Source: https://patents.google.com/patent/KR100413988B1/en
Timestamp: 2020-06-04 05:07:21
Document Index: 15667418

Matched Legal Cases: ['art 11', 'art 20', 'art 18', 'art 11', 'art 18', 'art 23', 'art 23', 'art 3', 'art 3', 'art 8', 'art 8', 'art 3', 'art 16', 'art 8', 'art 71', 'art 71', 'art 71', 'art 51', 'art 20', 'art 56']

KR100413988B1 - Electric Vacuum Cleaner - Google Patents
KR100413988B1
KR100413988B1 KR20010015128A KR20010015128A KR100413988B1 KR 100413988 B1 KR100413988 B1 KR 100413988B1 KR 20010015128 A KR20010015128 A KR 20010015128A KR 20010015128 A KR20010015128 A KR 20010015128A KR 100413988 B1 KR100413988 B1 KR 100413988B1
KR20010015128A
KR20010090527A (en
마쯔모또유끼미찌
오오따히로시
오오니시유우지
기무라겐지
쯔지이다까유끼
사또마사히로
니노미야고오지
하야시가즈마사
2000-03-24 Priority to JP2000088500A priority Critical patent/JP2001269297A/en
2000-03-24 Priority to JP2000-088500 priority
2000-08-07 Priority to JP2000238691A priority patent/JP2002051953A/en
2000-08-07 Priority to JP2000-238691 priority
2000-08-09 Priority to JP2000241333A priority patent/JP3530116B2/en
2000-08-09 Priority to JP2000-241333 priority
2000-08-10 Priority to JP2000242811A priority patent/JP3476076B2/en
2000-08-10 Priority to JP2000-242811 priority
2001-03-23 Application filed by 샤프 가부시키가이샤 filed Critical 샤프 가부시키가이샤
2001-10-18 Publication of KR20010090527A publication Critical patent/KR20010090527A/en
2004-01-07 Publication of KR100413988B1 publication Critical patent/KR100413988B1/en
In the electric vacuum cleaner, a separator for separating dust from intake is arranged in the intake passage provided between the nozzle unit having the nozzle and the electric blower for generating intake. A dust collection chamber is installed in the separator to accommodate the separated dust. The separator is provided with an exhaust tube having a discharge port provided with a filter on the side, and discharges the intake air in the separator downstream to the intake air via the exhaust tube. A cleaning member having a brush is provided for cleaning the filter. By moving the cleaning member in contact with the filter, the dust attached to the filter is taken out and used. The cleaning member is moved by manual operation, by an electric motor, or by intake air flow.
The present invention relates to an electric vacuum cleaner, in particular an electric vacuum cleaner having a cyclone dust collector which separates dust by turning intake air.
Background Art Conventionally, an electric vacuum cleaner having a cyclone dust collector for turning intake air driven by an electric blower to separate dust from intake air has been proposed. Fig. 49 is a schematic diagram showing an example of such a conventional electric vacuum cleaner. The connection pipe 3 is connected to the nozzle unit 4 which has the nozzle 4a facing the bottom surface F. As shown in FIG. The cyclone dust collector 5 is coupled to the connecting pipe 3.
The cyclone dust collector 5 communicates with the electric vacuum cleaner main body 1 having the electric blower 1a via the coupling member 10 and the suction hose 2 to form an intake path. In addition, a part of the coupling member 10 is bent to form a handle 10a held by the user. On the handle 10a, an operation portion 10g having an operation key for performing various operations, a display portion for displaying the operation status, and the like is provided.
When the electric blower 1a is driven, air is sucked in through the nozzle 4a of the nozzle unit 4 as shown by arrow f1, and the intake air is passed through the connecting pipe 3 through the inlet port 5a through the cyclone dust collector 5 Flows into). In the cyclone dust collector 5, the air is rotated to remove dust, and is discharged from the main vacuum cleaner 1 by the suction force of the electric blower 1a to the outside as shown by an arrow f2.
The cyclone dust collector 5 is shown in detail in the perspective view of FIG. 50, the vertical sectional view of FIG. 51, and the horizontal sectional view of FIG. The cyclone dust collector 5 has an intake guide 20 having an inlet 5a formed thereon, and is coupled to the connecting pipe 3 by an intake guide 20. Moreover, the cyclone dust collector 5 is formed in substantially cylindrical shape, and is arrange | positioned in parallel with the connecting pipe 3. Then, the introduced air flows into the cyclone dust collector 5 through the inlet port 5a in the tangential direction of the inner wall 5c of the cyclone dust collector 5.
The coupling member 10 has a coupling tube 10b formed integrally. The coupling pipe 10b has a closed end face 10c at one end and rushes into the cyclone dust collector 5 at this end. An outlet 5b is formed at a position lower than the inlet 5a on the outer circumferential surface of the coupling pipe 10b, and the introduced air is discharged out of the cyclone dust collector 5 through the outlet. The outlet 5b is fitted with a mesh filter having a plurality of through holes.
The intake guide 20 is provided with a valve 13 made of an elastic material such as rubber. Due to the vacuum pressure of the introduced air, the valve 13 is bent in the direction of the air flow, which causes air to flow in the tangential direction of the cyclone dust collector 5 as shown in FIG. As a result, the introduced air collides with the inner wall 5c of the cyclone dust collector 5 and turns into a spiral air flow, and dust is separated by centrifugal force and deposited in the first dust collection chamber 7.
In addition, when the intake air is not flowing, the valve 13 closes the inlet port 5a by elasticity, and prevents backflow of dust. For example, when the electric vacuum cleaner is housed, the collected dust is prevented from scattering around.
The lower part of the 1st dust collection chamber 7 is provided with the 2nd dust collection chamber 8 substantially coaxially, and the partition 9 is arranged between them. As shown in Fig. 53, an opening 9a is formed in the partition 9, and a mesh filter having a plurality of through holes is fitted in the opening 9a. The filter is formed of a resin such as nylon, a mesh metal, or the like, and is fixed to the partition 9 by double forming, welding, or bonding. Then, the fine dust passes through the filter of the opening 9a and is accommodated in the second dust collecting chamber 8.
Very fine dust is also contained in the dust which flows into the cyclone dust collector 5 like the air sucked by the electric blower 1a. These fine dusts are so light that they cannot be separated by the centrifugal force of the air flow turning in the cyclone dust collector 5. Therefore, when the introduced air is discharged through the discharge port 5b, fine dust is adsorbed to the filter of the discharge port 5b, thereby clogging the filter. In this case, a ventilation resistance is generated in the discharge port 5b due to the clogged portion of the filter, so that sufficient intake is not obtained for the output of the electric blower 1a, and the suction efficiency is lowered.
Further, even after the electric blower 1a is stopped, a lot of dust remains in the state of being adsorbed by the discharge port 5b. Therefore, if it is not cleaned regularly, dust will accumulate in succession every time the electric vacuum cleaner is operated, and the fall of suction efficiency by the clogging of the filter mentioned above will become remarkable. Therefore, regular maintenance such as cleaning of the discharge port 5b is essential, and much time and effort are required.
Moreover, since the discharge port 5b is formed in the coupling pipe 10b which penetrates into the cyclone dust collector 5, it is not easy to attach and detach from the cyclone dust collector 5, and the discharge port 5b is repaired well by cleaning etc. Make it difficult to be. Therefore, when the dust discharge outlet 5b is rubbed with a cloth or the like, there is a problem that the fallen dust adheres to the cleaner's finger, which is unsanitary and falls on the floor and becomes dirty. In addition, in order to completely clean every corner of the discharge port 5b, considerable time and effort are required, which is unsatisfactory in view of user preference.
In addition, since the filter is provided in the opening 9a of the partition 9, when relatively coarse dust such as a piece of paper accumulates in the first dust collecting chamber 7, part or all of the filter of the opening 9a is blocked. There is a fear that the last fine dust cannot be sufficiently accommodated in the second dust collecting chamber 8. In this case, during the next operation, the dust remaining in the first dust collection chamber 7 is wound up in the air flow turning in the cyclone dust collector 5, and as a result, the adsorption of dust to the above-described outlet 5b is further generated. It becomes easy.
SUMMARY OF THE INVENTION An object of the present invention is an electric vacuum cleaner that is easy to repair, such as cleaning of a filter disposed in an intake, in particular, a cyclone-type electric vacuum cleaner that separates dust by centrifugal force generated in the dust collector, and is provided at the outlet of the dust collector. It is to provide an electric vacuum cleaner that is easy to repair the filter.
According to an aspect of the present invention for achieving the above object, a nozzle unit having a nozzle, an electric blower for generating intake air, an intake path provided between the nozzle unit and the electric blower, and disposed in the intake path itself An electric vacuum cleaner comprising a cyclone dust collector that separates dust from the intake by swirling the intake air introduced into the helical airflow, wherein the cyclone dust collector is provided with a removable exhaust tube that outflows the intake air downstream to the intake air.
In this configuration, since it is possible to remove the exhaust tube from the cyclone dust collector, the maintenance of the exhaust tube becomes easy. It is also possible to wash the exhaust tube with water.
According to another aspect of the present invention, there is provided a nozzle unit having a nozzle, an electric blower for generating intake air, an intake path provided between the nozzle unit and the electric blower, and an intake air disposed in the intake path and introduced into itself. An electric vacuum cleaner comprising a cyclone dust collector that separates dust from intake by swirling in a helical airflow, wherein the cyclone dust collector is provided with a dust collecting chamber for receiving the separated dust. Here, the dust collection chamber is divided into a first compartment close to the inlet of the intake and a second compartment far from the inlet of the intake, provided with a partition having an opening and arranged along the rotational direction of the intake.
In such a configuration, it is possible to introduce the separated dust into the second compartment far from the inlet of the intake air through the opening of the partition wall, thereby preventing the dust from re-introducing into the intake air by the partition wall. This dust collection chamber has a simple structure and is easy to repair.
According to still another aspect of the present invention, there is provided a nozzle unit having a nozzle, an electric blower for generating intake air, an intake path provided between the nozzle unit and the electric blower, and an intake air disposed in the intake path and introduced into itself. An electric vacuum cleaner comprising a cyclone dust collector which separates dust from intake by turning the gas into a spiral airflow, wherein the cyclone dust collector includes a detachable dust collecting chamber for receiving the separated dust, and a holding mechanism for detachably holding the dust collecting chamber. It is provided.
In such a configuration, the dust collection chamber is detachable and therefore easy to repair. Furthermore, since the holding mechanism is provided, it is possible to prevent the separation of the dust chamber which is not desired.
According to still another aspect of the present invention, there is provided a nozzle unit having a nozzle, an electric blower for generating intake air, an intake path provided between the nozzle unit and the electric blower, and a separator disposed at the intake path to separate dust from the intake air. The vacuum cleaner includes: a detachable dust collection chamber in communication with the separator, in which the separated dust is collected, a filter for flowing out the air sucked from the separator to a downstream side of the intake, and an interlock to the movement of the dust collection chamber while the dust collection chamber is detached. Cleaning means for cleaning the filter in such a manner.
In such a configuration, since the filter is automatically cleaned each time the dust collecting chamber is detached, maintenance is easy.
According to still another aspect of the present invention, there is provided a nozzle unit having a nozzle, an electric blower for generating intake air, an intake path provided between the nozzle unit and the electric blower, and a separator disposed at the intake path to separate dust from the intake air. The electric vacuum cleaner comprises: a detachable dust collecting chamber which functions as a separator and receives separated dust; It has a discharge port provided with a filter formed on the peripheral surface, the discharge port is inserted into the dust collection chamber through an opening formed in the wall of the dust collection chamber so that the discharge port is located inside the dust collection chamber, and the intake air flows out from the dust collection chamber downstream through the discharge port to the dust suction path To an exhaust tube; And a cleaning means for cleaning the filter provided at the corner of the opening of the dust chamber.
Also in such a structure, since the cleaning means is provided, maintenance of a filter is easy. The exhaust tube may be fixed to the intake passage or attached to the dust chamber. It is also possible to further provide guide means for guiding the removal of the dust chamber.
