RU2339290C2 - Vacuum cleaner (versions) - Google Patents

Abstract

FIELD: engines and pumps.

SUBSTANCE: vacuum cleaner comprises a main casing, a drive unit to generate suck-in force, a dust separation device furnished with a dust inlet part and arranged in the said main casing, a dust collection chamber comprising dust intake and discharge parts and a mounting element accommodating the aforesaid dust collection chamber. Note that the aforesaid dust intake and discharge parts are linked by a pressure element when the said dust collection chamber is fitted on the aforesaid mounting element. The said dust separation device represents a cyclone made up of multiple auxiliary cyclones with their lengthwise axes aligned.

EFFECT: high-efficiency dust separation.

21 cl, 12 dwg

Description

The present invention relates to a vacuum cleaner and, more specifically, to a vacuum cleaner having a dust collecting device, which is improved in design, so that the user can use it in a more convenient way.

In general, a vacuum cleaner is a device that can suck in air containing dust by using the suction force generated by an engine mounted in the main body and filter the dust in the dust filter device.

Vacuum cleaners are classified as container-type vacuum cleaners and vertical-type vacuum cleaners. A container-type vacuum cleaner includes a main body and a suction nozzle connected to the main body by a connecting tube. A container-type vacuum cleaner includes a main body and a suction nozzle made in one piece with the main body.

Meanwhile, a conventional cyclone type vacuum cleaner includes a suction nozzle for suctioning dust containing air, a main body in communication with a suction nozzle, a dust collecting device for filtering off dust contained in the air and collecting dust, an extension tube for guiding air sucked through the suction nozzle to the main body, a connecting hose having a first end connected to an extension tube and a second end connected to the base th body.

The dust collecting device includes a dust collecting body defining an appearance, a main cyclone device for separating the relatively large-sized dust contained in the air, an auxiliary cyclone device located downstream of the main cyclone device and intended for separating the relatively small-sized dust, the main chamber for collecting dust separated in the main cyclone device, and an auxiliary chamber located around the main chamber in the housing For dust collection and designed to accumulate dust separated in an auxiliary cyclone device.

A conventional dust collecting device includes both a main cyclone device and an auxiliary cyclone device.

However, the following problems are associated with a conventional dust collecting device.

First, in order to minimize the space occupied by the vacuum cleaner and to move the vacuum cleaner more easily, it is preferable that the vacuum cleaner is as compact as possible while providing the same dust collection efficiency.

However, since a conventional dust collecting device includes both a main cyclone device and an auxiliary cyclone device, the volume and mass of the vacuum cleaner increase. Therefore, difficulties arise when handling the vacuum cleaner. This problem becomes more serious if a large amount of dust is collected in the dust collector.

Secondly, since a conventional dust collecting device includes both a main cyclone device and an auxiliary cyclone device, the space for the main camera is structurally reduced due to the presence of the auxiliary camera. Therefore, the volume of the main chamber for collecting dust is reduced, and therefore, the user must more often empty the dust collecting device.

Thirdly, since a conventional dust collecting device includes both a main cyclone device and an auxiliary cyclone device, the internal structure of the dust collecting device is complicated, and it is therefore difficult to clean or rinse the inside of the dust collecting device.

Fourthly, since a conventional dust collecting device includes both a main cyclone device and an auxiliary cyclone device, preparing a mold for manufacturing a dust collecting device is expensive. In addition, when the dust collector is leaked or damaged, the entire housing of the dust collector must be replaced.

Fifth, since the auxiliary chamber is located around the main body, it is difficult for the naked eye to determine the amount of dust accumulated in the main chamber.

Sixth, the interior may again be contaminated during the process of separating the dust collecting device from the main body when emptying the dust collecting device or when dust is emitted from the dust collecting device. Thus, again there is a need for cleaning the room.

Accordingly, the present invention is directed to the creation of a vacuum cleaner, which allows you to basically eliminate one or more problems caused by the limitations and disadvantages of the known devices.

An object of the present invention is to provide a vacuum cleaner having a dust collecting device that is simple in design and lightweight.

Another objective of the present invention is to provide a vacuum cleaner having a dust collecting device that can be easily emptied or cleaned.

Another objective of the present invention is to provide a vacuum cleaner, which is designed so that the user can easily determine the amount of dust accumulated in the dust collecting device.

Additional advantages, objects, and features of the invention will be disclosed in part in the following description, and in part will become apparent to ordinary specialists in the art when studying the following, or they can be learned by putting the invention into practice. The objectives and other advantages of the invention can be realized and achieved using the design disclosed in detail in the description and claims, as well as in the attached drawings.

