JP2003153840A - Vacuum cleaner - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide a vacuum cleaner in which the loss of an air stream is small and noise is reduced. SOLUTION: The air suction port 33a of a motor-driven fan 32 is arranged at the lower part of a cleaner body 21. An inner cylinder (exhaust cylinder part) 48a which is arranged in the center part of a cyclone-type dust collecting container 23 and whose exhaust port 48e at an upper end opens in the upper end part of the dust collecting container 23 is provided, and the lower end of the inner cylinder 48a is communicated with the air suction port 33a at the lower end of the fan 32 via an air duct 36 formed at the lower part of a cleaner body 44.

Description

Detailed Description of the Invention

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to an electric vacuum cleaner having a cyclone type dust collecting container.

[0002]

2. Description of the Related Art As a conventional electric vacuum cleaner, one having a cleaner main body as shown in FIG. 16 is considered.
This cleaner body has a body case 1 and an upper lid 2 that covers the upper part of the body case 1. This upper lid 2 is the main body case 1
A hinge (not shown) is attached to the rear end portion of the rear end portion so as to be vertically rotatable.

As shown in FIG. 17, a concave portion 3 for placing a container is formed in the front portion of the main body case 1, and the main body case 1 is formed.
A communication port 4 into the body case 1 is formed at the upper end of the rear part. The communication port 4 is covered with a filter 5. Moreover, in the rear part of the main body case 1, as shown in FIG.
As shown in 0, the electric blower 6 with the suction port 6a facing upward is built in. The suction port 6a is communicated with the communication port 4.

Further, a pipe portion 7 for connecting a hose is integrally provided at the front end portion of the upper lid 2, and a communication port 8 communicating with the pipe portion 7 is formed. A dust collecting hose H (not shown) is detachably connected to the pipe portion 7, and a suction port is connected to the dust collecting hose H through an extension pipe (not shown). Moreover, the upper lid 2 has an air inlet 9a.
And an air passage 9 having an air outlet 9b.

When the upper lid 2 is opened as shown in FIGS. 17 and 18, the lower portion of the cyclone type dust collecting container 10 is placed in the recess 3 of FIG. 17 as shown in FIG. The container 10 can be removed from the recess 3. This dust collecting container 10 has a bottomed cylindrical container body 11
And a filter 12 that closes the upper end of the container body 11. The filter 12 is provided with an air inlet 13 for guiding air into the container body 11.

Further, when the lower portion of the cyclone type dust collecting container 10 is placed in the concave portion 3 of FIG. 17 as shown in FIG. 18, the upper lid 2 is closed so that the upper portion of the main body case 1 as shown in FIG. Also, the upper part of the dust container 10 is covered. In this state, the communication port 8 is the air inlet 1
3, the upper end of the container body 11 communicates with the air inlet 9a of the air passage 9 through the filter 12, and the air outlet 9b of the air passage 9 communicates with the communication outlet 4 through the filter 5. ing.

In such a structure, when the electric blower 6 is operated to move the suction port body on the cleaning surface, dust on the cleaning surface is sucked into the suction port body together with the air. After that, the air containing dust sucked into the suction port body is guided to the communication port 8 via the extension pipe (not shown) and the dust collecting hose H.

Next, the air guided to the communication port 8 flows into the container body 11 from the air inlet port 13 in the circumferential direction and downward, and swirls downward (swirl) into the container body 11. Flow) is formed. At this time, a part of the dust contained in the air is separated from the swirling air by its own weight and falls and accumulates on the bottom of the container body 11. On the other hand, the air flowing downward while swirling flows upward from the center of the container body 11 and passes through the filter 12. At this time, the remaining dust contained in the air is captured by the filter 12. The air that has passed through the filter 12 is sucked into the electric blower 6 through the air passage 9 and the filter 5, cools the electric blower 6, and is exhausted to the atmosphere through the exhaust hole 1a.

[0009]

However, in the electric vacuum cleaner having such a structure, after the air flowing into the dust collecting container 10 flows to the lower part of the container body 11 as shown by the arrow 14, the electric cleaning is performed. Arrow 1 by suction negative pressure of blower 6
As shown at 5, the filter 12 is raised upwards.
Since it is sucked into the air passage 9 in the lid body 2 from the above, the loss of the air flow was large.

Further, in the above vacuum cleaner, the dust container 1
The air that has flowed into 0 through the air passage 9 in the upper lid 2 is shown in FIG.
9. As shown in FIG. 20, the electric blower 6 is sucked, and the suction port 6a of the electric blower 6 is directed upward, so that a sound generated when the air flows through the air passage 9 or The sound generated in the electric blower 6 leaks upward through the relatively thin lid plate 2 and causes noise, which is not preferable.

Therefore, an object of the present invention is to provide an electric vacuum cleaner in which the loss of air flow is small and the noise can be reduced.

[0012]

In order to achieve this object, the invention of claim 1 sucks air containing dust into the inside from an air inlet at the upper part of the dust container and collects the sucked air. By causing a swirling flow in the circumferential direction along the inner peripheral surface of the dust container, the dust contained in the air is separated from the air by its own weight and is dropped and deposited on the bottom of the dust container, and the dust is In an electric vacuum cleaner configured to suck the separated air through a filter into an electric blower built in the cleaner main body, the air suction port of the electric blower is located at the bottom of the cleaner main body,
At the center of the dust collecting container, an exhaust tube portion having an upper end exhaust port opening into an upper end portion of the dust collecting container is provided, and a lower end portion of the exhaust tube portion is provided at an air intake port of the electric blower with the cleaner body. It is characterized in that it is an electric vacuum cleaner that is communicated through an air passage provided in the lower part of.

[0013]

Embodiment 1 of the Invention Hereinafter, Embodiment 1 of the present invention will be described.
Will be described with reference to the drawings. [Structure] FIGS. 1 to 3 show a cleaner body 20 of an electric vacuum cleaner. This vacuum cleaner body 20 includes a body case 2
1, a lid 22, and a cyclone type dust collecting container 23.
The main body case 21 has a container mounting portion 24 on the front side as shown in FIGS. 2 and 3, and has a blower chamber 25 on the rear portion as shown in FIG. The blower chamber 25 communicates with the exhaust port 21a shown in FIGS. 1 and 2 via an air passage (not shown). <Main Body Case 21> A grip portion engaging hole 24a that opens upward is formed at the front end portion of the container main body 24. Further, a recess 26 for disposing the container that opens upward is formed in the container mounting portion 24, and an engaging cylinder portion 28 that protrudes upward is formed in the center of the bottom wall 27 of the recess 26. The engagement tube portion 28 is formed in a tapered shape, that is, a shape that is curved and is tapered toward the tip.