According to still another aspect of the present invention, there is provided a nozzle unit having a nozzle, an electric blower for generating intake air, an intake path provided between the nozzle unit and the electric blower, and an intake air disposed in the intake path and introduced into itself. The electric vacuum cleaner including a cyclone dust collector for turning the dust into a spiral airflow to separate dust from the intake air further includes a compression means for compressing the dust accumulated in the cyclone dust collector.
In such a structure, free space can be secured simply by compressing dust. This makes it possible to reduce the frequency of discarding accumulated dust. In addition, since dust is compressed, it is difficult to scatter when discarded.
According to still another aspect of the present invention, there is provided a nozzle unit having a nozzle, an electric blower for generating intake air, an intake path provided between the nozzle unit and the electric blower, and an intake air disposed in the intake path and introduced into itself. An electric vacuum cleaner comprising a cyclone dust collector for separating dust from the intake by turning the gas into a spiral airflow, wherein the cyclone dust collector has an exhaust tube having a filter formed on a peripheral surface thereof, and having an outlet for discharging intake air downstream through the outlet. Wow; Cleaning means for cleaning the filter using the intake force flowing out of the exhaust tube is provided.
In such a configuration, since the filter is always cleaned, maintenance is easy.
According to still another aspect of the present invention, there is provided a nozzle unit having a nozzle, an electric blower for generating intake air, an intake path provided between the nozzle unit and the electric blower, and a separator disposed at the intake path to separate dust from the intake air. The electric vacuum cleaner includes a dust collection chamber in communication with the separator to collect the separated dust; An exhaust tube having an outlet formed on the peripheral surface on which the filter is installed, and causing intake air to flow out from the separator downstream from the separator through the outlet; It is further provided with the cleaning member which moves in contact with a filter and cleans a filter.
In such a structure, a filter can be cleaned easily by moving a cleaning member, and maintenance is easy. The cleaning member may be moved by an electric motor, may be moved using intake air generated by an electric blower, or may be moved by manual operation.
The above and other objects and features of the present invention can be more clearly understood from the following description of the preferred embodiments with reference to the accompanying drawings.
1 is a vertical sectional view of a cyclone dust collector of an electric vacuum cleaner according to a first embodiment of the present invention.
Fig. 2 is a side view of the exhaust tube disposed in the cyclone dust collector of the first embodiment.
3 is a side view at the time of cleaning the exhaust tube;
4 is a vertical sectional view of the exhaust tube;
5 is a horizontal sectional view of the exhaust tube;
6 is a bottom view of the exhaust tube.
7 is a horizontal sectional view of a modification of the exhaust tube.
8 is a partially broken side view of the exhaust tube of another configuration;
Fig. 9 is a perspective view of a partition wall disposed in the cyclone dust collector of the electric vacuum cleaner of the first embodiment.
10 is a side view of a partition wall;
11 is a top view of a partition wall;
12 is a top view of a modification of the partition wall.
Fig. 13 is a perspective view showing how the cleaning cup is attached to the exhaust tube.
14 is an exploded perspective view of the cleaning cup;
Fig. 15 is a vertical sectional view of the cyclone dust collector with the cleaning cup attached.
Fig. 16 is a perspective view around the cyclone dust collector of the electric vacuum cleaner of the second embodiment.
Fig. 17 is a vertical sectional view of the cyclone dust collector of the electric vacuum cleaner of the second embodiment.
Fig. 18 is a horizontal sectional view of the cyclone dust collector of the electric vacuum cleaner of the second embodiment.
Fig. 19 is a perspective view of a second dust collecting chamber provided in a cyclone dust collector and a slide member used for attachment thereof.
Fig. 20 is a vertical sectional view of the cyclone dust collector showing a state in which the dust chamber is separated.
Fig. 21 is a vertical sectional view of the cyclone dust collector of the electric vacuum cleaner of the third embodiment.
Fig. 22 is a vertical sectional view of the cyclone dust collector showing a state where the dust chamber is separated.
Fig. 23 is a vertical sectional view of a cyclone dust collector of the electric vacuum cleaner of the fourth embodiment.
Fig. 24 is a vertical sectional view of the dust collection chamber separated from the cyclone dust collector.
25 is an exploded perspective view of the exhaust tube, the frame, and the first dust collection chamber provided in the cyclone dust collector of the fourth embodiment;
Fig. 26 is a vertical sectional view of the cyclone dust collector of the electric vacuum cleaner of the fifth embodiment.
27A and 27B are vertical sectional views of the cyclone dust collector of the electric vacuum cleaner of the sixth embodiment;
Fig. 28 is a perspective view of the lower part of the coupling pipe provided in the cyclone dust collector of the sixth embodiment;
Fig. 29 is a perspective view of a float and a partition provided in the cyclone dust collector of the sixth embodiment.
30A and 30B are vertical sectional views of the cyclone dust collector of the electric vacuum cleaner of the seventh embodiment;
Figure 31 is a perspective view of a float and a cleaning ring disposed in the cyclone dust collector of the seventh embodiment.
32 is a vertical sectional view of the cyclone dust collector of the electric vacuum cleaner of the eighth embodiment;
33A and 33B are vertical sectional views of the cyclone dust collector of the electric vacuum cleaner of the ninth embodiment;
34A and 34B are vertical sectional views of the cyclone dust collector of the electric vacuum cleaner of the tenth embodiment;
35 and 36 are vertical sectional views of the cyclone dust collector of the electric vacuum cleaner of the eleventh embodiment.
37 is a vertical sectional view of the cyclone dust collector of the electric vacuum cleaner of the twelfth embodiment;
38 is a vertical sectional view of the cyclone dust collector of the electric vacuum cleaner of the thirteenth embodiment;
39 is a perspective view of a cleaning member provided in the cyclone dust collector of the thirteenth embodiment;
40 is a vertical sectional view of the cyclone dust collector of the electric vacuum cleaner of the fourteenth embodiment;
Fig. 41 is a horizontal sectional view of the cyclone dust collector of the electric vacuum cleaner of the fifteenth embodiment.
42 is a horizontal sectional view of the cyclone dust collector of the electric vacuum cleaner of the sixteenth embodiment;
43 is a horizontal sectional view of part of a cyclone dust collector of the electric vacuum cleaner of the seventeenth embodiment;
44 is a vertical sectional view of the cyclone dust collector of the electric vacuum cleaner of the eighteenth embodiment;
45 is a perspective view of a cleaning member provided in the cyclone dust collector of the eighteenth embodiment;
46 is a vertical sectional view of the cyclone dust collector of the electric vacuum cleaner of the nineteenth embodiment;
Fig. 47 is a perspective view of a cleaning member provided in the cyclone dust collector of the nineteenth embodiment.
48 is a vertical sectional view of a cyclone dust collector of the electric vacuum cleaner of the twentieth embodiment;
49 is a schematic diagram showing an overall configuration of a conventional electric vacuum cleaner.
50 is a perspective view of the periphery of a cyclone dust collector of a conventional electric vacuum cleaner.
Fig. 51 is a vertical sectional view of a cyclone dust collector of a conventional electric vacuum cleaner.
Fig. 52 is a horizontal sectional view of a cyclone dust collector of a conventional electric vacuum cleaner.
Fig. 53 is a top view of a partition provided in a cyclone dust collector of a conventional electric vacuum cleaner.
<Description of the code | symbol about the principal part of drawing>
3: connector
5: cyclone dust collector
5a: inlet
7: first dust collection chamber
8: second dust collection chamber
9: bulkhead
10: coupling member
10b: conduit
15: exhaust tube
20: intake guide
In the following, embodiments of the present invention are described with reference to the drawings. Each embodiment is characterized by the structure of the cyclone dust collector, and the configuration other than that is the same as the conventional electric vacuum cleaner shown in Figs. Accordingly, in the following description and the drawings, these members, which are common to the embodiments of the present invention and the conventional examples, are defined by the same reference numerals, and the detailed description thereof is omitted.
1 is a vertical sectional view of a cyclone dust collector of the electric vacuum cleaner of the first embodiment. The cyclone dust collector 5 has an intake guide 20 having an inlet 5a formed thereon, and communicates with a connecting pipe 3 forming an intake path together with the intake guide 20. The cyclone dust collector 5 is formed in a cylindrical shape and is disposed substantially parallel to the connecting pipe 3. Then, the intake air flows into the cyclone dust collector 5 through the inlet port 5a along a path substantially perpendicular to the exhaust path from the cyclone dust collector 5.
On the intake guide 20, the coupling pipe 10b in communication with the coupling member 10 (see Fig. 50) is formed to protrude from approximately the center of the upper surface of the cyclone dust collector 5. On the intake guide 20, the holding portion 20a is formed to communicate with the coupling pipe 10b, and the exhaust tube 15 (to be described later) is detachably screwed together with the holding portion 20a.
In addition, the cyclone dust collector 5 is disposed on the opposite side of the bottom surface F (see FIG. 49) with respect to the connecting pipe 3. This allows the connecting pipe 3 to be inclined to a position where the bottom surface F comes in contact with the bottom gap of the bed or the like, and the cyclone dust collector 5 is placed on the floor when the user drops the connecting pipe 3. It can be prevented from crashing and breaking.
The partition 9 is provided in the lower part of the 1st dust collection chamber 7, and the 2nd dust collection chamber 8 is provided coaxially with the 1st dust collection chamber 7 via this partition 9 generally. The partition 9 is formed integrally with the first dust collecting chamber 7 by bonding, welding or the inner wall of the first dust collecting chamber 7. In the partition 9, an opening 9a is formed as shown in the perspective view of FIG. 9, the side view of FIG. 10, and the top view of FIG. The partition 9 has a flat partition portion 90, a horizontal portion 9b formed substantially parallel to the direction of the air flow turning around the first dust collecting chamber 7 and lower than the partition portion 90, and the partition wall A part of the periphery of (9) is divided into inclined portions 9c which have a gentle inclination and are concave spirally. The horizontal portion 9b and the inclined portion 9c together form an opening 9a. The opening 9a may be formed of only the inclined portion 9c.
Therefore, the opening 9a is formed in the turning direction of the airflow turning in the first dust collecting chamber 7 (Fig. 1), so that the dust turning like the swirling airflow is smoothly introduced into the second dust collecting chamber 8. Thus, the effect of promoting the separation and collection of dust in the first and second dust collection chambers 7 and 8 is obtained.
The edge portion 9e of the partition portion 90 of the partition 9 facing the opening 9a is chamfered in the direction of the swirling air from the upper surface of the partition portion 90 to the lower surface. That is, the edge portion 9e is inclined at the same slope as the inclined portion 9c. This makes it easier to collect the dust separated by the centrifugal force of the airflow turning in the first dust collection chamber 7 in the second dust collection chamber 8.
Reference numeral 9d denotes a dust holding part having a hollow or solid cylindrical shape projecting toward the second dust collecting chamber 8. When a large amount of dust such as fine dust is collected in the second dust collection chamber 8, the dust holding portion 9d keeps the collected dust down, so that the dust collected in the second dust collection chamber 8 is removed. 1 It is effectively prevented to fly back to the dust collection chamber (7) side.
In particular, in Fig. 11, air together with dust is blown into the second dust collecting chamber 8 along the outside 9f of the opening 9a, so that the air is along the inside 9g of the opening 9a. It is sucked out of (8). Thus, the dust in the second dust collecting chamber 8 is mainly collected at its central part. Therefore, the dust collected at the center of the second dust collection chamber 8 tends to expand as it follows the air flow along the interior 9g of the opening 9a and flow back to the first dust collection chamber 7, but retains the dust. The portion 9d prevents the dust from being deposited higher than the allowable level. In this way, dust is prevented from flowing back into the first dust collection chamber 7. In addition, the dust holding portion 9d forms its horizontal cross section in a substantially circular shape. This ensures a smooth turn of the airflow, allowing dust to be collected evenly in the second dust collection chamber 8.
