JP5447560B2 - Cyclone separation device and vacuum cleaner - Google Patents

Description

  The present invention relates to a cyclone separator and a vacuum cleaner equipped with a cyclone separator.

Patent Document 1 below describes a vacuum cleaner provided with a cyclone separator.
In the electric vacuum cleaner described in Patent Document 1, dust is separated from sucked air (dust-containing air) in two stages. That is, first, relatively bulky garbage (hereinafter, such garbage is also referred to as “garbage α”) is separated from the dust-containing air. Thereafter, relatively bulky garbage (hereinafter, such garbage is also referred to as “garbage β”) is separated from the dust-containing air. The separated waste α and waste β are collected in a dust collection chamber.

  In the vacuum cleaner described in Patent Document 1, when the dust collection chamber is full of dust, the case forming the dust collection chamber is removed and the dust is discarded. Since the dust collection chamber is frequently filled with bulky garbage (garbage α), the frequency of waste disposal increases. For this reason, there is a problem that the frequency of the waste β, which is likely to rise when the waste is thrown away, increases, which is not hygienic.

As another example of the electric vacuum cleaner, a configuration in which the garbage α and the garbage β can be separately disposed has been proposed (see, for example, Patent Document 2, FIGS. 8 and 9).
In the electric vacuum cleaner described in Patent Document 2, garbage α is collected in the first dust collection chamber, and garbage β is collected in the second dust collection chamber. The case forming the second dust collection chamber is provided separately from the case forming the first dust collection chamber. For this reason, when the first dust collecting chamber is filled with the garbage α, only the case forming the first dust collecting chamber can be removed, and the dust inside can be discarded.

Special table 2002-528250 gazette JP 2007-307352 A

  In the electric vacuum cleaner described in Patent Document 2, when throwing away the waste α and the waste β, first, the case forming the first dust collection chamber is removed from the main body of the cleaner, and the waste α is discarded. Thereafter, the case forming the second dust collection chamber is removed from the main body of the cleaner, and the waste β is discarded. For this reason, there was a problem that it took time to dispose of the garbage and the convenience was poor.

  The present invention has been made to solve the above-described problems, and an object of the present invention is to provide a cyclone separator that can sanitize waste and can reduce the time and effort of waste disposal. It is providing the vacuum cleaner provided with such a cyclone separator.

A cyclone separation device according to the present invention includes a swirl chamber that swirls dust-containing air flowing from an inlet and separates dust from the dust-containing air, a swirl chamber forming portion that forms one swirl chamber, and a swirl chamber A first opening provided in the forming portion, a first dust collecting portion that communicates with the swirl chamber via the first opening, and a swirl chamber forming portion that are disposed downstream of the first opening. The second opening and a second dust collecting portion that communicates with the swirl chamber through the second opening, and the first dust collecting portion collects dust larger than the second dust collecting portion and swirls. The chamber forming portion and the second dust collecting portion can be detached from the housing unit in a state where the chamber forming portion and the second dust collecting portion are fixed with respect to the predetermined housing unit. It can be removed.

  The vacuum cleaner according to the present invention includes the cyclone separation device and a blower for generating a predetermined air flow inside the cyclone separation device.

  According to this invention, in the vacuum cleaner provided with the cyclone separator and the cyclone separator, it becomes possible to sanitize garbage. In addition, it is possible to reduce the time and effort of throwing away garbage.

It is a perspective view which shows the electric vacuum cleaner in Embodiment 1 of this invention. It is a perspective view which shows the cleaner body of the vacuum cleaner in Embodiment 1 of this invention. It is a top view which shows the cleaner body of the vacuum cleaner in Embodiment 1 of this invention. It is AA sectional drawing of the cleaner body shown in FIG. It is BB sectional drawing of the cleaner body shown in FIG. It is a perspective view which shows the accommodating unit of the vacuum cleaner in Embodiment 1 of this invention. It is a perspective view which shows the dust collection unit of the vacuum cleaner in Embodiment 1 of this invention. It is a top view which shows the dust collection unit of the vacuum cleaner in Embodiment 1 of this invention. It is CC sectional drawing of the dust collection unit shown in FIG. It is DD sectional drawing of the dust collection unit shown in FIG. It is EE sectional drawing of the dust collection unit shown in FIG. It is a figure for demonstrating the operation | movement at the time of garbage disposal. It is a perspective view which shows the dust collection unit of the vacuum cleaner in Embodiment 2 of this invention. It is a figure for demonstrating the operation | movement at the time of garbage disposal. It is sectional drawing which shows the cleaner body of the vacuum cleaner in Embodiment 3 of this invention. It is sectional drawing which shows the other example of the cleaner body of the vacuum cleaner in Embodiment 3 of this invention.

  The present invention will be described in detail with reference to the accompanying drawings. In each drawing, the same or corresponding parts are denoted by the same reference numerals. The overlapping description is simplified or omitted as appropriate.

Embodiment 1 FIG.
1 is a perspective view showing an electric vacuum cleaner according to Embodiment 1 of the present invention.
As shown in FIG. 1, the main part of the vacuum cleaner 100 includes a suction port body 1, a suction pipe 2, a connection pipe 3, a suction hose 4, and a cleaner body 5.

The suction port body 1 is for sucking dust (dust) on the floor surface together with air from an opening formed downward. The suction port body 1 includes a connection portion for exhaust at the center in the longitudinal direction.
The suction pipe 2 is made of a straight member having a cylindrical shape. One end (intake side) of the suction pipe 2 is connected to a connection portion of the suction port body 1.

  The connection pipe 3 is made of a cylindrical member that is bent halfway. One end (intake side) of the connection pipe 3 is connected to the other end of the suction pipe 2. The connection pipe 3 is provided with a handle 6. The handle 6 is for a person who performs cleaning to operate. The handle 6 is provided with an operation switch 7 for controlling the operation of the vacuum cleaner 100.

  The suction hose 4 is made of a member having a bellows shape with flexibility. One end (intake side) of the suction hose 4 is connected to the other end of the connection pipe 3.

  The cleaner body 5 is for separating the dust from the air containing dust (dust-containing air) and discharging the air (clean air) from which the dust has been removed (for example, returning it to the room). The other end of the suction hose 4 is connected to the cleaner body 5 at the front end.

  The cleaner body 5 includes an electric blower 8 (not shown in FIG. 1) and a power cord 9. The power cord 9 is wound around a cord reel portion (not shown) inside the cleaner body 5. By connecting the power cord 9 to an external power source, the internal devices such as the electric blower 8 are energized. The electric blower 8 is driven by energization and performs a predetermined suction operation according to an operation on the operation switch 7.

  The suction port body 1, the suction pipe 2, the connection pipe 3, and the suction hose 4 are continuously formed inside. When the electric blower 8 performs the suction operation, the dust on the floor is sucked into the suction port 1 together with the air. The dust-containing air sucked into the suction port body 1 passes through each of the suction port body 1, the suction pipe 2, the connection pipe 3, and the suction hose 4 and is sent to the cleaner body 5. As described above, the suction port body 1, the suction pipe 2, the connection pipe 3, and the suction hose 4 form an air passage for allowing dust-containing air to flow into the cleaner body 5 from the outside.

