JP6918679B2 - Vacuum cleaner - Google Patents

Description

An embodiment of the present invention relates to an electric vacuum cleaner including an electric blower and a dust collecting unit that separates and collects dust sucked by the operation of the electric blower from the air.

Conventionally, as a dust collector used in an electric vacuum cleaner, a so-called cyclone dust collector, which separates and collects dust by using centrifugal force, is known. In such a cyclone dust collecting portion, a circular separation chamber is formed around a tubular suction cylinder, and a dust collecting chamber is formed in communication with the separation chamber. Further, the suction cylinder is provided with an opening that communicates with the suction side of the electric blower. Then, the dust-containing air sucked by the negative pressure of the electric blower is introduced into the separation chamber, and the dust-containing air circulates in the separation chamber to centrifuge the coarse dust, which is a relatively large dust, into the dust collection chamber. Be collected. Further, fine dust, which is relatively small dust that has not been centrifuged, passes through the opening and is collected through a filter or the like located on the downstream side.

The negative pressure generated by driving the electric blower acts from the inside of the suction cylinder to the separation chamber through the opening. Therefore, if coarse dust contained in the dust-containing air circulating around the separation chamber adheres to the opening and covers the opening, the sustainability of suction is impaired. Therefore, it is desired to suppress the adhesion of coarse dust to the opening and ensure the sustainability of suction. At this time, for example, a ventilation port for communicating the dust collecting chamber and the downstream side of the dust collecting chamber is provided, and the air obtained by centrifuging the dust is drawn further downstream from the dust collecting chamber to collect the dust. There is a configuration in which dust is effectively deposited in the dust chamber, dust is suppressed from accumulating near the opening of the suction cylinder, and suction is maintained. However, in the case of this configuration, a part of the dust separated in the dust collecting chamber flows from the ventilation port to the downstream side.

Japanese Patent No. 4528641

An object to be solved by the present invention is to provide an electric vacuum cleaner capable of maintaining a suction force without flowing dust separated in a housing portion to the downstream side.

The vacuum cleaner of the embodiment includes an electric blower and a dust collecting unit that separates and collects dust sucked by the operation of the electric blower from the air. The dust collecting unit includes a suction cylinder, a separation chamber, an introduction unit, a discharge port, a storage unit, a reflux chamber, and a ventilation port. The suction cylinder is formed in a tubular shape having an opening, and the negative pressure generated by the electric blower acts from the inside to the outside through the opening. The separation chamber is formed around the suction cylinder to separate dust. The introduction section has an introduction port on the downstream side for introducing dust-containing air into the separation chamber. The discharge port discharges a part of the dust separated in the separation chamber. The accommodating portion stores the dust discharged from the discharge port. The reflux chamber is arranged side by side with the introduction portion and communicates with the upstream side of the separation chamber. The ventilation port communicates the accommodating part with the return chamber.

It is a perspective view which shows typically the flow of the dust-containing air of the vacuum cleaner of 1st Embodiment. It is a perspective view which shows typically the movement of the dust separated in the separation chamber of the vacuum cleaner. It is a top view which shows typically the flow of the dust-containing air of the electric vacuum cleaner. It is a top view which shows typically the movement of the dust separated in the separation chamber as above. It is explanatory drawing which shows typically the air passage composition of the same-mentioned electric vacuum cleaner. It is a perspective view which shows the electric vacuum cleaner as above. It is a perspective view which shows a part of the vacuum cleaner of 2nd Embodiment.

Hereinafter, the configuration of the first embodiment will be described with reference to the drawings.

In FIG. 6, 11 shows a vacuum cleaner. The vacuum cleaner 11 will be described by taking, for example, a so-called handheld vacuum cleaner that the user directly grips and uses.

The vacuum cleaner 11 includes a vacuum cleaner main body 12. Further, although not shown, the vacuum cleaner 11 includes a power supply unit. Further, the vacuum cleaner 11 includes an electric blower 14. Further, although not shown, the vacuum cleaner 11 includes a control unit. Further, the vacuum cleaner 11 includes a setting button 16 as a setting means (setting unit) which is a power switch. Further, the vacuum cleaner 11 may include a handle 17 gripped by the user. Further, the vacuum cleaner 11 includes a dust collector 18. Hereinafter, the vertical direction (arrows U and D directions), the front-back direction (arrows FR and RR directions), and the left-right directions (arrows L and R directions) will be described with reference to the usage state of the electric vacuum cleaner 11.

The vacuum cleaner main body 12 houses, for example, a power supply unit, an electric blower 14, a control unit, and the like. In the present embodiment, the vacuum cleaner main body 12 is formed in a longitudinal shape, for example, along the front-rear direction.