The partition 9 may also have two openings 9a or two or more openings 9a as shown in FIG.
2 is an external view of an exhaust tube 15 equipped with a cleaning member. The exhaust tube 15 is cylindrical. On the outer circumferential surface of the exhaust tube main body 11, a discharge port 5b is introduced into the cyclone dust collector 5 and the air separated from the dust by the centrifugal force is exhausted from the cyclone dust collector 5. As shown in Fig. 2, this outlet 5b is formed by fitting a plurality of window openings 11a (vents) into a mesh filter 11b having a plurality of through holes.
The filter 11b is formed by a thin resin film such as nylon resin, and is exhausted so that there is no bump between the outer circumferential surface of the exhaust tube body 11 and the edges of the filter 11b by integral molding, welding or bonding, or the like. It is fixed to the tube body 11. This is because such bumps trap dust and promote clogging of the discharge ports 5b.
On the upper part of the exhaust tube main body 11 of the exhaust tube 15, the screw part 11c which is screwed to the holding part 20a (FIG. 1) of the intake guide 20 is provided. Reference numeral 21 denotes a ring inserted around the exhaust tube body 11 and slidable along the axial direction (ie, the direction of arrow A) of the outer circumferential surface of the exhaust tube body 11. Reference numeral 14 denotes a dust tray detachably fitted with a boss-and-hole mechanism or the like at the bottom of the exhaust tube body 11.
4, 5 and 6 are vertical sectional views, horizontal sectional views and a bottom view showing in detail the exhaust tube 15 composed of the exhaust tube body 11 and its accessory members, respectively. 4 shows two cross sections taken in two orthogonal directions. At a plurality of positions (four in Fig. 5) on the inner surface of the ring 21, a brush 22 for cleaning the discharge port 5b formed in the exhaust tube body 11 is provided. The brush 22 is formed of a suitable elastic fiber, and the length of the fiber is determined so that its tip is slightly in contact with the outer circumferential surface of the exhaust tube body 11.
The dust tray 14 has an inner diameter on top thereof that is slightly larger than the outer diameter of the exhaust tube body 11, so that the dust gap is around the entire circumference between the outer circumferential surface of the exhaust tube body 11 and the portion of the dust tray 14. 14a is formed. Reference numeral 18 denotes the wire as a whole, which is bent to follow the outline of the exhaust tube body 11. The upper end of this wire 18 is inserted into the support 21a of the ring 21, which is made of a bent and approximately horizontal through hole. On the other hand, the lower end of the wire 18 penetrates through the dust tray 14, and the central portion thereof is bent into a U shape to form the U-shaped portion 18a. The U-shaped portion 18a is inserted into the handle 19 and held by the pin 26. The lower end of the wire 18 can itself be used as a handle.
Two grooves 11d are formed along the axis at positions facing the outer circumferential surface of the exhaust tube body 11. This wire 18 is placed in the groove 11d and can slide along them. This prevents the wire 18 from sticking from the outer circumferential surface of the exhaust tube body 11. Therefore, it is possible to prevent the disturbance of the airflow turning inside the cyclone dust collector 5 with an excellent appearance.
The wire 18 has the curved part 18b which protruded inward near the edge part, The recessed part 11e of the shape according to the curved surface of these curved part 18b is 11 d of the groove | channel of the exhaust tube main body 11. As shown in FIG. Is formed at the upper end of the. Accordingly, when the ring 21 supported by the wire 18 is located at the upper end of the exhaust tube body 11, the curved portion 18b of the wire 18 is recessed 11e of the exhaust tube body 11. Combine with This prevents the ring 21 from flowing down due to vibration or the like accompanying the operation of the electric blower 1a (Fig. 49).
The bottom of the dust tray 14 is formed with a groove 14b on which the wire 18 is placed and a groove 14c on which one end of the handle 19 is placed. Therefore, when the ring 21 is held at the upper end of the exhaust tube body 11, the wire 18 does not stick from the bottom of the dust tray 14, and one end of the handle 19 is attached to the dust tray 14. Go down to the bottom. Therefore, it is possible to obtain an excellent appearance, and also to prevent the disturbance of the airflow exhausted through the exhaust tube 15 after being separated from the dust in the cyclone dust collector 5, and to prevent the clogging of dust at this portion. .
According to the above-described configuration, as shown in Fig. 3, the movement of the handle 19 in the vertical direction (the direction of arrow A) is transmitted to the ring 21 via the wire 18, so that the handle 19 operates. The ring 21 slides along the axial direction (direction of arrow A) of the outer circumferential surface of the exhaust tube body 11. When pulling the handle 19 all the way out, the brush 22 (FIG. 4) scrapes off the dirt blocking the filter 11b of the exhaust tube body 11 and collects it in the dust gap 14a of the dust tray 14. .
Accordingly, during the next operation of the electric vacuum cleaner, the dust collected in the dust gap 14a is blown by the intake air swirling in the cyclone dust collector 5 and blown into the first and second dust collection chambers 7 and 8. Is collected. Therefore, the exhaust tube 15 can be cleaned quickly without direct contact with the exhaust tube 15 soiled by the adhesion of dust.
This embodiment has been described with respect to the case of the brush 22 serving as a means for scraping off the dust attached to the exhaust tube body 11. However, in addition to the brush 22, it is also possible to arrange | position a material, such as a raised fabric, rubber | gum, or a resin foam, to the ring 21 in an appropriate magnitude | size. In addition, as shown in Fig. 7, it is also possible to form the recess 11f so as to accommodate the tip of the brush 22 at the upper end of the exhaust tube main body 11. This prevents the brush 22 from curling while the ring 21 is held at the upper end of the exhaust tube body 11, helping to extend the life of the brush 22, which is a consumable.
Furthermore, as shown in Fig. 8, the ring 21 is fixed to the other end of the spring 27, one end of which is connected to the threaded portion 11c of the exhaust tube body 11, to be pulled upward on the ring 21. It is also possible to continue to apply force. This allows the ring 21 to return to its original position by the restoring force of the spring 27 when simply pulling down the handle 19 to prevent the ring 21 from remaining in the pulled down position. . The spring 27 can be covered with the cover 11g to prevent dust from adhering to the spring 27.
When there is a lot of dust attached to the exhaust tube main body 11 or when hair or the like is entangled around the exhaust tube main body 11, simply pulling down the ring 14 once cleans the exhaust tube main body 11. And may be insufficient to receive dust in a dust gap 14a of the dust tray 14 in an appropriate manner. In this case, as shown in FIG. 13, the exhaust tube body 11 removes the first and second dust collection chambers 7 and 8 from the intake guide 20 of the cyclone dust collector 5 (FIG. 1). Instead, the cleaning cup 23 is cleaned with the surroundings of the exhaust tube 15.
As shown in FIG. 14, this cleaning cup 23 has the cylindrical part 23a which has an inner diameter substantially the same as the outer diameter of the dust tray 14 in the part of predetermined height from the bottom face. The opening 23b which is large enough for a finger to enter is formed in the opposing position of the outer peripheral surface of this cylindrical part 23a. Also on the bottom face of the cylindrical portion 23a, an approximately rectangular opening 23c formed in a dimension through which the wire 18 and the handle 19 (Fig. 2) penetrates is formed.
On the opening 23b, one piece of thin film 24 formed of an elastic material such as rubber is bonded to the cutout portion formed along a straight line passing through the approximately center of the short side of the opening 23c. On the outer circumferential surface of the cylindrical portion 23a, a ring-shaped member 25 having the same height as the cylindrical portion 23a and formed of an elastic body such as rubber is attached. In the cleaning cup 23, there is a space 23d surrounding the exhaust tube 15. As shown in Fig. 15, the user presses the cleaning cup 23 toward the intake guide 20 to keep the cleaning cup 23 in an appropriate position around the exhaust tube 15, and then the cleaning cup 23 The handle 19 is pulled up or down in the up and down direction (in the direction of arrow A) from the outside. This causes dust attached to the outer circumferential surface of the exhaust tube 11 to be scraped off with a brush 22 (Fig. 4) disposed on the ring 21 and collected in the cleaning cup 23. This makes it possible to clean the exhaust tube 15 quickly.
Thereafter, the user presses the two openings 23b formed in the cylindrical portion 23a from the outside of the ring-shaped member 25 to hold the dust tray 14 between the fingers of the user, and then the dust tray 14 And the exhaust tube 15 is rotated to remove the exhaust tube 15 from the holding portion 20a. Then, the user discards the dust stored in the cleaning cup 23 and cleans the exhaust tube 15 by cleaning or the like. Accordingly, the exhaust tube 15 can be removed from the cyclone dust collector 5 without directly contacting the exhaust tube 15 contaminated with dust, so that the electric vacuum cleaner can be maintained efficiently and cleanly.
In addition, the user can unbind and remove the dust tray 14 from the exhaust tube body 11, and then pull the handle 19 together with the wire 18, and then the ring 21 with the exhaust tube. It can be separated from the main body 11. This can clean individual components in a disassembled state.
In order to discard the dust stored in the first and second dust collection chambers 7 and 8, these dust collection chambers are first removed together from the intake guide 20, and then separated from each other on a trash box or the like. In this way, the dust collected in the individual dust collection chambers can be reliably discarded without being scattered around. One or both of the first and second dust collection chambers 7 and 8 may be formed of a transparent material such as glass or transparent resin. This allows the user to visually check the amount of dust collected in the first and second dust collection chambers and to easily know when to discard the dust.
16 and 17 show a perspective view and a vertical sectional view of the periphery of the cyclone dust collector of the electric vacuum cleaner of the second embodiment of the present invention, respectively. In this embodiment, the intake guide 20 and the connection pipe 3 are integrally formed, so that the appearance is excellent and the usability is improved.
FIG. 18 shows a horizontal cross section taken along the line VII-VII of FIG. On the intake guide 20 side of the connecting pipe 3, a dust collection chamber mounting portion 3a is formed along the longitudinal direction of the connecting pipe 3. The first dust collecting chamber 7 and the second dust collecting chamber 8 are mounted on the dust collecting chamber mounting part 3a. In the lower part of the dust collection chamber mounting part 3a, the slit 31 in which the slide member 16 is fitted is formed. The slide member 16 can slide in the slit 31 along the up-down direction (direction of arrow B), and the slit 31 restricts the stroke of the slide 16.
As shown in Fig. 19, the front surface of the slide member 16 is provided with a stop 16a and a projection 16b of the dust collection chamber, and a rear side locking (described later) provided in the dust collection chamber mounting portion 3a. A notch 16c is formed that engages the protrusion 17a formed on the member 17 (FIG. 17). At the bottom of the second dust collecting chamber 8, a first recessed portion 8a is formed to engage with the stop 16a of the slide member 16.
A groove 8c into which the projection 16b of the slide member 16 is inserted is formed in the peripheral surface of the 2nd dust collection chamber 8, and the projection 8d extended upward is formed in the lower end of the peripheral surface. . At the upper end of the slit 31, an L-shaped rib 31a (Fig. 17) extending downward therefrom is formed. When the slide member 16 is slid in the direction of the arrow B, the rib 31a clamps the projection 8d to hold the second dust collecting chamber 8 on the dust collecting chamber mounting portion 3a. In the present embodiment, the second recessed part 8b is formed in the peripheral surface of the second dust collecting chamber 8 in such a manner that the projection 8d does not adhere to the outside of the second recessed part 8b.
On the inner surface of the peripheral wall of the second dust collecting chamber 8, a ridge 8e as shown in Fig. 17 is formed. By following the air flow turning in the second dust collection chamber 8, the ridge 8e prevents dust from turning. This can prevent the collected dust from flying off, and the dust collection efficiency is improved. Reference numeral 8f denotes a convex or concave marking position display portion formed on the peripheral surface of the second dust collecting chamber 8. The user maintains the second dust collection chamber 8 while referring to this position display portion 8f as a reference for the position, thereby collecting the first and second dust collection chambers 7 and 8 in the correct direction with respect to the dust collection chamber mounting portion 3a. ) Can be mounted at an appropriate position on the
The locking member 17 is rotatably supported by the dust collection chamber mounting part 3a. The locking member 17 has a protrusion 17a formed on the front surface and presses toward the slide member 16 by a spring 28 provided between the rear surface of the locking member 17 and the peripheral surface of the connecting pipe 3. Strength is given. This allows the protrusion 17a of the locking member 17 to protrude toward the slide member 16.
