JP2019092807A - Vacuum cleaner - Google Patents

Abstract

To provide a vacuum cleaner capable of suppressing collected dust from flying up when removing and disposing of tissue paper held as a filter in a dust collection part.SOLUTION: A vacuum cleaner includes an electric blower 9 and a dust collection part 10. The electric blower 9 generates air current. The dust collection part 10 has at least one air course cylinder 19 for holding tissue paper T as a filter for collecting dust. A long side of the tissue paper T is wound around an outside surface at an upstream side of the air course cylinder 19, and an opposite side thereto is folded from an opening 19a of the air course cylinder 19 to the inside of the air course cylinder 19 so as to hold the tissue paper T as a filter inside the air course cylinder 19. The inside surface of the air course cylinder 19 is provided with a plurality of ribs 24 for forming a space between the tissue paper T.SELECTED DRAWING: Figure 2

Description

  The present invention relates to a vacuum cleaner.

  Patent Document 1 describes an example of a vacuum cleaner. The vacuum cleaner includes an electric blower and a dust collection unit. The dust collection unit includes a dust box that holds tissue paper in the dust collection unit. In the vacuum cleaner, dust collected from the outside by the air flow generated by the electric blower is collected by the dust collection unit.

Unexamined-Japanese-Patent No. 2005-224391

  However, in the vacuum cleaner of Patent Document 1, when the tissue paper is removed for disposal, the shape of the held tissue paper is not maintained. For this reason, the dust collected on the tissue paper may fly up due to the deformation of the tissue paper.

  The present invention has been made to solve such problems. An object of the present invention is to provide an electric vacuum cleaner capable of suppressing soaking of collected dust when removing and disposing of a tissue paper held in a dust collection unit.

  In the electric vacuum cleaner according to the present invention, an electric blower for generating an air flow, and a first side of dust attracted from the outside by the air flow is wound around the upstream outer surface of the air flow and is opposite to the first side. A dust collection unit for collecting tissue paper which is folded inside the opening on the upstream side of the air flow through the two or more air passage cylinders, each of which holds the filter as a filter; Each of the tubes comprises a plurality of ribs on the inner side to form a space between the tissue and the tissue.

  According to the present invention, the vacuum cleaner comprises an electric blower and a dust collection unit. The electric blower generates an air flow. In the dust collection section, the first side of the dust sucked from the outside by the air flow is wound on the outer surface on the upstream side of the air flow, and the second side which is the opposite side of the first side is the opening of the upstream side of the air flow. The tissue paper folded inside is collected through one or more air ducts, each of which is held as a filter. Each of the one or more air ducts comprises a plurality of ribs on the inner side to form a space between the tissue and the tissue. Thereby, when removing and discarding the tissue paper currently hold | maintained at the dust collection part, the vacuum cleaner can suppress that the collected dusts soar.

1 is a perspective view of a vacuum cleaner according to Embodiment 1. FIG. FIG. 2 is a top cross-sectional view of the cleaner body according to Embodiment 1; FIG. 2 is a perspective view of a dust collection unit according to the first embodiment. FIG. 2 is a front view of a dust collection unit according to Embodiment 1; 5 is a rear perspective view of the dust collection unit according to Embodiment 1. FIG. FIG. 2 is a perspective view of a dust collection unit according to the first embodiment. FIG. 2 is a perspective view of a dust collection unit according to the first embodiment. FIG. 2 is a perspective view of a dust collection unit according to the first embodiment. FIG. 2 is a perspective view of a dust collection unit according to the first embodiment. FIG. 2 is a perspective view of a dust collection unit according to the first embodiment. FIG. 2 is a perspective view of a dust collection unit according to the first embodiment. 7 is a perspective view of a dust collection unit according to Embodiment 2. FIG. FIG. 7 is a top cross-sectional view of a vacuum cleaner main body according to a second embodiment. FIG. 7 is a top cross-sectional view of a vacuum cleaner main body according to a second embodiment. FIG. 16 is a perspective view of a dust collection unit according to a third embodiment. FIG. 16 is a perspective view of a dust collection unit according to a third embodiment. FIG. 10 is a perspective view of an air passage cylinder according to a third embodiment. FIG. 20 is a perspective view of a cylindrical unit according to Embodiment 3. FIG. 20 is a perspective view of a cylindrical unit according to Embodiment 3. FIG. 10 is a top cross-sectional view of a vacuum cleaner main body according to a third embodiment. FIG. 20 is a perspective view of a cylindrical unit according to Embodiment 3.

  DETAILED DESCRIPTION OF THE INVENTION Embodiments of the present invention will be described with reference to the attached drawings. In the drawings, the same or corresponding parts are denoted by the same reference numerals, and overlapping descriptions will be appropriately simplified or omitted.

Embodiment 1
The structure of the vacuum cleaner which concerns on Embodiment 1 is demonstrated using FIG.
FIG. 1 is a perspective view of a vacuum cleaner according to the present embodiment.

  The vacuum cleaner 1 includes a vacuum cleaner body 2, a hose 3, a connection pipe 4, and a cleaning tool 5.

  The vacuum cleaner body 2 has an openable main body lid 6 at the top. The cleaner body 2 has an inlet 7 at the front end, which is an opening. The vacuum cleaner body 2 has an exhaust port 8 which is an opening at the rear end.

  The cleaner body 2 includes an electric blower 9, a dust collection unit 10, and a notification unit 11.

  The electric blower 9 is disposed forward of the exhaust port 8. The electric blower 9 is disposed at the rear of the cleaner body 2. The electric blower 9 is configured to be capable of generating an air flow for suctioning dust from the outside.

  The dust collection unit 10 is disposed rearward of the intake port 7. The dust collection unit 10 is disposed forward of the electric blower 9. The dust collection unit 10 is configured to be able to hold tissue paper as a filter.

  The hose 3 is a tubular member having flexibility by means of bellows. The hose 3 is connected to a front end having an inlet 7 of the cleaner body 2 at one end.

  The connection pipe 4 is a bent hollow cylindrical member. The connection pipe 4 is connected to an end not connected to the inlet 7 of the hose 3 at one end. The connection pipe 4 comprises a handle 12.

  The handle 12 is provided with an operation switch for operating the vacuum cleaner 1.

  The cleaning tool 5 has an air inlet (not shown) on the bottom surface. The cleaning tool 5 is provided with a connecting portion in which the air inlet and the space communicate with each other. The cleaning tool 5 is connected at the connection to the end of the connection pipe 4 not connected to the hose 3.

  The notification unit 11 is configured to notify the user that the air pressure in the space provided between the electric blower 9 and the dust collection unit 10 has decreased. The notification unit 11 includes, for example, an LED (Light Emitting Diode) disposed on the upper surface of the cleaner body 2.