The blower chamber 25 has a bottom wall 29 having substantially the same height as the bottom wall 27. The bottom wall 29 has through holes 3
0 is formed, and the cylindrical portion 3 is concentric with the through hole 27.
1 is integrally formed upward. Moreover, the bottom wall 2
An electric blower 32 is arranged on the upper part 9. The electric blower 32 includes a centrifugal fan 33 having an air suction port 33a.
And a drive motor 34 for driving the centrifugal fan 33. The air suction port 33a of the centrifugal fan 33 is directed downward and faces the center of the through hole 30. Moreover, the centrifugal fan 33 is installed in the cleaner body 2
It is arranged in the rear part and the lower part. The centrifugal fan 33 is supported on the bottom wall 29 and in the tubular portion 31 via a tubular elastic member 35 made of rubber or the like. Moreover,
Below the bottom walls 27 and 29, an air passage 36 is formed that connects the engagement cylinder portion 28 and the air suction port 33a. <Lid Body 22> The rear end portion of the above-mentioned lid body 22 is attached to the main body case 21 via a hinge 37 so as to be vertically rotatable. The hinge 37 includes a hinge arm 38 attached to the lid 22 and the hinge arm 38.
1 has a support shaft 39 supported so as to be vertically rotatable.
As a result, the lid 22 is attached to the main body case 21 so as to be vertically rotatable about the support shaft 39.

At the front end portion of the lid body 23, a cylindrical hose connection port 40 extending in the front-rear direction and opening in the lid body 23 is formed. At the rear end of the hose connection port 40, a tubular portion 40a is formed which is inclined rearward as it goes upward.
A seal ring 41 is attached to the rear end of the tubular portion 40a.

Lock levers 42, 42 projecting downward when the lid 22 is closed are attached to the hose connection port 40. The lock levers 42, 42 are provided on the claw portion 4
2a and 42a are urged by elastic members (not shown) in directions away from each other. Further, the hose connection port 40 is equipped with a lock release button 43 (not shown on the other hand) protruding from the outer side surface. By pressing the lock release button 43 (other not shown), the gap between the lock levers 42, 42 and the claws 42a, 42a can be narrowed.

One end of a dust collection hose (not shown) is connected to the hose connection port 40, and a suction port is connected to the other end of the dust collection hose via an extension pipe (not shown). <Dust Collection Container 23> The cyclone type dust collection container 23 includes a dust collection container body 44, a handle 45 attached to the dust collection container body 44, and a filter frame 46 that closes the upper end of the dust collection container body 44. And a cap-shaped lid 47 that covers the upper portion of the filter frame 46. The dust collecting container body 44 has a dust collecting container 48 and a cyclone container 49 mounted in the upper end portion of the dust collecting container 48. (Dust Collection Container 48) This dust collection container 48 is shown in FIG.
As shown in FIG. 5 and FIG. 7, it has an inner cylinder (exhaust cylinder part) 48a and an outer cylinder 48b which are arranged inside and outside in a dual and concentric manner. The inner cylinder 48a is located at the center of the dust collection container 48. Moreover, a bottom wall 48c is formed between the lower ends of the inner cylinder 48a and the outer cylinder 48b. Further, the outer cylinder 48b is integrally formed with a cylindrical air inlet port 48d which is located at the upper end portion and opens laterally.

An exhaust port 48e for exhausting the air flowing into the dust collecting container 48 downward is formed at the upper end of the inner cylinder 48a as the exhaust cylinder. The exhaust port 48e is set (disposed) higher than the air inlet port 48d of the outer cylinder 48b.

The dust collecting container 48 is provided in the cleaner main body 21.
The lower part is inserted into the recess 26 in the front part of the above, and the bottom wall 48c is placed on the bottom wall 27 of the recess 26. Moreover, in the lower end of the inner cylinder (exhaust cylinder) 48 a of the dust collecting container 48, the engaging cylinder 28 protruding from the center of the bottom wall 27 is provided.
Are fitted in a substantially airtight manner. As a result, the inner cylinder 48
a is the centrifugal fan 3 of the electric blower 32 through the air passage 36.
3 is made to communicate with the suction port 33a. (Cyclone container 49) The cyclone container 49 is provided on the side wall (inner wall of the dust container) 50 inserted into the upper end portion of the dust collection container 48 and the lower end of the side wall 50 as shown in FIGS. Bottom wall (that is, an inclined wall that serves as a guide wall for dust fall) 51 and a flange 5 provided at the upper end of the side wall 50
Have two. The peripheral edge of the flange 52 is brought into contact with the upper end of the dust collection container 48.

As shown in FIG. 4, the side wall 50 has a horizontal cross section of a substantially cut circle. The side wall 50 has one side edge 50a inscribed in the outer cylinder 48b of the dust collection container 48 so as to match with one side of the air inlet port 48d and the air inlet port as shown in FIG. The other side edge 50b inscribed in the outer cylinder 48b so as to match the other side portion of 48d.
Have. Moreover, the side wall 50 includes a partition wall 50c extending from the other side edge 50b toward the tangential direction of the outer peripheral surface of the inner cylinder 48a provided in the dust collecting container 48, and an inner cylinder 48a from the one side edge 50a to the partition wall 50c. It has a spiral wall 50d extending along the outer cylinder 48b. This partition wall 50c and one side edge 50
An air inlet 50e is formed between a and a. The air inlet 50e and the air outlet 48d of the dust collecting container 48 form a series of air inlets A through which air flows in the tangential direction of the inner cylinder 48a.

The spiral wall 50d is formed so as to spiral toward the center side from the one side edge 50a toward the partition wall 50c. As a result, the inner wall surface of the spiral wall 50d is formed in a spiral shape from the one side edge 50a toward the partition wall 50c, and the outer peripheral edge 51a of the bottom wall 51 is also the one side edge 50.
It is formed in a spiral shape (spiral shape) from a toward the partition wall 50c.