To achieve these goals and other advantages, and in accordance with the purpose of the invention, as embodied and widely described herein, a vacuum cleaner is developed that includes a main body having a drive device for generating suction force, a dust separation device, which is provided in the main body for separating dust from air and is made with a part for the release of dust through which the separated dust is discharged; a dust collecting chamber that is provided with a dust inlet portion through which dust released from the dust outlet is introduced; and a mounting element which is formed on the main body and on which the dust collecting chamber is mounted, wherein the dust discharge part and the dust inlet part are in contact with each other under a pressing force with which the dust storage chamber is mounted on the mounting element, thereby preventing air leak.

In accordance with another aspect of the present invention, there is provided a vacuum cleaner including a main body; a cyclone device, which is provided in the main body and is designed to separate dust from the air that is introduced into it and in which many auxiliary cyclones are located in parallel; and a dust collecting device that is removably mounted on the main body, collects dust separated by the cyclone device, and communicates with the cyclone device when it is mounted on the main body.

The above described vacuum cleaner has the following advantages.

First, since the main cyclone device is provided on the dust collecting device, while the auxiliary cyclone device is separated from the dust collecting device and provided on the main body, the structure of the dust collecting device is simplified and has become easier. Therefore, the user can more conveniently manipulate the dust collecting device.

Secondly, although the auxiliary cyclone device is separated from the dust collecting device, dust separated by the auxiliary cyclone device still accumulates in the dust collecting device. Therefore, only the dust collecting device is separated from the main body and emptied.

Thirdly, since the dust exhaust device, through which the dust separated by the auxiliary cyclone device, is in close contact with the dust suction device due to the force used to install the dust removal device on the main body, a tight seal between the dust exhaust device and the suction device dust is improved, and therefore losses during air intake are reduced, which improves the efficiency of dust collection with a vacuum cleaner.

Fourth, since the outer wall of the main chamber for accumulating most of the dust is made of a transparent material, the user can easily determine the amount of dust collected in the main chamber, and therefore determine the appropriate moment of emptying.

It should be understood that both the foregoing general description and the following detailed description of the present invention are provided by way of example and for explanation and are intended to provide further clarification of the claimed invention.

The accompanying drawings, which are included to provide a further understanding of the invention and form part of it, illustrate embodiment (s) of the invention and together with the description serve to explain the principle of the invention. In the drawings:

figure 1 is a perspective view of a vacuum cleaner in accordance with one embodiment of the present invention, when the device for separating dust is separated from the vacuum cleaner;

figure 2 is a perspective view of the vacuum cleaner of figure 1, when the dust collecting device is assembled together with a vacuum cleaner;

figure 3 is a section taken along the line I-I 'in figure 2;

FIG. 4 is a perspective view of the dust cleaner of the vacuum cleaner of FIGS. 1 and 2;

5 is a perspective view of the connection between the auxiliary cyclone device and the connecting channel of the vacuum cleaner of FIGS. 1 and 2;

FIG. 6 is a front perspective view of the dust collecting device of FIG. 4;

7 is a perspective view of an auxiliary cyclone device;

Fig.8 is a section taken along the line II-II 'in Fig.7;

Fig.9 is a cross section of a modified example of Fig.8;

10 is a perspective view of a vacuum cleaner in accordance with another embodiment of the present invention;

11 is a perspective view of a connection between a dust separator and a drive device of a vacuum cleaner in accordance with another embodiment of the present invention; and

12 is a perspective view of a connection between a dust separator and a drive device of a vacuum cleaner in accordance with another embodiment of the present invention.

The following describes in detail preferred embodiments of the present invention, examples of which are illustrated in the accompanying drawings. Where possible, the same reference numerals are used in the drawings to refer to the same or similar parts.

Figure 1 is a perspective view of a vacuum cleaner in accordance with one embodiment of the present invention, when the dust collecting device is separated from the vacuum cleaner; figure 2 is a perspective view of the vacuum cleaner of figure 1, when the dust collecting device is assembled together with the vacuum cleaner; and FIG. 3 is a section taken along line I-I ′ in FIG. 2.

As shown in FIGS. 1-3, the vacuum cleaner 100 includes a main body 200, a drive device located in the main body 200 and designed to create a suction force for suctioning air containing dust, a suction nozzle (not shown), designed to suck air containing dust in the main body 200, a dust collecting device 300.

The suction portion 220 of the main body in communication with the suction nozzle is formed on the front lower part of the main body 200. The exhaust portion 290 of the main body through which air is discharged from which dust is separated in the dust separation device 300 is formed on the side of the main body 200.

The drive device 210 includes a fan motor assembly 211 for generating a suction force for drawing in external air into the suction nozzle. The fan motor assembly 211 is inserted into the fan motor cavity 213 formed in the main body 200.