In the present embodiment, for example, a battery is used as the power supply unit. As this battery, for example, a replaceable primary battery or a secondary battery that can be repeatedly used by charging is used. Instead of the battery, a cord reel device including a power cord connected to an external power source such as a commercial AC power source can also be used.

The electric blower 14 operates by supplying power from the power supply unit, and this operation generates a negative pressure for sucking dust into the dust collecting unit 18. As the electric blower 14, an alternating current or a direct current can be used depending on the power supply unit. In the present embodiment, for example, a brushless motor fan is used as the electric blower 14.

The control unit operates by a power source generated by power supply from the power supply unit, and controls the operation of the electric blower 14 and the like. For this control unit, for example, a microcomputer is used.

The setting button 16 sets the on / off of the operation of the electric blower 14 or the strength (operation mode) of the suction force of the electric blower 14 in the control unit.

The handle 17 is arranged on the vacuum cleaner main body 12 in the present embodiment. The handle 17 is formed in a longitudinal shape, for example, along the front-rear direction. That is, the handle 17 is arranged along the longitudinal direction of the vacuum cleaner main body 12 in the present embodiment. The handle 17 has a thickness that can be gripped by the user and is formed so as to have a length that can be gripped. The handle 17 is not an indispensable configuration.

The dust collecting unit 18 separates and collects the dust sucked by the operation of the electric blower 14 from the air. The dust collecting unit 18 may be detachable from the vacuum cleaner main body 12. In the present embodiment, the dust collector 18 is arranged at the front end of the vacuum cleaner main body 12, but may be built in the vacuum cleaner main body 12, for example. The dust collecting unit 18 is roughly classified into a dust collecting unit main body 21 and a cover 22 as shown in FIG. Further, the dust collecting unit 18 includes a filter unit 23. The dust collecting unit main body 21 is provided with a suction cylinder 25 as shown in FIGS. 1 to 5. Further, the dust collecting unit main body 21 is provided with an outer wall 26. Further, the dust collecting unit main body 21 is provided with a bottom surface portion 27. Further, the dust collecting unit main body 21 is provided with a separation chamber 28. Further, the dust collecting unit main body 21 is provided with a reflux chamber 29. Further, the dust collecting unit main body 21 is provided with an introduction unit 30. Further, the dust collecting unit main body 21 is provided with a separation cover 31. Further, the dust collecting unit main body 21 is provided with a discharge port 32. Further, the dust collecting unit main body 21 is provided with a ventilation port 33. Therefore, the dust collector 18 includes a suction cylinder 25. Further, the dust collecting unit 18 includes an outer wall 26. Further, the dust collecting unit 18 includes a bottom surface portion 27. Further, the dust collecting unit 18 includes a separation chamber 28. Further, the dust collecting unit 18 includes a reflux chamber 29. Further, the dust collecting unit 18 includes an introduction unit 30. Further, the dust collector 18 includes a separation cover 31. Further, the dust collecting unit 18 includes a discharge port 32. Further, the dust collecting unit 18 is provided with a ventilation port 33. On the other hand, the cover 22 is arranged so as to cover the dust collecting unit main body 21. Therefore, a storage chamber 35, which is a storage unit, is formed between the dust collecting unit main body 21 and the cover 22. Further, the cover 22 is formed with a suction portion 36 separately from the storage chamber 35. Therefore, the dust collector 18 includes a storage chamber 35. Further, the dust collecting unit 18 includes a suction unit 36.

The dust collecting unit main body 21 has a function of separating a part of dust, that is, coarse dust which is a relatively large dust, from the dust-containing air. The coarse dust separated by the dust collecting unit main body 21 is discharged from the discharge port 32 to the storage chamber 35 and stored in the storage chamber 35. Further, in the dust collecting unit main body 21 of the present embodiment, the introduction unit 30, the separation chamber 28, the reflux chamber 29, and the accommodation chamber 35 are separated.

The suction cylinder 25 is the center of rotation of the dust-containing air in the dust collecting unit main body 21. The suction cylinder 25 is formed in a tubular shape, or in the present embodiment, in a cylindrical shape (including a substantially cylindrical shape). The suction cylinder 25 is arranged so as to have an axial direction along the vertical direction. The suction cylinder 25 is arranged at the center (including substantially the center) of the separation chamber 28 and the reflux chamber 29. Further, the suction cylinder 25 has an opening 41 which is a communication hole. Further, the suction cylinder 25 has a lap blocking portion 42.