Moreover, the bottom wall 51 which is a guide wall extends from the lower end of the inner wall surface of the spiral wall 50d to the inner cylinder 48a which is the exhaust cylinder part.
Projecting toward the inner peripheral edge 51b of the inner cylinder 4
8a is provided concentrically with a predetermined interval. Thus, a dust dropping gap 53 is formed between the inner peripheral edge 51b of the bottom wall 51 and the inner cylinder 48a.

The bottom wall (guide wall) 51 is an inner cylinder 48a.
And extending in a band shape in the circumferential direction at a predetermined interval, and the width thereof gradually narrows from the air inlet port toward the downstream side in the air flow direction (from one side edge 50a toward the partition wall 50c). Is formed. Moreover, the width of the bottom wall 51 is "0" at the partition wall 50c. Further, the bottom wall 51 is provided below the air suction port and provided inside the dust container body, and is inclined downward from the outer peripheral edge 51a toward the inner peripheral edge 51b (handle 45 and lock). Also, the handle 45 is connected to the lower surface of the air inlet port 48d, and has a hollow mounting portion 54 having one end integrally formed with the outer cylinder 48b and a lower end connected to the other end of the mounting portion 54. It is formed in an L shape from the provided hollow grip portion 55. On the upper wall 54a of the mounting portion 54,
Engagement holes 56, 56 into which the claw portions 42a, 42a of the lock levers 42, 42 provided in the hose connection port 40 are inserted and engaged are formed as shown in FIGS.

Further, the container locking means 5 is provided in the grip portion 55.
7 is provided. This container locking means 57 is shown in FIG.
As shown in FIG. 7, the support shaft 58 is rotatably mounted in the lower end of the grip portion 55, and the locking claw 59 is integrally provided on the support shaft 58 and rotates back and forth. Moreover, the locking claw 59
Is urged to rotate rearward by an elastic member (not shown), and the lower end claw portion 59a retracts into the grip portion 55. When the back surface of the locking claw 59 is pressed and displaced to the front side against the biasing force of the elastic member, the claw portion 59a of the locking claw 59 is formed.
2 can be projected from the grip portion 55 to the front side.

Further, the container locking means 57 has a slide member 60 which extends vertically and is arranged in the grip portion 55 so as to be vertically movable. The slide member 60 is biased upward by a spring (not shown) or the like. Then, the slide member 60 has the claw portions 42 of the lock levers 42, 42.
When the a and 42a are inserted into the engaging holes 56 and 56, they are pressed and displaced downward by the claws 42a and 42a to press the back surface of the locking claw 59, and the claws at the lower end of the locking claw 59. 59
The a is projected from the grip 55 to the front side. <Filter frame 46 and lid 48> This filter frame 46
Is the annular plate portion 46a and the annular plate portion 4 as shown in FIG.
6a and a lattice part 46b provided in the central portion of the 6a
It has a net filter 46c attached to the lower surface of b.
The entire lattice portion 46b is projected upward.
Moreover, a protrusion 46b1 that protrudes downward is formed at the center of the lattice portion 46b. By thus providing the protrusion 46b1 at the center of the lattice 46b, the lattice 46b
An annular recess 46b2 is formed on the lower surface of the.

Such an annular plate portion 46a of the filter frame 46
Are abutted on the flange 52 of the cyclone container 49 so that their peripheral edges are aligned with each other. Moreover, the filter frame 46 is covered with a cap-shaped lid 47. The cylindrical portion 47a of the lid 47 is fitted to the peripheral portion of the annular plate portion 46a and the peripheral portion of the flange 52, and also fitted to the outer periphery of the upper end portion of the outer cylinder 48b provided in the dust collecting container 48. Has been done. As a result, the cyclone container 49 and the filter frame 46 are held at predetermined positions with respect to the dust collection container 48. [Operation] Next, the operation of the electric vacuum cleaner having such a configuration will be described. (1) Setting of dust collecting container With such a configuration, the lower end of the grip portion 55 of the dust collecting container 23 is inserted into the grip portion engaging hole 24a with the lid 22 opened as shown in FIG. By fitting the lower end portion of the dust collecting container 23 into the disposing recess 26, the engaging cylinder portion 28 provided on the bottom wall 27 of the recess portion 26 becomes the inner cylinder 4 of the dust collecting container 23.
It is fitted in the lower end portion of 8a.

Next, the lid 22 of FIG. 3 is rotated downward to cover the upper part of the main body case 21 of the cleaner main body 20 and the upper part of the dust container 23, and the hose connection port 40 of the lid 22. The lock levers 42 provided on the
42a is an engagement hole 56 provided in the handle 45 of the dust container 23,
By being inserted into 56, the claw portions 42a, 42a are locked to the upper wall 54a of the mounting portion 54. Moreover, the slide member 60 has the claw portions 42a, 42 of the lock levers 42, 42.
When a is inserted into the engagement holes 56, 56, the claw portion 42
a, 42a are pressed and displaced downward, and the locking claw 5
The rear surface of 9 is pressed, and the claw portion 59a at the lower end of the locking claw 59 is projected from the grip portion 55 to the front side and locked in the grip portion engaging hole 24a.

In this way, the dust container 23 is attached to the lid 2
By covering it with 2, the hose connection port 4 provided on the lid 22
The rear end of 0 is the air inlet A of the dust container 23 (the air inlet 4
8d), the hose connection port 40 is communicated with the air inflow port A. Moreover, in this state, the dust container 2
The lid 47 of No. 3 is pressed by the lid 22 of the cleaner body 20. (2) Operation of dust container When the electric blower 32 is operated in such a configuration,
Suction negative pressure is generated in the suction port 33a of the centrifugal fan 33 of the electric blower 32. This suction negative pressure is applied to the air passage 36 and the inner cylinder 48.
a, a cyclone container 50, an air inflow port A, a hose connecting port 40, a dust collecting hose (not shown), and an extension pipe (not shown) to act on a suction port body (not shown).

By moving the suction port body along the cleaning surface in this state, dust on the cleaning surface is sucked into the suction port body together with air. The dust-containing air is supplied to the extension pipe, the dust collecting hose, and the hose connection port 4 not shown.
0 to the air inlet A of the cyclone container 49 as indicated by an arrow 60 in FIGS.