An electric motor pre-filter 215 may be provided in the main body 200 upstream of the fan motor assembly 211 to filter out fine particles contained in the air flowing towards the fan motor assembly 211.

Since the pre-filter 215 of the motor serves to protect the motor and the collection of fine dust, there is a need for periodic cleaning or replacement of the pre-filter to prevent a decrease in the efficiency of dust collection.

Therefore, in this embodiment, the filter accommodating portion 216 in which the motor pre-filter 215 is detachably mounted is formed in the main body. The filter accommodating portion 216 is opened and closed by a filter cover 253 that is detachably attached to the main body 200.

The dust separator 300 includes a cyclone device 360 provided in the main body 200 for dust separation by using the cyclone principle, and a dust collecting device 310 for collecting dust separated in the cyclone device 360.

The dust collecting device 310 is detachably mounted in the main body 200. When the dust collecting device 310 is mounted in the main body 200, it is connected to the cyclone device 360 for receiving and collecting dust separated by the cyclone device 360.

That is, when the user separates the dust collecting device 310 from the main body 200 to empty the dust collecting device 310, the dust collecting device 310 is separated from the cyclone device 360. When the dust collecting device 310 is again installed in the main body 200, the dust collecting device 310 is connected to the cyclone device 360.

In this case, to increase the dust separation efficiency, the dust separation device 300 may further include a dust separation element 320 for additionally separating dust.

Therefore, in this embodiment, the dust separating member 320 is located upstream of the cyclone device 360.

That is, the main body 200 is configured to first allow dust to be separated by using the dust separating member 320 before the introduced air is directed to the cyclone device 360, thereby increasing the efficiency of the dust separating apparatus 300 when dust is separated.

In this case, the dust separating member 320 is integrally formed with the dust collecting device 310, which is preferably configured to separate the dust by using the cyclone principle. However, the present invention is not limited to this embodiment.

For convenience of description, in the following description, the dust separating element 320 will be called the main cyclone device 320, and the cyclone device 360 provided in the main body 200 will be called the cyclone device 360.

The main cyclone device 320 is integrally formed with the upper part of the dust collecting device 310. The main cyclone device 320 is made with the first suction part 321 formed in a tangential direction.

That is, the first suction portion 321 allows the introduction of dust-containing air in the tangential direction of the main cyclone device 320 to create a cyclone therein.

An exhaust element 323, made on the outer periphery with a plurality of holes 324, is provided on the axis of the cyclone device 320. The exhaust element 323 allows air to be released from which dust was first removed in the cyclone device 320.

Meanwhile, the dust collecting device 310 collects dust separated by the main cyclone device 320 and the auxiliary cyclone device.

That is, the dust collecting device 310 includes a main dust collecting chamber 331 for dust separated by the main cyclone device 320, and an auxiliary dust collecting chamber 335 for dust separated by the auxiliary cyclone device 360.

That is, the main chamber 331 is formed at the bottom of the main cyclone device 320, and the auxiliary chamber 335 is formed at the outside of the dust collecting device 310.

In this embodiment, the auxiliary chamber 335 is integrally formed with the dust collecting device 310. However, the auxiliary camera 335 can be detachably mounted in the dust collecting device 310. In this case, the surface of the auxiliary chamber, which is facing the dust collecting device 310, can be made so that it matches the shape of the dust collecting device 310.

When the dust collecting device 310 is installed in the main body 200, the auxiliary chamber 335 is connected to the auxiliary cyclone device 360, and thus, dust separated by the auxiliary cyclone device will accumulate in the auxiliary chamber 335.

That is, the auxiliary chamber 335 is not integral with the auxiliary cyclone device 360, but is designed to be detached and selectively connected to the auxiliary cyclone device 360.

Meanwhile, in order for the user to empty the dust collecting device 310 by turning the dust collecting device 310 upside down, there is a top cover 340 that can be detached to the upper part of the main cyclone device 320 to detach to open and close the upper part of the main cyclone device 320.

A top cover 340 is provided in the central part with a first exhaust portion 342 through which air passing through the exhaust element 323 is discharged from the main cyclone device 320.

Meanwhile, an auxiliary cyclone device 360 is provided in the main body 200 to further separate dust contained in the air that has passed through the main cyclone device 320.

Here, the auxiliary cyclone device 360 may be in a position in which it "lies" on the main body 200.

That is, when the auxiliary cyclone device 360 is located horizontally on the main body 200, the efficiency of using the space occupied by the vacuum cleaner can be improved, taking into account the design with the drive device 210.

Next, a connection structure of the main cyclone device and the auxiliary cyclone device will be described.