  When the user uses the vacuum cleaner 1, the user holds the handle 12 to operate the vacuum cleaner 1. The user causes the bottom surface of the cleaning tool 5 to face a surface to be cleaned such as a floor surface. The user starts the operation of the vacuum cleaner 1 by the operation switch provided on the handle 12. That is, the user starts the operation of generating the air flow of the electric blower 9.

  The air flow generated by the electric blower 9 is sucked from the air inlet of the cleaning tool 5 together with dust on the surface to be cleaned. The air flow generated by the electric blower 9 passes through the inside of the cleaning tool 5, the connection pipe 4 and the hose 3 in this order and flows into the dust collection unit 10 from the air inlet 7. The front of the cleaner body 2 is the upstream side of the air flow generated by the electric blower 9.

  The dust sucked with the air flow generated by the electric blower 9 passes through the inside of the cleaning tool 5, the connection pipe 4 and the hose 3 in this order and flows into the dust collection unit 10 from the air inlet 7. The dust sucked with the air flow generated by the electric blower 9 is collected on the tissue paper held as a filter in the dust collection unit 10.

  The air flow that has flowed into the dust collection unit 10 is sucked by the electric blower 9 as air from which dust is separated by collection. The air from which dust has been separated is delivered from the exhaust port 8 by the electric blower 9. The rear of the cleaner body 2 is the downstream side of the air flow generated by the electric blower 9.

Then, the structure of the cleaner body 2 which concerns on Embodiment 1 is demonstrated using FIG.
FIG. 2 is a top cross-sectional view of the cleaner body according to the present embodiment. In FIG. 2, the front of the cleaner body 2 is in the left direction on the paper surface.

  The cleaner body 2 includes a support member 13, a dust collection unit mounting unit 14, and a detection unit 15.

  The support member 13 is formed of, for example, rubber or soft resin.

  The electric blower 9 is disposed behind the support member 13. The electric blower 9 is fixed to the cleaner body 2 by the support member 13.

  The dust collecting portion mounting portion 14 is provided rearward of the air intake port 7 and forward of the electric blower 9. The internal space of the dust collecting portion mounting portion 14 communicates with the air intake port 7.

  The dust collection unit 10 is detachably provided to the dust collection unit mounting unit 14. The dust collection unit 10 is disposed such that the air flowing from the intake port 7 to the electric blower 9 can pass through the dust collection unit 10 in a state where the dust collection unit 10 is mounted on the dust collection unit mounting unit 14.

  The vacuum cleaner body 2 has a space 16. The space 16 is an air passage provided between the dust collection unit 10 and the electric blower 9. The space 16 is provided by the support member 13 so as to ensure airtightness between the dust collection unit 10 and the electric blower.

  The detection unit 15 is provided to be able to detect a decrease in air pressure in the space 16. The detection unit 15 includes, for example, a barometer provided in the space 16.

  The notification unit 11 is connected to the detection unit 15 so as to be able to receive a signal representing a decrease in air pressure in the space 16 detected by the detection unit 15.

Then, the structure of the dust collection part 10 which concerns on Embodiment 1 is demonstrated using FIGS. 3-5.
FIG. 3 is a perspective view of the dust collection unit according to the present embodiment. FIG. 4 is a front view of the dust collection unit according to the present embodiment. FIG. 5 is a rear perspective view of the dust collection unit according to the present embodiment.

  The dust collection unit 10 includes a dust box 17 and an opening cover 18.

  The dust box 17 is a structure made of, for example, a resin. The dust box 17 includes an air passage cylinder 19, a filter holding unit 20, a connecting unit 21, and a knob 22.

  The air passage tube 19 is a cylindrical body having an opening 19a and having a length of 60 mm in the front-rear direction. The opening 19a of the air passage tube 19 has an outer diameter of 50 mm and an inner diameter of 46 mm. The cross-sectional area of the air duct 19 in a plane perpendicular to the central axis is about 2000 square millimeters.

  The filter holding portion 20 has a rectangular parallelepiped shape having an opening at the rear.

  The connecting portion 21 connects between the air passage cylinder 19 and the filter holding portion 20.

  The knob 22 is integrally provided on the top of the filter holder 20. The knob 22 protrudes from the upper surface of the filter holding unit 20.

  The opening cover 18 is configured to be removable from the opening 19 a of the air passage cylinder 19. The opening cover 18 covers the outer surface of the air passage cylinder 19 from the opening 19 a in a state of being mounted on the air passage cylinder 19. The opening cover 18 covers the outer peripheral portion of the opening 19 a in a state of being mounted on the air passage cylinder 19. The opening cover 18 has an inner diameter of 52 mm in the side peripheral portion 18a. The opening cover 18 has a length of 30 mm in the front-rear direction of the side peripheral portion 18 a. The opening cover 18 includes a sealing member 23.

  The seal member 23 is formed of a flexible material such as rubber or soft resin, for example. The seal member 23 is disposed from the front surface to the rear surface of the portion of the opening cover 18 covering the outer peripheral portion of the opening 19 a of the air passage cylinder 19. The seal member 23 is provided on the front surface of the opening cover 18 so as to ensure airtightness between the dust collection portion mounting portion 14 and the opening cover 18. The sealing member 23 is provided on the rear surface of the opening cover 18 so as to ensure the airtightness between the opening cover 18 and the air passage cylinder 19. The outer diameter of the seal member 23 is adjusted so that the seal member 23 is compressed when the dust box 17 is mounted on the dust collection portion mounting portion 14 and air tightness of the air passage can be secured.

  As shown in FIG. 4, the air passage cylinder 19 includes a plurality of ribs 24 on the inner surface.

  The twelve ribs 24 are arranged at equal intervals in the circumferential direction around the axis of the air passage cylinder 19. The rib 24 protrudes from the inner surface of the air passage cylinder 19 toward the central axis of the air passage cylinder 19. The height of the rib 24 projecting from the inner surface of the air passage tube 19 is configured such that the side closer to the opening 19a is lower than the side closer to the opposite end 19b. The height of the rib 24 projecting from the inner surface of the air passage tube 19 is 5 mm at the highest portion.

  As shown in FIG. 5, the air passage cylinder 19 includes a guard body 25 connecting the ribs 24.

  The guard body 25 connects four of the twelve ribs 24 arranged in the circumferential direction every other sheet on the central axis of the air passage cylinder 19. The guard body 25 connects the ribs 24 at the rear end 19 b of the air passage cylinder 19.

  The dust collection unit 10 includes a fine dust filter 26.

  The fine dust filter 26 is accommodated in the filter holding unit 20. The fine dust filter 26 includes a filter frame 27 and a filter medium 28.

  The filter frame 27 is formed of resin. The filter frame 27 is a rectangular frame of a size that can be accommodated from the opening at the rear of the filter holder 20. The filter frame 27 has a cross-sectional area in a plane parallel to the rear opening of approximately 5200 square millimeters.