  FIG. 2 is a perspective view showing a vacuum cleaner body of the electric vacuum cleaner according to Embodiment 1 of the present invention. FIG. 3 is a plan view showing a vacuum cleaner body of the electric vacuum cleaner according to Embodiment 1 of the present invention. 4 is a cross-sectional view of the vacuum cleaner body taken along the line AA in FIG. 5 is a BB cross-sectional view of the cleaner body shown in FIG.

  The cleaner body 5 includes a storage unit 10 and a dust collection unit 11. Various devices other than the dust collection unit 11 are accommodated in the accommodation unit 10. The dust collection unit 11 is detachably provided on the storage unit 10. 2 to 5 show a state in which the dust collection unit 11 is properly attached to the storage unit 10.

  FIG. 6 is a perspective view showing the housing unit of the electric vacuum cleaner according to Embodiment 1 of the present invention. FIG. 6 shows a state in which the dust collection unit 11 is removed from the cleaner body 5.

  The accommodation unit 10 includes an intake air passage formation portion 12, an exhaust air passage formation portion 13, and wheels 14 in addition to the electric blower 8 and the cord reel portion described above. The electric blower 8 and the cord reel portion are provided inside the housing unit 10. The wheels 14 are provided on both sides of the housing unit 10.

  The housing unit 10 has a box shape in outer shape. The accommodation unit 10 has an upper surface near the front end facing obliquely rearward, and an upper surface 10b of the rear part facing obliquely forward. For this reason, the upper surface of the storage unit 10 is formed in an L shape when viewed from the side. The L-shaped upper surface of the storage unit 10 forms a storage portion 10a above the upper surface. The accommodating portion 10 a is a space for accommodating the dust collection unit 11. When the dust collection unit 11 is appropriately attached to the storage unit 10, the main part of the dust collection unit 11 is disposed in the storage unit 10 a, that is, above the storage unit 10. The dust collecting unit 11 is stably held by covering the bottom surface side with the (front) upper surface of the housing unit 10 facing obliquely rearward.

  The suction air passage forming unit 12 forms a suction air passage 15 for guiding dust-containing air to the dust collecting unit 11 in the cleaner body 5. One end of the suction air passage forming portion 12 opens at the front surface of the housing unit 10. The suction air passage forming part 12 passes through the internal space of the housing unit 10, and the other end opens at the upper surface 10 b on the rear side of the housing unit 10. The other end of the suction air passage forming unit 12 forms a connection port 16 with the dust collection unit 11.

The dust collection unit 11 is for separating garbage from dust-containing air and temporarily storing the separated garbage. The dust collection unit 11 rotates dust-containing air inside to separate dust from air by centrifugal force. That is, the dust collection unit 11 has a cyclone separation function.
The specific configuration and function of the dust collection unit 11 will be described later.

  The exhaust air passage forming unit 13 is for guiding the air discharged from the dust collection unit 11 (clean air from which dust is removed in the dust collection unit 11) in the cleaner body 5 to an exhaust port (not shown). An exhaust air passage 17 is formed. One end of the exhaust air passage forming portion 13 opens at the upper surface 10 b of the housing unit 10. The exhaust air passage forming unit 13 passes through the internal space of the housing unit 10, and the other end opens toward the outside of the housing unit 10. The one end of the exhaust air passage forming unit 13 forms a connection port 18 with the dust collecting unit 11. The other end of the exhaust air passage forming unit 13 forms an exhaust port.

  The electric blower 8 includes an air passage formed in the vacuum cleaner 100 (an air passage for allowing dust-containing air to flow into the cleaner body 5, an intake air passage 15, an air passage in the dust collection unit 11 described later, This is for generating an air flow in the exhaust air passage 17). The electric blower 8 is disposed in the exhaust air passage 17.

  When the electric blower 8 starts the suction operation, an air flow is generated in each air passage formed in the electric vacuum cleaner 100. The dust-containing air sucked into the suction port body 1 is taken into the cleaner body 5 as described above. The dust-containing air that has flowed into the cleaner body 5 is sent to the dust collecting unit 11 from the connection port 16 via the intake air passage 15. The airflow generated inside the dust collection unit 11 will be described later. Air (clean air) discharged from the dust collection unit 11 flows into the exhaust air passage 17 from the connection port 18 and passes through the electric blower 8 in the exhaust air passage 17. The air that has passed through the electric blower 8 further travels through the exhaust air passage 17 and is discharged from the exhaust port to the outside of the cleaner body 5 (the electric vacuum cleaner 100).

Next, the dust collection unit 11 will be described in detail with reference to FIGS.
FIG. 7 is a perspective view showing the dust collection unit of the electric vacuum cleaner according to Embodiment 1 of the present invention. FIG. 8 is a plan view showing the dust collection unit of the electric vacuum cleaner according to Embodiment 1 of the present invention. FIG. 9 is a cross-sectional view of the dust collection unit shown in FIG. FIG. 10 is a cross-sectional view taken along the line DD of the dust collection unit shown in FIG. 11 is an EE cross-sectional view of the dust collection unit shown in FIG.

The dust collection case 11 includes a cylindrical portion 19, a conical portion 20, an inflow pipe 21, a first dust collection portion 22, a second dust collection portion 23, a first discharge portion 24, and a second discharge portion 25.
In the following, when the dust collection unit 11 is described alone, the upper and lower sides are specified based on the orientation shown in FIG.

  Each structure of the dust collection case 11 shown by the code | symbol 19 thru | or 25 consists of molded products, for example. Any one of the configurations shown in 19 to 25 or a plurality of them are appropriately arranged, so that the dust collection unit 11 includes an inflow air passage 26, a swirl chamber 27, a first dust collection chamber 28, and a second dust collection chamber. 29, outflow air passage 30 is formed

  The cylindrical portion 19 has a hollow cylindrical shape. The cylindrical portion 19 is disposed so that the central axis faces the up-down direction. The conical portion 20 has a hollow conical shape with a tip portion cut off. The conical portion 20 is arranged in the vertical direction so that the central axis coincides with the central axis of the cylindrical portion 19. The conical portion 20 is provided so that the upper end portion is connected to the lower end portion of the cylindrical portion 19 and extends downward from the lower end portion of the cylindrical portion 19 so that the diameter decreases as it goes downward. For this reason, the lower end part of the cone part 20 is opened downward (center axis direction). This opening formed at the lower end of the conical portion 20 is the second opening 31.

  A continuous space composed of the internal space of the cylindrical portion 19 and the internal space of the conical portion 20 constitutes a swirl chamber 27. That is, the cylindrical portion 19 and the conical portion 20 form a side wall of the swirl chamber 27. The cylindrical portion 19 and the conical portion 20 are part of a swirl chamber forming portion that forms a swirl chamber 27. The swirl chamber 27 is a space for swirling the dust-containing air.

  The inflow pipe 21 is for guiding the dust-containing air that has passed through the suction air passage 15 to the inside of the cylindrical portion 19 (the swirl chamber 27). An internal space of the inflow pipe 21 forms an inflow air passage 26. The inflow air passage 26 is an air passage for allowing dust-containing air to flow into the swirl chamber 27 from the intake air passage 15.