FIG. 4 is a perspective view of a dust separator, and FIG. 5 is a perspective view of a connecting structure of an auxiliary cyclone device and a connecting channel.

As shown in FIGS. 4 and 5, the main cyclone device 320 and the auxiliary cyclone device 360 are connected to each other via a connecting channel 350.

The connecting channel 350 has a first side connected to the upper cover 340 located on the upper part of the main cyclone device 320, and a second side connected to the connecting hole 364 formed in the upper part of the auxiliary cyclone device 360.

The connecting channel 350 has a cross-section, the area of which gradually increases towards the connecting hole 364. Therefore, the air flow rate decreases gradually towards the connecting hole 364 of the auxiliary cyclone device 360, and therefore, the aerodynamic drag decreases next to the connecting hole 364 of the auxiliary cyclone 360 devices.

In addition, a sealing element 352 may be provided between the connecting channel 350 and the top cover 340 and between the connecting channel 350 and the connecting hole 364.

6 is a perspective view of a dust collecting device.

As shown in FIGS. 5 and 6, the main body 200 is provided with a part 240 for installing a dust collecting device in which the dust collecting device is installed.

The auxiliary chamber 335 has a dust suction portion 336 through which dust is introduced, separated by the auxiliary cyclone device 360.

The auxiliary cyclone device 360 is provided with a dust discharge part 365 through which dust separated by the auxiliary cyclone device 360 is discharged to the dust suction part 336.

Therefore, the dust discharge part 365 is connected to the dust suction part when the user installs the dust collecting device 310 on the dust collecting part 240.

Here, the dust extraction part 365 and the dust suction part 336 are in close contact with each other due to the force exerted to install the dust collecting device 310.

That is, when the dust collecting device 310 is installed on the dust collecting device part 240 by a force exerted by the user, the dust suction part 336 will come into contact with the dust evacuation part 365 to gradually press the dust evacuation part 365, and the dust discharging part 365 creates a force repulsion with respect to the force applied to install the dust collecting device 310. Therefore, the dust extraction part 365 and the dust suction part 336 will be in tight contact with each other due to s applied to install the dust collecting device 310.

The dust suction portion 336 has a first contact surface 337 formed with one or more dust suction openings 338 through which dust is separated from the auxiliary cyclone device 360.

Part 365 for the release of dust has a second contact surface 366 made with one or more holes 367 for the release of dust through which dust is discharged. The second contact surface 366 is in close contact with the first contact surface 337, so that the dust suction port 338 is in communication with the dust outlet 367.

In this case, the number of dust suction openings 338 is equal to the number of dust suction openings 367. Alternatively, the plurality of dust exhaust openings 367 may be in communication with one dust suction open 338.

In this case, the first and second contact surfaces 337 and 366 may come into contact with each other when the dust collecting device 310 is mounted on the dust collecting device portion 240.

Therefore, the second contact surface 366 is inclined at a predetermined angle with respect to the direction in which the dust collecting device 310 is separated. However, the second contact surface 366 may be curved.

That is, the second contact surface 366 is inclined at a predetermined angle, preferably at a right angle, with respect to the direction in which the dust collecting device 310 is detached so as to provide a repulsive force with respect to the force applied to install the dust collecting device 310 when the dust collecting device 310 mounted on part 240 for installing a dust collecting device. Therefore, airtightness is ensured between the dust suction portion 336 and the dust suction portion 365.

In this case, when the second contact surface 366 is inclined at a predetermined angle relative to the direction in which the dust collecting device 310 is separated, the predetermined angle can be within the range of 45-135 °. Preferably, the predetermined angle is substantially straight with respect to the direction in which the dust collecting device 310 is separated. The term “substantially straight” means that the angle between the second contact surface 366 and the direction in which the dust collecting device 310 is separated is in within the range of 75-105 °.

In this embodiment, the second contact surface 366 is formed so that it is oriented toward the inlet portion of the dust collecting part 240.

When the second contact surface 366 is substantially perpendicular to the direction in which the dust collecting device 310 is installed or separated, and the dust collecting device 310 is mounted to the dust collecting device part 240 by sliding in the horizontal direction, the first contact surface 337 of the dust suction portion 336 located in front of the dust collecting device with respect to the installation direction of the dust collecting device 310, so that the first contact surface 337 This will face the second contact surface 366.

That is, when the dust collecting device 310 is installed towards the front of the main body 200, the first contact surface 337 can be formed approximately on the rear side of the surface of the dust collecting device 310. When the dust collecting device 310 is installed towards the rear of the main body 200, the first surface 337 contact can be formed approximately on the front side of the surface of the dust collecting device 310.

In this case, the degree of contact between the dust discharge part 365 and the dust suction part 336 increases, and the airtightness between the dust exhaust part 365 and the dust suction part 336 is increased, thereby increasing the dust collection efficiency.

