction port body 24 is already connected to the dust suction hose 22 connected to the cleaner body 20 via the extension pipe 23. In this state, the electric blower 33 is driven by operating the operation switch 27B of the hand operation unit 27. Thereby, the negative pressure chamber part 56 of the container case body 53 becomes negative pressure through the opening 34 </ b> A of the electric part 34. Since this negative pressure sequentially acts on the separation opening 64 of the air passage formation body 62, the separation air passage 62a of the air passage formation body 62, the dust suction hose 22, the extension pipe 23, and the suction opening body 24, from the suction opening body 24, Dust is sucked together with air.
[0055]
The sucked dust and air are sucked into the separation air passage 62 a of the air passage formation body 62 of the first dust separation portion 61 through the extension pipe 23 and the dust suction hose 22. A part of the air sucked into the separation air passage 62a passes through the filter F2 of the separation opening 64 of the air passage formation body 62 and is sucked into the negative pressure chamber portion 56 of the container case body 53, and further the opening of the container case body 53. The air is sucked into the air inlet 33 </ b> A of the electric blower 33 through the filter 80 attached to 51.
[0056]
In the above suction, dust having a mass exceeding a predetermined value sucked into the separation air passage 62a linearly extending in the front-rear direction of the cleaner body 20 is suddenly changed in direction due to its inertia, and the separation opening 64 is formed. Can't pass. For this reason, the dust having the mass is separated from the air passing through the separation opening 64, travels straight through the separation air passage 62 a, collides with the air blowing wall portion 63 </ b> C of the guide portion 63, and the first dust along the guide portion 63. It is introduced into the reservoir 55.
[0057]
At the same time, a part of the air is introduced into the first dust reservoir 55 through the guide part 63 in the same manner as the dust having the mass. The air thus introduced becomes a downward swirling flow that rotates along the inner peripheral surface of the first dust reservoir 55 by the guide wall 55G. For this reason, the dust introduced into the first dust reservoir 55 is accumulated while being compressed along the lower inner peripheral surface of the first dust reservoir 55 by the swirl flow. Then, the air that has been introduced into the first dust reservoir 55 and turned into a swirl flow rises and reverses at the center of the first dust reservoir 55, and the ventilation opening of the ceiling wall 58 of the first dust reservoir 55. The liquid is sucked into the negative pressure chamber portion 56 of the container case body 53 through 59.
[0058]
On the other hand, the light dust does not travel straight through the separation air passage 62a in the air passage formation body 62 of the first dust separation portion 61, but passes through the filter F2 of the separation opening 64 by the negative suction pressure of the electric blower 33. And flows to the negative pressure chamber portion 56, and is attached to the inner peripheral surface of the filter F2.
[0059]
As described above, in the first dust separation unit 61, dust having a large mass such as coarse dust goes straight without swirling dust-containing air and centrifuging dust and air while reversing the traveling direction of the swirl flow. Since this dust is separated from the air by utilizing the inertial force to be achieved, the air path loss in the first dust separation unit 61 is small.
[0060]
In this case, the intake port 52, the separation air passage 62a, the opening 51 of the container case body 53, and the intake port 33A of the electric blower 33 are located at substantially the same height and are sequentially arranged in the front-rear direction. When air is sucked from the separation air passage 62a through the filter F2 into the negative pressure chamber portion 56 of the container case body 53, the main flow of the air is represented by an arrow Q in FIG. It does not change greatly and flows almost linearly at substantially the same height position and is sucked into the electric blower 33.
[0061]
As a result, the air path loss is further reduced, and the function of the electric blower 33 can be fully exhibited. Further, since the suction port 43 and the cylindrical air passage forming body 62 are aligned in a straight line, the direction of the air introduced toward the intake inlet 52 of the container case body 53 and the air passage forming body 62 extend. Since the direction is substantially straight, the air path loss can be further reduced.