The opening 41 is formed on the outer surface (outer peripheral surface) of the suction cylinder 25. A plurality of the openings 41 are formed. In the present embodiment, each opening 41 is formed in the shape of a long slit in the vertical direction. Further, these openings 41 are arranged at equal intervals (including substantially equal intervals) in the circumferential direction of the suction cylinder 25. These openings 41 are arranged over the entire circumferential direction of the suction cylinder 25. These openings 41 communicate with the suction side of the electric blower 14. In the present embodiment, these openings 41 communicate with the air passage portion 44 that communicates from the inside of the suction cylinder 25 to the upstream side of the filter portion 23. Therefore, these openings 41 communicate with the suction side of the electric blower 14 via the filter unit 23. Therefore, the negative pressure generated by the electric blower 14 acts from the inside (center axis C side) to the outside (separation chamber 28 and reflux chamber 29) of the suction cylinder 25 through these openings 41. Further, these openings 41 may also be formed in the lap blocking portion 42. In the lap blocking portion 42, the openings 41 are arranged at equal intervals (including substantially equal intervals).

The lap blocking unit 42 blocks the direct lap of the dust-containing air in the separation chamber 28 to the reflux chamber 29. That is, the circulation blocking portion 42 divides the separation chamber 28 and the reflux chamber 29. The lap blocking portion 42 is a lap blocking wall formed in a wall shape. The lap blocking portion 42 is formed so that a part of the suction cylinder 25 extends toward the right edge portion which is one edge portion of the discharge port 32. The lap blocking portion 42 is located at the front portion of the suction cylinder 25. In the present embodiment, the lap blocking portion 42 extends in the front-rear direction. Further, the lap blocking portion 42 is located on the side opposite to the downstream end side of the introduction portion 30 with respect to the central axis C of the suction cylinder 25. That is, the lap blocking portion 42 is located on the downstream end side of the separation chamber 28. Further, the end portion (front end portion) of the lap blocking portion 42 on the discharge port 32 side extends outward from the separation cover 31.

The air passage portion 44 communicates the separation chamber 28 and the reflux chamber 29 with the suction side of the electric blower 14. The air passage portion 44 is formed in the dust collecting portion main body 21 from the inside of the suction cylinder 25, passing through the lower part of the separation chamber 28 and the reflux chamber 29, and extending to the rear portion of the separation chamber 28, for example.

The outer wall 26 is located so as to surround the suction cylinder 25, and forms a separation chamber 28 with the suction cylinder 25. The outer wall 26 is located behind the suction cylinder 25, that is, away from the introduction portion 30. Further, the outer wall 26 is formed in a cylindrical surface shape. In the present embodiment, the outer wall 26 is formed in a substantially semi-cylindrical shape. Further, the outer wall 26 is formed in a coaxial shape (including a substantially coaxial shape) with respect to the suction cylinder 25. Further, the outer wall 26 is located from one side (left side) to the other side (right side) with respect to the suction cylinder 25. Further, the outer wall 26 is partially positioned so as to face the downstream end (rear end) of the introduction portion 30. Further, the upper end portion of the outer wall 26 is located below the upper end portion 25a of the suction cylinder 25.

The bottom surface portion 27 constitutes the bottom portion of the separation chamber 28. That is, the bottom surface portion 27 constitutes the lower edge portion of the discharge port 32. The bottom surface portion 27 is located below the lower end portion of the suction cylinder 25, and is arranged so as to surround the periphery of the suction cylinder 25. Therefore, the bottom surface portion 27 is formed in a curved shape along an arc. In the present embodiment, the bottom surface portion 27 is formed in a C shape, for example. Further, the bottom surface portion 27 is formed adjacent to the outer wall 26. That is, the outer wall 26 is formed by being raised from the position of the outer edge of the bottom surface portion 27. Further, the bottom surface portion 27 is continuous with the bottom surface of the introduction portion 30. Further, the bottom surface portion 27 is gradually inclined upward from the introduction portion 30, that is, the upstream side of the separation chamber 28 toward the discharge port 32 side, that is, the downstream side of the separation chamber 28.

The separation chamber 28 communicates with the suction side of the electric blower 14 to separate coarse dust from dust-containing air. The separation chamber 28 of the present embodiment is, for example, a small one having a diameter of about 5 to 10 cm. The separation chamber 28 is formed in a curved shape along an arc. In the present embodiment, the separation chamber 28 is formed in a C shape, for example. That is, the separation chamber 28 is formed so as to be folded back with respect to the introduction direction of the dust-containing air. The side portion of the separation chamber 28 is partitioned by the suction cylinder 25, the outer wall 26, and the separation cover 31, the lower portion is partitioned by the bottom surface portion 27 and the introduction portion 30, and the upper portion is partitioned by the separation cover 31. The bottom surface 27 of the separation chamber 28 is gradually inclined upward from the upstream side to the downstream side, so that the cross-sectional area of the air passage is gradually narrowed from the upstream side to the downstream side. It is configured in.