  The inflow pipe 21 is made of, for example, a straight member having a quadrangular cross section. One end of the inflow pipe 21 opens outward, and the other end opens inside the cylindrical portion 19. The one end of the inflow pipe 21 forms a unit inlet 32 for taking dust-containing air into the dust collection unit 11. The other end of the inflow pipe 21 forms an inflow port 33 for taking in the dust-containing air that has passed through the inflow air passage 26 into the inside of the cylindrical portion 19 (the swirl chamber 27). The inflow pipe 21 is connected to the upper portion of the cylindrical portion 19 so that the dust-containing air from the inflow air passage 26 flows into the cylindrical portion 19 from the tangential direction.

The first dust collection unit 22 and the second dust collection unit 23 are arranged side by side in the lower part of the dust collection unit 11.
The second dust collecting portion 23 has a box shape as a whole, and is provided in the conical portion 20 (the swirl chamber forming portion) so that the conical portion 20 penetrates the upper surface. That is, the lower portion (including the lower end) of the conical portion 20 is disposed inside the second dust collecting portion 23.

  Of the internal space of the second dust collection part 23, the part excluding the conical part 20 forms the second dust collection chamber 29. The second dust collection chamber 29 communicates with the swirl chamber 27 through the second opening 31. Part of the dust separated from the dust-containing air in the swirl chamber 27 enters the second dust collection chamber 29 through the second opening 31 and is collected. The second dust collection chamber 29 is disposed so as to surround the lower part of the conical part 20 and the periphery of the lower part of the conical part 20.

The second dust collecting unit 23 includes a second base 34, a second lid 35, and second opening / closing means (not shown).
The second base 34 has a cylindrical shape with the top closed. The upper portion of the second base 34 is integrally provided with the conical portion 20. The lower end of the second base 34 opens downward. This opening formed at the lower end of the second base 34 forms a second outlet 36. The second outlet 36 is an opening for discarding the dust accumulated in the second dust collecting chamber 29.

  The second lid 35 is for opening and closing the lower end (second outlet 36) of the second base 34. The second lid 35 has a predetermined structure that can seal the second outlet 36. For example, one end of the second lid 35 is rotatably provided at the lower end of the second base 34 via a predetermined shaft. When the other end of the second lid 35 is lifted to a predetermined position, the second lid 35 is disposed so as to completely close the second outlet 36.

  The second opening / closing means is provided at the other end of the second lid 35, for example. The second opening / closing means has a predetermined structure that can hold the second lid 35 in a state where the second lid 35 completely closes the second outlet 36 (closed state). When a predetermined opening operation is performed, the second opening / closing means releases the holding state that holds the second lid 35 in the closed state. That is, when the holding state is released, the other end of the second lid 35 moves downward, and the lower end (second outlet 36) of the second base 34 is opened.

  The first dust collecting portion 22 has a box shape as a whole, and is arranged side by side on the side of the cylindrical portion 19, the conical portion 20, and the second dust collecting portion 23. The internal space of the first dust collection unit 22 forms a first dust collection chamber 28. The first dust collecting unit 22 is detachably provided on the swirl chamber unit by predetermined first attaching / detaching means (not shown).

  The swirl chamber unit refers to a member that includes the swirl chamber 27 and is formed integrally. In this Embodiment, parts other than the 1st dust collection part 22 among the dust collection units 11 comprise a turning chamber unit. For example, the swirl chamber forming unit and the second dust collecting unit 23 constitute a main part of the swirl chamber unit. Below, the case where the 1st dust collection part 22 is attached to the cylindrical part 19 by a 1st attachment / detachment means as an example is demonstrated.

  A first opening 37 is formed in the cylindrical portion 19 at a predetermined height. The first opening 37 is provided at a position (downstream side) lower than the inflow port 33 and at a position (upstream side) higher than the second opening 31. The first dust collecting unit 22 has an opening formed at a position facing the upper first opening 37. Therefore, the first dust collection chamber 28 communicates with the swirl chamber 27 via the first opening 37 (and the upper opening). Part of the dust separated from the dust-containing air in the swirl chamber 27 enters the first dust collection chamber 28 through the first opening 37 and is collected. The first dust collection chamber 28 is provided to extend from the first opening 37 downward (in the direction of the central axis of the swirl chamber 27) and in a direction in which air swirls in the swirl chamber 27 (swirl direction).

The first dust collecting unit 22 includes a first base 38, a first lid 39, and first opening / closing means (not shown).
The first base 38 has a cylindrical shape in which an upper portion is closed and an opening facing the first opening 37 is formed in the upper portion. The first base 38 is detachably fixed to the cylindrical portion 19 by the first attaching / detaching means. The lower end of the first base 38 opens downward. This opening formed at the lower end of the first base 38 forms a first outlet 40. The first outlet 40 is an opening for discarding the dust accumulated in the first dust collection chamber 28. Similar to the second outlet 36, the first outlet 40 opens toward the central axis direction (downward) of the swirl chamber 27.

  The first lid 39 is for opening and closing the lower end (first outlet 40) of the first base 38. The first lid 39 has a predetermined structure that can seal the first outlet 40. For example, one end of the first lid 39 is rotatably provided at the lower end of the first base body 38 via a predetermined shaft. When the other end of the first lid 39 is lifted to a predetermined position, the first lid 39 is disposed so as to completely close the first outlet 40.

  The first opening / closing means is provided at the other end of the first lid 39, for example. The first opening / closing means has a predetermined structure that can hold the first lid 39 in a state (closed state) in which the first lid 39 completely closes the first outlet 40. When a predetermined opening operation is performed, the first opening / closing means releases the holding state that holds the first lid 39 in the closed state. That is, when the holding state is released, the other end of the first lid 39 moves downward, and the lower end (first outlet 40) of the first base 38 is opened.

The first discharge unit 24 and the second discharge unit 25 are arranged to overlap with each other in the dust collection unit 11.
The first discharge portion 24 is placed on the upper end portion of the cylindrical portion 19 so as to be in close contact from above. The upper wall of the swirl chamber 27 is formed by the first discharge part 24. The first discharge part 24 is provided with a first discharge pipe 41. The first discharge pipe 41 is for discharging the air in the swirl chamber 27 to the outside of the swirl chamber 27. The first discharge pipe 41 is disposed so as to protrude into the swirl chamber 27 from the upper wall of the swirl chamber 27 downward (in the direction of the central axis of the swirl chamber 27).

  The first discharge pipe 41 has a cylindrical shape above the predetermined intermediate position. The portion below the intermediate position of the first discharge pipe 41 has a hollow conical shape with a diameter that decreases downward. The first discharge pipe 41 is arranged in the vertical direction so that the central axis coincides with the central axis of the cylindrical portion 19. The first discharge pipe 41 is provided with a large number of fine holes. This fine hole is an opening for discharging the air in the swirl chamber 27 out of the swirl chamber 27.

  The 2nd discharge part 25 is provided in the upper end part of the cylindrical part 19 so that the 1st discharge part 24 may be covered from upper direction. The second discharge part 25 is provided with a second discharge pipe 42. The second discharge pipe 42 is for switching the traveling direction of the air that has passed through the inside of the first discharge pipe 41 and discharging it to the outside of the dust collection unit 11. One end of the second discharge pipe 42 is connected to the upper end of the first discharge pipe 41. The other end of the second discharge pipe 42 forms a unit outlet 43. The unit outlet 43 is an opening through which air flows out from the dust collection unit 11. The unit outlet 43 opens in the same direction as the unit inlet 32.