[0062]
The air in the negative pressure chamber 56 passes through the filter 80 and is sucked into the electric blower 33. Thereby, the fine dust that has passed through the filters F1 and F2 can be captured by the filter element 82 of the filter 80, and the electric blower 33 can suck the air cleaned thereby. A first dust separation unit 61 is provided on the upstream side of the filter 80, and coarse dust and the like are separated in advance by the first dust separation unit 61 as described above. Large dust does not interfere with its function.
[0063]
Most of the dust that mainly adheres to the upstream surface of the filter element 82 and is captured is dropped by its own weight as the operation of the electric blower 33 is stopped. The fallen dust passes through the gap G and the like and is stored in the second dust storage portion 72 provided below the lower frame portion of the filter frame 81.
[0064]
With the operation of the electric vacuum cleaner 1 described above, light dust adheres to the inner peripheral surface of the filter F2 of the first dust separator 61 as described above. When clogging of the filter F2 increases due to such light dust adhesion, the air volume passing through the filter F2 decreases.
[0065]
However, the negative pressure in the negative pressure chamber portion 56 is increased by this reduced amount, and the negative pressure in the first dust storage portion 55 is increased through the vent opening 59 of the ceiling wall 58. For this reason, since the wind speed and the air volume of the air that travels straight through the separation air passage 62a increase, it becomes easy for the air that travels straight to remove the dust attached to the filter F2. At this time, since the diameter of the cylindrical air passage forming body 62 gradually decreases from the upstream circular frame portion W1 to the downstream circular frame portion W2, the wind straightly traveling through the separation air passage 62a is The filter F2 uniformly hits the entire surface of the filter F2 and flows while being drawn toward the center of the separation air passage 62a. For this reason, the dust adhering to the inner surface of the filter F2 can be more easily peeled off. The dust thus peeled is introduced into the first dust reservoir 55 through the guide portion 63 in the same manner as dust having a large mass, and is accumulated in the dust reservoir 55 by being centrifuged from the air.
[0066]
As described above, even if the amount of air passing through the filter F2 decreases due to clogging, the amount of air that goes straight through the separation air passage 62a increases, so the amount of air sucked by the electric blower 33 is kept substantially constant. For this reason, it is possible to always suck dust with a predetermined suction force regardless of the clogging of the filter F2.
[0067]
However, since the dust removal on the inner surface of the filter F2 is not complete, when the operation of the vacuum cleaner 1 is stopped, dust or the like is attached to the filter F2. Can be improved by the following procedure.
[0068]
That is, by pulling the connection pipe 26 of the dust suction hose 22 in a state where the clamp release operation portion 46 is operated, the connection pipe 26 can be pulled out from the suction port 43 of the cleaner body 20, and the connection pipe 26 and Together, the air passage forming body 62 is drawn out through the suction port 43. Thereby, the air path formation body 62 can be removed from the air path from the suction port 43 to the intake port 33A of the electric blower 33.
[0069]
In this way, the air passage formation body 62 can be easily pulled out of the cleaner body 20 with one behavior, so that the air passage formation body 62 is washed outside the cleaner body 20 without being restricted by the dust collecting container 50 or the like. By doing so, dust adhering to the filter F2 can be removed. In this case, in this embodiment, since the air passage forming body 62 can be removed from the connecting pipe 26, the air passage forming body 62 is attached to the filter F2 even though it is in the shape of a hollow truncated cone. Dust can be easily removed from the large-diameter circular frame W1 side.
[0070]
In the present invention, the air passage forming body 62 can be formed in a cylindrical shape with almost no change in diameter. In this case, even if the cylindrical air passage forming body is not removed from the connecting pipe 26, the downstream circular frame W2 fitted to the inlet 63A can perform a cleaning operation to remove dust. Therefore, the cylindrical air passage forming body may be connected to the connecting pipe 26 so as not to be removed.
[0071]
As described above, since the air passage forming body 62 can be inserted into and removed from the suction port 43 of the cleaner body 20 together with the connection pipe 26 of the dust suction hose 22, the air passage forming body 62 is provided outside the cleaner body 20 as necessary. Can be taken out and care can be taken to remove dust adhering to the filter F2.