The return chamber 29 communicates the containment chamber 35 with the upstream side of the separation chamber 28. In other words, the recirculation chamber 29 recirculates the dust-containing air that has passed from the separation chamber 28 to the storage chamber 35 through the discharge port 32 from the storage chamber 35 to the separation chamber 28. The reflux chamber 29 is formed adjacent to the separation chamber 28 between the suction cylinder 25 and the separation cover 31. Therefore, the internal chamber 45 is composed of the reflux chamber 29 and the separation chamber 28. That is, the dust collecting unit 18 includes an inner chamber 45. The inner chamber 45 has a substantially circular shape in a plan view, and is formed between the separation cover 31 and the suction cylinder 25. Therefore, the inner chamber 45 includes a separation chamber 28 and a reflux chamber 29. Further, the reflux chamber 29 is divided into a side portion by a suction cylinder 25 and a right portion which is another side portion of the separation cover 31, a lower portion is partitioned by an introduction portion 30, and an upper portion is partitioned by a separation cover 31. .. The reflux chamber 29 communicates with the separation chamber 28 at a position on the upstream side of the separation chamber 28.

The introduction unit 30 introduces dust-containing air into the separation chamber 28. The introduction portion 30 is located in front of the separation chamber 28. Further, the introduction portion 30 is airtightly connected to the suction portion 36 with the cover 22 attached to the dust collecting portion main body 21. The introduction portion 30 is formed in a tubular shape (duct shape) extending along the tangential direction of the separation chamber 28. The introduction portion 30 has an introduction ceiling portion 30a which is a ceiling portion as an upper surface portion constituting the ceiling surface. The introduction unit 30 includes a suction port 46 and an introduction port 47.

The introduction ceiling portion 30a is arranged at a position lower than the ceiling portion of the separation chamber 28. In the introduction ceiling portion 30a, the front side, which is the upstream side of the introduction portion 30, protrudes in front of the reflux chamber 29, and the rear side, which is the downstream side of the introduction portion 30, extends to the separation chamber 28. The introduction ceiling portion 30a is arranged so as to cover the upper side of the dust-containing air between the reflux chamber 29 and the separation chamber 28. In other words, the introduction ceiling portion 30a forms the lower part of the reflux chamber 29. Further, the introduction ceiling portion 30a is covered above by a separation cover 31 at the position of the reflux chamber 29. That is, inside the separation cover 31, the portion on the other side opposite to the discharge port 32 of the suction cylinder 25, that is, the portion on the base end side (front side) of the introduction ceiling portion 30a on the right side side than the tip end (rear end). It is a reflux chamber 29.

The suction port 46 forms the upstream end of the introduction portion 30 and sucks dust-containing air. The suction port 46 is airtightly connected to the suction portion 36 with the cover 22 attached to the dust collecting portion main body 21.

The introduction port 47 forms the downstream end of the introduction portion 30 and introduces dust-containing air into the separation chamber 28. That is, the introduction port 47 forms the upstream end of the separation chamber 28. Therefore, in the inner chamber 45, the portion extending from the introduction port 47 to the discharge port 32 is partitioned as the separation chamber 28, and the other portion is partitioned as the reflux chamber 29.

The suction cylinder 25, the outer wall 26, the bottom surface portion 27, and the introduction portion 30 may be integrally formed, for example. In the present embodiment, the suction cylinder 25, the outer wall 26, the bottom surface portion 27, and the introduction portion 30 are integrated to form the main body portion 48.

The separation cover 31 covers at least a part around the suction cylinder 25 and partitions the ceiling portion and the side surface portion of the separation chamber 28 and the reflux chamber 29, and the discharge port 32. The separation cover 31 is made of, for example, a synthetic resin. Further, the separation cover 31 is formed in a covered cylindrical shape. That is, the separation cover 31 includes a top surface portion 31a. Further, the separation cover 31 includes a cylindrical side surface portion 31b. Further, the separation cover 31 includes a notch 31c that forms a part of the discharge port 32. Further, the separation cover 31 may be formed separately from the main body 48. In the present embodiment, the separation cover 31 may be pivotally supported with respect to the main body 48. That is, the separation cover 31 may include a shaft-mounted support portion 31d, which is a mounted portion.