  The outflow air passage 30 includes an internal space of the first discharge pipe 41 and an internal space of the second discharge pipe 42. The outflow air passage 30 is an air passage for causing the air inside the swirl chamber 27 to flow out of the dust collection unit 11.

  The dust collection unit 11 is detachably provided on the storage unit 10 by a predetermined mounting means (not shown). The mounting means is provided in the dust collection unit 11 and the storage unit 10. The member on the dust collection unit 11 side of the mounting means is provided in a swirl chamber unit (for example, a swirl chamber forming portion). When the swirl chamber unit (dust collection unit 11) is attached to the storage unit 10 by the mounting means, the unit inlet 32 is connected to the connection port 16. The unit outlet 43 is connected to the connection port 18.

Next, the function of the dust collection unit 11 having the above configuration will be specifically described.
When the suction operation of the electric blower 8 is started, the dust-containing air passes through the suction air passage 15 and reaches the connection port 16 as described above. The dust-containing air sequentially passes through the connection port 16 and the unit inlet 32 and flows into the inflow pipe 21. The dust-containing air passes through the inflow air passage 26 and flows into the inside of the cylindrical portion 19 (swirl chamber 27) from the inflow port 33.

  The dust-containing air flows into the swirl chamber 27 along the inner peripheral surface of the cylindrical portion 19. For this reason, the dust-containing air forms a swirling airflow that rotates in a predetermined direction in the swirling chamber 27. The whirling airflow flows downward due to the path structure and gravity while forming a forced vortex region near the central axis and a free vortex region outside the central vortex region.

  Centrifugal force acts on the dust contained in the swirling airflow. For example, relatively bulky waste (garbage α) such as fiber waste and hair falls inside the swirl chamber 27 while being pressed against the inner peripheral surface of the cylindrical portion 19 (inner wall surface of the swirl chamber 27) by this centrifugal force. To do. When the waste α reaches the height of the first opening 37, it is separated from the swirling airflow, passes through the first opening 37 and enters the first dust collecting chamber 28. The dust α that has entered the first dust collection chamber 28 from the first opening 37 falls in the first dust collection chamber 28 while moving in the same direction as the direction of the airflow swirling in the swirl chamber 27 (the swirl direction). . And garbage alpha reaches the lowest part of the 1st dust collection room 28, and is collected.

  Garbage that has not entered the first dust collection chamber 28 from the first opening 37 rides on the airflow in the swirl chamber 27 and proceeds downward while swirling in the swirl chamber 27. Relatively small waste (garbage β) such as sand dust and fine fiber waste passes through the second opening 31. And garbage (beta) falls in the 2nd dust collection chamber 29, and is captured.

  When the airflow swirling in the swirl chamber 27 reaches the lowermost part of the swirl chamber 27, the traveling direction is changed upward, and the airflow rises along the central axis of the swirl chamber 27. Garbage α and dust β are removed from the air forming the updraft. The airflow (clean air) from which the waste α and the waste β are removed passes through the fine holes formed in the first discharge pipe 41 and is discharged out of the swirl chamber 27. The air discharged from the swirl chamber 27 passes through each of the first discharge pipe 41 and the second discharge pipe 42 (outflow air passage 30) and reaches the unit outlet 43. Then, the clean air sequentially passes through the unit outlet 43 and the connection port 18 and is sent to the exhaust air passage 17.

  When the electric blower 8 performs a suction operation, the dust α is accumulated in the first dust collecting chamber 28 and the dust β is accumulated in the second dust collecting chamber 29. With the dust collection unit 11 having the above configuration, dust can be removed from the dust-containing air in two stages, and the collection performance can be improved.

  Hereinafter, the operation when the collected garbage is discarded will be described with reference to FIG. FIG. 12 is a diagram for explaining the operation when discarding garbage.

  When the electric vacuum cleaner 100 is used (when the electric blower 8 performs a suction operation) or during storage, the dust collection unit 11 (swirl chamber unit) is usually attached to the accommodation unit 10 by mounting means. Moreover, in the dust collection unit 11, the 1st dust collection part 22 is attached to the cylindrical part 19 by the 1st attachment / detachment means. The first lid 39 is held in a predetermined closed state by the first opening / closing means. The second lid 35 is held in a predetermined closed state by the second opening / closing means.

  Since bulky dust (garbage α) enters the first dust collection chamber 28, the first dust collection chamber 28 tends to accumulate dust faster than the second dust collection chamber 29. The first dust collecting unit 22 is configured to be removable from the swirl chamber unit in a state where the swirl chamber unit is fixed to the housing unit 10 by the mounting means. That is, by performing a predetermined release operation on the first attaching / detaching means, the fixing function of the first attaching / detaching means can be released and the first dust collecting part 22 can be detached from the swirl chamber unit. That is, only the first dust collecting portion 22 can be detached from the housing unit 10.

  After removing the first dust collecting unit 22 from the housing unit 10, a predetermined opening operation is performed on the first opening / closing means, the holding function of the first opening / closing means is released, and the first lid 39 is opened. Thereby, the waste α collected in the first dust collecting chamber 28 falls from the first outlet 40, and the waste α can be discarded.

  After discarding the garbage α, the first lid 39 is closed, and a predetermined closing operation is performed on the first opening / closing means. Thereby, the 1st cover body 39 can be returned to an original position, and can be hold | maintained in the obstruction | occlusion state. After closing the first lid 39, the first dust collecting part 22 is arranged at an appropriate position with respect to the cylindrical part 19, and a predetermined attaching operation is performed on the first attaching / detaching means. Thereby, the 1st dust collection part 22 can be fixed to a swirl chamber unit (for example, cylindrical part 19) in the state where the upper opening of the 1st dust collection part 22 was made to oppose the 1st opening 37 appropriately.

  The series of operations for discarding the waste α can be performed with the swirl chamber unit attached to the storage unit 10. For this reason, it is possible to reduce the waste disposal frequency of the waste β that is likely to rise when the waste is disposed of, and the waste can be disposed of in a sanitary manner.

  In addition, when the vacuum cleaner 100 is used, dust also accumulates in the second dust collection chamber 29. The second dust collection unit 23 is configured to be integrated with the first dust collection unit 22 so as to be removable from the storage unit 10. In the dust collection unit 11, the second dust collection unit 23 is formed integrally with the swirl chamber forming unit. For this reason, in the dust collection unit 11 of this structure, the swirl chamber unit and the first dust collection unit 22 are removed from the storage unit 10 as a unit. That is, by performing a predetermined release operation on the mounting means, the mounting function of the mounting means is canceled and the swirl chamber unit is removed from the storage unit 10. The first dust collecting unit 22 is fixed to the swirl chamber unit by the first attaching / detaching means. For this reason, by removing the swirl chamber unit from the storage unit 10, both the first dust collection unit 22 and the second dust collection unit 23 can be simultaneously removed from the storage unit 10.

  After removing both the first dust collection unit 22 and the second dust collection unit 23 (that is, the dust collection unit 11) from the storage unit 10, a predetermined opening operation is performed on the second opening / closing means, and the second opening / closing is performed. The holding function of the means is released and the second lid 35 is opened. As a result, the waste β collected in the second dust collecting chamber 29 falls from the second outlet 36, and the waste β can be discarded. At this time, it is also possible to perform a predetermined opening operation on the first opening / closing means to discard the waste α accumulated in the first dust collecting chamber 28.