  The filter medium 28 has a pleated structure. The filter media 28 is attached to the inside of the filter frame 27. The filter media 28 is formed of a filter media having high repair efficiency. The filter medium 28 is, for example, a polymer medium, a High Efficiency Particulate Air (HEPA) medium, or an Ultra Low Penetration Air (ULPA) medium.

  The dust box 17 has a connection space 29 inside the connection portion 21. The connection space 29 is configured such that the cross-sectional area in a plane perpendicular to the central axis continuously increases from the front to the rear.

Then, operation | movement of the vacuum cleaner 1 is demonstrated using FIGS. 6-11.
6 to 11 are perspective views of the dust collection unit according to the present embodiment.

  The user mounts the tissue paper on the air passage cylinder 19 of the dust box 17 before starting the operation of the vacuum cleaner 1.

  Many of the commonly used tissue papers are rectangular with a long side of 200 to 220 mm and a short side of 160 to 210 mm. Below, the case where a user mounts | wears the dust box 17 with the tissue paper T whose long side Ta is 210 mm and whose short side Tb is 190 mm as an example is demonstrated. The long side Ta is an example of the first side of the tissue paper T. The long side Tc which is the opposite side of the long side Ta is an example of the second side of the tissue paper T.

  First, as shown in FIG. 6, the user applies the long side Ta, which is one side of the tissue paper T, along the outer surface of the air passage cylinder 19. The user places the long side Ta of the tissue paper T on the rear side about 30 mm from the opening 19a. A portion from the long side Ta of the tissue paper T to the position of the opening 19a is referred to as a contact portion Td.

  Next, as shown in FIG. 7, the user wraps the tissue T on the outer surface of the air passage tube 19. Since the length of the outer surface of the opening 19a is shorter than the length of the long side of the tissue paper T, the user overlaps the winding start end and the winding end end of the tissue paper T. The portion where the ends of the tissue paper T overlap is referred to as an overlapping portion Te.

  The circumferential width of the overlapping portion Te is about 50 mm because the circumferential length of the outer surface of the opening 19a is about 160 mm. The tissue paper T is in the state of a cylinder whose length is the length of the short side Tb, with the long side Tc as the front end. The length from the long side Tc of the tissue paper T, which is a portion on the front side of the opening 19a to the opening 19a, is the length from the short side Tb to the axial length of the air passage tube 19 of the abutting portion Td. The difference is about 160 mm.

  Next, as shown in FIG. 8, the user pushes the portion including the long side Tc in the forward direction of the opening 19a of the tissue paper T from inside the opening 19a while folding it. At this time, the user holds the contact portion Td so that the tissue paper T does not come off the air passage cylinder 19.

  Next, as shown in FIG. 9, the portion of the tissue paper T in the forward direction of the opening 19 a is pushed into the air passage cylinder 19. Since the air passage tube 19 has a length of 60 mm in the front-rear direction, the air passage tube 19 is configured to be shorter than the length 160 mm of the portion on the front side of the opening 19a of the tissue paper T. For this reason, a surplus portion of about 100 millimeters of the portion in the forward direction of the opening 19a of the tissue paper T is folded at the rear end 19b inside the air passage cylinder 19.

  The tissue paper T is supported by a plurality of ribs 24 provided on the inner surface of the air passage cylinder 19 such that a space is formed between the tissue paper T and the inner surface of the air passage cylinder 19. The guard body 25 supports the folded portion at the downstream end 19 b of the tissue paper T. The tissue paper T forms a cup-like filter in which the cross-sectional area decreases in the air passage cylinder 19 from the opening 19a side to the downstream side due to the change in the height of the rib 24.

  Next, as shown in FIG. 10, the user mounts the opening cover 18 so as to cover the tissue paper T mounted on the air passage cylinder 19. The side peripheral portion 18 a of the opening cover 18 covers the contact portion Td of the tissue paper T. The tissue paper T mounted by the above procedure is held by the air passage cylinder 19 as a cup-shaped filter.

  The user mounts the opening cover 18 in the dust box 17 on which the tissue paper T is mounted. The dust box 17 to which the opening cover 18 is attached constitutes the dust collection unit 10. The user mounts the dust collection unit 10 on the dust collection unit mounting unit 14 by holding the knob 22 from the upper part of the cleaner body 2 with the main body lid 6 opened. The user closes the main body lid 6.

  When the dust collection unit 10 to which the tissue paper T is mounted is mounted on the dust collection unit mounting unit 14, the seal member 23 provided on the front side is in contact with the dust collection unit mounting unit 14 to open from the air inlet 7 Ensuring air tightness leading to the cover 18. Since the seal member 23 provided on the rear side is formed of a flexible material, it adheres to the overlapping portion of the tissue paper T and irregular wrinkles and the like. The seal member 23 provided on the rear side ensures airtightness of the air passage from the opening cover 18 to the air passage cylinder 19 by sandwiching the tissue paper T.

  The user starts the operation of the vacuum cleaner 1. The air flow generated by the electric blower 9 flows into the dust collection unit 10 together with dust.

  The air flow that has flowed into the dust collection unit 10 passes through the space formed between the tissue paper T and the inner surface of the air passage cylinder 19 by the plurality of ribs 24, and the wind of the tissue paper T including the side surface formed in a cup shape. It passes through the entire surface inside the road cylinder 19.

  The tissue paper T including the cup-shaped side face has the largest volume in the space restricted by the plurality of ribs 24 when it receives force by the passing air flow. That is, when the tissue paper T is attached to the air passage cylinder 19 before the operation of the vacuum cleaner 1, the vacuum cleaner 1 does not contact the plurality of ribs 24 or the guard body 25 sufficiently. When the air flow passes after the operation, the plurality of ribs 24 and the guard body 25 are in close contact. Therefore, when the user mounts the tissue paper T on the air passage cylinder 19, the tissue paper T can be driven by the operation of the vacuum cleaner 1 even if the long side Tc of the tissue paper T is not firmly pushed into the air passage cylinder 19. It is shaped like a cup.

  The dust that has flowed into the dust collection unit 10 is collected by the tissue paper T formed as a cup-shaped filter held by the air passage cylinder 19. Most of the dust that has flowed into the dust collection unit 10 is guided by the air flow to the bottom surface of the cup-shaped filter formed by the tissue paper T and collected. Since the bottom surface is a folded portion of the tissue paper T, the folded tissue portion collects dust as a plurality of filters. The guard body 25 holds the tissue paper T inside the air passage cylinder 19 so as to prevent the end of the tissue paper T from flowing downstream by the air flow flowing through the air passage cylinder 19.

  Fine dust of about several micrometers in diameter can pass through the air ducts 19 together with the air flow without being collected by the tissue paper T. Fine dust having passed through the air passage tube 19 flows into the filter holding portion 20 together with the air flow via the connection space 29.

  The fine dust that has flowed into the filter holding unit 20 is collected by the fine dust filter 26.