The air containing dust which has flowed into the air inlet A is introduced into the inner cylinder 4 of the dust collecting container 48 by the air inlet A.
After the flow is directed in the tangential direction of 8a, it flows so as to swirl along the spiral wall 50d of the side wall 50 and the bottom wall 51 toward the partition wall 50c. As a result, the air containing dust is
As it goes to the partition wall 50c, the center side, that is, the inner cylinder 48
It flows to the a side. In addition, since the bottom wall (partition wall) 51 for partitioning the dust collecting container body 44 into upper and lower portions is provided, the swirling flow of air as described above occurs in the upper portion of the dust collecting container body 44, that is, in the cyclone container 49. become. However, such a swirling flow of air is less likely to occur below the bottom wall 51 due to the presence of the bottom wall 51.

Further, the air containing the dust is separated from the partition wall 50.
The flow velocity decreases toward c and the partition wall 50
As it goes to c, it flows toward the center side, that is, the inner cylinder 48a side. Moreover, since the ridgeline, that is, the outer peripheral edge 51a of the bottom wall 51 is inclined downward as it goes toward the partition wall 50c, the inclination angle becomes smaller as it goes toward the partition wall 50c. That is, the bottom wall 51 approaches horizontal as it approaches the partition wall 50c.

Therefore, as for the dust contained in the air, the air and the dust are separated along the spiral wall 50d and the bottom wall 51.
When flowing toward the c side, the heavier ones are sequentially dropped downward by their own weight, and as the air and dust approach the partition wall 50c and the flow velocity of the air is reduced, the lighter ones are also downwardly dropped by their own weight and the bottom wall 51 Bottom wall 48 of the dust collection chamber below
will be deposited on c. At this time, the dust is smoothly guided downward along the upper surface (inclined surface) of the bottom wall 51 that inclines inward and is swirled in the circumferential direction by the inertial force. However, the dust is not swirled in the circumferential direction at high speed, but is swirled slightly in the circumferential direction and is accumulated on the bottom wall 48c. In this way, most of the dust contained in the air is deposited on the bottom wall 48c of the dust collection chamber. In addition, since the bottom wall 51 is provided with an inclination, heavy dust easily falls down without being caught by the bottom wall 51.

Further, the air flowing toward the partition wall 50c toward the center side, that is, the inner cylinder 48a side is the partition wall 50c.
The action of the bottom wall 51 in which the inclination angle approaches horizontal as it goes toward is gradually directed in the horizontal direction, and is prevented from flowing into the dust collecting chamber below the bottom wall 51. Moreover, the flow velocity of this air decreases toward the partition wall 50c as described above. As a result, the dust accumulated on the bottom wall 48c of the dust collecting chamber below the bottom wall 51 is agitated by the air flowing into the cyclone container 49 from the air inlet A,
This agitation does not cause energy loss of the air flowing into the cyclone container 49 from the air inlet A.

In addition, the width of the bottom wall 51 is widest on the air inlet A side, gradually narrows from the air inlet A in the air flow direction, and turns 360 ° from the air inlet A in the air flow direction. It is "0" in the part of the partition wall 50c at the open position. For this reason, since no step can be formed at the beginning (the widest portion) and the end (the portion whose width is “0”) of the bottom wall 51, the air flow becomes smooth.

On the other hand, since the flow velocity of the air containing dust decreases toward the partition wall 50c, this air is separated by the partition wall 5c.
As it goes to 0c, a part of the air flowing on the inner cylinder 48c side flows upward along the inner cylinder 48a, permeates the peripheral edge sides of the net filter 46c and the lattice portion 46b, and passes through the filter frame 46 and the lid. It flows in between the body 47. At this time, the remaining dust that flows upward together with the air without falling due to its own weight is captured by the net filter 46c.

After this, the air from which the remaining dust is captured and removed is the central portion of the lattice portion 46b and the net filter 46.
The exhaust port 4 at the upper end of the inner cylinder 48a is transmitted through the central portion of c.
8e flows into the inner cylinder (exhaust cylinder part) 48a. At this time, the dust remaining in the air is further captured by the filter 46c. In this way, the air from which dust contained in the air has been removed flows into the inner cylinder 48a. Incidentally, this lattice part 46
By attaching a filter having a finer mesh than the filter 46c on the recess 46b3 at the center of b, fine dust remaining in the air can be captured. It is desirable to provide such a filter.

The air flowing into the exhaust port 48e of the inner cylinder 46a flows downward in the inner cylinder 48a and flows into the air passage 36, and then through the air passage 36, the central suction port of the centrifugal fan 33. 33a, the centrifugal fan 3 from the suction port 33a
It is sucked into 3. The air sucked into the centrifugal fan 33 is blown into the drive motor 34 of the electric blower 32 by the centrifugal fan 33 to cool the inside of the drive motor 34, and then is discharged from the exhaust port 34a of the drive motor 34, and the main body case The gas is exhausted to the atmosphere from the exhaust hole 21 a of the exhaust gas.

In the centrifugal fan 33, the centrifugal fan 3
3 sucks air and blows it into the drive motor 34,
Generates noise such as wind noise. This wind noise is generated by the elastic member 3
Since it is difficult for the side surface of the centrifugal fan 33 covered with 5 to leak, most of it leaks to the outside of the centrifugal fan 33 from the suction port 33a. However, the suction port 33a is
Since the suction port 33a is located in the lower part of 1 and is directed downward, and the suction port 33a is open to the air passage 36, part of the wind noise of the centrifugal fan 33 forms the air passage 36.
It leaks to the outside of the air passage 36 through the a and the bottom wall 29. At this time, part of the wind noise is generated by the wall 3 forming the air passage 36.
Energy is absorbed by the 6a and the bottom wall 29, and the air passage 3
6 leaks to the outside of the wall 36a forming 6 and becomes a low volume. Therefore, the wind noise of the centrifugal fan 33 that leaks from the bottom wall 29 to the blower chamber 25 is reduced, so that the blower chamber 25
When the wind noise that leaks to the upper part penetrates the lid 22 further above and leaks upward, the energy of the wind noise is further absorbed,
The volume of the wind noise leaking upward from the lid 22 is extremely low. As a result, a very quiet vacuum cleaner can be provided. (3) Removal of dust container By pressing the lock release button 43 and narrowing the interval between the claws 42a, 42a, the claws 42a, 42a can be pulled out from the engagement holes 56, 56. And the claw portion 4
By pulling out 2a and 42a from the engagement holes 56 and 56, the slide member 60 is displaced upward by a biasing means such as a spring (not shown). As a result, the locking claw 59
Is released, the locking claw 59 is rotated rearward by a biasing means (not shown), and the claw portion 59a of the locking claw 59 is retracted into the grip portion 55, so that the grip portion 55 The lower end is unlocked. In this state, the dust container 23 can be removed from the recess 26 of the main body case 21 by opening the lid 22 upward. Then, by removing the lid 47 upward from the dust collecting container main body 44, the filter frame 46 can also be removed from the dust collecting container main body 44, and the dust captured by the net filter 46c of the filter frame 46 can be removed. Further, by extracting the cyclone container 49 upward from the dust collection container 48, the dust collected in the dust collection container 48 can be discarded.