  The dust collection unit 11 may be provided with a first connecting means (not shown). The first connecting means is for connecting the first opening / closing means and the second opening / closing means. Since the first dust collecting unit 22 is detachable from the swirl chamber unit, the first connecting means is, for example, when the first dust collecting unit 22 is attached to the swirl chamber unit by the first attaching / detaching unit. The first opening / closing means and the second opening / closing means are connected. When the first opening / closing means and the second opening / closing means are connected by the first connecting means, the first lid 39 and the second lid 35 can be opened simultaneously. That is, if the first opening / closing means and the second opening / closing means are connected by the first connecting means, the opening of the first opening / closing means and the opening operation of the second opening / closing means are performed. The body 39 and the second lid 35 can be opened together.

  The first connecting means does not need to physically connect the first opening / closing means and the second opening / closing means as long as the first opening / closing means and the second opening / closing means can be interlocked. For example, a protrusion may be provided on the first lid 39, and the operation portion of the second opening / closing means may be pushed by the protrusion when the first lid 39 is opened.

  After the waste β is discarded, the second lid 35 is closed and a predetermined closing operation is performed on the second opening / closing means. Thereby, the 2nd cover 35 can be returned to an original position, and can be hold | maintained in a obstruction | occlusion state. In addition, when the 1st cover body 39 is open, the 1st cover body 39 is closed by the same operation. After confirming that both the first lid 39 and the second lid 35 are closed, the dust collecting unit 11 is placed at an appropriate position in the housing portion 10a, and a predetermined mounting operation is performed on the mounting means. . Thereby, the dust collection unit 11 can be fixed to the storage unit 10 in a state where the unit inlet 32 is appropriately opposed to the connection port 16 and the unit outlet 43 is appropriately opposed to the connection port 18.

  The series of operations for discarding the waste β is performed in a state where the first dust collecting unit 22 is fixed to the swirl chamber unit. For this reason, when the waste β is discarded, the waste α can be discarded. The effort of throwing away trash is reduced, and usability can be greatly improved. When the first collection means is provided in the dust collection unit 11, both the waste α and the waste β can be discarded by a single opening operation, so that the operability can be further improved.

  Further, in the dust collection unit 11 having the above-described configuration, both the first outlet 40 and the second outlet 36 open toward the central axis direction (downward) of the swirl chamber 27. For this reason, the direction at which the waste α is discarded coincides with the direction at which the waste β is discarded, and the waste can be easily discarded.

  Furthermore, the first dust collection chamber 28 is provided so as to spread downward from the first opening 37. Therefore, the dust α is accumulated from the lowermost part of the first dust collection chamber 28. The dust collection space in the first dust collection unit 22 can be used without waste and the amount of collection can be increased. In addition, since the direction of waste accumulation and the direction of disposal are the same, the dust easily drops when the first lid 39 is opened, and can be easily discarded.

  When the dust collection unit 11 is appropriately attached to the storage unit 10 by the mounting means, the second dust collection unit 23 is disposed below the swirl chamber 27. The second opening 31 opens upward (obliquely upward) when viewed from the second dust collection chamber 29. Therefore, the waste β can be dropped into the second dust collection chamber 29 using gravity and can be deposited from the lower part of the second dust collection chamber 29. The dust collection space in the second dust collection unit 23 can be used without waste, and the amount of collection can be increased, and the frequency of waste disposal can be reduced.

  In the dust collection unit 11, the second base 34 of the second dust collection unit 23 is formed integrally with the conical unit 20. For this reason, the configuration of the swirl chamber unit can be simplified. Handling of the dust collection unit 11 is also facilitated.

  In the dust collection unit 11, the first opening 37 is formed in the cylindrical portion 19 that forms the side wall of the swirl chamber 27, and the first dust collection portion 22 is arranged side by side on the side of the swirl chamber forming portion. For this reason, even when the swirl chamber unit is attached to the housing unit 10, the first dust collecting part 22 can be easily attached to and detached from the housing unit 10 from the radial direction of the swirl chamber 27. That is, the first dust collecting part 22 can be attached to and detached from the storage unit 10 by pulling upward from the lateral direction, and usability can be improved. In particular, even when the bottom surface side of the dust collection unit 11 is covered with the housing unit 10 in order to stably hold the dust collection unit 11, the operability of the first dust collection unit 22 is not deteriorated.

  Further, the sealing direction when connecting the first dust collecting chamber 28 to the swirl chamber 27 can be made to coincide with the radial direction of the swirl chamber 27. For this reason, even if the attaching / detaching direction of the first dust collecting part 22 is made to coincide with the radial direction of the swirl chamber 27, the sealing performance is not impaired. It is possible to reliably prevent the dust-containing air in the swirl chamber 27 from leaking from the connecting portion between the first dust collecting unit 22 and the swirl chamber forming unit.

  In the dust collection unit 11, the first dust collection chamber 28 extends downward (in the direction of the central axis of the swirl chamber 27) from an opening (opening facing the first opening 37) disposed in the upper portion of the first base 38. The swirl chamber 27 is formed so as to extend in the swirl direction. For this reason, the dust (particularly, the waste α) can be caused to flow into the first dust collection chamber 28 by using the momentum of the dust swirling in the swirl chamber 27. It is possible to suppress a large amount of dust from flowing downstream from the first opening 37, and to reduce the frequency of waste disposal in the second dust collecting chamber 29.

Furthermore, the dust collection unit 11 may have the following configuration.
For example, the volume of the second dust collecting chamber 29 in which the dust β is collected is made larger than the volume of the first dust collecting chamber 28 in which the dust α is collected. With such a configuration, it is possible to further reduce the waste disposal frequency of the waste β that is likely to rise when the waste is disposed. Moreover, the 1st dust collection part 22 which needs frequent attachment and removal for garbage disposal can be reduced in size. For this reason, handling of the 1st dust collection part 22 becomes easy, and usability can be improved.

  Further, for example, when the dust collection unit 11 (swirl chamber unit) is removed from the storage unit 10, the first dust collection unit 22 cannot be removed from the swirl chamber unit. That is, when the swirl chamber unit is removed from the storage unit 10, the first attaching / detaching means maintains the state in which the first dust collecting unit 22 is fixed to the swirl chamber unit even if a predetermined release operation is performed.

  With such a configuration, when the dust collection unit 11 is attached or detached, or after the dust collection unit 11 is removed from the storage unit 10, the first dust collection unit 22 falls unintentionally and dust is scattered around. Can be prevented. The dust collection unit 11 can be handled easily and the usability can be improved.

  Moreover, when the dust collection unit 11 is provided with the 1st connection means, only the operation lever (operation means) for operating the 1st opening / closing means is installed. That is, no means for operating the second opening / closing means is installed. When the first dust collecting unit 22 is removed from the swirl chamber unit and the waste α is discarded, the first lid 39 is opened by opening the operation lever. Similarly, when the dust collection chamber unit 11 is detached from the storage unit 10 and the waste α and the waste β are discarded, the operation lever is opened. The second opening / closing means is connected to the first opening / closing means by the first connecting means. For this reason, the second lid 35 is opened and closed in conjunction with the first lid 39 by the opening / closing operation on the operation lever.