  The air flow that has flowed into the filter holding unit 20 is sucked by the electric blower 9 as air from which dust is separated by collection. The air from which dust has been separated is delivered from the exhaust port 8 by the electric blower 9.

  In the space 16, when dust collected on the tissue paper T or the fine dust filter 26 is accumulated by the operation of the vacuum cleaner 1, the air pressure during the operation of the vacuum cleaner 1 decreases. When the air pressure in the space 16 becomes equal to or less than a predetermined value, the detection unit 15 transmits a signal representing a decrease in the air pressure in the space 16 to the notification unit 11. When the notification unit 11 receives a signal from the detection unit 15, the notification unit 11 notifies the user that the air pressure in the space 16 has decreased by turning on the LED disposed on the upper surface of the cleaner body 2. That is, the notification unit 11 notifies the user that the dust collected on the tissue paper T or the fine dust filter 26 is accumulated.

  After the user cleans the surface to be cleaned by sucking the dust, the user ends the operation of generating the air flow of the electric blower 9 by the operation switch.

  The user opens the main body lid 6. The user holds the knob 22 and takes out the dust collection unit 10 from the dust collection unit mounting unit 14.

  Next, as shown in FIG. 11, the user removes the opening cover 18 and the cup-like tissue paper T from the dust box 17 in this order. The user removes the cup-like tissue paper T by holding the contact portion Td and pulling it out of the air passage cylinder 19. The user discards the removed tissue paper T together with the collected dust.

  As explained above, the vacuum cleaner 1 which concerns on this Embodiment is provided with the electric blower 9 and the dust collection part 10. As shown in FIG. The electric blower 9 generates an air flow. The dust collection unit 10 collects dust, which is sucked from the outside by an air flow, through one or more air passage cylinders 19 that hold the tissue paper T as a filter. In the tissue paper T, the long side Ta is wound on the outer surface on the upstream side of the air flow, and Tc, which is the opposite side of the long side Ta, is folded inside the opening on the upstream side of the air flow.

  The dust box 17 holds the tissue paper T on the air passage cylinder 19 as a cup-shaped filter. The cup-like tissue paper T removed from the dust box 17 has the abutment portion Td folded back to the outside. For this reason, the cup-like tissue paper T is easy to maintain its shape. The tissue paper T maintains its cup-like shape even when it is shaken by holding the abutment portion Td folded outward. That is, the tissue paper T does not deform significantly until it is removed from the dust box 17 and discarded. Therefore, when removing and discarding the tissue paper T currently hold | maintained at the dust collection part 10, the vacuum cleaner 1 can suppress that the collected dusts soar.

  The user pulls out the tissue paper T from the air passage tube 19 by pinching the contact portion Td folded back to the outside of the opening 19a. The user can easily take out the tissue T from the air passage cylinder 19.

  Since the contact portion Td is located outside the air passage through which the air including dust passes when the vacuum cleaner 1 is in operation, the dust does not adhere. The user can hygienically discard the tissue paper T without removing his / her hand when taking it out.

  The user discards the collected dust at a higher frequency as compared with the dust collection unit of the vacuum cleaner using a paper pack having a larger dust collection capacity than the tissue paper T. Since the period in which the collected dust remains in the dust collection unit 10 is shortened, the vacuum cleaner 1 can reduce the amount of the discharged odor generated by the collected dust.

  In addition, the air passage cylinder 19 includes a plurality of ribs 24 on the inner side surface to form a space between the air passage cylinder 19 and the tissue paper T. Thus, the air flow flowing through the air passage cylinder 19 can pass through the entire tissue T in the air passage cylinder 19. The surface area on which the tissue paper T acts as a filter is increased. The air flow resistance of the air passage cylinder 19 including the tissue paper T is reduced. Therefore, the vacuum cleaner 1 can improve suction efficiency.

  In addition, the air passage cylinder 19 includes a guard body 25 that connects at least two of the plurality of ribs 24. The guard body 25 prevents the end portion having the long side Tc of the tissue paper T from flowing downstream by the air flow flowing through the air passage cylinder 19. This makes it easier to maintain the cup-like shape of the tissue paper T. The guard body 25 prevents the dust from passing through the air passage cylinder 19 without being collected by the tissue paper T when the end of the tissue paper T flows.

  Further, in the air passage cylinder 19, the length in the air passage direction from the opening 19a to the downstream end 19b of the air flow is shorter than the length from the long side Tc of the tissue paper T to the opening 19a. . That is, the air passage cylinder 19 can hold the tissue paper T such that the peripheral portion including the long side Tc is folded at the end portion 19 b. The portion corresponding to the bottom portion of the folded cup-like tissue paper T at the end portion 19 b functions as a plurality of filters. Thereby, the dust collection part 10 becomes high in filtration performance.

  In addition, the circumferential length of the outer surface of the air passage tube 19 is shorter than the length of the long side Ta of the tissue paper T. That is, the air passage cylinder 19 can hold the tissue paper T such that both ends of the long side Ta overlap on the outer side surface. The cup-like tissue paper T is more easily maintained in shape because the overlap portion Te is formed. In addition, since the cup-shaped tissue paper T is less likely to have a circumferential gap, dust can be collected more reliably.

  Moreover, the circumferential length of the outer surface of the air passage cylinder 19 is a length within the range of 100 mm or more and 220 mm or less. Most of general tissue papers have a long side of 220 mm or less, and the circumferential length of the outer surface of the air passage cylinder 19 is smaller than this. Therefore, the user can form the overlap portion Te using a common tissue paper.

  The diameter of the cylindrical air passage tube is 30 mm or more by setting the circumferential length of the outer surface to 100 mm or more. When the diameter of the air passage tube is larger than 30 mm, the user can easily attach the tissue paper. In this case, it is possible to prevent an increase in the air flow resistance of the air passage cylinder without the amount of tissue paper becoming too large relative to the volume inside the air passage cylinder.

  Further, the dust collection unit includes a fine dust filter for collecting fine dust on the downstream side of the air flow from the air passage cylinder.

  The tissue paper T held in the air passage cylinder 19 captures, among the sucked dust, a large amount of surface area large waste and fine dust upstream of the fine dust filter 26 with respect to the mass of the fiber component or the hair. Collect. The fine dust filter 26 collects fine dust that has passed through the tissue paper T.

  In the dust collection unit 10 including the fine dust filter 26, the tissue paper T reduces the amount of fine dust that reaches the fine dust filter 26. The continuous usable time until the fine dust filter 26 is clogged by the fine dust becomes long.

  In the fine dust filter 26, the collected fine dust gradually accumulates while the tissue paper T is replaced and used a plurality of times. The fine dust filter 26 is cleaned by removing the fine dust accumulated after the fine dust filter 26 is removed from the filter holder 20. The fine dust collected in the fine dust filter 26 is removed by vibrating the filter medium 28 or washing the filter medium 28 with water. The dust collection unit 10 reduces the time and labor of the user by significantly reducing the frequency of the cleaning work of the fine dust filter 26 which takes more labor than the replacement work of the tissue paper T.