The aforementioned members together form a mounting mechanism 30 which allows the first and second dust collection chambers 7, 8 to be removably mounted to the intake guide 20 and the connecting pipe 3. In this configuration, in order to mount the first and second dust collection chambers 7 and 8 to the dust collection chamber mounting portion 3a, the user can insert the projection 16b of the slide member 16 into the groove of the second dust collection chamber 8. It inserts into 8c, and couples the stop part 16a and the 1st recessed part 8a. Moreover, in this state, the user lifts the first and second dust collection chambers 7 and 8 while pressing them toward the connecting pipe 3, thereby lifting the projection 8d of the second dust collection chamber 8 into the ribs ( Lock in 31a). This causes the projection 17a of the locking member 17 to which the force by the spring 28 is applied is fitted in the notch 16c of the slide member 16.
As a result, the opening of the upper surface of the first dust collecting chamber 7 is pressed to the intake guide 20 by the gaskets 7a and 7b, so that the first and second dust collecting chambers 7 and 8 have their internal spaces. Kept in a confidential position. In this state, the dust collection chambers 7 and 8 and the intake guide 20 together form a cyclone dust collector 5.
On the contrary, when the first and second dust collection chambers 7 and 8 are removed, the user first presses the unlocking button 17b (Fig. 16) that cooperates with the locking member 17, as shown in Fig. 20. This releases the protrusion 17a from the notch 16c. Then, the user pulls them down while keeping pressing the first and second dust collection chambers 7 and 8 toward the dust collection chamber mounting portion 3a. In this state, the user pulls the first and second dust collection chambers 7 and 8 away from the dust collection chamber mounting portion 3a, thereby detaching them from the dust collection chamber mounting portion 3a.
Then, the user takes the removed first and second dust collection chambers 7 and 8 over the trash can or the like and separates them from each other. In this way, separately collected dust in the individual dust collection chambers can be reliably discarded without dust scattering around.
A third embodiment of the present invention will be described below. Fig. 21 is a vertical sectional view of the cyclone dust collector 5 of the cyclone electric vacuum cleaner of this embodiment. In this embodiment, the adapter pipe 29 is integrally formed in the intake guide 20, and the connecting pipe 3 is attached to the lower end of the adapter pipe 29. The adapter pipe 29 and the second dust collection chamber 8 are provided with a mounting mechanism 30 as described in the second embodiment.
The exhaust tube 15 is inserted into the coupling pipe 10b and fixed to the coupling pipe 10b with a screw (not shown). A gasket 7c is attached to the lower end of the coupling pipe 10b. The flange 88 perpendicular to the axial direction is formed on the vent 11a and the filter 11b of the exhaust tube 15, and the upper surface of the flange 88 is in intimate contact with the gasket 7c.
The frame member 71 is detachably attached to the upper end opening of the first dust collecting chamber 7. The frame member 71 consists of the cylindrical part 71a which is cylindrical shape, and the flange part 71b formed in the upper end part of this cylindrical part 71a. On the inner circumferential surface of the cylindrical portion 71a, a brush 22 is provided as a cleaning member. The frame member 71, the first dust collection chamber 7 and the second dust collection chamber 8, when assembled together, form a dust collection chamber unit. As shown in Fig. 21, when the dust collecting chamber unit is mounted on the intake guide 20, the exhaust tube 15 passes through the opening 71c of the cylindrical portion 71a, and the brush 22 passes through the vent 11a. ) And the filter 11b.
In this embodiment, removing the dust chamber unit from the member on which it is mounted makes it possible to clean the filter 11b. As described above, the slide member 16 while the user operates the unlocking button 17b to disengage the slide member 16 and the locking member 17 and then press the dust chamber unit toward the adapter pipe 29. When the exhaust tube 15 is fixed to the intake guide 20 when pulled down together, the exhaust tube 15 comes out of the cylindrical portion 71a of the frame member 71. On the other hand, the brush 22 scratches the surface of the filter 11b, and the dust adhering to the filter 11b is scraped off by the brush 22 and scattered into the first and second dust collection chambers 7 and 8. Dust is collected.
FIG. 22 is a vertical sectional view of the cyclone dust collector 5, showing a state where the dust chamber unit is separated from the intake guide 20. As shown in FIG. As shown, when the slide member 16 is pulled down to the lower end of the slit 31, the exhaust tube 15 completely exits from the cylindrical portion 71a of the frame member 71. In this state, the user pulls out the dust collecting chamber unit from the adapter pipe 29 to disengage the groove 8c of the second dust collecting chamber 8 from the protrusion 16b of the slide member 16, thereby removing the dust collecting chamber unit. Separate. Then, the user discards the dust collected in the dust collection chambers 7 and 8.
When the electric vacuum cleaner of this embodiment discards the dust stored in the 2nd dust collection chamber 8, the filter 11b is also cleaned simultaneously. This reduces the difficulty and improves the convenience of the user. In addition, the filter 11b is not only cleaned by simply removing the dust collecting chamber unit, but the dust scraped off from the filter 11b is retained in the first and second dust collecting chambers 7, 8. This prevents the user's hands and clothing from being contaminated from dust, which is hygienic.
A fourth embodiment of the present invention will be described below. Fig. 23 is a vertical sectional view of the cyclone dust collector 5 of the cyclone electric vacuum cleaner of this embodiment. The electric vacuum cleaner of this embodiment is the same as the third embodiment except for the configuration of the exhaust tube 15, the frame member 71, and the first and second dust collection chambers 7 and 8 which will be described below.
In this embodiment, the exhaust tube 15 is detachably inserted into the coupling pipe 10b of the intake guide 20. On the inner wall of the coupling pipe 10b, a gasket 7d is fitted to seal the gap between the exhaust tube 15 and the coupling pipe 10b. This leads all air in the first dust collection chamber 7 to the intake passage through the exhaust tube 15 and through the coupling pipe 10b. Therefore, dust hardly adheres to a part of the exhaust tube 15 inserted in the coupling pipe 10b. The gasket 7d may be installed at the lower end of the coupling pipe 10b like the gasket 7c shown in FIG.
The exhaust tube 15 is fixed to the frame member 71 by a first coupling mechanism (to be described later) while penetrating the cylindrical portion 71a of the frame member 71. In this state, the brush 22 is positioned above the filter 11b and the vent 11a of the exhaust tube 15. The frame member 71 is fixed to the peripheral surface of the first dust collecting chamber 7 (to be described later) by the second coupling mechanism.
Now, the cleaning method of the filter 11b in the present embodiment will be described. First, the user operates the unlocking button 17b to release the engagement of the slide member 16 and the locking member 17 together with the slide member 16 while pressing the dust chamber unit toward the adapter pipe 29. Pull down. As a result, since the exhaust tube 15 is fixed to the frame member 71, the exhaust tube 15 moves downward together with the dust collecting chamber unit to be separated from the intake guide 20. After the slide member 16 is pulled down to the end of the slit 31, the user pulls out the dust collecting chamber unit from the adapter pipe 29 so that the groove 8c of the second dust collecting chamber 8 and the slide member 16 can be removed. The coupling 16b is released, thereby separating the dust collecting chamber unit.
After the user releases the coupling between the exhaust tube 15 and the frame member 71 by the first coupling mechanism, as shown in Fig. 24, a part of the exhaust tube 15 inserted into the coupling tube 10b. And pull the exhaust tube 15 upward (arrow C direction) out of the frame member 71. Therefore, the exhaust tube 15 comes out of the cylindrical portion 71a of the frame member 71. On the other hand, the brush 22 scrapes off the surface of the filter 11b, and the dust adhering on the filter 11b is scraped off by the brush 22, and the first and second dust collection chambers 7 in which dust is accumulated are accumulated. , 8) scattered within. Finally, the user dismantles the dust chamber unit and discards the dust collected in the dust collector 5.
In the electric vacuum cleaner of this embodiment, the exhaust tube 15 can be removed. Here, the exhaust tube 15 is removed together with the dust collecting chamber unit, and then a portion of which dust is hardly attached is caught by the user and pulled out of the dust collecting chamber unit. This is hygienic by preventing dust or dirt on the user's hands or clothing. In addition, dust scraped off from the filter 11b is retained inside the first and second dust collection chambers 7 and 8, which is more preferable.
Next, examples of the first and second coupling mechanisms of the present embodiment will be described. 25 is an exploded perspective view of the exhaust tube 15, the frame member 71 and the first dust collection chamber 7 of the present embodiment. First, the first coupling mechanism will be described. At two opposite positions on the peripheral edge of the flange 88 of the exhaust tube 15, a first projection 88a is formed so as to extend horizontally.
On the other hand, the peripheral wall portion 71d is formed in the frame member 71 so as to extend upward from the peripheral edge of the flange portion 71b. At two opposite positions of the peripheral wall portion 71d, from the upper end of the peripheral wall portion 71d, down along the axial direction of the exhaust tube 15 (in the direction of arrow A) and along the circumference of the peripheral wall portion 71d An L-shaped first cutout 71e extending in the direction (direction of arrow W) is formed.
In order to couple the exhaust tube 15 to the frame member 71, the user, in the axial direction (the direction of arrow A), inserts the exhaust tube 15 into the cylindrical portion 71a of the frame member 71. The first protrusion 88a is fitted into the portion of the first cutout 71e that extends. Then, the user rotates the exhaust tube 15 counterclockwise (in the direction of arrow W) to move the first projection 88a to the end of the first cutout 71e. In this way, the exhaust tube 15 is fixed axially with respect to the frame member 71.
Next, the second coupling mechanism will be described. The second projection 71f is formed at two opposite positions on the outer surface of the peripheral wall portion 71d of the frame member 71 so as to extend horizontally. At two opposite positions of the peripheral surface of the first dust collection chamber 7, from the upper end of the first dust collection chamber 7 down along the axial direction (direction of arrow A) of the exhaust tube 15 and in the first dust collection chamber. An L-shaped second cutout 61c extending in the clockwise direction (direction of arrow W ') is formed along the periphery of (7).
In order to couple the frame member 71 to the first dust collection chamber 7, the user first inserts the second protrusion 71f into the portion of the second cutout 61c extending in the axial direction (the direction of arrow A). Fit. Then, the user rotates the frame member 71 in the clockwise direction (direction of arrow W ') to move the second projection 71f to the end of the second cutout 61c. As a result, the frame member 71 is fixed in the axial direction with respect to the first dust collecting chamber 7.
In the above-mentioned first and second coupling mechanisms, the first cutout 71e and the second cutout 61c are both L-shaped and bent in opposite directions. This is because when the user rotates the exhaust tube 15 to release the engagement by the first coupling mechanism, the engagement between the frame member 71 and the first dust collection chamber 7 by the second coupling mechanism is inadvertently released. To prevent them.
The structures of the first and second coupling mechanisms are not particularly limited to those described above.
A fifth embodiment of the present invention will be described. 26 is a vertical sectional view of the cyclone dust collector 5 of the electric vacuum cleaner of this embodiment. On the periphery of the first dust collection chamber 7, an operation chamber 50 is formed integrally with the first dust collection chamber 7 so as to extend vertically on the side opposite to the adapter pipe 29. A slit 50a is formed on the front surface of the operation chamber 50, and the operation unit 51 protrudes from the inside of the operation chamber 50 to the outside through the slit, and the operation unit 51 moves along the slit. Slide vertically between the top and bottom of 50.
Reference numeral 52 denotes an operation rod inserted into the operation chamber 50 to protrude toward the second dust collection chamber 8. One end of the training rod 52 is fixed to the operation unit 51, and a disk-shaped partition wall 9 is attached to the other end of the training rod 52. The outer diameter of the partition 9 is somewhat smaller than the inner diameter of the second dust collection chamber 8 such that a gap is formed between the inner wall of the second dust collection chamber 8 and the partition 9. The interior of the operation chamber 50 is sealed in the first and second dust collection chambers 7 and 8 by the gasket 53.