  With this configuration, it is possible to unify the operations when throwing away the garbage. For this reason, the operation procedure is easy to understand, and usability can be improved.

  Further, when the dust collection unit 11 is appropriately attached to the storage unit 10 by the mounting means, the first opening 37 (particularly, the downstream edge with respect to the swirling direction of the swirl chamber 27) The dust-containing air swirling in the swirl chamber 27 is arranged in a portion that flows downward (not upward).

  When the dust collection unit 11 is attached to the storage unit 10, the swirl chamber 27 passes through the central axis of the swirl chamber 27 and has a vertical plane as a reference, and a region where dust-containing air flows upward against gravity, It can be divided into two areas: a direction where gravity acts and an area flowing downward. The 1st opening 37 is arrange | positioned at the side wall which forms the area | region where dust-containing air displaces vertically downward. For example, in the state shown in FIG. 5, the turning direction of the swirl chamber 27 is counterclockwise. A vertical plane passing through the central axis of the swirl chamber 27 is represented by a line F. In such a case, the first opening 37 is formed in a portion of the cylindrical portion 19 located below the straight line F.

  With such a configuration, when the dust enters the first dust collection chamber 28 from the swirl chamber 27, the momentum is not weakened by gravity. For this reason, more dust (especially bulky waste α) can be collected in the first dust collection chamber 28, and the frequency of waste disposal in the second dust collection chamber 29 can be reduced.

  Further, the second dust collecting part 23 is detachably provided on the swirl chamber forming part by a predetermined second attaching / detaching means. For example, the second base 34 of the second dust collecting portion 23 is attached to the conical portion 20 by the second attaching / detaching means. If it is this structure, the 2nd dust collection part 23 (2nd base | substrate 34) can be removed from a turning chamber formation part as needed. Since the inner wall of the second dust collecting unit 23 (second base 34) can be easily cleaned, maintenance of the second dust collecting unit 23 is facilitated.

In the dust collection unit 11, it is desirable to arrange the first dust collection unit 22 as shown in FIG.
That is, the first opening 37 is arranged in the upper part of the cylindrical portion 19 when the dust collection unit 11 is appropriately attached to the storage unit 10 by the mounting means.

  When the dust collection unit 11 is mounted on the storage unit 10, the swirl chamber 27 has an upper region and a lower region on the basis of a plane passing through the central axis of the swirl chamber 27 and parallel to the upper surface 10 b of the storage unit 10. The area is divided into two areas. The first opening 37 is disposed on the side wall that forms the upper region. In the state shown in FIG. 5, a plane that passes through the central axis of the swirl chamber 27 and is parallel to the upper surface 10 b of the storage unit 10 is represented by a line G. In such a case, the first opening 37 is formed in a portion of the cylindrical portion 19 located on the left side of the line G.

  Further, when the dust collection unit 11 is appropriately attached to the storage unit 10 by the mounting means, a portion of the first dust collection unit 22 that is disposed on the upper surface 10b side than the surface represented by the line G is And extend in a direction perpendicular to the upper surface 10b.

  With such a configuration, the attaching / detaching direction of the first dust collecting portion 22 can be matched with the direction perpendicular to the upper surface 10b. The user can easily attach and detach the first dust collecting part 22 to the swirl chamber forming part by an operation from the front side of the cleaner body 5. The first dust collecting unit 22 can be easily handled, and usability can be improved.

  Further, the upper surface of the first dust collecting unit 22 (first base 38) is inclined so that the height decreases as the distance from the first opening 37 in the turning direction increases. Similarly, the upper surface of the first dust collecting unit 22 is inclined so that the height decreases as the distance from the first opening 37 in the radial direction of the swirl chamber 27 increases. With this configuration, the dust that has entered the first dust collection chamber 28 from the first opening 37 can be moved downward along the upper wall of the first dust collection chamber 28. For this reason, the dust in the first dust collection chamber 28 accumulates from the lower part of the second dust collection chamber 29. The dust collection space in the first dust collection unit 22 can be used without waste to increase the amount of collection, and the frequency of waste disposal can be reduced.

Embodiment 2. FIG.
FIG. 13: is a perspective view which shows the dust collection unit of the vacuum cleaner in Embodiment 2 of this invention. FIG. 14 is a diagram for explaining the operation when discarding garbage.
As shown in FIGS. 13 and 14, in the dust collection unit 11 in the present embodiment, the specific configurations of the first dust collection unit 22 and the second dust collection unit 23 are different from those in the first embodiment. . Other configurations are the same as the configurations disclosed in the first embodiment.

The second dust collecting unit 23 includes a second base body 44, a second lid body 45, and second holding means (not shown).
The second base 44 has a cylindrical shape with the lower part closed. The upper end of the second base 44 opens upward. This opening formed at the upper end of the second base 44 forms a second outlet 46. The second outlet 46 is an opening for discarding the dust accumulated in the second dust collection chamber 29.

  The second lid 45 is for opening and closing the upper end (second outlet 46) of the second base 44. The second lid 45 has a predetermined structure that can seal the second outlet 46. The second lid 45 is provided integrally with the conical portion 20 such that the conical portion 20 penetrates from the upper surface, for example.

  The second holding means has a predetermined structure that can hold the second base body 44 in a state where the second outlet 46 is completely closed by the second lid 45 (closed state). When a predetermined opening operation is performed, the second holding unit releases the holding state that holds the second base body 44 in the closed state. That is, the second base 44 can be removed from the second lid 45 by releasing the holding state.

The first dust collecting unit 22 includes a first base 47, a first lid 48, and first holding means (not shown).
The first base body 47 has a cylindrical shape whose lower part is closed. The upper end of the first base 47 opens upward. This opening formed at the upper end of the first base 47 forms a first outlet 49. The first outlet 49 is an opening for discarding the dust accumulated in the first dust collection chamber 28. Similar to the second outlet 46, the first outlet 49 opens toward the central axis direction (upward) of the swirl chamber 27.

  The first lid 48 is for opening and closing the upper end (first outlet 49) of the first base 47. The first lid 48 has a predetermined structure that can seal the first outlet 49. The first lid 48 is detachably fixed to the cylindrical portion 19 by, for example, a first attaching / detaching means. The first lid 48 is formed with an opening facing the first opening 37 at the top thereof.

  The first holding means has a predetermined structure that can hold the first base body 47 in a state (closed state) in which the first outlet 49 is completely closed by the first lid body 48. When a predetermined opening operation is performed, the first holding unit releases the holding state that holds the first base body 47 in the closed state. That is, by releasing the holding state, the first base 47 can be removed from the first lid 48.

  The operation when the collected garbage is discarded will be described below.

  After the first dust collecting unit 22 is removed from the housing unit 10, a predetermined opening operation is performed on the first holding unit to remove the first base body 47 from the first lid body 48. Thus, if the first base 47 is turned upside down, the waste α accumulated in the first dust collecting chamber 28 can be discarded from the first outlet 49. Also in the present embodiment, the above series of operations for discarding the waste α can be performed entirely with the swirl chamber unit attached to the storage unit 10. For this reason, it is possible to reduce the waste disposal frequency of the waste β that is likely to rise when the waste is disposed of, and the waste can be disposed of in a sanitary manner.