[0072]
If large dust is accidentally sucked in, it is conceivable that the dust is clogged in the air frustum 62 having a hollow truncated cone shape. Even in such a case, it is possible to easily remove the clogged dust by drawing the air passage forming body 62 out of the cleaner body 20 as described above.
[0073]
Furthermore, since the container case body 53 and the air path forming body 62 of the dust collecting container 50 can be separately molded by adopting the above configuration, the configuration of these molding dies can be simplified and the mold cost can be reduced. .
[0074]
9 to 11 show a second embodiment of the present invention. Since this embodiment is basically the same as the first embodiment, the same components as those of the first embodiment will be denoted by the same reference numerals, description thereof will be omitted, and differences in configuration will be described below.
[0075]
In the second embodiment, the circular frame portion W1 that forms the inlet of the air passage forming body 62 is loosely fitted in the holder portion 26a of the connecting pipe 26 (see FIG. 9). And the connection structure of the holder part 26a and circular frame part W1 employ | adopted in 1st Embodiment, ie, the engaging part and the engaging part receiving, are abbreviate | omitted (refer FIG. 11). As a result, the air passage forming body 62 is not necessarily moved together with the connecting pipe 26. For this reason, insertion and removal of the air passage forming body 62 with respect to the suction port 43 of the cleaner body 20 is manually performed by a user or the like.
[0076]
Therefore, as the connecting pipe 26 is inserted and attached to the suction port 43, the holder portion 26a and the circular frame portion W1 are fitted with play, and the air path forming body 62 is pushed to collect the dust collecting container 50. It is arranged at an appropriate position inside. Further, when the connection pipe 26 is pulled out from the suction port 43, for example, when the filter F2 of the air path forming body 62 is cleaned or dust clogged inside is removed, the air path forming body 62 is illustrated in FIG. It is still installed in the dust collecting container 50. The air passage forming body 62 is artificially drawn out through the suction port 43. In this case, the rib 67 can be picked and implemented.
[0077]
Configurations other than those described above are the same as those in the first embodiment, including configurations not shown in FIGS. 9 to 11. For this reason, also in the second embodiment, the air passage forming body 62 is pulled out of the cleaner body 20 as necessary, and the air passage is formed outside the cleaner body 20 without being restricted by the dust collecting container 50 or the like. The dust adhering to the filter F2 can be removed by washing the body 62 with water or the like. In this case, since the air passage formation body 62 is detached from the connecting pipe 26, the dust attached to the filter F2 is removed from the large-diameter circular frame portion even though the air passage formation body 62 has a hollow frustum shape. It can be easily removed from the W1 side. Thus, also in 2nd Embodiment, the subject of this invention can be solved by obtaining the same effect as 1st Embodiment.
[0078]
In addition, this invention is not restrict | limited to the said each embodiment. For example, when the air passage forming body is attached to and detached from the air passage extending from the suction port to the intake port of the electric blower, it is not necessarily restricted to pass through the suction port, and can be attached and detached from the opening side of the container case body, for example. It is also possible to configure.
[0079]
【The invention's effect】
According to the present invention, there is provided a vacuum cleaner that can reduce the air path loss as compared with the one that centrifuges dust, can eliminate clogging of the filter of the dust separation unit, and can easily suppress the decrease in the air volume. Can be provided.
[Brief description of the drawings]
FIG. 1 is a perspective view showing a vacuum cleaner according to a first embodiment of the present invention.
2 is a side view showing a partial cross section of the vacuum cleaner main body of the electric vacuum cleaner of FIG. 1 with a connecting pipe inserted into a suction port of the main body. FIG.
3A is a side view showing the cleaner body of FIG. 2 with the lid open. FIG. (B) is a perspective view which shows the cleaner main body of FIG. 2 in the state which opened the cover body and removed the dust collecting container.