Meanwhile, in contrast to the above, when installing the dust collecting device 310, one of the following parts — the dust extraction part 365 or the dust suction part 336 — can be inserted into the other in the direction in which the dust collecting device 310 is installed.

In this embodiment, the dust discharge part 365 is inserted into the dust suction part 336.

That is, the dust suction portion 336 is formed with a holding portion 339 designed to cover the dust exhaust portion 365. The holding portion 339 extends in a perpendicular direction from the auxiliary chamber.

Therefore, the holding portion 339 is in tight contact with the periphery of the dust exhausting part 365 to prevent air leakage between the dust exhausting part 365 and the dust suctioning part 336.

Meanwhile, in order to prevent the dispersion of dust accumulated in the main chamber 331 towards the main cyclone device 320 by spiraling air, the anti-scatter part 327 separating the main cyclone device 320 from the main chamber 331 is formed horizontally in the dust collecting device 310.

In this case, the dust separated by the main cyclone device 320 moves downward through an opening 329 formed at the edge of the part 327 to prevent scattering, and accumulates in the main chamber 331.

As described above, in contrast to the prior art, the auxiliary cyclone device 360 is provided in the main body 200, and the auxiliary dust collecting chamber 335 for dust separated by the auxiliary cyclone device 360 is integrally formed with the dust collecting device 310.

Therefore, since the auxiliary cyclone device 360, which is repeatedly mounted and removed for dust discharge, is not made integrally with the dust collecting device 310, the structure of the dust collecting device 310 is simplified and becomes easier.

In addition, the user easily separates only the dust collecting device 310 from the main body 200, then separates the upper cover 340 from the upper part of the dust collecting device 310 and unloads dust from the dust collecting device 310 by turning the dust collecting device over.

Here, the main chamber 331 can be made of a transparent material so that the user can determine the amount of dust accumulated in the main chamber 331.

Accordingly, since the user can easily determine the state within the main camera 331, the user can empty the main camera 331 in time.

Fig. 7 is a perspective view of an auxiliary cyclone device, and Fig. 8 is a section taken along line II-II 'in Fig. 7.

As shown in FIGS. 7 and 8, the auxiliary cyclone device 360 consists of a plurality of small cyclones 363. In this embodiment, four small cyclones 363 are located in the same plane in parallel.

That is, air containing dust is introduced into the auxiliary cyclone device 360 through the dust collecting device 310, and therefore, it can be noted that the dust collecting device 310 is connected in series with the auxiliary cyclonic device 360.

In contrast, the air leaving the dust collecting device 310 is directed to the auxiliary cyclone device 360 through the connecting channel 350 and is divided in two at the inlet to the auxiliary cyclone device 360 for introducing air into the small cyclones 363. The dust contained in the air is separated in each small cyclone 363 .

That is, the air discharged from the dust collecting device 310 passes inconsistently through the small cyclones 363, and simultaneously passes through the small cyclones 363.

Therefore, it can be clearly noted that in this embodiment, the auxiliary cyclone device 360 has many small cyclones 363 that are arranged in parallel.

In addition, the longitudinal axes of the respective minor cyclones 363 are located in the same plane, so that the structure can be more compact. In this case, the axis is the center line passing through the center of each small cyclone 363. That is, the distances between the axes of the respective small cyclones 363 are gradually reduced from the second suction portion 361 towards the dust outlet 367.

Consequently, small cyclones located in the same plane and converging with each other are fan-shaped.

In this case, the axes of at least two small cyclones 363 preferably converge. 7, the longitudinal axes of all small cyclones 363 converge with each other so as to make the auxiliary cyclone device 360 compact.

Alternatively, the two central minor cyclones 363 may have corresponding longitudinal axes that are parallel to each other, while the left and right small cyclones 363 may have corresponding longitudinal axes that converge with each other.

The angles at which small cyclones 363 are placed to ensure the convergence of their longitudinal axes can be determined in accordance with their sizes or the volume of the auxiliary chamber 335 connected to the small cyclones 363.

The distances between the small cyclones 363 gradually increase towards the dust discharge part 365. Alternatively, adjacent small cyclones 363 may be in contact with each other to minimize the gaps between the dust exhaust openings 367.

As described above, since the small cyclones 363 are arranged so as to be convergent with respect to each other, the space occupied by the auxiliary cyclone device 360 can be reduced, as a result of which the dimensions of the vacuum cleaner are reduced.

Furthermore, by reducing the gaps between the dust exhaust openings 367 formed at the end of the auxiliary cyclone device 360, it is possible to reduce the size of the dust suction portion 336 of the auxiliary chamber 335 connected to the auxiliary cyclone device 360. As a result, the size of the auxiliary chamber does not excessively increase. .