The operation rod 52 is fitted through the spring 54 so that the operation portion 51 is urged upward in the operation chamber 50. Therefore, the user grasps the operation part 51 with a finger and pulls it downward (in the direction of arrow D) along the slit 50a against the force by the spring 54, and the partition 9 is downward (in the direction of arrow E). ) Together. When the user releases the operation unit 51, the restoration of the spring 54 causes the operation unit 51 to return to the upper end of the slit 50a, so that the partition 9 also returns to the initial position.
When dust has accumulated to a considerably high position in the second dust collection chamber 8, the user grasps the operation unit 51 with a finger and pulls it from the upper end of the slit 50a to the lower end, then releases the operation unit 51 to return to the upper end. Let's do it. Thereby, dust can be compressed to the low position by the partition 9, and volume can be reduced. If the compression of the dust is insufficient in such one operation, this operation can be repeated several times.
In this embodiment, the partition wall 9 is movable so that the accumulated dust can be compressed into the partition wall 9 so that the free space in the second dust collection chamber 8 increases so that the already collected dust is not discarded. You can collect a lot of dust. This makes it possible for the user to reduce the number of dust discards and to further reduce the dust in the second dust collecting chamber 8. In order to discard the dust collected in the first and second dust collection chambers 7 and 8, first, the user pushes down the dust collection chambers 7 and 8 integrally, and removes them integrally from the mounting mechanism 30, These two dust collection chambers are then separated from each other. At this time, the collected dust is hardly scattered because it is compressed.
A sixth embodiment of the present invention will be described. 27A and 27B are vertical sectional views of the cyclone dust collector 5 of the electric vacuum cleaner of this embodiment. In these figures, reference numeral 55 denotes an operating chamber which is disposed above the intake guide 20 and communicates with the intake air via the cyclone dust collector 5. The cylindrical coupling pipe 10b is provided coaxially on the upper surface of the operation chamber 55. A part of the coupling pipe 10b located in the operating chamber 55 is stopped as shown in FIG. 28, having an arcuate opening 10d at a plurality of positions (three in FIG. 28) of the cylindrical peripheral surface. It is formed in the portion 10c.
Inside the operating chamber 55, the coupling pipe 10b and the holding part 20a are coaxially provided in the float 56, and a gap is formed between the inner wall of the operating chamber 55 and the float 56. A force for pressing the float 56 toward the holding portion 20a by the spring 57 is applied to the float 56. One end of the spring 57 is fixed to the rib 55a provided on the lower side of the upper surface of the operating chamber 55, and the other end of the spring 57 is connected to the upper surface of the float 56.
As shown in FIG. 29, the protrusion part 56a is formed in the position (3 in FIG. 29) on the outer peripheral surface of the float 56. As shown in FIG. These protrusions 56a allow the float 56 to slide stably along the inner wall of the operation chamber 55. Reference numeral 58 denotes a coupling rod whose one end is fixed to the center line of the float 56. The engagement rod 58 is laid through the exhaust tube 15, and then the partition 9 is attached to the other end with a nut 161. Reference numeral 59 denotes a gasket formed of rubber or the like disposed at the lower end of the exhaust tube 15. The gasket 59 prevents intake air from flowing along a portion of the coupling rod 58 placed through the exhaust tube 15.
As shown in Fig. 27A, the force by the spring 57 urges the float 56 to the holding portion 20a side of the intake guide 20. As shown in Figs. In this state, when the electric blower 1a is driven, the generated intake air generates negative pressure in the operation chamber 55, so that the float 56 is subjected to the force by the spring 57 as shown in Fig. 27B. It is suctioned upward until it comes into contact with the stop 10c toward the coupling tube 10b. Thereby, the intake air flows through the electric blower 1a, the suction port 2, the operation chamber 55, the cyclone dust collector 5, the connection pipe 3, and the nozzle unit 4, is formed.
The intake air flows together with the dust from the connecting pipe 3 through the inlet port 5a into the cyclone dust collector 5 and then separates the dust while turning in the first dust collection chamber 7. Some of the separated dust passes through the partition 9 and is collected in the second dust collecting chamber 8. The intake air from which the dust is separated passes through the outlet 5b formed in the exhaust tube 15, passes through the exhaust tube 15, passes through the gap around the float 56, and passes through the opening 10d to the electric blower 1a. Reaches and is exhausted.
When the drive of the electric blower 1a is stopped, the negative pressure in the operating chamber 55 is released. Therefore, the force by the spring 57 moves the float 56 and the partition 9 downward, and returns to the state shown in Fig. 27A. On the other hand, the downwardly moving partition 9 presses the dust accumulated in the second dust collection chamber 8, thereby reducing the volume. The next time the electric blower 1a is driven, dust is sucked back into the partition 9 so that a part of the dust is collected in the second dust collecting chamber 8.
In this manner, every time the electric blower 1a is driven and stopped, the dust in the second dust collecting chamber 8 is compressed. This increases the free space in the second dust collection chamber 8 and makes it possible to collect more dust without discarding the dust already collected. This allows the user to reduce the number of times the dust collected in the second dust collection chamber 8 has to be discarded and to make the second dust collection chamber 8 more compact. In order to discard the dust collected in the first and second dust collection chambers 7 and 8, the user first pushes the first and second dust collection chambers 7 and 8 integrally and integrally pulls them from the mounting mechanism 30. And then these two dust collection chambers are separated from each other.
A seventh embodiment of the present invention will be described. 30A and 30B are vertical sectional views of the cyclone dust collector 5 of the electric vacuum cleaner of this embodiment. In these figures, reference numeral 203 denotes an engagement arm securely attached to float 56. At the lower end of the engagement arm 203 a ring 21 is provided. Around the inner circumferential surface of the ring 21, a brush 22 for cleaning the discharge port 5b formed in the circumferential surface of the exhaust tube 15 is provided. On the upper surface of the intake guide 20, a guide hole 20b for guiding the vertical movement of the engaging arm 203 is formed at a plurality of positions around the circle on the outer side of the base of the holding portion 20a protruding from the surface. do. The outer portion of these guide holes 20b is sealed by a ring-shaped gasket 59 made of rubber or the like.
31 is a perspective view showing the relationship between the float 56, the engagement arm 203, and the ring 21. FIG. Grooves 56b are formed on the upper surface of the float 56 so as to extend from the center of the float 56 at a distance of about 120 ° from each other. On the upper surface of the engagement arm 203, branch portions 203a are formed so as to extend at a distance of about 120 ° from each other from their center. By engaging this branch portion 203a and the groove portion 56b of the float 56, the engagement arm 203 is fixed to the float 56. This causes the float 56 and the ring 21 to move in one piece. Reference numeral 203b is integrally formed at the lower end of the engagement arm 203 and represents an edge portion having an outer diameter larger than the engagement arm 203.
As shown in Fig. 30A, by the pressing of the spring 57, the float 56 is compressed to the holding portion 20a side of the intake guide 20. As shown in Figs. When the electric blower 1a is driven in this state, the final intake air generates negative pressure in the operating chamber 55, until the float 56 contacts the stop 10c, as shown in Fig. 30B. It is suctioned upward in the direction of 10b. Accordingly, the intake passages are formed to be guided through them in the order of the electric blower 1a, the suction hose 2, the operation chamber 55, the cyclone dust collector 5, the connecting pipe 3, and the nozzle unit 4 in this order. do.
The ring 21 and the partition 9 rise together when the float 56 is aspirated. On the other hand, since the brush 22 provided in the ring 21 rubs the surface of the discharge port 5b formed on the peripheral surface of the exhaust tube 15, dust attached to the position is removed. At the same time, the partition 9 rises to increase the volume inside the second dust collection chamber 8.
When the ring 21 rises simultaneously with the float 56, the edge 203b of the engagement arm 203 is pressed onto the gasket 59. This prevents the intake air flow into the operating chamber 55 through the guide hole 20b. Therefore, the intake air flows through the exhaust tube 15 without leaking anywhere and is efficiently sucked into the electric blower 1a.
The intake air flows together with the dust from the connecting pipe 3 through the inlet port 5a into the cyclone dust collector 5, and then turns inside the first dust collection chamber 7 to separate the dust. Some of the separated dust passes through the partition 9 and is collected in the second dust collecting chamber 8. The dust-intake air flows through the outlet 5b formed in the exhaust tube 15, flows through the gap around the float 56 of the exhaust tube 15, and then passes through the opening 10d to the electric blower. After reaching (1a), it is discharged.
Stopping the driving of the electric blower 1a stops discharging the sound pressure in the operation chamber 55. Thus, the force pushed by the spring 57 moves the float 56 down together with the partition 9 and the ring 21 to return to the state shown in FIG. 30A. On the other hand, the brush 22 provided in the ring 21 rubs the surface of the discharge port 5b formed in the peripheral surface of the exhaust tube 15. At the same time, the partition 9 moves downward to pressurize the dust collected in the second dust collection chamber 8 to reduce the volume. When the electric blower 1a is next driven, the partition 9 is raised so that a part of the dust is collected in the second dust collecting chamber 8, so that the dust is attracted.
In this way, the dust collected in the second dust collecting chamber 8 is compressed every time the electric blower 1a is driven and stopped. This increases the free volume in the second dust collection chamber 8 and can accumulate more dust without treating the dust. This reduces the number of times a user processes dust collected in the second dust collection chamber 8, thereby making the second dust collection chamber 8 more compact.
In addition, the discharge port 5b formed on the peripheral surface of the exhaust tube 15 can be cleaned without repairing. This eliminates the need to clean the outlet 5b by hand, contributing to the user's hassle and hygiene. In order to treat the dust collected in the first and second dust collection chambers 7 and 8, the user first presses the first and second dust collection chambers 7 and 8 downwardly integrally from the mounting mechanism 30. After dismounting, the two dust chambers are separated from each other.
An eighth embodiment of the present invention will be described below. 32 is a vertical sectional view of the cyclone dust collector 5 of the electric vacuum cleaner of this embodiment. The embodiment is a modification of the seventh embodiment. 32 shows an example in which the float 56, the engagement arm 203, the ring 21 and the partition 9 are joined together. In this embodiment, as in the seventh embodiment, the ring 21 is coupled through the coupling arm 203 to the float 56 provided in the operating chamber 55 to follow the vertical movement of the float 56.
The cyclone dust collector 5 of this embodiment is characterized by the following structural features. Reference numeral 581 denotes a first engagement rod suspended downward along the central axis with an upper end fixed to the lower side of the upper surface of the float 56. The lower end of the first coupling rod 581 is formed as a disc-shaped edge portion 581a, and the first coupling rod 581 is inserted through the second coupling rod 582. Reference numeral 60 denotes a spring suspended from the spring base 581b provided at an appropriate position on the first engagement rod 581. The spring 60 loads the second coupling rod 582 with a force weaker than the force applied by the spring 57 to press the second coupling rod 582 downward. The partition 9 is fixed to the lower end of the second coupling rod 582 by a nut 161. The second engagement rod 582 penetrates the bottom surface of the exhaust tube 15 with the gasket 59a fixed therebetween.
Inside the second engagement rod 582, cylindrical first spaces 582a and second spaces 582b having different internal diameters are formed coaxially with shoulders 582c formed therebetween. The second space 582b is substantially the same as the outer diameter of the edge 581a of the first engagement rod 581 inserted from the upper end through the first space 582a. Accordingly, in the state shown in the drawing, the second coupling rod 582 is fully downwardly pressed by the spring 60, and the edge portion 581a of the first coupling rod 581 is connected to the second coupling rod 582. The shoulder 582c is contacted to lock in a predetermined position.