As described above, according to the embodiment of the present invention, the air containing dust is sucked into the inside of the dust collecting container 48 from the air inlet A, and the sucked air is collected. By making a swirl flow in the circumferential direction along the inner peripheral surface of 48, the dust contained in the air is separated from the air by its own weight and dropped and deposited on the bottom of the dust container 48, and the dust is collected. The separated air is passed through the filter (net filter 46c) to the cleaner body 2
The electric blower 32 built into the 0 is made to suck. Moreover, the air suction port of the electric blower 32 is located at the lower part of the cleaner body 20, and the exhaust port 48e at the upper end is provided at the center of the dust collecting container 48.
An exhaust tube portion (inner tube 48a) that opens into the upper end portion of the cleaner. The lower end portion of the exhaust tube portion (inner tube 48a) is provided at the air suction port 33a of the electric blower 32 at a lower portion of the cleaner body 20. It is made to communicate via the wind path 36. According to this configuration, it is possible to reduce the air flow loss and reduce the noise.

Further, in the embodiment of the present invention, the exhaust port 48e is set at a position higher than the air inflow port A. According to this configuration, even if air containing dust flows into the dust container, the air does not immediately flow into the exhaust port and becomes a vortex in a direction along the inner peripheral surface of the dust container.
Most of the dust can be dropped and separated from the vortexed air by its own weight. .

Further, in the embodiment of the present invention, the dust collecting container 48 is provided so as to project from the inner wall surface (spiral wall 50d) toward the exhaust cylinder portion (inner cylinder 48a) and the exhaust cylinder portion (48a). ) And a guide wall (bottom wall 51) extending in the circumferential direction in a belt-like manner is provided below the air suction port in the dust container 48, and the guide wall (bottom wall) is provided. The wall 51) is inclined downward from the outer peripheral edge toward the inner peripheral edge. According to this structure, when the air containing dust flows along the inner wall surface of the dust container, the dust separated downward from the air by its own weight and falling downward can be smoothly guided downward.

In the embodiment of the present invention, the inner wall surface (the spiral wall 50d) is formed in a spiral shape in the air flow direction from the air inlet A, so that the guide wall (bottom wall 51) is formed. The outer peripheral edge is formed in a spiral shape. According to this structure, the air containing dust can be swirled along the inner wall surface so as to swirl.

Further, in the embodiment of the present invention, the width of the guide wall (bottom wall 51) is formed so as to become gradually narrower from the air inlet A toward the downstream in the air flow direction. With this configuration, the fluid resistance due to the guide wall decreases as the air containing dust flows downstream along the guide wall. Therefore, even if the flow velocity of the air flowing along the guide wall gradually decreases toward the downstream, the resistance of the air flow due to the guide wall gradually decreases toward the downstream, so that the air flows smoothly. [Modification] In the embodiment described above, the cyclone container 49
However, the cyclone container 49 is not always necessary. For example, as shown in FIG. 8A, the air inlet A is provided in the upper part of the dust collecting container 48, and the air inlet A is provided in the inner cylinder 48a and the outer cylinder 48b of the dust collecting container 48.
In addition to having a configuration in the direction parallel to the tangent line of FIG.
As shown in (b), a filter F may be provided at the exhaust port 48e of the inner cylinder 48a. The exhaust port 48e is provided at a position higher than the air inlet A.

Even in the case of such a construction, the air containing dust flows into the outer cylinder 48b of the dust collecting container 48 from the air inlet A. At this time, the air containing dust is
As shown in FIG. 5, after flowing into the outer cylinder 48b from the air inlet A toward the tangential direction of the inner wall surface of the outer cylinder 48b, the outer cylinder 48b
It flows in the circumferential direction and the horizontal direction along the inner wall surface of b, and as it returns to the air inlet A side, the flow velocity gradually decreases as shown by the length in the arrow 70. Then, the air containing dust is exhausted through the exhaust port 48e at the upper end of the inner cylinder 48a as the flow velocity decreases.
By the suction negative pressure acting on the inner cylinder 48a side and the inner cylinder 48
After flowing to the upper side of a and becoming a vortex, it is sucked into the exhaust port 48e through the filter F.

Most of the dust contained in the air swirls as shown by the arrow 81 in FIG. 8A when the air flows along the inner wall surface of the outer cylinder 48b as described above. After being separated from the air by falling downward due to its own weight, it is deposited on the bottom wall 48c. The rest of the dust will be captured by the filter F when the air passes through the filter F.

The air from which the dust has been removed in this manner flows downward in the inner cylinder 48a in the same manner as in the above-described embodiment, and then the centrifugal fan 3 of the electric blower 32 passes through the air passage 46.
It will be sucked into 3. Also in this case, the wind noise of the centrifugal fan 33 is generated by the main body case 2 as in the above-described embodiment.
It is possible to sufficiently reduce the amount of leakage to the outside of 1.