The top surface portion 31a constitutes the ceiling portion of the separation chamber 28 and the reflux chamber 29. The top surface portion 31a is formed in the shape of a circular plate. The top surface portion 31a is located close to the upper end portion 25a of the suction cylinder 25, having a gap of, for example, 1 mm or less, and preferably in contact with the upper end portion 25a. Therefore, the size of the separation chamber 28 and the reflux chamber 29 in the vertical direction is defined by the height from the bottom surface portion 27 to the upper end portion 25a of the suction cylinder 25.

The side surface portion 31b is formed in a cylindrical surface shape, constitutes the outer peripheral side surface portion of the separation chamber 28 together with the outer wall 26, and constitutes the outer peripheral side surface portion of the reflux chamber 29 in front of the outer wall 26, that is, above the introduction ceiling portion 30a. Is. The side surface portion 31b is continuous with the upper part of the outer wall 26 to form a cylindrical surface flush with the outer wall 26 (including substantially flush surface). The side surface portion 31b is formed continuously with the outer peripheral edge of the top surface portion 31a.

The cutout portion 31c is formed by cutting out a position extending from the top surface portion 31a to the side surface portion 31b of the separation cover 31. The notch 31c forms the upper edge and both edges of the outlet 32. The notch 31c is formed on one side of the front side of the separation cover 31 by, for example, a virtual surface parallel to (including substantially parallel to) the axial direction of the separation cover 31 along the lap blocking portion 42 and a virtual surface intersecting the virtual surface. (Left front part) is cut out in a substantially L shape. This notch 31c is formed, for example, on the left side of the separation cover 31.

The shafted branch 31d is a portion to which the separation cover 31 is attached to the main body 48. In the present embodiment, the shafted support portion 31d rotates, for example, the separation cover 31 in the front-rear direction. The shafted support portion 31d is projected from the side surface portion 31b, for example, and is pivotally supported by the shaft support portion 49. The shaft support portion 49 can be formed at an arbitrary position of the main body portion 48. For example, in the present embodiment, the shaft support portion 49 is formed on the upper portion of the introduction portion 30 (introduction ceiling portion 30a).

The discharge port 32 discharges coarse dust, which is a part of the dust separated in the separation chamber 28, to the storage chamber 35. That is, the discharge port 32 is a boundary between the separation chamber 28 and the accommodation chamber 35. The discharge port 32 is partitioned by a circulation blocking portion 42, an outer wall 26, a notch 31c of the separation cover 31, and a bottom surface portion 27.

The ventilation port 33 communicates the accommodation chamber 35 with the upstream side (upstream side of the air flow of dust-containing air) from the accommodation chamber 35. In the present embodiment, the ventilation port 33 recirculates air from the accommodating chamber 35 to the upstream side of the separation chamber 28 located on the upstream side of the air flow of dust-containing air from the accommodating chamber 35 via the recirculation chamber 29. It is a thing. In the present embodiment, the ventilation port 33 is opened, for example, in the separation cover 31. More specifically, the ventilation port 33 is opened to the top surface portion 31a of the separation cover 31. Further, in the present embodiment, the ventilation openings 33 are formed as fine holes and have a plurality of openings. For example, each ventilation port 33 is formed in a round hole shape. The size of each ventilation port 33 is set to a size that, for example, coarse dust cannot pass through and fine dust (fine dust) as small as dust can pass through. In other words, the size of these ventilation ports 33 is formed so that the centrifugally separated coarse dust does not flow back into the reflux chamber 29, for example, a size of about 2 mm in diameter. These ventilation ports 33 are separated from each other at equal intervals (including substantially equal intervals). The ventilation port 33 communicates the accommodation chamber 35 and the reflux chamber 29. Therefore, the ventilation port 33 is arranged on the side of the suction cylinder 25 opposite to the discharge port 32. For example, the ventilation openings 33 are arranged in a row along the circumferential direction of the top surface portion 31a, and a plurality of the rows are formed in the radial direction of the top surface portion 31a.

The cover 22 shown in FIG. 5 is removable from the front end portion of the vacuum cleaner main body 12. The cover 22 covers the dust collecting unit main body 21. That is, the cover 22 covers the outside of the introduction portion 30 and the separation cover 31. Further, as shown in FIG. 6, the cover 22 is formed with a recess 51. The recess 51 is formed so that the user can pick the cover 22 from both sides when the cover 22 is removed from the vacuum cleaner main body 12 (dust collecting portion main body 21). That is, the recess 51 is formed, for example, on both side portions (only one of them is shown) of the cover 22.