In this configuration, when the electric blower 1a is driven, the float 56 is sucked upward in the direction of the coupling pipe 10b until it comes into contact with the stop 10c. As a result, the intake air is formed to be guided through them in the order of the electric blower 1a, the intake hose 2, the operation chamber 55, the cyclone dust collector 5, the connecting pipe 3, and the nozzle unit 4 in this order. .
When the float 56 is attracted, the ring 21 and the partition 9 move upward together. On the other hand, the brush 22 provided on the ring 21 rubs the surface of the discharge port 5b formed on the peripheral surface of the exhaust tube 15 to remove dust deposited thereon. At the same time, the partition 9 moves upward to increase the volume inside the second dust chamber 8.
When the ring 21 rises simultaneously with the float 56, the edge 203b of the engagement arm 203 is pressed onto the gasket 59. This prevents the intake flow from flowing into the operating chamber 55 through the guide hole 20b. Thus, the intake air flows through the exhaust tube 15 without leaking anywhere and is effectively sucked by the electric blower 1a.
At the same time, the intake air flows from the connecting pipe 3 through the inlet port 5a into the cyclone dust collector 5, and then turns inside the first dust collection chamber 7 to separate the dust. Some of the separated dust passes through the partition 9 and is collected in the second dust collecting chamber 8. The intake air flow from which the dust is separated passes through the discharge port 5b formed in the exhaust tube 15, and then passes through the gap around the exhaust tube 15 and the float 56, and then passes through the opening 10d to provide an electric blower ( It reaches 1a) and it exhausts.
When the drive of the electric blower 1a stops, the sound pressure in the operating chamber 55 does not exist. Thus, the strong force applied by the spring 57 forces the float 56 together with the partition 9 and the ring 21 until the float 56 contacts the retaining portion 20a of the intake guide 20. Move down. On the other hand, when a large amount of dust is collected in the second dust collecting chamber 8, the downward movement of the partition 9 is stopped because the force applied by the spring 60 is weak.
In this structure, even when the dust collected in the second dust collection chamber 8 restricts the downward movement of the partition 9, the ring 21 can move downward to the lower end of the exhaust tube 15 without damage. This allows the brush 22 provided on the ring 21 to remove dust deposited on the surface of the outlet 5b provided in the peripheral surface of the exhaust tube 15 without damage.
The ninth embodiment of the present invention is described below. 33A and 33B are vertical sectional views of the cyclone dust collector 5 of the electric vacuum cleaner of this embodiment. As shown in the drawings, the cyclone dust collector 5 of the present embodiment has a partition wall separating the first and second dust collection chambers 7 and 8 from each other and is fixed to the first dust collection chamber 7, and the ring 21 ) Is coupled to the float 56 via the coupling arm 203.
As shown in Fig. 33A, the force applied by the spring 57 presses the float 56 on the holding portion 20a side of the intake guide 20 to open the intake passage on the upstream side of the holding portion 20a. Block it. In this state, when the electric blower 1a is driven, the final intake air generates a negative pressure inside the hermetic operation chamber 55, so that the float 56 is connected with the stop 10c. It is suctioned upward toward the coupling pipe 10b until it contacts. As a result, the intake passages are formed to be guided through them in the order of the electric blower 1a, the suction hose 2, the operation chamber 55, the cyclone dust collector 5, the coupling pipe 3 and the nozzle unit 4 in this order.
When the float 56 is aspirated, the rings 21 move upward together. On the other hand, the brush 22 provided on the ring 21 rubs the surface of the discharge port 5b formed on the peripheral surface of the exhaust tube 15 to remove dust deposited thereon.
As the ring 21 moves upward with the float 56, the edge 203b of the engagement arm 203 is pressed onto the gasket 56. This prevents intake flow from flowing into the operating chamber 55 through the guide hole 20b. Thus, the intake air flows through the exhaust tube 15 without leaking anywhere and is efficiently sucked by the electric blower 1a.
The intake flow, which flows together with the dust from the coupling pipe 3 through the inlet 5a into the cyclone dust collector 5, separates the dust while turning around the inside of the first dust collection chamber 7. Some of the separated dust is collected in the second dust collecting chamber 8 through the opening 9a formed in the partition 9. The separated intake air flows through the outlet 5b formed in the exhaust tube 15 and then passes through the gap around the exhaust tube, float 56 and through the opening 10d to reach the electric blower 1a. To be exhausted.
When the electric blower 1a is stopped from driving, the sound pressure inside the operating chamber 55 does not exist. Thus, the force applied by the spring 57 moves the float 56 together with the ring 21 to restore the state shown in FIG. 33A. On the other hand, the brush 22 provided on the ring 21 rubs the surface of the discharge port 5b formed on the peripheral surface of the exhaust tube 15 to remove dust deposited thereon.
Therefore, the discharge port 5b formed on the peripheral surface of the exhaust tube 15 can be cleaned without repair. This eliminates the need to clean the outlet 5b by hand, contributing to the user's hassle and hygiene. In order to treat the dust collected in the first and second dust collection chambers 7, the user first presses the first and second dust collection chambers 7 and 8 downwards integrally to mount them integrally from the mounting mechanism 30. Release to separate the two dust collection chambers from each other.
In this embodiment and in this embodiment, the members fastened to the float 56, that is, the float 56 itself, the ring 21, the partition 9, the coupling rods 58, 581, 582 and the rest are metal or synthetic It may be formed of a material having a high specific gravity such as resin. In this case, when the electric blower 1a is stopped driving, the float 56 is returned to its initial position by its own weight. This eliminates the need to use the springs 57, 60, making the structure simpler and reducing the cost of the cyclone dust collector 5.
A tenth embodiment of the present invention will be described below. 34A and 34B are vertical sectional views of the cyclone dust collector 5 of the electric vacuum cleaner of this embodiment. This is a modified embodiment of the seventh embodiment described above.
In the sixth to ninth embodiments, using the operating chamber 55 shown in FIGS. 27A and 27B as an example, when the output of the electric blower 1a is reduced or the resistance through the intake passage is reduced, the float 56 Does not move up high enough to contact the stop 10c, but moves up and down unstable repeatedly. This can be prevented by adopting the structure shown in Figs. 34A and 34B. This structure ensures that the float 56 moves stably over a predetermined distance, thereby ensuring that the ring 21 or the partition 9 moves over a predetermined distance.
34A and 34B, inside the operating chamber 55, a float guide 551 having an inner diameter substantially the same as the outer diameter of the float 56 is provided. Inside the float guide 551, the float 56 is loaded by a force urged downward by the spring 57. The float guide 551 has an outlet 551a formed on its upper surface and another outlet 551b formed on its peripheral surface.
In the state shown in Fig. 34A, when the electric blower 1a starts to drive, the negative pressure is in communication with the inside of the operating chamber 55 through the operating chamber 55, the upper outlet 551a, and the lower outlet 551b. The float 56 is drawn inside the guide 551. When the float 56 reaches the lower outlet 551b, the intake air sucked through the nozzle unit 4 is sucked out through the operating chamber 55 and the coupling pipe 10b by the electric blower 1a. . This structure ensures that the float 56 moves up slightly above the lower outlet 551b. Therefore, by setting the distance at which the float 56 moves upwards to be equal to the distance at which the rings 21 and the partition walls 9 need to be moved, the filter 11b can be cleaned and pressurized dust collected without damage. have.
Furthermore, by having a wall 9b extending downward from the peripheral edge of the partition 9, the dust collected under the partition 9 can be reduced in "soaring up" back onto the partition 9. . The cyclone dust collector 5 can be separated from each other with the first and second dust collection chambers 7, 8, but is not manufactured as a single unit with the dust collection chambers integrated with each other.
An eleventh embodiment of the present invention is described below. 35 and 36 are vertical sectional views of the cyclone dust collector 5 of the electric vacuum cleaner of this embodiment. This embodiment is a modified embodiment of the second embodiment described above. The intake guide 20 and the coupling pipe 3 are integrally formed and the mounting mechanism 30 provides the first and second dust collection chambers 7 to be detachably fixed to the intake guide 20 and the coupling pipe 3. do.
The ring 21 has a brush 22 provided inside and has an outer diameter slightly smaller than the inner diameter of the intake guide 20. The threaded portion 11c at the upper end of the exhaust tube 15 is inserted through the ring 21 and then the threaded portion 11c is screwed into the coupling tube 10b. This allows the ring 21 to be held in place with the dust tray 14 provided to prevent it from descending. The ring 21 is slidable along the outlet of the exhaust tube 15, and is pushed in the direction of the dust tray by a spring 42 inserted between the ring 21 and the ceiling surface of the intake guide 20. Loaded. In this embodiment, the peripheral wall 70 of the first dust collection chamber 7 extends upward so that the upper end of the peripheral wall 70 hits the edge of the ring 21 so that the ring 21 is connected to the spring 42. To move up to the upper end of the exhaust tube 15 against the force applied by it. 35 shows this state. In this state, the ring 21 is located on the inlet 5a. In order to ensure the air inlet passage, the first dust collection chamber 7 has an opening 7w formed in the peripheral surface overlapping the inlet port 5a.
In order to treat the collected dust, when the user slides the slide member 16 downward as shown in Fig. 36 after disengaging the locking member 17 from the slide member 16, the first and second dust collection The chambers 7, 8 move downward together and at the same time the ring 21 is pressed down by the spring 42 and moves downward. On the other hand, the brush 22 slides along the filter 11b while keeping contact, and scratches the dust settled on the filter 11b. The scraped dust as such is collected in the dust tray 14 or in the first dust collection chamber 7. This scraping continues until the ring 21 hits the dust tray 14 and stops moving. On the other hand, the exhaust tube 15 is surrounded and maintained by the inner wall of the first dust collecting chamber 7 so that no dust is scattered to the outside of the first dust collecting chamber 7. Also in all the embodiments described below, the filter 11b is cleaned while the exhaust tube 15 is surrounded by the peripheral wall of the first dust collection chamber 7.
The dust scraped from the filter 11b and collected in the first dust collection chamber 7 is treated together with the dust collected previously. After the treatment of the collected dust, when the first and second dust collection chambers 7 and 8 are mounted again, the brush 22 is bottomed while the first dust collection chamber 7 presses the ring 21 upward. Rub the filter 11b upwards from the dust. In this case, the upper end of the peripheral wall 70 of the first dust collection chamber 7 is in intimate contact with the ring 21 so that the exhaust tube 15 is surrounded and maintained by the inner wall of the first dust collection chamber 7. . Thus, no part of the dust separated from the exhaust tube 15 is scattered out of the first dust collection chamber 7. In this way, the filter 11b is cleaned every time the first and second dust collection chambers 7, 8 are mounted and demounted.
<Twelfth Example>
A twelfth embodiment of the present invention is described below. 37 is a vertical sectional view of the cyclone dust collector 5 of the electric vacuum cleaner of this embodiment. In this embodiment, the ring 21 has the same shape as in the eleventh embodiment but slides into another mechanism. In particular, a motor 150 is provided on the back side of the ceiling surface of the intake guide 20, and the screw shaft 151 coupled with the motor 150 is a ring 21 driving mechanism, which is connected to the ring 21. Screwed together. When the motor 150 is driven, the screw shaft 151 is rotated, and the ring 21 slides toward the lower end or the upper end of the exhaust tube 15 depending on the direction of rotation. On the other hand, the brush 22 cleans the filter 11b.
An actuation switch for controlling the motor 150 is arranged in the actuation portion 10g (as shown in FIG. 49) on the engagement member 10. For safety and to prevent dust from scattering outside the first dust collection chamber 7, the motor 150 can be driven when the first dust collection chamber 7 is dismounted from the dust collection chamber mount 3a. none.
The motor 150 may be driven through automatic operation at a predetermined time as well as the operation of the operation switch by the user. The motor 150 may be programmed to be started at predetermined time intervals or by predetermined operation. By way of example, the motor 150 may be programmed to start rotation when the power cord of the body 1 of the electric vacuum cleaner is connected to the power outlet. This allows the filter 11b to be cleaned in advance when it is preparing for floor cleaning. Alternatively, the motor 150 may be programmed to start rotation when cleaning is finished and the operation switch of the electric blower 1a is turned off. This causes the filter 11b to be cleaned at this point when it is preparing for the next cleaning.