[0047]

Second Embodiment of the Invention FIG. 10 shows a second embodiment of the present invention. In the first embodiment of the invention described above, the swirling flow in which the air containing dust is caused to flow into the dust collecting container 48 and the inflowing air containing dust is directed toward the bottom side along the inner peripheral surface of the dust collecting container 48. (Swirl flow) separates the dust contained in the air from the air and deposits it on the bottom of the dust container 48, while the dust-free air is directed upward from the center of the dust container 48. It is turned upside down so that the turned up air is sucked into the electric blower 32 from the upper part of the dust collecting container 48. Here, when the swirling flow (vortex) of air toward the bottom side of the dust container is formed to separate the dust from the air, the vector component of the swirling flow of the air directed in the axial direction is the straight-ahead component of the air. Then,
The air flow after separating the dust does not contain a straight component,
It is only the inversion component. Therefore, the dust collecting container 48 according to the first embodiment of the invention uses a reversing type (reversing exhaust system) in which the air flow after separating the dust is reversed.

On the other hand, in the second embodiment of the invention described below, air containing dust is swirled toward the bottom along the inner peripheral surface of the dust container, and dust is removed from the air. After separating, when the air after the dust is separated is exhausted from the inside of the dust container, the swirling flow (vortex flow) of the air toward the bottom side of the dust container described above in the vector component of the exhausted air
It is designed to include the straight-ahead component of. That is, although the dust container according to the second embodiment of the invention includes a vector component that is partially inverted in the air flow after separating the dust,
A straight-advance type (a straight-advance exhaust system) having a straight-advance component of air that is used when separating dust is used.

Hereinafter, in FIG. 10, the same parts as those of the first embodiment of the present invention described above will be denoted by the same reference numerals. [Structure] In FIG. 10, reference numeral 100 denotes a dust collecting container used in place of the dust collecting container 48. The dust container 100 is attached to the container attachment portion 24 of FIGS. 2 and 3 and is covered by the lid 22 shown in FIG. A suction air passage 101 is formed in the lid body 22.

Further, in FIG. 10, reference numeral 102 denotes a connecting pipe provided at one end of a dust collecting hose (not shown). The connection pipe 102 is configured to be airtightly connected to one end of the suction air passage 101 when the connection pipe 102 is inserted and connected to the connection pipe portion 40 of FIG.

Further, the dust collecting container 100 has a dust separating container portion 103 for separating the dust from the air, and a dust collecting container portion 104 for collecting and depositing the separated dust.

The dust collecting container portion 104 has an upper end opening at the peripheral edge of the bottom wall 103a of the dust separating container portion 103. In addition, the dust collection container part 104 is the dust separation container part 10
Although it is shown as an integral part of FIG. 3, it is actually provided so as to be separable from the dust separation container section 103.

The upper end of the dust separating container 103 is the upper wall 1.
It is closed by 03b. Although illustration of the detailed structure is omitted, a lid member detachably screwed or fitted to the upper end of the dust separation container portion 103 is used for the upper wall 103b.
Although detailed illustration of this structure is omitted, a well-known structure can be adopted. Moreover, an air inlet 105 is formed at the center of the upper wall (lid member) 103b. It should be noted that the suction air passage 101 provided in the lid 22 is covered by the lid 22.
When the upper part of 0 is covered, the lower end is the air inlet 105
It is designed to be airtightly connected to.

Moreover, a vane type rectifying device 106 as a swirling flow generating means (vortex generating means) is mounted in the vicinity of the upper end of the dust separation container section 103.

This vane type rectifying device 106 has a shaft portion 107 arranged in the central portion of the dust separation container portion 103 and a plurality of rectifying blades (swirl flow generating blades) 108 integrally formed with the shaft portion 107. Have. The upper end of the shaft 107 is
The air inlet 105 is formed in a hemispherical shape having substantially the same diameter as the air inlet 105, and is opposed to the air inlet 105 at a distance. Further, the outer peripheral surface of the shaft portion 107 is tapered in diameter from the upper end toward the lower end.

A plurality of flow straightening vanes (swirl flow generating vanes)
Reference numeral 108 denotes the dust separation container portion 1 in the radial direction from the shaft portion 107.
It extends radially to the inner peripheral surface of 03. Moreover, the rectifying blade 108 swirls the dust and air that have flowed into the upper portion of the dust separation container portion 103 from the air inlet 105 along the inner peripheral surface of the dust separation container portion 103 toward the bottom wall 103a. It has the function of rectifying the flow.

Further, the distance between the flow control vanes 108, 108 is formed larger than the diameter of the air inlet 105. As a result, even if dust having a size substantially equal to the diameter of the air inlet 105 flows in, the dust can be guided between the flow straightening vanes 108 and 108 to the lower side of the vane type straightening device 106.

Further, the bottom wall 103 of the dust separation container section 103
An exhaust cylinder portion 109 is concentrically and integrally formed as an inner cylinder at the center of a. The upper end of the exhaust tube portion 109 is located below the vane type rectifying device 106 as a swirling flow generating means. The upper open end of the exhaust tube portion 109 is opposed to the shaft portion 107 of the vane type rectifying device 106. The diameter of the hemispherical lower end portion of the shaft portion 107 is formed larger than the diameter of the upper end opening of the exhaust cylinder portion 109.

With this structure and the structure in which the outer peripheral surface of the shaft portion 107 expands in a taper shape from the upper end to the lower end as described above, dust and swirl generated by the vane type rectifying device 106 The air goes straight and goes to the exhaust tube portion 109.
It does not flow in.

Moreover, the lower end of the exhaust cylinder 109 is communicated with the air suction port 33a of the electric blower 32 through the air passage 36 provided in the lower portion of the cleaner body 20. still,
A filter 110 is arranged in the middle of the air passage 36. [Operation] Next, the operation of the electric vacuum cleaner having such a configuration will be described.

When the electric blower 32 is operated in such a structure, suction negative pressure is generated in the suction port 33a of the centrifugal fan 33 of the electric blower 32. This suction negative pressure is applied to the air passage 3
6, an exhaust tube portion 109, a dust separation container portion 103, a blade type rectifying device 106, an air inlet 105, a suction air passage 101, a connection pipe 102, a dust collecting hose (not shown), an extension pipe (not shown) It acts on the suction port body (not shown) through.

By moving the suction port body along the cleaning surface in this state, dust on the cleaning surface is sucked into the suction port body together with air. Then, the air containing the dust passes through an extension pipe (not shown), a dust collecting hose and its connecting pipe 102, an intake air passage 101, an air inlet 105 of the dust separation container portion 103, and an upper portion of the dust separation container portion 103. Flow into.