The storage chamber 35 shown in FIG. 1 stores coarse dust, which is dust discharged from the discharge port 32. The accommodation chamber 35 is a space portion partitioned between the cover 22 and the separation chamber 28 (separation cover 31). Therefore, the introduction portion 30 and the separation cover 31 are located in the accommodation chamber 35. The storage chamber 35 is formed with the end portion (rear end portion) of the cover 22 as a waste opening. That is, the coarse dust contained in the storage chamber 35 can be disposed of to the outside from the end of the opened cover 22 by removing the cover 22 from the dust collecting portion main body 21.

The suction unit 36 is a main body suction port that sucks dust-containing air into the dust collection unit 18 (introduction unit 30). The suction portion 36 is located at the front end portion of the dust collecting portion 18. An air passage body such as an extension pipe or a suction port body (not shown) may be connected to the suction portion 36.

The filter unit 23 collects dust in the dust-containing air that has not been separated in the separation chamber 28, that is, fine dust that is relatively small dust. The filter unit 23 is located in the dust collecting unit 18 on the downstream side of the separation chamber 28 and the reflux chamber 29. In the present embodiment, the filter portion 23 is removable from the downstream end of the air passage portion 44 (FIG. 5). Further, the filter unit 23 includes a seal member 54 in the present embodiment. The sealing member 54 is configured to seal the peripheral edge portion of the filter portion 23 with respect to the air passage portion 44 (FIG. 5) and to be pressed against the inner surface of the cover 22 to close the gap. That is, the seal member 54 has a function of sealing the storage chamber 35. The filter portion 23 can be arranged at an arbitrary position in the air passage portion 44 (FIG. 5), for example, the opening 41 of the suction cylinder 25.

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

First, the outline of the cleaning operation by the vacuum cleaner 11 will be described. In the vacuum cleaner 11, the control unit operates the electric blower 14 by operating the setting button 16 in a state where power can be supplied from the power supply unit. Due to the negative pressure generated by the operation of the electric blower 14, the dust is sucked into the dust collecting unit 18 together with the air. Therefore, the user grips the handle 17 and carries the vacuum cleaner 11 to a desired position, and sucks the dust on the surface to be cleaned such as the floor surface into the dust collecting unit 18. Then, the dust sucked into the dust collecting unit 18 is separated by the dust collecting unit main body 21 and collected in the storage chamber 35 and also collected by the filter unit 23. The air from which the dust is separated is further sucked into the electric blower 14, cools the electric blower 14, and then discharged.

More specifically, the negative pressure generated by the operation of the electric blower 14 acts on the filter unit 23, the air passage unit 44, the separation chamber 28, the introduction unit 30, and the suction unit 36. Therefore, dust is sucked from the suction portion 36 together with the air. The dust-containing air sucked from the suction unit 36 is introduced from the suction port 46 of the introduction unit 30 to the separation chamber 28 and from the introduction port 47 along the tangential direction of the separation chamber 28.

Then, in the separation chamber 28, the dust-containing air basically swirls and flows around the suction cylinder 25 along the inner surface of the outer wall 26 and the side surface portion 31b of the separation cover 31, and a part of each of them flows. It is sucked into the opening 41 (arrow A1 in FIGS. 1 and 3), and the remaining other part passes from the discharge port 32 to the accommodation chamber 35 and then returns from the ventilation port 33 to the return chamber 29 (FIG. 1). , Arrow A2) in FIG. 3, rejoining in the separation chamber 28 communicating with the reflux chamber 29. Therefore, the relatively heavy coarse dust in the dust-containing air is separated from the air flow by the centrifugal force when swirling around the separation chamber 28, and the coarse dust that reaches the discharge port 32 is separated from the storage chamber 35 from the storage chamber 35. It is drawn into the containment chamber 35 by the dust-containing air returning to the ventilation port 33, and is separated and collected in the containment chamber 35 without accumulating near the discharge port 32 (arrows A3 in FIGS. 2 and 4). At this time, the dust-containing air is throttled by the inclination of the bottom surface 27 of the separation chamber 28 and flows while maintaining the flow velocity, so that the coarse dust is introduced from the discharge port 32 into the storage chamber 35 without reducing the speed. Will be done. Further, the dust-containing air in the separation chamber 28 is regulated by the lap blocking portion 42 so as to flow into the accommodation chamber 35 without making one or more laps around the suction cylinder 25, so that coarse dust can flow into the suction cylinder 25. It is immediately put into the storage chamber 35 without going around the circumference of the suction cylinder 25 many times, and it is difficult to stick to the circumference of the suction cylinder 25 and to close the opening 41.