Alternatively, pressure detectors may be provided inside and outside the exhaust tube 15, and when the pressure difference on the downstream and upstream side of the filter 11b becomes larger than a predetermined valve, it is determined whether the filter 11b is clogged and The motor 150 starts to rotate. This allows the ring 21 to operate whenever there is a sign of a reduction in suction force while the electric vacuum cleaner is in use. In this way, it is possible to maintain the suction force above a certain level at all times and to clean efficiently.
In this case, it is preferable that the electric blower 1a is turned off while the motor 150 is rotating, and the driving of the motor 150 is suppressed while the electric blower 1a is rotating. The reason is that if the ring 21 is lowered below the inlet 5a while air is flowing through the inlet 5a, dust may collect on the upper surface of the ring 21. In order to prevent dust from being collected on the upper surface of the ring 21, the original position of the ring 21 is located at the top of the exhaust tube 15, and the tip of the brush 22 is in the recess 11f. Received, the ring 21 is always moved upwards to its original position before the motor 150 stops rotating.
<Thirteenth Example>
A thirteenth embodiment of the present invention is described below. 38 is a vertical sectional view of the cyclone dust collector 5 of the electric vacuum cleaner of the present invention. In this embodiment, the cylindrical member 160 shown in Fig. 39 is used to clean the filter 11b. The cleaning member 160 consists of a pair of upper and lower rings joined together by a plurality (three in FIG. 39) vertical ribs 161. This vertical rib 161 has a brush 162 extending parallel to the axis of the exhaust tube 15 and fixed on each inner surface. This brush 162 is in flexible contact with the filter 11b. The cleaning member 160 is arranged generally coaxially with the exhaust tube 51. After the threaded portion 11c at the upper end of the exhaust tube 15 is fitted through the cleaning member 160, the threaded portion 11c is screwed into the coupling pipe 10b. This, together with the dust tray 14 provided to prevent the cleaning member 160 from lowering, is provided in such a way that the cleaning member 160 is slidable around the exhaust tube 15 and is rotatable relative to the exhaust tube 15. To be in position.
The motor 163 provided on the back side of the ceiling surface of the intake guide 20 rotates the cleaning member 160 via the drive mechanism 164. The drive mechanism 164 is configured as a reduction drive mechanism, a pinion 165 fixed to the shaft of the motor 163, an intermediate gear 167 pivotally pivoted on the intake guide 20 and engaged with the pinion 165. And an intermediate shaft 167 having integrally formed therein and a standby gear 169 integrally formed at an upper end of the cleaning member 160 and coupled with another intermediate gear 168 on the intermediate shaft 166.
Like the motor of the twelfth embodiment, the motor 163 cannot be driven when the first dust collecting chamber 7 is dismounted from the dust collecting chamber mounting portion 3a. In addition, like the motor 150, the motor 163 may be driven through the operation of the operation switch of the user or through the automatic operation at a predetermined time.
It is preferable to have a partition wall that flows through the inlet port 5a and shields the drive mechanism 164 from the airflow discharged through the coupling pipe 10b. This prevents dust from settling on the drive mechanism 164 and preventing movement and eventually causing damage to the drive mechanism 164.
40 is a vertical sectional view of the cyclone dust collector 5 of the electric vacuum cleaner of the fourteenth embodiment of the present invention. In this embodiment, the same cleaning member 160 as used in the thirteenth embodiment is used, but the cleaning member is not by a motor but by a pinwheel that is rotated by air flowing into the first dust collection chamber 7. By 170). The air passage guided from the connecting pipe 3 is bifurcated into the intake guide 20, and an inlet 171 provided to the pinwheel 170 is formed on the inlet 5a. The shaft 172 fixed to the pinwheel 170, the pinion 173 fixed to the shaft 172, and the air gear 169 formed at the upper end of the cleaning member 160 to engage with the pinion 173 together are the cleaning member. The drive mechanism 174 for 60 is comprised. When the electric blower 1a is driven and air is sucked through the connecting pipe 3, a portion of the air flows through the inlet 171 to hit the pinwheel 170. As a result, the pinwheel 170 rotates, which rotation is first reduced by the drive mechanism 174 and then transmitted to the cleaning member 160. That is, while cleaning the floor, the filter 11b is always cleaned continuously.
Fig. 41 is a horizontal sectional view of the cyclone dust collector 5 of the electric vacuum cleaner of the fifteenth embodiment of the present invention. This embodiment is a modified embodiment of the fourteenth embodiment, only the position of the pinwheel 170 is different. In particular, in this embodiment, a portion of the intake guide 20 extends outwardly to form the pinwheel chamber 5d, and the pinwheel 170 is accommodated in the pinwheel chamber 5d. The intake air flowing through the inlet 5a is rotated by swiping the pin wheel 170.
In both the fourteenth and fifteenth embodiments, it is preferable to have a partition that shields the drive mechanism 174 from the air flowing in through the inlets 5a and 171. This attaches dust and hinders its movement, thus preventing damage to the drive mechanism 174.
42 is a horizontal sectional view of the cyclone dust collector 5 of the electric vacuum cleaner of the sixteenth embodiment of the present invention. This embodiment is a modified embodiment of the fifteenth embodiment. In particular, in this embodiment, an inlet 175 which takes air directly through the outside is formed on the intake guide 20, and the intake flow flowing through the inlet 175 is defined by the pinwheel (5) received in the pinwheel chamber 5d. Struck 170). The air that is opposed to the air flowing through the connecting pipe 3 does not contain the dust sucked from the floor surface and does not cause damage even when directly hitting the drive mechanism. At the inlet of the inlet 175, a valve 176 is provided such that the intake air is controlled to drive the drive mechanism 174 intermittently. The valve 176 is opened by being driven by a motor or solenoid and the opening and closing of the valve 176 is controlled by operating a switch provided near the user's hand. By using the electric drive valve in this way, the valve can be opened at a predetermined time, such as in an arrangement using a motor, or in accordance with the pressure difference between the internal pressure and the external pressure of the exhaust tube 15.
Fig. 43 is a horizontal sectional view of part of a cyclone dust collector 5 of the electric vacuum cleaner of the seventeenth embodiment of the present invention. This embodiment is a modified embodiment of the sixteenth embodiment. In particular, the inlet 175 and the valve 176 provided at the inlet are arranged inside the intake guide 20, and the opening 177 through which air is introduced is formed on the peripheral wall of the intake guide 20. The valve 176 is pivoted on the shaft 178 and is loaded with a force to bring it closer to the inlet 175 by a spring (not shown). Reference numeral 179 denotes a pressing portion extending from the valve 176 passing through the shaft 178, and the rod 180 penetrating the peripheral wall of the intake guide 20 faces the pressing portion 179. To the rod 180, the push button 181 is fixed outside the intake guide 20 and the stop pin 182 is fixed inside the intake guide 20. The rod 180 is loaded by a force that presses the intake guide 20 outside by the spring 183.
When the push button 181 is pressurized while the electric blower 1a is rotating, the rod 180 pressurizes the pressurizing portion 179 and causes the valve 176 to rotate to the open position. As a result, air is introduced through the inlet 175 to rotate the pinwheel 170. That is, the cleaning member 160 may be intermittently moved as will. In addition, as in the sixteenth embodiment, the valve 176 can be driven by a motor, a solenoid, or the like.
An eighteenth embodiment of the present invention is described below. Fig. 44 is a vertical sectional view of the cyclone dust collector 5 of the electric vacuum cleaner of this embodiment. In this embodiment, the member 190 shown in Fig. 45 is used to clean the filter 11b. A cleaning member 190 similar to the cleaning member 160 described above is composed of a pair of upper and lower rings and is joined by a plurality of vertical ribs 191, which vertical ribs 191 are flexible with the filter 11b. In contact with each other and fixed on each inner surface. The cleaning member 190 is arranged substantially axially with the exhaust tube 15. Using the dust tray 14 detached from the exhaust tube 15, the cleaning member 190 is fixed around the exhaust tube 15, and then the dust tray 14 prevents the cleaning member 190 from lowering. So as to be fixed to the exhaust tube 15. In this way, the cleaning member 190, such as the cleaning member 160, is fixed in place in a sliding way around and rotatable relative to the exhaust tube 15.
The cleaning member 190 has a difference in that it has a pinwheel 193 formed at the upper end instead of the standby gear. The pinwheel 193 may be integrally formed with the ring-shaped upper end of the cleaning member 190, may be formed separately, and then fixed to the cleaning member 190. The pinwheel 193 is located at the same level as the inlet 5a to be rotated by receiving air flowing therein through the inlet 5a. This causes the entire cleaning member 190 to rotate to clean the filter 11b. The cleaning member 190 preferably rotates in the same direction as the flow direction of air swirling around the exhaust tube 15. This causes the cleaning member 190 to swirl more strongly by cooperating with the swirling force of the air. This also applies to the fourteenth to seventeenth embodiments.
Reference numeral 194 denotes a brake mechanism having a brake shoe 195 fixed on the intake guide 20 and in contact with the cleaning member 190. Generally, the braking shoe 195 is pressed against the cleaning member 190 by a spring (not shown) to keep the cleaning member 190 at rest. When the braking shoe 195 is pulled upward with a motor, solenoid or the like to be spaced apart from the cleaning member 190, the cleaning member 190 starts to rotate by being driven by the air flow flowing through the inlet 5a. That is, by appropriately adjusting the braking mechanism 194, the cleaning member 190 can be driven at will. In the arrangement in which the cleaning member is driven by the motor, the motor may be programmed to release the braking at a predetermined time or to release the braking according to the pressure difference between the inner pressure and the outer pressure of the exhaust tube 15.
<19th Example>
Fig. 46 is a vertical sectional view of the cyclone dust collector 5 of the electric vacuum cleaner of the nineteenth embodiment of the present invention, and Fig. 47 shows the cleaning member 190 used in this embodiment. This embodiment is a modified embodiment of the eighteenth embodiment. The difference from the eighteenth embodiment is that the vanes of the pinwheel 193 of the cleaning member 190 extend upwards so as not to be struck by the intake air flow flowing through the inlet 5a, and the pinwheel chamber 196 is pinwheel 193. It is formed to be provided in the intake guide 20 to accommodate the. The air for rotating the pinwheel 193 is introduced in the same manner as in the fourteenth, sixteenth and seventeenth embodiments, wherein the air introduced through the inlet 5a is not used to drive the pinwheel.
The twentieth embodiment of the invention is described below. 48 is a vertical sectional view of the cyclone dust collector 5 of the electric vacuum cleaner of this embodiment. In this embodiment, a ring 21 of the same type as that used in the eleventh and twelfth embodiments is used. The ring 21 is coupled to the lower end of the rod 197 penetrating the upper partition of the intake guide 20. The upper end of the rod 197 is fixed with a knob-shaped operating portion 199 protruding outward through the window 198 formed in the coupling member 10. The rod 197 is loaded with a force to upwardly press by a spring 100 inserted between the operating portion 199 of the intake guide 20 and the upper partition. Thus, the ring 21 coupled to the rod 197 is pulled upward to the level at which the tip of the brush 22 is received in the recess 11f. By repeatedly pressing the actuator 199 downward against the force applied by the spring 100 and releasing it, the ring 21 is moved up and down together with the actuator 19 to clean the filter 11b. Can be.
The spring 100 may be omitted. Optionally, the spring 100 may be fixed to apply the force in the opposite direction so that the spring 21 is loaded with the downward pressure. In this structure, it is possible to clean the filter 11b by repeatedly pulling the operating portion 199 upward against the force which is loaded and then released. In such a case, a suitable fastening mechanism is provided such that the ring 21 is maintained around the top of the exhaust tube 15 or the ring 21 and the intake guide 20 are not disturbed by the external dimensions of the ring 21. It can be reduced to widen the gap between the inner walls of the.