  Further, the dust collection unit 10 includes an opening cover 18 that covers the upstream outer surface of the air flow of the air passage cylinder 19 and at least a part of the opening 19 a. Thereby, the tissue paper T is covered by the opening cover 18 when the dust box 17 is mounted on the cleaner body 2. The opening cover 18 prevents the tissue paper T from coming into contact with the dust collection unit mounting unit 14 or the user's finger when the dust box 17 is mounted on the cleaner body 2. Therefore, the opening cover 18 can prevent the loosening and removal of the attachment state of the tissue paper T to the air passage cylinder 19. Therefore, the user can easily attach the dust collection unit 10 to the cleaner body 2.

  Further, the opening cover 18 is provided with a flexible seal member 23 on at least one of the upstream side surface and the downstream side surface of the air flow in the portion covering the opening 19a. The upstream surface of the air flow is the front surface. The downstream surface of the air flow is the rear surface. By providing the seal member 23 on the front side, the opening portion cover 18 contacts the dust collection portion mounting portion 14 to ensure the air passage airtight. By providing the seal member 23 on the rear side, the opening cover 18 is in contact with the opening 19a to ensure the airtightness of the air passage. Thus, when the dust collection unit 10 is attached to the dust collection unit mounting unit 14, the air passage cylinder 19 allows the air flow generated by the electric blower 9 to pass through the air inlet 7 without air leakage. it can.

  Further, the connection space 29 is configured such that the cross-sectional area in the plane perpendicular to the central axis continuously extends from the upstream side to the downstream side. The air flow resistance in the connection space 29 from the air passage cylinder 19 to the fine dust filter 26 is suppressed to a low level. Thus, the vacuum cleaner 1 has a high suction efficiency.

  The vacuum cleaner 1 further includes a detection unit 15 and a notification unit 11. The detection unit 15 detects a decrease in air pressure in a space 16 provided between the electric blower 9 and the dust collection unit 10. When the detection unit 15 detects a decrease in air pressure in the space 16, the notification unit 11 notifies the user that the dust collected on the tissue paper T or the fine dust filter 26 is accumulated. Thus, the vacuum cleaner 1 can prompt the user to change the tissue T or clean the fine dust filter 26.

  Further, the air passage tube 19 has a circular cross-sectional shape. Since the cross-sectional shape where the ratio of the cross-sectional area to the outer peripheral length is the largest is a circle, when the number of air passage cylinders 19 is one, the dust collection portion 10 is smaller than air passage cylinders of other cross-sectional shapes.

  Further, the knob 22 is integrally formed so as to protrude from the upper surface of the filter holding unit 20. The user can easily attach and detach the dust collection unit 10 from the dust collection unit mounting unit 14 by holding the knob 22.

  The length of the contact portion Td when the air passage cylinder 19 holds the tissue paper is not limited to 30 mm. The air passage tube 19 is configured such that the user can adjust the length of the contact portion Td or the overlap portion Te in accordance with the size of the tissue paper or the like. The air passage tube 19 is configured such that the user can select which of the short side or the long side of the tissue paper is wound around and attached to the outer surface according to the size of the tissue paper or the like.

  When the contact portion Td has a length of 20 mm or more, the effect of maintaining the cup-like shape of the tissue paper is enhanced.

  The air passage tube 19 may have an oval or rectangular cross-sectional shape.

  The detection unit 15 may detect a change in air pressure in the space 16 based on a change in current that drives the electric blower 9. The detection unit 15 may include a barometer disposed in the connection space 29. The vacuum cleaner 1 may not include the detection unit 15 or the notification unit 11.

  The guard body 25 may connect only two facing ribs 24 together. The air passage tube 19 may not have the guard body 25. The air passage tube 19 may have, for example, a net on the downstream side that prevents the end of the tissue paper T from flowing.

  The air passage tube 19 may not have the rib 24. The air passage tube 19 may have asperities on the inner side surface to prevent the tissue paper T from being in close contact with the inner side surface.

  The air passage tube 19 may be configured such that the length from the opening 19a to the end 19b is equal to or longer than the length from the long side Tc of the tissue paper T to the opening 19a. The air passage tube 19 may be provided with a guard for maintaining the cup-like shape of the tissue paper T at an intermediate position in the air passage direction.

  The vacuum cleaner 1 may be of a stick type, for example.

Second Embodiment
In this embodiment, points different from the example disclosed in Embodiment 1 will be described in detail. As the features not described in the present embodiment, any feature of the example disclosed in the first embodiment may be adopted.

The structure of the dust collection part 10 which concerns on Embodiment 2 is demonstrated using FIG.
FIG. 12 is a perspective view of the dust collection unit according to the present embodiment.

  The opening cover 18 is provided with a shielding valve 30 for closing the opening 19 a of the air passage cylinder 19.

  The shielding valve 30 has a structure in which a 1 mm thick disc is divided into four. The shield valve 30 is integrally formed with a seal member 23 made of a flexible material such as rubber or soft resin. The shielding valve 30 is flexible. The shielding valve 30 is configured to be able to be deformed downstream by the air flow generated by the electric blower 9.

Then, operation | movement of the vacuum cleaner 1 which concerns on Embodiment 2 is demonstrated using FIG. 13 and FIG.
13 and 14 are top cross-sectional views of the cleaner body according to the present embodiment.

  Drawing 13 shows the state where vacuum cleaner 1 has stopped. The shielding valve 30 closes the opening 19a in a state where the electric blower 9 does not generate an air flow because the electric vacuum cleaner 1 is stopped.

  FIG. 14 shows a state where the vacuum cleaner 1 is in operation. In a state where the electric blower 9 generates an air flow because the electric vacuum cleaner 1 is operating, the shielding valve 30 is bent toward the downstream side of the dust collection unit 10 by the air flow drawn from the air inlet 7. The shielding valve 30 opens the opening 19a by bending.

  When the vacuum cleaner 1 stops its operation, the shielding valve 30 returns to its original state and closes the opening 19a of the opening cover 18 again.

  As described above, in the electric vacuum cleaner 1 according to the present embodiment, the opening cover 18 closes the opening 19a when the electric blower 9 does not generate an air flow, and the electric blower 9 generates an air flow. It has the shielding valve 30 which opens the opening 19a when it is making it do. Thus, the shielding valve 30 prevents the collected dust from falling out of the opening 19 a when the user takes out the dust collection unit 10 from the cleaner body 2. The user can hygienically work to discard the collected dust.

Third Embodiment
In this embodiment, points different from the example disclosed in Embodiment 1 or 2 will be described in detail. As the features not described in the present embodiment, any feature of the example disclosed in the first embodiment or the second embodiment may be adopted.