In this way, the coarse dust basically flows from the introduction port 47 toward the discharge port 32 side, so that the position of the suction cylinder 25 from the introduction port 47 to the discharge port 32 side, that is, in the present embodiment, is the suction cylinder 25. It will pass from the rear side to the left side position. Therefore, compared to the (one) opening 41a located in the separation chamber 28 from the rear side to the left side of the suction cylinder 25, coarse dust basically does not pass through, and the side opposite to the discharge port 32 side with respect to the introduction port 47. The (other) opening 41b (opening 41b facing the introduction ceiling 30a) located in the reflux chamber 29 on the right side of the suction cylinder 25 is more difficult for coarse dust to adhere. Therefore, even if the opening 41a is clogged due to the adhesion of dust, the opening 41b is still less likely to be clogged. Therefore, more dust-containing air is sucked from these openings 41b. Furthermore, suction can be sustained.

Then, the fine dust contained in the air sucked into the opening 41 and not separated by the separation chamber 28 is collected by the filter unit 23 when the air passes through the air passage portion 44, so that the dust is abbreviated. All dust is separated and collected.

The air in which the dust is separated and collected is sucked into the electric blower 14, cools the heat-generating member such as the electric blower 14, and then discharged to the outside of the vacuum cleaner main body 12.

When the cleaning is completed, the control unit stops the electric blower 14 by operating the setting button 16. The dust collected in the storage chamber 35 of the dust collecting unit 18 and the filter unit 23 can be disposed of as needed by removing the dust collecting unit 18 from the vacuum cleaner main body 12 and removing the cover 22 and the filter unit 23.

As described above, according to the first embodiment, since the accommodation chamber 35 and the reflux chamber 29 on the upstream side of the accommodation chamber 35 are communicated with each other by the ventilation port 33, the separation chamber 28 to the accommodation chamber 35 The dust-containing air returns to the return chamber 29 through the air. Therefore, the dust that has moved from the separation chamber 28 to the discharge port 32 due to the airflow returning from the storage chamber 35 through the ventilation port 33 is effectively discharged into the storage chamber 35, so that the opening 41 of the suction cylinder 25 Dust does not easily adhere to the air, and the suction force can be maintained without flowing the dust separated in the storage chamber 35 to the downstream side.

Further, the ventilation port 33 recirculates air to a position close to the opening 41 of the suction cylinder 25, for example, a side portion of the suction cylinder 25 opposite to the discharge port 32, that is, toward the upstream side of the air flow of dust-containing air. Therefore, the wind speed can be secured, and the dust separated in the separation chamber 28 can be drawn into the storage chamber 35 more efficiently.

Next, the second embodiment will be described with reference to FIG. The same components and operations as those in the first embodiment are designated by the same reference numerals, and the description thereof will be omitted.

In this second embodiment, the ventilation port 33 of the first embodiment is formed in the introduction portion 30. That is, the ventilation port 33 communicates the accommodation chamber 35 with the introduction portion 30 on the upstream side of the accommodation chamber 35.

A plurality of ventilation ports 33 are formed at positions outward (front) of the separation cover 31 of the introduction portion 30. For example, a plurality of ventilation ports 33 are formed on the upper portion of the introduction portion 30 and on one side portion, that is, the left side portion on the discharge port 32 side. Therefore, these ventilation ports 33 communicate the accommodation chamber 35 with the outside of the inner chamber 45. Further, these ventilation ports 33 are formed so as to communicate with the position of the introduction portion 30 on the downstream side of the suction port 46 and on the upstream side of the introduction port 47. In this embodiment, the reflux chamber 29 is not an essential configuration.

Then, the negative pressure generated by the operation of the electric blower 14 acts on the filter unit 23, the air passage unit 44, the separation chamber 28, the introduction unit 30, and the suction unit 36. Therefore, dust is sucked from the suction portion 36 together with the air. The dust-containing air sucked from the suction unit 36 is introduced from the suction port 46 of the introduction unit 30 to the separation chamber 28 and from the introduction port 47 along the tangential direction of the separation chamber 28. In the separation chamber 28, the dust-containing air basically swirls and flows around the suction cylinder 25 along the inner surface of the outer wall 26 and the side surface portion 31b of the separation cover 31, and a part of each opening. It is sucked into 41, and the rest of the rest passes from the discharge port 32 to the containment chamber 35, then returns from the ventilation port 33 to the introduction section 30, and is reintroduced from this introduction section 30 into the separation chamber 28. .. Therefore, the relatively heavy coarse dust in the dust-containing air is separated from the air flow by the centrifugal force when swirling around the separation chamber 28, and the coarse dust that reaches the discharge port 32 is separated from the storage chamber 35 from the storage chamber 35. It is drawn into the containment chamber 35 by the dust-containing air that returns to the ventilation port 33, and is separated and collected in the containment chamber 35 without accumulating near the discharge port 32.