In this case, the longitudinal axes of the small cyclones 363 are located in the same plane so as to make the auxiliary cyclone device 360 compact. However, the present invention is not limited to this.

In addition, small cyclones 363 can be made in many different shapes.

In addition, despite the fact that each small cyclone 363 can have many different shapes, it is preferable that the small cyclone 363 is made in the form of a body of revolution, which can ensure the effective separation of dust contained in the air, through the use of centrifugal force. In this embodiment, the small cyclone 363 has a conical body structure.

Meanwhile, each of the small cyclones 363 of the auxiliary cyclone device 360 is formed with a second suction portion 361 through which air is introduced. A guide 362 is provided on the second suction portion 361 for directing air in a direction tangential to the second suction portion 361.

The guide portion 362 serves to divide the second suction portion 361 into two sections that are surface symmetrical. As shown in FIG. 8, one guide 362 is provided in the center of the second suction portion 361, so that the left and right sides relative to the guide 362 can be symmetrical.

To direct the air in a tangential direction to each small cyclone 363, a second suction portion 361 adjacent to the guide 362 is open in a portion adjacent to the guide. The second suction portion 361 of the small cyclones located at the side edges is open in the direction of the guide 362.

In this case, the guide 362 may extend inside the connecting channel 350. Since in this embodiment, the guide 362 is located in the center of the second suction part 361, the inner part of the connecting channel 350 is divided into left and right sections.

Typically, the amount of air passing through the central part of the auxiliary cyclone device 360 exceeds the amount of air passing through the side edges of the auxiliary cyclone device 360.

Therefore, since the guide 362 dividing the second suction portion 361 into two sections extends inside the connecting channel 350, the air flow is divided into left and right flows. Therefore, air is not absorbed concentrically through the second suction portion 361 located in the center, but is sucked in uniformly.

Since in this case, the part of the guide 362, which is located inside the connecting channel 350, serves to divide the inner part of the connecting channel 350 into two channels, the guide 362 can be called a partition.

In this embodiment, the guide 362 is designed to divide the inner part of the connecting channel 350 into two sections. However, the present invention is not limited to this. For example, a separate partition may be formed in the connecting channel 350 to divide the channel into two channels. In this case, the partition will be formed so that it matches the guide 362.

Fig.9 is a cross section of an example modified with respect to the example of Fig.8.

As shown in FIG. 9, as in the previous embodiment, the rail 462 is arranged so as to allow the second suction portion 461 to be divided into two sections. A second suction portion 461 adjacent to the rail 462 is open in a portion adjacent to the rail 462.

The second suction portion 461 of the small cyclones at the lateral edges is open at the outer portions of these cyclones, so that air can be sucked in in a tangential direction.

Next, the operation of the above-described vacuum cleaner 100 will be described.

First, when electric power is supplied to the drive unit 210 of the vacuum cleaner 100, the drive unit 210 creates a suction force, and air containing dust is sucked into the suction nozzle due to the created suction force.

Air introduced into the suction nozzle is directed to the main cyclone device 320 through the main suction part 220 and the first suction part 321. That is, the air sucked through the first suction part 321 is directed tangentially along the inner wall of the main cyclone 320 to form a flow passing in a spiral. Therefore, the dust contained in the air is separated by the difference of the centrifugal forces between the dust and air.

In addition, the separated dust is collected in the main chamber 331, passing through the opening 329. Here, the dispersion of dust collected in the main chamber 331 can be prevented by the part 327 to prevent scattering.

On the contrary, the air from which the dust was first separated by means of the main cyclone device 320 flows upward, passing sequentially through the exhaust element 323 and the first exhaust part 342. Then, the air passing upward is directed to the auxiliary cyclone device 360 through the connecting channel 350.

In this case, the air passing along the connecting channel 350 is directed to the inner walls of the small cyclones 363 in the tangential directions. In addition, dust is additionally separated from the air directed tangentially to each small cyclone 363 by centrifugal force. The separated dust is discharged through the dust outlet 368 and is collected in the auxiliary chamber 335.

The air, which has undergone additional dust separation, is directed to the exhaust channel (390 in FIG. 3) by exhausting it from the auxiliary cyclone device 360 through a second exhaust part (362 in FIG. 3) formed at the rear end of each small cyclone 363. Then, air directed into the outlet channel (390 in FIG. 3) is directed to the drive device 210 after passing through the motor pre-filter 215 and then to the main body 200 through the outlet channel 390.

Figure 10 is a perspective view of a vacuum cleaner in accordance with another embodiment of the present invention.