Then, the structure of the dust collection part 10 is demonstrated using FIG. 15 and FIG.
15 and 16 are perspective views of the dust collection unit according to the present embodiment.

  The dust collection unit 10 is provided directly on the cleaner body 2 instead of the dust collection unit mounting unit 14 in the example disclosed in the first embodiment.

  The dust collection unit 10 has an air intake port 7, a filter holding unit 20, two cylindrical unit storage units 31, and an air passage switching unit 32.

  The intake port 7 is an opening provided in front of the dust collection unit 10. The front end of the dust collection unit 10 having the air inlet 7 is connected to an end of the hose 3 not connected to the connection pipe 4.

  The filter holding unit 20 is provided at the rear of the dust collection unit 10. The filter holder 20 has an opening on the top surface.

  The two cylindrical unit accommodating parts 31 are provided in front of the filter holding part 20 side by side. Each of the cylindrical unit accommodating parts 31 is provided so as to communicate with the filter holding part 20. Each of the cylindrical unit accommodating parts 31 includes a seal member 33 at the rear.

  The air passage switching unit 32 is provided in front of the two cylindrical unit accommodating units 31. The air passage switching unit 32 communicates with the air intake port 7 internally. The air passage switching unit 32 communicates with the inside of each of the cylindrical unit housing units 31. The air passage switching unit 32 forms an air passage extending from the intake port 7 to any one of the cylindrical unit accommodation units 31. The air passage switching unit 32 has a support 34 between the two cylindrical unit housings 31. The air passage switching unit 32 includes an air passage switching valve 36 having a support shaft 35.

  The support shaft 35 is rotatably attached to the support portion 34. The support shaft 35 penetrates the air path switching unit 32 upward. The support shaft 35 penetrates the main body lid 6 upward when the main body lid 6 is closed. The support shaft 35 has a fitting portion 35 a at an upper end portion penetrating the main body lid 6.

  The air passage switching valve 36 is a plate whose one side is integrally formed with the support shaft 35. The air passage switching valve 36 is made of resin. The air passage switching valve 36 is provided with a seal member 37 at its periphery. The air passage switching valve 36 is provided so as to be rotatable in the left-right direction as the support shaft 35 rotates. The air passage switching valve 36 is provided such that the seal member 37 contacts the inner surface of the air passage switching valve 36 when the air passage switching valve 36 is rotated in the left-right direction. The air passage switching valve 36 is configured to be switched by rotating the air passage switching valve 36 around the support shaft 35 so that the tubular unit accommodation portion 31 in which the air passage is formed from the intake port 7.

  The dust collection unit 10 includes a fine dust filter 26 and two cylindrical units 38.

  The fine dust filter 26 is accommodated in the filter holding unit 20 from above.

  Each of the two cylindrical units 38 is configured to be removable from above in each of the two cylindrical unit accommodating portions 31. The cylindrical unit 38 is disposed such that the air flowing from the intake port 7 to the electric blower 9 can pass through the cylindrical unit housing 31 in a state where the cylindrical unit 38 is mounted in the cylindrical unit housing 31. Each of the cylindrical units 38 is configured such that the airtightness of the air passage can be ensured by the rear side coming into contact with the seal member 33 provided on the rear side of each of the cylindrical unit housing portions 31.

  As shown in FIG. 16, the vacuum cleaner 1 is provided with an air passage switching dial 39.

  The air passage switching dial 39 is provided above the main body lid 6. The air passage switching dial 39 is connected to the support shaft 35 at the fitting portion 35 a. The air passage switching dial 39 is configured such that the support shaft 35 can rotate together with the air passage switching dial 39.

Subsequently, the configuration of the cylindrical unit 38 will be described with reference to FIG.
FIG. 17 is a perspective view of an air passage cylinder according to the present embodiment.

  Each of the cylindrical units 38 includes an air passage cylinder 19 and an opening cover 18.

  The air passage cylinder 19 is formed of, for example, a resin. The air passage tube 19 is a rectangular tubular member having an opening 19 a and having a length of 60 mm in the front-rear direction. The opening 19a of the air passage tube 19 has a width of 25 mm in the lateral direction and a height of 60 mm in the vertical direction. The air passage tube 19 includes a plurality of ribs 24 on the inner surface. The air passage cylinder 19 includes a guard body 25.

  The five ribs 24 are provided on the inner side of the vertical surface of the air passage cylinder 19. The ribs 24 are provided one by one on the inner side of the horizontal surface of the air passage cylinder 19. A total of twelve ribs 24 are provided on the inner surface of the air passage cylinder 19. The rib 24 protrudes from the inner surface of the air passage cylinder 19 perpendicularly to the inner surface of the air passage cylinder 19. The height of the rib 24 projecting from the inner surface of the air passage tube 19 is configured such that the opening 19a side is lower than the opposite end 19b side. The height of the rib 24 projecting from the inner surface of the air passage tube 19 is 5 mm at the highest portion.

  The guard body 25 connects four of the twelve ribs 24 arranged at the center of the inner side surfaces of the four faces of the air passage cylinder 19 on the central axis of the air passage cylinder 19. The guard body 25 connects the ribs 24 at the downstream end 19 b of the air passage cylinder 19.

Subsequently, the configuration of the cylindrical unit 38 will be described with reference to FIG.
FIG. 18 is a perspective view of a cylindrical unit according to the present embodiment.

  The opening cover 18 is configured to be removable from the opening 19 a of the air passage cylinder 19. The opening cover 18 covers the outer surface of the air passage cylinder 19 from the opening 19 a in a state of being mounted on the air passage cylinder 19. The opening cover 18 covers the outer peripheral portion of the opening 19 a in a state of being mounted on the air passage cylinder 19. The opening cover 18 has an inner width of 27 mm in the left-right direction of the side peripheral portion 18a. The opening cover 18 has an inner width of 62 mm in the vertical direction of the side peripheral portion 18a. The opening cover 18 has a length of 30 mm in the front-rear direction of the side peripheral portion 18 a. The opening cover 18 includes a sealing member 23.

  The seal member 23 is formed of, for example, a flexible material such as rubber or soft resin. The seal member 23 is disposed from the front surface to the rear surface of the portion of the opening cover 18 covering the outer peripheral portion of the opening 19 a of the air passage cylinder 19. The sealing member 23 is provided on the upstream side of the opening cover 18 so as to ensure airtightness between the dust collection portion mounting portion 14 and the opening cover 18. The seal member 23 is provided on the rear side of the opening cover 18 so as to ensure the airtightness between the opening cover 18 and the air passage cylinder 19. The outer diameter of the seal member 23 is adjusted so that the seal member 23 is compressed when the dust box 17 is mounted on the dust collection portion mounting portion 14 and air tightness of the air passage can be secured.