In this way, since the accommodation chamber 35 and the introduction portion 30 on the upstream side of the accommodation chamber 35 are communicated with each other by the ventilation port 33, dust-containing air is communicated from the separation chamber 28 to the introduction portion 30 via the accommodation chamber 35. Circulates. Therefore, the dust that has moved from the separation chamber 28 to the discharge port 32 is effectively discharged into the storage chamber 35 by the airflow that flows back from the storage chamber 35 through the ventilation port 33, so that the opening 41 of the suction cylinder 25 Dust does not easily adhere to the air, and the suction force can be maintained without flowing the dust separated in the storage chamber 35 to the downstream side.

Further, since the ventilation port 33 recirculates the air to a position away from the separation chamber 28, specifically to a position outside the inner chamber 45, the air flow of the separation chamber 28 is less likely to be disturbed by this recirculation, and the separation chamber 28 is less likely to be disturbed. It is difficult to reduce the separation performance at.

In each of the above embodiments, the vacuum cleaner 11 is a canister type vacuum cleaner in which the user pulls the vacuum cleaner 11 and runs the vacuum cleaner on the floor to clean the vacuum cleaner. It can be used for various types of vacuum cleaners 11, such as a type or a robot type that runs autonomously (self-propelled).

According to at least one embodiment described above, the accommodation chamber 35 separated by the separation chamber 28 and accommodating the dust discharged from the discharge port 32 and the upstream side of the accommodation chamber 35 communicate with each other by the ventilation port 33. As a result, the dust-containing air returns from the separation chamber 28 to the upstream side of the containment chamber 35 via the containment chamber 35. Therefore, the dust that has moved from the separation chamber 28 to the discharge port 32 is effectively discharged into the storage chamber 35 by the airflow that flows back from the storage chamber 35 through the ventilation port 33, so that the opening 41 of the suction cylinder 25 Dust does not easily adhere to the air, and the suction force can be maintained without flowing the dust separated in the storage chamber 35 to the downstream side.

As a result, it is necessary to separately provide a filter or the like for collecting dust from the accommodating chamber 35 to the downstream side thereof, for example, when dust-containing air is flowed from the accommodating chamber 35 to the downstream side thereof. Therefore, the configuration can be simplified, maintenance such as removal of dust adhering to the filter is not required, maintenance can be improved, and the sustainability of the suction force due to clogging of the filter does not decrease.

Further, by making the ventilation port 33 a fine hole, it is possible to prevent coarse dust from returning from the storage chamber 35 to the upstream side of the storage chamber 35 through the ventilation port 33, and if it is fine dust, it can be prevented. Since it can pass through the ventilation port 33, the ventilation port 33 is less likely to be blocked by fine dust, and the return of air from the accommodation chamber 35 to the upstream side of the accommodation chamber 35 due to the clogging of the ventilation port 33 is suppressed. The configuration can be formed inexpensively.

Although some embodiments of the present invention have been described, these embodiments are presented as examples and are not intended to limit the scope of the invention. These novel embodiments can be implemented in various other embodiments, and various omissions, replacements, and changes can be made without departing from the gist of the invention. These embodiments and modifications thereof are included in the scope and gist of the invention, and are also included in the scope of the invention described in the claims and the equivalent scope thereof.

11 vacuum cleaner
14 Electric blower
18 Dust collector
25 suction tube
28 Separation room
29 Reflux chamber
30 Introduction
32 outlet
33 Ventilation port
35 Containment room
41 opening
47 Introductory port

Claims (4)

It is an electric vacuum cleaner provided with an electric blower and a dust collecting unit that separates and collects dust sucked by the operation of the electric blower from the air.
The dust collector
A suction cylinder that is formed in a tubular shape with an opening and in which the negative pressure generated by the electric blower acts from the inside to the outside through the opening.
A separation chamber formed around the suction cylinder to separate dust, and
An introduction section having an introduction port on the downstream side for introducing dust-containing air into this separation chamber,
A discharge port that discharges a part of the dust separated in the separation chamber, and
A storage unit that stores dust discharged from this discharge port,
A reflux chamber, which is arranged side by side with the introduction portion and communicates with the upstream side of the separation chamber,
A vacuum cleaner characterized by having a ventilation port that communicates the accommodating portion and the reflux chamber. The vacuum cleaner according to claim 1, wherein the ventilation port communicates the accommodating portion and the introduction portion. Reflux chamber, vacuum cleaner according to claim 1 wherein characterized in that communicating with the separation chamber disposed on a portion of the periphery of the suction tube. The vacuum cleaner according to any one of claims 1 to 3, wherein the ventilation port is formed of a plurality of fine holes.

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