All the embodiments described above deal with cyclone electric vacuum cleaners. However, these structures, which can perform filter cleaning in a separate embodiment, are applicable not only to cyclone type electric vacuum cleaners but also to some types of electric vacuum cleaners having cylindrical filters.
It will be apparent that various changes and modifications of the present invention are possible in view of the above description. It is, therefore, to be understood that within the scope of the appended claims, the invention may be practiced otherwise than as specifically described above.
The present invention is a cyclone-type electric vacuum cleaner that is easy to repair such as cleaning the filter disposed in the intake and separates the dust by the centrifugal force generated in the dust collector, the electric vacuum cleaner easy to repair the filter installed at the outlet of the dust collector. to provide.
A nozzle unit 4 having a nozzle 4a, an electric blower 1a for generating intake air flow, intake passages 2 and 3 provided between the nozzle unit and the electric blower, and disposed inside the intake passage An electric vacuum cleaner comprising a cyclone dust collector (5) for turning intake air flowing into the helical air stream to separate dust from the intake air.
The cyclone dust collector is provided with a detachable exhaust tube (15) for outflowing intake air to the downstream side of the intake passage.
The electric vacuum cleaner according to claim 1, wherein the exhaust tube has an outlet (11a) formed on its outer circumferential surface, and a filter (11b) for removing dust is provided at the outlet.
3. The electric vacuum cleaner according to claim 2, further comprising cleaning means (22) for cleaning the filter by manual operation.
4. The electric vacuum cleaner according to claim 3, further comprising a dish-shaped member (14) installed on an end face of the exhaust tube and having a dust collecting gap (14a) between the side surfaces of the exhaust tube.
4. The electric vacuum cleaner according to claim 3, further comprising a cleaning cup (23) which is inserted around the exhaust tube to prevent the scattering of dust separated from the filter when cleaning the filter by the cleaning means. .
4. An electric machine according to claim 3, further comprising movable members (18, 19) connected to the cleaning means and subjected to manual operation, and pressing means (27) for holding the movable member in a pressurized state in a predetermined direction. Vacuum cleaner.
A nozzle unit 4 having a nozzle 4a, an electric blower 1a for generating intake air flow, intake passages 2 and 3 provided between the nozzle unit and the blower, and an intake passage disposed therein. An electric vacuum cleaner comprising a cyclone dust collector (5) for turning inflow of intake air into a spiral stream to separate dust from intake air,
The cyclone dust collector has dust collection chambers 7 and 8 for collecting the separated dust,
The dust collection chamber has an opening 9a and is partitioned by a partition 9 arranged along the rotational direction of the intake air, the first compartment 7 close to where the intake air flows and the second compartment far from the intake air flow. Electric vacuum cleaner, characterized in that divided into (8).
8. The electric vacuum cleaner according to claim 7, wherein the partition has a protrusion (9d) formed almost at the center side opposite the second compartment.
8. An electric vacuum cleaner according to claim 7, wherein a projection (8e) is formed in the second compartment to obstruct the flow of swirling air of the intake air.
The cyclone dust collector comprises a removable dust collection chamber (7, 8) for collecting the separated dust and a holding mechanism (30) for detachably holding the dust collection chamber.
11. The electric vacuum cleaner according to claim 10, wherein a display portion (8f) is provided on the peripheral surface of the dust collecting chamber for easy positioning of the dust collecting chamber when the dust collecting chamber is attached to the cyclone dust collector.
The electric vacuum cleaner according to claim 10, wherein at least a part of the dust collecting chamber is formed of a transparent or translucent material so that the inside of the dust collecting chamber can be visually observed.
A nozzle unit 4 having a nozzle 4a, an electric blower 1a for generating intake air, intake paths 2 and 3 provided between the nozzle unit and the electric blower, and an intake path, An electric vacuum cleaner comprising a separator (5) for separating dust,
Removable dust collection chambers 7 and 8 in communication with the separator and collecting the separated dust,
A filter 11b for allowing the intake air flow out from the separator to flow downstream to the intake air;
An electric vacuum cleaner, characterized in that it further comprises cleaning means (22) for cleaning the filter in association with movement of the dust collection chamber when the dust collection chamber is detached.
A removable dust collection chamber (7, 8) which acts as a separator and collects the separated dust,
The discharge port 11a provided with the filter 11b is provided on the peripheral surface, and is inserted into the dust collection chamber through the opening 71c formed in the wall 71 of the dust collection chamber so that the discharge port is located inside the dust collection chamber, An exhaust tube 15 through which the intake air is discharged to the downstream side of the intake path through the discharge port,
And vacuum cleaning means (22) installed at the corners of said opening of said dust collection chamber and for cleaning the filter.
The exhaust tube according to claim 14, wherein the exhaust tube is fixed to the intake passage,
The dust collecting chamber is detached by moving along the axial direction of the exhaust tube,
And the cleaning means cleans the filter when the dust collecting chamber is detached.
The method according to claim 15, further comprising guide means (30) for guiding movement of the dust collection chamber when the dust collection chamber is detached.
A slit 31 extending along the axis of the exhaust tube,
A slide member 16 which slides inside the slit and the dust collection chamber is detachably attached;
A locking member 17 coupled to the slide member at one end of the slit to hold the slide member in a fixed position,
The dust collecting chamber is mounted to the intake air when the slide member is located at the one end of the slit, and is discharged from the intake air when the slide member is located at the other end of the slit.
15. The electric vacuum cleaner according to claim 14, wherein the exhaust tube is freely detachable from the intake passage and is installed in the dust collecting chamber through a coupling executed by the coupling by the first coupling means (88a, 71e).
18. The electric vacuum cleaner according to claim 17, wherein the cleaning means cleans the filter when the engagement performed by the first coupling means is released and the exhaust tube leaves the dust chamber.
18. The electric vacuum cleaner according to claim 17, wherein a coupling pipe (10b) is provided on the downstream side of the intake passage, and the exhaust tube is fitted into the coupling pipe with gaskets (7c, 7d) sandwiched therebetween. .
18. The electric vacuum cleaner according to claim 17, wherein the wall in which the opening is formed is detachable from the rest of the dust collecting chamber.
18. The exhaust tube according to claim 17, wherein the first coupling means comprises: a first projection 88a extending vertically in the axial direction of the exhaust tube from the outer circumferential surface of the exhaust tube and extending along the axis of the exhaust tube from the outer surface of the wall and subsequently Electric vacuum cleaner, characterized in that consisting of the L-shaped first cut portion (71e) formed on the wall so as to extend to the outer peripheral surface of the.
22. The wall according to claim 21, wherein the wall is installed in the remaining part of the dust chamber through the engagement executed by the second coupling means (71f, 61c), the second coupling means being perpendicular to the axial direction of the exhaust tube from the outer surface of the wall. An elongated second projection 71f and an L-shaped second cutout 61c formed in the remaining portion so as to extend along the axis of the exhaust tube from one end of the remaining portion and continue along the outer circumferential surface of the exhaust tube; Electric vacuum cleaner, characterized in that consisting of.
23. The electric vacuum cleaner according to claim 22, wherein the first cutout portion and the second cutout portion are formed in an L shape in opposite directions.
And vacuum means (9, 51, 56) for compressing the dust collected in the cyclone dust collector.
25. The electric vacuum according to claim 24, wherein the compression means comprises an operation member 51 located outside the cyclone dust collector and subjected to manual operation, and a compression member 9 located in the cyclone dust collector and interlocked with the operation member. vacuum cleaner.
25. The apparatus of claim 24, further comprising an operating chamber (55) located above the cyclone dust collector and in communication with the cyclone dust collector downstream of the dust suction path,
The compression means comprises a float 56 arranged in the operating chamber and kept pressed downward, a compression member 9 arranged in the cyclone dust collector, and a coupling rod 58 connecting the float and the compression member to each other. Electric vacuum cleaner, characterized in that.
27. The intake air flow according to claim 26, wherein an outlet 11a is arranged in the operating chamber so as to reach the interior of the cyclone dust collector, and on the outer circumferential surface thereof, an outlet 11a is formed in the cyclone dust collector. Further comprising an exhaust tube (15) for allowing the outlet to exit the operating chamber via an outlet;
And the coupling rod is fitted to the exhaust tube.
28. The electric vacuum cleaner according to claim 27, further comprising cleaning means (22) connected to the float and for cleaning the filter in conjunction with movement of the float.
A nozzle unit 4 having a nozzle 4a, an electric blower 1a for generating intake air flow, intake passages 2 and 3 provided between the nozzle unit and the electric blower, and disposed inside the intake passage An electric vacuum cleaner including a cyclone dust collector (5) for turning intake air flowing into the helical air stream to separate dust from the intake air.
An exhaust tube 15 through which the filter 11b is provided and has an outlet port 11a formed on its outer circumferential surface so that the intake air flows out through the outlet port to the downstream side of the intake line,
An electric vacuum cleaner comprising cleaning means (22, 56, 203) for cleaning the filter using the force of intake air flowing out of the exhaust tube.
30. The apparatus of claim 29, further comprising an operating chamber 55 located above the cyclone dust collector, in communication with the cyclone dust collector via an exhaust tube, and in communication with a downstream side to the intake air,
The cleaning means includes a float 56 disposed in the operating chamber and floating by the intake air flowing out of the exhaust tube, a cleaning member 22 in contact with the filter, and a coupling member 203 for coupling the float and the cleaning member. Electric vacuum cleaner, characterized in that.
A dust collection chamber (7, 8) in communication with the separator and collecting the separated dust,
An exhaust tube (15) provided with a filter (11b) and having an outlet (11a) formed on its outer circumferential surface so that the intake air flows out from the separator through the outlet to the downstream side to the intake path,
And a cleaning member (22) for cleaning the filter by moving in contact with the filter.
32. The electric vacuum cleaner of claim 31, wherein the cleaning member moves along the axis of the exhaust tube.
33. The apparatus of claim 32, further comprising a pressing member 42 for maintaining a state of pressing the cleaning member along the axis of the exhaust tube,
The dust chamber is detachable from the separator and is attached to the separator by moving the cleaning member against a force held by the pressing member.
32. The electric vacuum cleaner of claim 31, wherein the exhaust tube is substantially cylindrical in shape, and the cleaning member rotates about the axis of the exhaust tube.
32. The electric vacuum cleaner according to claim 31, further comprising a drive mechanism for moving the cleaning members (151, 164).
36. The electric vacuum cleaner according to claim 35, wherein the drive mechanism moves the cleaning member at a predetermined time.
36. The electric vacuum cleaner according to claim 35, further comprising an electric motor (150, 163) for supplying power to the drive mechanism for moving the cleaning member.
36. The electric vacuum cleaner according to claim 35, wherein the drive mechanism moves the cleaning member by using the intake air generated by the electric blower as the power.
The electric vacuum cleaner according to claim 38, further comprising a control mechanism (176) for controlling the intake air that the drive mechanism uses as power.
32. The electric vacuum cleaner according to claim 31, further comprising an operation member (199) arranged outside the dust collecting chamber and subjected to manual operation, and a coupling member (197) for coupling the operation member and the cleaning member.
KR20010015128A 2000-03-24 2001-03-23 Electric Vacuum Cleaner KR100413988B1 (en)
JP2000088500A JP2001269297A (en) 2000-03-24 2000-03-24 Electric vacuum cleaner
JP2000-088500 2000-03-24
JP2000238691A JP2002051953A (en) 2000-08-07 2000-08-07 Vacuum cleaner
JP2000-238691 2000-08-07
JP2000241333A JP3530116B2 (en) 2000-08-09 2000-08-09 Electric vacuum cleaner
JP2000-241333 2000-08-09
JP2000242811A JP3476076B2 (en) 2000-08-10 2000-08-10 Electric vacuum cleaner
JP2000-242811 2000-08-10
KR20010090527A KR20010090527A (en) 2001-10-18
KR100413988B1 true KR100413988B1 (en) 2004-01-07
ID=27481147
KR20010015128A KR100413988B1 (en) 2000-03-24 2001-03-23 Electric Vacuum Cleaner
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