The vacuum cleaner according to this embodiment is basically identical to the vacuum cleaner according to the previous embodiment of FIGS. 1-8, except for the structure for separating the auxiliary chamber from the dust collecting device. Therefore, a different part will now be described.

As shown in FIG. 10, in this embodiment, the auxiliary dust collecting chamber 435 for dust separated by the auxiliary cyclone device 360 is separated from the main chamber 431 and is detachably provided in the dust collecting device 410.

That is, as shown in FIG. 10, the dust collecting device 410 is separated in the main body 200, and the auxiliary chamber 435, separated from the dust collecting device 410, is detachably mounted in the main body.

Therefore, in this embodiment, only the dust collecting device 410 is separated from the main body 200 and the main chamber 431 is empty.

In addition, if required, the dust collecting device 410 is separated and the auxiliary chamber 435 installed in the main body 200 is separated. Therefore, the auxiliary chamber 435 may be emptied.

As a rule, when comparing the main cyclone device with the auxiliary cyclone device 360, it can be noted that the dust separated by the main cyclone device has a relatively large volume and its quantity will be greater. Therefore, the main chamber, designed to accumulate dust separated by the main cyclone device, should be emptied more often than the auxiliary chamber 435.

In view of the foregoing, the auxiliary chamber 435, which is emptied less frequently, is configured to separate it from the main body 200, so that only the dust collecting device 410 is designed to separate from the main body 210 so as to empty the main chamber 431.

11 is a partially exploded perspective view of a state in which a dust separator is connected to a drive device of a vacuum cleaner in accordance with yet another embodiment of the present invention.

The vacuum cleaner according to this embodiment is basically identical to the vacuum cleaner according to the above embodiment according to FIGS. 1-8, except for the design of the auxiliary cyclone device. Therefore, a different part will now be described.

As shown in FIG. 11, the auxiliary cyclone device 560 according to this embodiment is not located horizontally on the main body 200, but is located in a vertical direction or tilted at a predetermined angle with respect to the vertical direction.

In addition, the auxiliary chamber 535 is attached to the lower end of the auxiliary cyclone device 560 at the bottom of the main chamber 531.

Meanwhile, the bottoms of the main camera 531 and the auxiliary camera 535 are configured to open and close.

That is, the bottoms of the lower chamber 531 and the auxiliary chamber 535 have opening / closing elements 533 that are integrally formed with them.

The opening / closing element 533 is pivotally attached to the hinge portion 537 formed on the first lower side of the dust collecting device 510. The opening / closing element 533 is opened by pressing the connecting hook 539 formed on the second lower side of the dust collecting device 510.

Next, operation of the vacuum cleaner in accordance with this embodiment will be described.

When the drive unit is actuated, air containing dust is introduced into the suction nozzle. The dust contained in the air is first separated while the air passes through the main cyclone device 520. The separated dust moves down to collect it in the main chamber 531.

In addition, the air from which the dust was first separated by the main cyclone device 520 passes through the exhaust element 523 and then passes upward. Then, the air flows along the connecting channel 550. Then, the air is directed tangentially to the inner walls of the small cyclones through the second suction part 561. In addition, by means of centrifugal force, there is an additional separation of dust from the air introduced into the auxiliary cyclone device 560. The separated dust accumulates in an auxiliary chamber 535 attached to the end of the auxiliary cyclone device 560.

Meanwhile, the air from which the dust is further separated is discharged from the auxiliary cyclone device 560 through the second exhaust part and then directed downward through the exhaust channel 590. The fine particles contained in the downward air are finally separated by the motor pre-filter 215. and are introduced in the axial direction of the node consisting of a fan and an electric motor.

The air directed to the node 211, consisting of a fan and an electric motor, is directed in the radial direction and then finally is discharged from the main body 200 through the exhaust part 290 of the main body provided on the side of the main body 200.

12 is a partially exploded perspective view of a state in which a dust separating device is connected to a drive device of a vacuum cleaner in accordance with yet another embodiment of the present invention.

The vacuum cleaner according to this embodiment is basically identical to the vacuum cleaner according to the above embodiment of FIGS. 1-8, except that the main cyclone device that initially filters the dust before introducing air into the auxiliary cyclone device is replaced by a filter device 620.

As shown in FIG. 12, in this embodiment, a filter device 620 for initially filtering dust before introducing air into the auxiliary cyclone device is provided in the dust collecting device.

The filter device 620 includes a dust filter 621 and an element 623 for installing a filter for installing a dust filter 621.

That is, a filter mounting member 623 is provided on the lower part of the upper cover 640 to house the dust filter 621.

The dust filter 621 is separately inserted into the filter element 623. The dust filter 621 may be made of sponge or non-woven material.