The air containing dust that has flowed into the upper portion of the dust separation container portion 103 flows downward between the flow control vanes 108, 108 of the vane flow control device 106 as indicated by arrow A1. At this time, the air containing dust becomes a swirling flow (vortex) that flows in the circumferential direction along the inner peripheral surface of the dust separation container portion 103 due to the action of the flow regulating vanes 108.

In this case, especially dust that is heavier than air is indicated by the arrow A due to the inertial force and its own weight when it becomes a swirling flow.
As indicated by 2, the dust flows along the inner peripheral surface of the dust separation container portion 103 toward the bottom wall 103a. On the other hand, the swirling air has a weaker swirling force toward the lower side (on the side of the bottom wall 103a), and becomes a flow toward the upper end of the exhaust cylinder portion 109. Therefore, the dust contained in the air becomes a swirling flow together with the air and is separated from the air as it goes downward. Then, the dust separated from the air is separated from the air by its own weight while turning and falls downward, and is collected in the dust collecting container 104.

On the other hand, the air from which the dust has been separated in this way becomes a swirling flow and the swirling force weakens as it flows downward, and a part of the air flows from the upper end of the exhaust cylinder 109 to the exhaust cylinder as indicated by arrow A3. 109 into the bottom wall 103
a Exhaust tube portion 1 after the reverse flow is formed as indicated by arrow A4
It flows into 09.

The air flowing into the exhaust tube portion 109 is sucked into the electric blower 32 from the air suction port 33a through the air passage 36 and the filter 110, and cools the drive motor (motor portion) 34 of the electric blower 32. After the exhaust port 34
The air is exhausted from a to the periphery of the drive motor 34, and is exhausted to the atmosphere from the exhaust port 21a of the cleaner body 1 in FIG.

The upward flow of air on the side of the exhaust cylinder 109 indicated by the arrow A4 includes a vector component directed toward the bottom wall 103a (downward) along the axis of the exhaust cylinder 109. Not not. Therefore, the air flow indicated by the arrow A4 is a reverse flow that is reversed upward with respect to the lower air flow.

However, the arrow A above the exhaust tube portion 109
The air flow indicated by 3 includes a vector component directed toward the bottom wall 103a side (downward) along the axis of the exhaust tube portion 109. Therefore, the air flow indicated by the arrow A3 includes a component in the same direction as the air flowing downward between the flow straightening vanes 108, 108, and is directed downward with respect to the air flowing downward between the flow straightening vanes 108, 108. It goes straight.

Although a partially inverted vector is included,
By exhausting the air having such a straight flow from the dust separation container section 103 into the exhaust tube section 109, the air flow can be made smooth as compared with the reverse exhaust method in which the air flow is only the reverse component. Energy loss (energy loss) when the air is exhausted to the exhaust tube portion 109 and sucked into the electric blower 32 can be reduced.

In the embodiment of the present invention described above,
At the upper center of the dust collecting container 100, a vane type flow rectifying device 106 is provided as a swirling flow generating means for turning the air sucked from the air inlet 105 into a swirling flow in the circumferential direction of the dust collecting container 100. Moreover, an exhaust tube portion 109 having an open upper end is provided in the dust container 100 below the vane type rectifying device 106 which is a swirling flow generating means, and the air suction port 33a of the electric blower 32 is provided in the cleaner body. Two
The lower end of the exhaust tube portion 109 is in communication with the air suction port 33a of the electric blower 32 via an air passage 36 provided in the lower portion of the cleaner body 20.

According to this structure, since the air exhausted to the exhaust tube portion 109 contains the straight-moving component, the air is swirled to the lower side of the dust collecting container, and then the air is turned upside down. Compared to the inversion method in which air is exhausted from the upper end side of the dust collecting container, the loss of the air flow is small, and in addition, the exhaust air from the dust collecting container 100 is provided on the bottom side of the cleaner body 20. Since the electric blower 32 is sucked from below via 36, noise can be reduced. (Modification 1) Further, in the embodiment shown in FIG. 10, the example in which the dust collection container 104 is arranged below the bottom wall 103a of the dust separation container portion 103 is shown, but the present invention is not necessarily limited to this. Absent. For example, as shown in FIG. 11, the dust collection container 104 may be arranged on the side of the dust separation container portion 103. (Modification 2) Further, in the embodiment shown in FIG. 10, the air flowing into the dust separation container portion 103 is a straight flow,
It is not necessarily limited to this. For example, in FIG.
2, as shown in FIG. 13, the upper wall 103b of the dust separation container portion 103 is formed in a conical shape, and the suction air passage 101 is formed.
May be used as the swirling flow generating means. This suction air passage 101
Includes a connection tube portion 101a to the air inlet 105, and an air passage 101b connected to a peripheral portion of the connection tube portion 101a in a tangential direction.

According to this structure, the air containing dust sucked into the air passage 101b flows into the connecting tube portion 101a from the tangential direction and becomes a swirling flow in the connecting tube portion 101a, while the lower blade type flow rectifier is formed. Flow down to the device 106. At this time, the direction of the swirling flow is made to coincide with the rectification direction of the vane rectification device 106.

Therefore, the swirling flow formed in the dust separation container portion 103 by the vane type rectifying device 106 becomes a smoother flow. (Modification 3) As a configuration in which the air flowing toward the vane type rectifying device 106 is made into a swirling flow as in Modification 2, Modification 2 is adopted.
The suction air passage 101 is not limited to the above. For example, by forming a suction air passage to the dust separation container portion 103 in a spiral shape, the blade-type rectifying device 106 is formed from the spiral suction air passage.
The air directed toward may be a swirling flow as in the second modification.

In this case, in order to form the spiral suction air passage, for example, as shown in FIG. 14, the spiral cylindrical body 11 is formed.
2 may be connected to the dust separation container section 103 to form a spiral suction air passage in the spiral cylindrical body 112. (Modification 4) Further, as shown in FIG. 15, a conical cylindrical portion 113 is formed at the upper end of the dust separation container portion 103, and a spiral blade (screw blade) 114 is provided in the conical cylindrical portion 113. As a result, a spiral suction air passage 115 may be formed along the spiral blade 114.