Subsequently, the operation of the vacuum cleaner 1 according to the third embodiment will be described with reference to FIGS. 19 to 21.
FIG. 19 is a perspective view of a cylindrical unit according to the present embodiment. FIG. 20 is a top cross-sectional view of the cleaner body according to the present embodiment. FIG. 21 is a perspective view of a cylindrical unit according to the present embodiment.

  The user mounts the tissue T on the tubular unit 38 before starting the operation of the vacuum cleaner 1.

  First, the user applies the long side Ta, which is one side of the tissue paper T, along the outer surface of the air passage cylinder 19. The user places the long side Ta of the tissue paper T on the rear side about 30 mm from the opening 19a. A portion from the long side Ta of the tissue paper T to the position of the opening 19a is referred to as a contact portion Td.

  Next, the user wraps the tissue T on the outer surface of the air passage cylinder 19. Since the length of the outer surface of the opening 19a is shorter than the length of the long side of the tissue paper T, the user overlaps the winding start end and the winding end end of the tissue paper T. The portion where the ends of the tissue paper T overlap is referred to as an overlapping portion Te.

  The circumferential length of the overlapping portion Te is about 40 mm because the circumferential length of the outer surface of the opening 19a is about 170 mm. The tissue paper T is in the form of a rectangular cylinder having a long side Tc as the front end and a length of the short side Tb. The length of the portion on the front side of the opening 19a of the tissue paper T is about 160 mm obtained by subtracting the axial length of the air passage tube 19 of the contact portion Td from the length of the short side Tb.

  Next, the user pushes the portion including the long side Tc in the forward direction of the opening 19a of the tissue T from the opening 19a into the inside of the opening 19a while folding. At this time, the user holds the contact portion Td so that the tissue paper T does not come off the air passage cylinder 19.

  Since the air passage tube 19 has a length of 60 mm in the front-rear direction, the air passage tube 19 is configured to be shorter than the length 160 mm of the portion on the front side of the opening 19a of the tissue paper T. For this reason, a surplus portion of about 100 millimeters of the portion in the forward direction of the opening 19a of the tissue paper T is folded at the rear end 19b inside the air passage cylinder 19.

  The tissue paper T is supported by a plurality of ribs 24 provided on the inner surface of the air passage cylinder 19 such that a space is formed between the tissue paper T and the inner surface of the air passage cylinder 19. The guard body 25 supports the folded portion at the downstream end 19 b of the tissue paper T. The tissue paper T forms a cup-like filter in which the cross-sectional area decreases in the air passage cylinder 19 from the opening 19a side to the downstream side due to the change in the height of the rib 24.

  Next, the user mounts the opening cover 18 so as to cover the tissue paper T mounted on the air passage cylinder 19. The side peripheral portion 18 a of the opening cover 18 covers the contact portion Td of the tissue paper T. The tissue paper T mounted by the above procedure is held by the air passage cylinder 19 as a cup-shaped filter.

  Next, as shown in FIG. 20, the user mounts the cylindrical unit 38 with the tissue paper T mounted thereon from above onto the cylindrical unit housing portion. The user closes the main body lid 6.

  When the dust collection unit 10 to which the tissue paper T is mounted is mounted on the dust collection unit mounting unit 14, the seal member 23 provided on the front side is in contact with the dust collection unit mounting unit 14 to open from the air inlet 7 Ensuring air tightness leading to the cover 18. Since the seal member 23 provided on the rear side is formed of a flexible material, it adheres to the overlapping portion of the tissue paper T and irregular wrinkles and the like. The seal member 23 provided on the rear side ensures airtightness of the air passage from the opening cover 18 to the air passage cylinder 19 by sandwiching the tissue paper T.

  The user starts the operation of the vacuum cleaner 1. The air flow generated by the electric blower 9 flows into the dust collection unit 10 together with dust.

  The air flow that has flowed into the dust collection unit 10 together with dust is guided by the air passage switching valve 36 to the air passage cylinder 19 provided in any one of the cylindrical units 38.

  The air flow that has flowed into the air passage cylinder 19 passes through the space formed between the tissue paper T and the inner surface of the air passage cylinder 19 by the plurality of ribs 24, and the wind of the tissue paper T including the side surface formed in a cup shape. It passes through the entire surface inside the road cylinder 19.

  The dust that has flowed into the air duct 19 is collected by the tissue paper T formed as a cup-shaped filter held by the air duct 19. Most of the dust that has flowed into the dust collection unit 10 collides with the air flow on the bottom surface of the cup-shaped filter formed by the tissue paper T. Since the bottom surface is a folded portion of the tissue paper T, the folded tissue portion collects dust as a plurality of filters. The guard body 25 holds the tissue paper T inside the air passage cylinder 19 so as to prevent the end of the tissue paper T from flowing downstream by the air flow flowing through the air passage cylinder 19.

  Fine dust of about several micrometers in diameter can pass through the air ducts 19 together with the air flow without being collected by the tissue paper T. Fine dust having passed through the air passage tube 19 flows into the filter holding portion 20 together with the air flow via the connection space 29.

  The fine dust that has flowed into the filter holding unit 20 is collected by the fine dust filter 26.

  The air flow that has flowed into the filter holding unit 20 is sucked by the electric blower 9 as air from which dust is separated by collection. The air from which dust has been separated is delivered from the exhaust port 8 by the electric blower 9. The rear of the cleaner body 2 is the downstream side of the air flow generated by the electric blower 9.

  In the space 16, when dust collected on the tissue paper T or the fine dust filter 26 is accumulated by the operation of the vacuum cleaner 1, the air pressure during the operation of the vacuum cleaner 1 decreases. When the air pressure in the space 16 becomes equal to or less than a predetermined value, the detection unit 15 transmits a signal representing a decrease in the air pressure in the space 16 to the notification unit 11. When the notification unit 11 receives a signal from the detection unit 15, the notification unit 11 notifies the user that the air pressure in the space 16 has decreased by turning on the LED disposed on the upper surface of the cleaner body 2. That is, the notification unit 11 notifies the user that the dust collected on the tissue paper T or the fine dust filter 26 is accumulated.

  The user rotates the air passage switching dial 39 when it is determined that the dust collected on the tissue paper T is accumulated by the notification of the notification unit 11. The air passage switching dial 39 rotates the support shaft 35 via the fitting portion 35a. The air passage switching valve 36 is internally rotated around the support shaft 35. The air passage switching valve 36 rotates so as to slide in contact with the inner surface of the air passage switching unit 32. The sealing member 37 ensures air tightness of the air passage by contacting the inner surface of the air passage switching unit 32. As a result, when the user rotates the air passage switching dial 39, the air passage communicating with the air passage cylinder 19 is switched.

  After the user cleans the surface to be cleaned by sucking the dust, the user ends the operation of generating the air flow of the electric blower 9 by the operation switch.