  When the waste β is discarded, a predetermined release operation is performed on the mounting means, and the swirl chamber unit (dust collection unit 11) is removed from the storage unit 10. After the dust collection unit 11 is removed from the storage unit 10, a predetermined opening operation is performed on the second holding unit, and the second base 44 is removed from the second lid 45. Accordingly, if the second base 44 is turned upside down, the waste β collected in the second dust collecting chamber 29 can be discarded from the second outlet 46. At this time, it is also possible to perform a predetermined opening operation on the first holding means to discard the waste α accumulated in the first dust collecting chamber 28.

  Also in the present embodiment, the dust collection unit 11 may be provided with first connection means (not shown). In the dust collection unit 11 having the above configuration, the first connecting means connects the first holding means and the second holding means. Since the first dust collecting unit 22 is detachable from the swirl chamber unit, the first connecting means is, for example, when the first dust collecting unit 22 is attached to the swirl chamber unit by the first attaching / detaching unit. The first holding means and the second holding means are connected.

  When the first holding means and the second holding means are connected by the first connecting means, the removal of the first base 47 from the first lid 48 and the removal of the second base 44 from the second lid 45 are performed. , Will be able to do at the same time. That is, if the first holding means and the second holding means are connected by the first connecting means, the first base body can be obtained by performing either the opening operation for the first holding means or the opening operation for the second holding means. Both 47 and the second base body 44 can be removed from the swirl chamber forming portion side.

  The series of operations for discarding the waste β is performed in a state where the first dust collecting unit 22 (the first base 47) is fixed to the swirl chamber unit. For this reason, when the waste β is thrown away, the waste α can be thrown away. The effort of throwing away trash is reduced, and usability can be greatly improved. When the first collection means is provided in the dust collection unit 11, both the waste α and the waste β can be discarded by a single opening operation, so that the operability can be further improved.

  In the dust collection unit 11 having the above configuration, when the second base 44 is removed, the second outlet 46 faces upward, so that the user can discard the waste while adjusting the falling speed of the waste. . For this reason, it is possible to suppress the rising of the garbage when the garbage is thrown away. The same effect can be obtained for the first base 47.

The dust collection unit 11 may employ the following configuration.
For example, when the dust collection unit 11 is provided with the first connection means, only the operation lever (operation means) for operating the first holding means is installed. That is, no means for operating the second holding means is installed. When the first dust collecting unit 22 is removed from the swirl chamber unit and the waste α is thrown away, the first base 47 is removed by opening the operation lever. Similarly, when the dust collection chamber unit 11 is detached from the storage unit 10 and the waste α and the waste β are discarded, the operation lever is opened. The second holding means is connected to the first holding means by the first connecting means. Therefore, both the first base body 47 and the second base body 44 can be removed at the same time by the opening operation with respect to the operation lever.

  With this configuration, it is possible to unify the operations when throwing away the garbage. For this reason, the operation procedure is easy to understand, and usability can be improved.

  Further, the dust collection unit 11 may be provided with predetermined second connecting means. The second connecting means is for connecting the second base 44 to the first base 47 when the second base 44 is detached from the second lid 45. In particular, when the dust collection unit 11 is provided with the first connecting means, both the first base 47 and the second base 44 can be removed by performing an opening operation on the first holding means or the second holding means. it can. If the 2nd connection means is provided at this time, the 1st base 47 and the 2nd base 44 which were removed from the turning chamber formation part side can be handled as one. For this reason, handling becomes easy and usability can be improved. If the heights (positions) of the first outlet 49 and the second outlet 46 are aligned, handling becomes easier.

Embodiment 3 FIG.
FIG. 15 is a sectional view showing a vacuum cleaner main body of the electric vacuum cleaner according to Embodiment 3 of the present invention. FIG. 15 is a view corresponding to the AA cross section of FIG.
The cleaner body 5 in the present embodiment is different from that in the first or second embodiment in that it includes dust detection means and notification means. Other configurations are the same as those disclosed in the first or second embodiment.

  The dust detection means has a function of detecting that a predetermined amount of dust has accumulated in the second dust collection chamber 29. The dust detection means includes a transmission unit 50, a reception unit 51, a reflection unit 52, and a control unit (not shown). The configuration (transmission unit 50, reception unit 51, control unit) other than the reflection unit 52 is provided in the storage unit 10, for example.

  The transmitter 50 is provided on the upper surface 10b of the accommodation unit 10, for example. The transmitter 50 is disposed so as to face the side wall that forms the second dust collection chamber 29 when the dust collection unit 11 is appropriately attached to the storage unit 10. The transmission unit 50 transmits a predetermined detection signal toward the second dust collection unit 23. The detection signal transmitted from the transmitter 50 passes through the side wall (for example, the second base 34) that forms the second dust collection chamber 29 and passes through the second dust collection chamber 29. As the detection signal, for example, light, infrared light, ultrasonic waves, or the like can be used.

  Similarly to the transmission unit 50, the reception unit 51 is provided on the upper surface 10b of the accommodation unit 10, for example. The receiving unit 51 is disposed so as to face the side wall forming the second dust collecting chamber 29 when the dust collecting unit 11 is appropriately attached to the housing unit 10. The reception unit 51 receives the detection signal transmitted from the transmission unit 50. In the configuration illustrated in FIG. 15, the transmission unit 50 and the reception unit 51 are directed in the same direction. The reflection unit 52 is provided for reflecting the detection signal transmitted from the transmission unit 50 and switching its traveling direction.

  The reflection part 52 is provided, for example, on the outer peripheral surface of the conical part 20 disposed inside the second dust collection part 23. If there is no dust in the second dust collection chamber 29, the detection signal transmitted from the transmission unit 50 passes through the second dust collection chamber 29 and is reflected by the reflection unit 52. The detection signal reflected by the reflection unit 52 travels again through the second dust collection chamber 29, passes through a side wall (for example, the second base 34) that forms the second dust collection chamber 29, and is received by the reception unit 51. .

  The path along which the detection signal travels is set according to the dust detection position. That is, if dust accumulates in the second dust collecting chamber 29 and the path of the detection signal is blocked by dust, the reception unit 51 cannot receive the detection signal transmitted by the transmission unit 50, or the reception intensity thereof decreases. To do. The transmission unit 50 and the reception unit 51 are controlled by the control unit. If the intensity of the signal received by the receiving unit 51 is less than or equal to a predetermined value when the detection signal is transmitted from the transmitting unit 50, the control unit confirms that a predetermined amount of dust has accumulated in the second dust collection chamber 29. To detect.

  The notification means has a function of notifying the result detected by the dust detection means. The notification means is configured by a notification device 53 such as a lamp, for example. The alarm device 53 is disposed in a place that is easily visible to the user, for example, a place that is not covered by the dust collection unit 11 in the upper surface of the storage unit 10.

  When the controller detects that a predetermined amount of dust has accumulated in the second dust collection chamber 29, the controller turns on the alarm 53 to notify the user that it is time to discard the dust.

  As described above, it is difficult for dust to collect in the second dust collection chamber 29. In addition, the collected garbage is often small. For this reason, it is not necessary to frequently throw away the dust collected in the second dust collecting chamber 29, and it is difficult for the user to know the time. With the dust collection unit 11 having the above-described configuration, it is possible to accurately notify the time for discarding the dust in the second dust collection chamber 29. The user frequently throws away the dust in the second dust collecting chamber 29 to cause the dust to rise, or more than the capacity of dust accumulates in the second dust collecting chamber 29, and the separation performance of the dust decreases. Can be prevented.