Meanwhile, since dust settles on the dust filter 621, it is necessary to periodically clean or replace the dust filter 621 to prevent deterioration in suction provided by the vacuum cleaner. Therefore, the dust filter 621 should be easily detachable from the main body.

In this embodiment, the dust filter 621 is separated after the top cover 640 has been separated. Alternatively, the dust filter 621 can be inserted into the filter mounting element 623 by sliding movement, so that the dust filter 621 can be separated from the filter mounting element 623 by moving with a slip.

It will be apparent to those skilled in the art that various modifications and variations can be made to the present invention. Thus, it is intended that the present invention cover the modifications and variations of this invention provided that they fall within the scope of the claims of the appended claims and their equivalents.

Claims (21)

1. A vacuum cleaner containing main building; a device for separating dust, which is provided in the main body for separating dust from air and has a part for discharging dust through which the separated dust is discharged; a dust collecting chamber that has a dust inlet part through which dust is discharged from the dust exhaust part, wherein the dust inlet part includes a first contact surface formed with at least one dust inlet opening through which dust, and the dust discharge part includes a second contact surface, which is located at a predetermined angle relative to the direction in which the dust chamber is separated, and which is made with at least one hole for discharging dust that is connected to the dust inlet, for discharging dust, a mounting element that is formed on the main body and on which the dust collecting chamber is mounted, wherein the dust discharge part and the dust inlet part are in contact with each other under a pressing force with which the dust collecting chamber is mounted on the mounting element, thereby preventing air leakage. 2. The vacuum cleaner according to claim 1, in which the second contact surface of the dust discharge part is vertical with respect to the direction in which the dust chamber is separated. 3. The vacuum cleaner according to claim 1, in which the second contact surface of the part for the release of dust is oriented towards the entrance of the mounting element. 4. The vacuum cleaner according to claim 1, further comprising a dust collecting device that is configured to be mounted on a mounting element and which has a main dust separating device for separating dust from air introduced into the dust separating device. 5. The vacuum cleaner according to claim 4, in which the dust collecting device has a main chamber in which dust is collected separated by the dust separating device, and the dust collecting chamber is integrally formed with the dust collecting device. 6. The vacuum cleaner according to claim 5, in which the dust collecting device further comprises a top cover designed to simultaneously open and close the upper parts of the main chamber and the dust chamber. 7. The vacuum cleaner according to claim 5, in which the dust collecting device further comprises an opening / closing element for simultaneously opening and closing the lower parts of the main chamber and the dust collecting chamber. 8. The vacuum cleaner according to claim 4, in which the dust collecting device is installed on the mounting element after installing the dust chamber on the mounting element. 9. The vacuum cleaner according to claim 4, in which the main device for separating dust is made with a configuration that allows the separation of dust from air through the use of the cyclone method. 10. The vacuum cleaner according to claim 4, in which the main device for separating dust is a dust filter. 11. The vacuum cleaner according to claim 1, in which the device for separating dust is located horizontally on the main body. 12. The vacuum cleaner according to claim 1, in which the device for separating dust is located vertically on the main body. 13. The vacuum cleaner according to claim 1, in which the device for separating dust includes many auxiliary cyclones. 14. A vacuum cleaner containing main building; a cyclone device, which is provided in the main body and is designed to separate dust from the air that is introduced into it, and in which the plurality of auxiliary cyclones are parallel, and at least two longitudinal axes of the longitudinal axes of the auxiliary cyclones converge, and a dust collecting device that is detachably mounted on the main body collects dust separated by the cyclone device and communicates with the cyclone device when it is mounted on the main body. 15. The vacuum cleaner according to 14, in which the longitudinal axis of the auxiliary cyclones are located in a common plane. 16. The vacuum cleaner according to 14, in which the suction part formed in each auxiliary cyclone is divided into two sections that are surface symmetrical, and the vacuum cleaner further comprises a guide device for directing air flow from the suction part. 17. The vacuum cleaner of claim 14, further comprising a dust separation device that is provided in the dust collecting device for initially separating dust from air sent to the cyclone device, and a connecting channel that connects the dust separation device to the cyclone device. 18. The vacuum cleaner according to 17, in which the connecting channel has a cross-sectional area, which gradually decreases as you approach the device for separating dust from the cyclone device. 19. The vacuum cleaner according to 17, in which the connecting channel is made with a partition to allow air flow through multiple channels. 20. The vacuum cleaner according to claim 19, in which the partition passes from the guide device for directing air from the auxiliary cyclones into the connecting channel. 21. The vacuum cleaner according to claim 17, wherein the dust collecting device comprises a main chamber in which dust separated by the dust separation device is collected, and an auxiliary dust collecting chamber separated in the cyclone device.

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