  The user opens the main body lid 6. The user takes out the cylindrical unit 38 from the cylindrical unit storage portion 31.

  Next, as shown in FIG. 21, the user removes the opening cover 18 and the cup-like tissue paper T from the tubular unit 38 in this order. The user removes the cup-like tissue paper T by holding the contact portion Td and pulling it out of the air passage cylinder 19. The user discards the removed tissue paper T together with the collected dust.

  As explained above, electric vacuum cleaner 1 concerning this embodiment is provided with electric blower 9 and dust collection part 10. The electric blower 9 generates an air flow. The dust collection unit 10 collects dust sucked from the outside by the air flow generated by the electric blower 9 through at least one of one or more air passage cylinders 19 each holding the tissue paper T as a filter. One side of the tissue paper T is wound around the outer surface of the opening 19a on the upstream side of the air flow, and the opposite side of one side is folded inside the opening.

  As a result, when all the tissue papers T of the plurality of cylindrical units 38 are clogged, the user can collectively perform the replacement work of the tissue papers T of the plurality of cylindrical units 38 at one time. Thereby, the dust collection part 10 can reduce the effort of the user of the replacement | exchange operation | work of tissue paper T. FIG.

  Further, the dust collection unit 10 includes an air passage switching valve 36 that guides the air flow to any one of the one or more air passage cylinders 19. This allows the user to switch to another tubular unit 38 when one of the two tubular units 38 becomes clogged. The user can continue the cleaning operation continuously without replacing the tissue paper T of the clogged tubular unit 38.

  The vacuum cleaner 1 further includes a detection unit 15 and a notification unit 11. The detection unit 15 detects a decrease in air pressure in a space provided between the electric blower and the dust collection unit. When the detection unit 15 detects a decrease in air pressure in the space, the notification unit 11 notifies that the air passage switching valve switches the air passage cylinder leading the air flow. Thus, the user can switch the air passage cylinder 19 when the tissue paper T held by one air passage cylinder 19 is clogged.

  Further, each of the plurality of air passage cylinders 19 has a rectangular cross-sectional shape, and is disposed in the dust collection unit 10 so that the other air passage cylinder 19 is adjacent to the side. The dust collecting unit 10 is smaller than in the case where two air passage cylinders having a circular cross-sectional shape are arranged by arranging the two air passage cylinders 19 so that the long sides of the rectangular cross-sectional shape are adjacent to each other. Become.

  The air passage tube 19 holds the tissue paper T as a cup-shaped filter having a rectangular cross-sectional shape. When the cup-shaped tissue paper T is pulled out from the air passage cylinder 19 and a force is applied by touching with a hand, the cross-sectional shape can be deformed into a circular shape due to the flexibility of the tissue paper T. Also in this case, the tissue paper T does not lose its cup-like shape because the contact portion Td is folded outward. Therefore, when discarding the tissue paper T held as a filter by the dust collection unit 10, the vacuum cleaner 1 can suppress the dust collected from rising.

  The cross-sectional shape of the plurality of air passage cylinders 19 may be circular or elliptical.

  Dust collection part 10 may be provided with three cylindrical units. The three tubular units have a circular cross-sectional shape, and are disposed in the dust collection unit 10 such that the three circles are in contact with each other. Alternatively, the three tubular units have a hexagonal cross-sectional shape, and are disposed in the dust collection unit 10 such that one side is adjacent to each other. Instead of the air passage switching valve 36 rotating around the vertical axis, the air passage switching unit switches the air passage by a rotating body that rotates around a longitudinal axis having an opening serving as an air passage.

  Reference Signs List 1 electric vacuum cleaner, 2 vacuum cleaner main body, 3 hoses, 4 connection pipes, 5 cleaning tools, 6 main body lids, 7 inlets, 8 exhaust ports, 9 electric blowers, 10 dust collecting units, 11 notification units, 12 handles, 13 Support member, 14 dust collecting part mounting part, 15 detection part, 16 space, 17 dust box, 18 opening cover, 18a side peripheral part, 19 air passage tube, 19a opening part, 19b end part, 20 filter holding part, 21 connection Parts, 22 knobs, 23 sealing members, 24 ribs, 25 guard bodies, 26 fine dust filters, 27 filter frames, 28 filter filter media, 29 connecting spaces, 30 shielding valves, 31 tubular unit housing parts, 32 air path switching parts, 33 seal member, 34 support portion, 35 support shaft, 35a fitting portion, 36 Road switching valve, 37 seal member, 38 tubular unit, 39 air passage switching dial

Claims (11)

An electric blower that generates an air flow;
The dust sucked from the outside by the air flow is wound around the outer surface on the upstream side of the air flow, and the second side which is the opposite side of the first side is the opening portion on the upstream side of the air flow. A dust collection unit for collecting tissue paper to be folded inward through one or more air ducts each held as a filter;
Equipped with
Each of the one or more air ducts comprises a plurality of ribs for forming a space between the tissue paper and an inner surface.   The vacuum cleaner according to claim 1, wherein each of the one or more air ducts comprises a guard body connecting at least two of the plurality of ribs.   Each of the one or more air ducts is configured such that the length from the opening to the downstream end of the air flow is shorter than the length from the second side of the tissue paper to the opening The vacuum cleaner according to any one of claims 1 or 2, which is   The circumferential length of the outside surface of each of the one or more air ducts is shorter than the length of the first side of the tissue paper. Vacuum cleaner as described.   The electricity according to any one of claims 1 to 4, wherein each of the one or more air ducts has a circumferential length of the outer side surface within a range of 100 millimeters or more and 220 millimeters or less. Vacuum cleaner.   The said dust collection part is provided with the fine dust filter which collects fine dust in the downstream of the said airflow rather than any of the said one or more air-passage tubes in any one of the Claims 1-5. Vacuum cleaner.   7. The dust collection unit according to claim 1, wherein the dust collection unit includes an opening cover that covers the upstream outer surface of the air flow of each of the one or more air passage cylinders and at least a part of the opening. A vacuum cleaner according to any one of the preceding claims.   The vacuum cleaner according to claim 7, wherein the opening cover comprises a flexible sealing member on at least one of the upstream side surface and the downstream side surface of the air flow in the portion covering the opening.   The said opening cover is provided with the shielding valve which closes the said opening when the said electric blower is not generating the said airflow, and opens the said opening when the said electric blower is producing the said airflow. Item 9. A vacuum cleaner according to item 8.   The vacuum cleaner according to any one of claims 1 to 9, wherein the dust collection unit includes an air passage switching valve that guides the air flow to any one of the one or more air passage cylinders. A detection unit that detects a decrease in air pressure in a space provided between the electric blower and the dust collection unit;
A notification unit that notifies that the air passage switching valve switches the air passage cylinder leading the air flow when the detection unit detects a decrease in air pressure in the space;
The vacuum cleaner according to claim 10, comprising:

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