[0075]

As described above, according to the invention of claim 1, the air suction port of the electric blower is located at the lower part of the cleaner body, and the exhaust port at the upper end is provided at the center of the dust collecting container. An exhaust tube portion that opens into the upper end portion of the dust container is provided, and the lower end portion of the exhaust tube portion is in communication with the air suction port of the electric blower via an air passage provided in the lower portion of the cleaner body. Since it is configured, there is little loss of air flow,
In addition, noise can be reduced.

[Brief description of drawings]

FIG. 1 is a perspective view showing a cleaner body of an electric vacuum cleaner according to the present invention.

FIG. 2 is a perspective view of the vacuum cleaner body of FIG. 1 with a cover opened.

3 is a vertical cross-sectional view of the cleaner body of FIG.

FIG. 4 is a cross-sectional view showing the relationship between the hose connection port of the cleaner body of FIG. 3 and the air inlet port of the dust container and the shape of the cyclone container.

5 is a perspective view of the cyclone container of FIG.

FIG. 6 is a plan view of the cyclone container of FIG.

7 is an exploded perspective view of the cyclone container of FIG.

8A is a cross-sectional view showing a modified example of the cyclone container of the electric vacuum cleaner according to the present invention, and FIG. 8B is an explanatory view in which a filter is attached to the upper end of the inner cylinder of FIG. 8A.

9 is a horizontal cross-sectional view of the cyclone container at the air inlet portion of FIG. 8 (a).

FIG. 10 is a schematic explanatory view showing another example of the dust container of the electric vacuum cleaner according to the present invention.

FIG. 11 is a schematic explanatory view showing a modified example of the dust container of the electric vacuum cleaner shown in FIG.

FIG. 12 is a schematic explanatory view showing another modification of the dust container of the electric vacuum cleaner shown in FIG.

FIG. 13 is a schematic plan view illustrating the relationship between the dust collection container and the suction air passage of FIG.

FIG. 14 is a schematic explanatory view showing another modification of the dust collection container shown in FIG.

FIG. 15 is a schematic explanatory view showing another modification of the dust collection container shown in FIG.

FIG. 16 is a perspective view showing a cleaner body of a conventional cyclone type vacuum cleaner.

FIG. 17 is a perspective view showing a state where the lid of the cleaner body of FIG. 16 is opened.

18 is a perspective view showing a state where a cyclone type dust collecting container is set in the cleaner body of FIG.

FIG. 19 is a schematic explanatory view for explaining an air flow in the cleaner body shown in FIG.

20 is an explanatory diagram showing an air flow in the dust collecting container shown in FIG. 19 and a position of an air passage from the dust collecting container to the electric blower.

[Explanation of symbols]

A: Air inlet 21 ... Vacuum cleaner body 23 ... Dust collection container 44 ... Dust container body 46c: Net filter 32 ... Electric blower 33 ... Centrifugal fan 33a ... Air inlet 36 ... wind path 48 ... Dust collection container 48a ... Inner cylinder (exhaust cylinder part) 48b ... Outer cylinder 48c ... bottom wall 48e ... Exhaust port 49 ... Cyclone container 50 ... Side wall (inner wall) 51 ... Bottom wall (guide wall, inclined wall) 51a ... Outer peripheral edge 51b ... inner peripheral edge

   ─────────────────────────────────────────────────── ─── Continued front page    (72) Inventor Takeshi Sato             Toshiba Tec, 43 Horiyamashita, Hadano City, Kanagawa Prefecture             Hadano Factory Co., Ltd. (72) Inventor Yoshihiro Tsuchiya             Toshiba Tec, 43 Horiyamashita, Hadano City, Kanagawa Prefecture             Hadano Factory Co., Ltd. F-term (reference) 3B062 AH02 AH05

Claims (6)

[Claims] Claims: 1. Air containing dust is sucked into the inside of the dust collecting container from an air inlet, and the sucked air is made a swirling flow along the inner peripheral surface of the dust collecting container in the circumferential direction. The dust contained in the air is separated from the air by its own weight to drop and accumulate on the bottom of the dust container, and the air from which the dust is separated is built into the cleaner body through the filter. In an electric vacuum cleaner adapted to suck air into a blower, an air suction port of the electric blower is located at a lower portion of a cleaner body, and an exhaust port at an upper end is provided in a center of the dust collecting container in an upper end portion of the dust collecting container. An exhaust tube portion that is open to the inside is provided, and a lower end portion of the exhaust tube portion is communicated with an air suction port of the electric blower via an air passage provided in a lower portion of the cleaner body. Vacuum cleaner. 2. The electric vacuum cleaner according to claim 1, wherein the exhaust port is set at a position higher than the air inflow port. 3. The vacuum cleaner according to claim 2, wherein the dust collecting container is provided with a band-like shape projecting from an inner wall surface of the dust container toward the exhaust cylinder portion and spaced from the exhaust cylinder portion in a circumferential direction. A guide wall extending downwardly is provided in the dust container below the air suction port, and the guide wall is inclined downward from the outer peripheral edge toward the inner peripheral edge. Vacuum cleaner to do. 4. The vacuum cleaner according to claim 3, wherein the inner wall surface is formed in a spiral shape in the air flow direction from the air inlet, whereby the outer peripheral edge of the guide wall is formed in a spiral shape. An electric vacuum cleaner characterized by being. 5. The vacuum cleaner according to claim 4, wherein the width of the guide wall is formed so as to become gradually narrower from the air inlet toward the downstream side in the air flowing direction. Vacuum cleaner. 6. Air containing dust is sucked into the inside of the dust collecting container from an air inlet, and the sucked air is made to be a swirling flow directed in the circumferential direction along the inner peripheral surface of the dust collecting container. The dust contained in the air is separated from the air by its own weight to drop and accumulate on the bottom of the dust collecting container, and the air from which the dust is separated is sucked into the electric blower built in the cleaner body. In the electric vacuum cleaner, the swirl flow generating means for making the air sucked from the air inlet into a swirl flow in the circumferential direction of the dust collection container is provided at the upper center of the dust collection container. An exhaust pipe part having an upper end opened inside the dust container is provided below the generating means, and an air suction port of the electric blower is located at a lower part of the cleaner body, and the exhaust pipe part of the exhaust pipe part is provided. under An electric vacuum cleaner, wherein an end portion is connected to an air suction port of the electric blower via an air passage provided in a lower portion of the cleaner body.