4 is a longitudinal sectional view showing a dust collecting container with a lid provided in the electric vacuum cleaner of FIG. 1 and an air passage forming body drawn out from the dust collecting container. FIG.
5A is a perspective view showing a state in which an air passage forming body is supported on a connecting pipe provided in the electric vacuum cleaner of FIG. 1; FIG. (B) is sectional drawing which shows the state by which the air path formation body was supported by the connection pipe with which the vacuum cleaner of FIG. 1 is equipped.
6 is a perspective view showing an air passage forming body provided in the electric vacuum cleaner of FIG. 1. FIG.
7 is a perspective view showing the lower part of the dust collecting container of FIG. 4 as seen from the rear side.
8 is a bottom view showing the dust collecting container of FIG. 4. FIG.
FIG. 9 is a cross-sectional view showing the vicinity of an air passage forming body of a vacuum cleaner according to a second embodiment of the present invention in a state where a connection pipe is inserted.
FIG. 10 is a cross-sectional view showing the vicinity of the air passage forming body of the electric vacuum cleaner according to the second embodiment with the connecting pipe removed.
FIG. 11 is a perspective view showing a distal end portion of a connection pipe and an air path forming body used in the second embodiment.
[Explanation of symbols]
10 ... Vacuum cleaner
20 ... Vacuum cleaner body
21 ... Suction guide means
22 ... Dust suction hose
26 ... Connection pipe of dust suction hose
26a ... Connection pipe holder
26b: engaging portion of connecting pipe
33 ... Electric blower
33A ... Inlet
43 ... Suction port
50 ... Dust collection container (dust cup)
55 ... Dust storage
56 ... Negative pressure chamber (negative pressure space)
59 ... Ventilation opening
61 ... Dust separator
62: Air channel formation body
62a ... Separation air passage of air passage formation body
63 ... Guide
63A ... Entrance to the guide
63C ... Breeting wall of the guide
65. Engaging portion receiver
F2 ... Filter
W1 ... Large-diameter circular frame part (entrance) of the air passage formation body
W2: Small diameter circular frame (outlet) of the air passage forming body

Claims (3)

A vacuum cleaner main body, and suction guide means having a connecting pipe that is detachably inserted into and connected to the suction port of the main body, and the wind passage extends from the suction port to the intake port of the electric blower. A vacuum cleaner provided with a dust separation part that separates air and dust flowing through a road, and a dust storage part that collects dust separated by the dust separation part,
The dust separation portion is formed in a cylindrical shape having an opening at one end forming an inlet and an opening at the other end facing the opening at the one end, and is attached to a separation opening formed on a peripheral surface. An air passage forming body having a filter, and a cylindrical guide portion that has an air blowing wall portion facing the outlet of the air passage forming body and guides dust that travels straight through the air passage forming body to the dust reservoir. With
The air path forming body is attached to the tip of the connection pipe so as to move together with the connection pipe, and the outlet of the air path forming body is detachably fitted to the inlet of the guide section. Machine. The vacuum cleaner of Claim 1 WHEREIN: The said air path formation body is detachable with respect to the said connection pipe. A vacuum cleaner main body, and suction guide means having a connecting pipe that is detachably inserted into and connected to the suction port of the main body, and the wind passage extends from the suction port to the intake port of the electric blower. A vacuum cleaner provided with a dust separation part that separates air and dust flowing through a road, and a dust storage part that collects dust separated by the dust separation part,
The dust separation portion is formed in a cylindrical shape having an opening at one end forming an inlet and an opening at the other end facing the opening at the one end, and is attached to a separation opening formed on a peripheral surface. An air passage forming body having a filter, and a cylindrical guide portion that has an air blowing wall portion facing the outlet of the air passage forming body and guides dust that travels straight through the air passage forming body to the dust reservoir. With
An electric cleaner in which an inlet of the air passage forming body and a tip of the connecting pipe are detachably fitted, and an outlet of the air passage forming body is detachably fitted to an inlet of the guide portion Machine.

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