  The dust detection means may have any configuration as long as the above function can be realized. FIG. 16: is sectional drawing which shows the other example of the cleaner body of the vacuum cleaner in Embodiment 3 of this invention.

  In the cleaner body 5 shown in FIG. 16, the transmission unit 50 and the reception unit 51 of the dust detection means are installed on the side wall (exhaust air passage forming unit 13) that forms the exhaust air passage 17. The receiving unit 51 is disposed so as to face the transmitting unit 50. For this reason, the receiving unit 51 can directly receive the detection signal transmitted from the transmitting unit 50. The dust detection means of this configuration does not include the reflection unit 52.

  When dust exceeding the capacity accumulates in the second dust collecting chamber 29, the separation performance of the dust is deteriorated, and the dust flows into the exhaust air passage 17. In the dust detection means having the above configuration, when the intensity of the signal received by the receiving unit 51 becomes a predetermined value or less, it is determined that the detection signal is blocked by the dust flowing through the exhaust air passage 17, and Detect that a certain amount of garbage has accumulated. When the controller detects that a predetermined amount of dust has accumulated in the second dust collection chamber 29, the controller turns on the alarm 53 to notify the user that it is time to discard the dust.

  In the cleaner body 5 shown in FIG. 16, the dust detection means can be realized with a simpler configuration. There is no need to install the reflecting portion 52 in the dust collecting unit 11. For this reason, maintainability can be improved.

  As another example of the dust detection means, the transmission unit 50 and the reception unit 51 may be opposed to each other with the second dust collection chamber 29 interposed therebetween.

  In the first to third embodiments, the case where the first opening 37 and the first dust collecting unit 22 are provided on the upstream side of the second opening 31 and the second dust collecting unit 23 has been described. However, the first opening 37 and the first dust collecting unit 22 may be provided on the downstream side of the second opening 31 and the second dust collecting unit 23. For example, the second opening 31 is disposed on the upstream side of the first opening 37, and a fine pore mesh is provided in the second opening 31. Thereby, in the 2nd dust collection part 23 of an upstream, the waste (beta) which passed the microporous mesh of the 2nd opening 31 is collected. Thereafter, the waste α is collected in the first dust collecting section 22 on the downstream side.

  By adopting such a configuration, even if the dust β once collected in the second dust collecting unit 23 is small and wound up by an air flow and returned to the swirl chamber 27, the first downstream side In the dust collection part 22, it becomes possible to collect garbage (beta) with garbage (alpha) again. For this reason, high dust collection performance is securable.

  In the first to third embodiments, the canister type vacuum cleaner 100 has been described. However, the present invention may be applied to other types of vacuum cleaners.

DESCRIPTION OF SYMBOLS 1 Suction port body 2 Suction pipe 3 Connection pipe 4 Suction hose 5 Vacuum cleaner main body 6 Handle 7 Operation switch 8 Electric blower 9 Power supply cord 10 Accommodating unit 10a Accommodating part 10b Upper surface 11 Dust collecting unit 12 Intake air path formation part 13 Exhaust air path Forming part 14 Wheel 15 Suction air path 16, 18 Connection port 17 Exhaust air path 19 Cylindrical part 20 Cone part 21 Inflow pipe 22 First dust collecting part 23 Second dust collecting part 24 First discharge part 25 Second discharge part 26 Inflow Air passage 27 Swirl chamber 28 First dust collection chamber 29 Second dust collection chamber 30 Outflow air passage 31 Second opening 32 Unit inlet 33 Inlet 34, 44 Second base 35, 45 Second lid 36, 46 Second Outlet 37 First opening 38, 47 First base body 39, 48 First lid body 40, 49 First outlet 41 First discharge pipe 42 Second discharge pipe 43 Unit outlet 50 Shin portion 51 receiving portion 52 reflecting portion 53 annunciator 100 vacuum cleaner

Claims (12)

A swirl chamber that swirls the dust-containing air flowing in from the inlet and separates dust from the dust-containing air;
A swirl chamber forming portion that forms the one swirl chamber;
A first opening provided in the swirl chamber forming portion;
A first dust collecting portion, the interior of which communicates with the swirl chamber via the first opening;
A second opening provided in the swirl chamber forming portion and disposed downstream of the first opening ;
A second dust collecting portion whose inside communicates with the swirl chamber via the second opening;
With
The first dust collecting unit collects dust larger than the second dust collecting unit, and the swirl chamber forming unit and the second dust collecting unit are fixed to a predetermined storage unit, Can be removed from the containment unit,
The first dust collecting part and the second dust collecting part can be removed from the housing unit as a unit. 2. The cyclone according to claim 1, wherein the second dust collection chamber formed inside the second dust collection portion has a volume larger than that of the first dust collection chamber formed inside the first dust collection portion. Separation device. The first opening is formed in a portion of the swirl chamber forming portion that forms a side wall of the swirl chamber,
The cyclone separator according to claim 1 or 2 , wherein the first dust collecting part is arranged side by side on the side of the swirl chamber forming part. Wherein the first dust collecting portion, the internal space from the opening opposite the first opening, according to any one of claims 1 to 3 which is formed so as to spread in the turning direction of the swirling chamber Cyclone separation device. The second dust collection part is disposed below the swirl chamber when properly attached to the storage unit, and the second opening opens upward as viewed from the internal space. cyclonic separating apparatus as claimed in any one of claims 1 to 4. The first opening is formed in a portion of the swirl chamber forming portion that forms a side wall of the swirl chamber,
When the swirl chamber forming portion is appropriately attached to the housing unit, the edge portion on the downstream side of the first opening displaces dust-containing air swirling in the swirl chamber vertically downward in the swirl chamber. cyclonic separating apparatus as claimed in any one of claims 1 to 5 which is arranged on the side wall to form a region. A cyclone separator as claimed in any one of claims 6,
A blower for generating a predetermined air flow inside the cyclone separator;
Vacuum cleaner with Dust detection means for detecting that a predetermined amount of dust has accumulated in the second dust collecting section;
The vacuum cleaner according to claim 7 , comprising: The dust detection means includes:
A transmission unit that is provided in the housing unit and transmits the detection signal so that a predetermined detection signal passes through the inside of the second dust collecting unit;
A receiving unit that is provided in the housing unit and receives a detection signal transmitted from the transmitting unit;
The vacuum cleaner of Claim 8 provided with. A reflection unit for reflecting the detection signal transmitted from the transmission unit;
With
A part of the swirl chamber forming part is disposed inside the second dust collecting part,
The vacuum cleaner according to claim 9 , wherein the reflecting portion is provided in the part of the swirl chamber forming portion. An exhaust air passage through which the air discharged from the cyclone separator passes,
An exhaust air passage forming portion that forms the exhaust air passage;
With
The dust detection means includes:
A transmission unit that is provided in the exhaust air passage formation unit and transmits a predetermined detection signal;
A receiving unit that is provided in the exhaust air passage forming unit and receives a detection signal transmitted from the transmitting unit;
The vacuum cleaner of Claim 8 provided with. Informing means for informing the detection result of the dust detecting means,
Vacuum cleaner according to any one of claims 11 claim 8 comprising a.

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