RU2332918C1 - Dust collecting device and vacuum cleaner (variants) - Google Patents

Abstract

FIELD: items of personal and household use.

SUBSTANCE: vacuum cleaner contains basic case, device for air intake and dust collecting device. The dust collecting device contains a dust separating device, separating polluting particles containing in air, a dust collecting container for storage of polluting particles, the motionless element fixed in dust collecting container and, at least, one clamping element mounted in a dust collecting container to reduce of amount of polluting particles at interaction with a motionless element. The clamping element has the actuating unit which contains an electric drive motor, and is capable of rotating in two directions.

EFFECT: increase in efficiency of gathering polluting particles and their quantity.

22 cl, 9 dwg

Description

The present invention relates to a dust collecting device and a vacuum cleaner, and more particularly, to a dust collecting device and a vacuum cleaner having an increased dust collecting volume.

Typically, a vacuum cleaner is a device that can suck in air containing contaminants using vacuum pressure generated by a vacuum motor mounted in the main body and filter out the contaminants in the main body.

Such a vacuum cleaner comprises a suction brush for sucking in air containing contaminants, a main body of the vacuum cleaner that communicates with the suction brush, a sliding tube for directing air drawn in through the suction brush to the main body and a connecting channel for guiding air that passes through the sliding tube, in the main building.

The suction brush forms the suction hole of the brush of a predetermined size in its lower part to suck in air containing contaminants collected from the floor.

A drive device is provided in the main body of the vacuum cleaner, which creates a suction force for drawing in external air containing contaminants through the suction brush.

In addition, a dust collecting device for separating and storing contaminants is detachably mounted in the main body. The dust collector separates and stores the contaminants contained in the air that is sucked through the suction brush.

In more detail, the dust collecting device comprises a dust collecting housing with an inlet through which air is sucked into the dust collecting housing, a cyclone device for separating the polluting particles from the air drawn into the dust collecting housing, a part for storing the polluting particles for storing the polluting particles separated in the cyclone device, and an outlet through which purified air exits.

Pollutant particles stored in the lower part of the dust-collecting case (i.e., polluting particles in the part for storing the polluting particles) are continuously circulated along the inner circumference of the dust-collecting case under the influence of the circulation flow in the dust-collecting case during operation of the vacuum cleaner.

When the vacuum cleaner is turned off, polluting particles settle to the bottom of the dust collecting case and are stored in it having a low density.

Therefore, in the known dust collecting device, when the amount of polluting particles exceeds a predetermined amount in the dust collecting device during operation of the vacuum cleaner, the polluting particles circulate and rise along the inner wall of the dust collecting device and pass into the cyclone device formed in the upper space of the dust collecting body. Thus, non-segregated contaminants are discharged together with the air flow through the outlet, thereby reducing the collection efficiency of the contaminants of the dust collecting device.

As described above, when the vacuum cleaner is turned off, pollutant particles settle to the bottom of the dust collecting case and have a low density. In other words, the contaminants in the dust collecting case occupy an excessive volume in proportion to their weight, requiring frequent (and therefore burdensome) emptying of the dust collecting case to maintain an effective level of collection of the polluting particles.

Therefore, to improve the usability of the vacuum cleaner, constant efforts are made to create an article in which it is possible to maximize the amount of contaminants collected in the dust collecting case while increasing the efficiency of collecting the contaminants.

Therefore, the present invention relates to a dust collecting device and a vacuum cleaner, which essentially eliminate one or more problems due to limitations and disadvantages of the prior art.

An object of the present invention is to provide a dust collecting device and a vacuum cleaner having an increased dust collecting volume.

Another objective of the present invention is to provide a dust collecting device and a vacuum cleaner having an increased dust collecting volume by automatically compacting the contaminants stored therein.

Additional advantages, objectives, and features of the present invention will be partially discussed in the following description and partially understood by those skilled in the art after studying the following, or may be studied by practicing the present invention. The objectives and other advantages of the present invention can be realized and achieved due to the design specifically specified in the description and its claims, as well as in the accompanying drawings.

To achieve these goals and other advantages, and in accordance with the purpose of the present invention, there is provided a dust collecting device comprising a dust separation device for separating pollutants contained in air, a dust collecting container comprising a storage part for polluting particles separated by a dust separating device, a stationary element fixed in the dust container, at least one clamping element mounted for movement in the dust container and interacting ones with a fixed element to reduce the volume of the dusts stored in the portion for storing the dusts, and a driving device for driving the pressing member, the pressing member has a rotational shaft, movably connected to the dust collection container, and a drive device connected to the rotational shaft of the pressing member.

Preferably, the dust separation device is detachably connected to the upper part of the dust collecting container.

Preferably, for separating the dust separating device and the part for storing contaminant particles, a separation plate is installed in the lower part of the dust separating device.

Preferably, the clamping element rotates with a rotational shaft located on the same axis as the center of the dust collecting container.

Preferably, the inner peripheral surface of the dust collecting container is shaped so as to surround the path described by the pressure member when it rotates in the dust collecting part.

Preferably, the pressing member is rotatable in two directions to seal contaminants on both sides of the fixed member.

Preferably, the pressure member is rotated by a drive device coupled to the rotational shaft.

Preferably, the drive device comprises a drive motor, a driven gear connected to the rotational shaft of the pressure member, and a drive gear selectively connected to the rotational shaft of the drive motor to transmit driving force to the driven gear.

Preferably, the driven gear is connected to the rotational shaft of the pressing member on the outside of the dust collecting container.

Preferably, the fixed element is permanently attached either to the inner peripheral surface of the dust collecting container or to a fixed shaft mounted on the same axis as the rotational shaft of the pressing member.

These goals are also achieved by creating a vacuum cleaner, comprising: a main body, including a device for suctioning air to generate a suction force for air; a dust separation device for separating airborne contaminants, detachably connected to a main body; a dust collecting container comprising a part for storing pollutant particles for storing pollutant particles separated by a dust separation device; a first clamping member located inside the dust collecting container to reduce the amount of contaminant particles stored in the dust collecting container, and a drive motor for driving the first clamping member.

Preferably, the vacuum cleaner further comprises a second pressure member integrally formed with the dust collecting container.

Preferably, the first pressure member rotates together with a rotational shaft mounted on the same axis in the center of the dust container, and the drive device comprises a drive motor, a driven gear connected to the movable element on the outside of the dust container, and a drive gear connected with a drive motor for transmitting the rotation force of the drive motor to the driven gear.

The objectives of the present invention, in addition, are achieved by creating a vacuum cleaner containing a main body, including a device for suctioning air to generate a suction force for air, a dust collecting device connected with the possibility of detachment from the main body and containing a dust separation device for separating polluting particles, contained in the air, and a dust container containing a part for storing pollutants for storing pollutants separated by dust separation devices m; a first pressure member located inside the dust collecting container to reduce the amount of contaminants in the dust collecting container; and a drive device for driving a first pressure member having a drive electric motor, wherein the first pressure member is connected to the drive electric motor by installing a dust collecting device on the main body.

Preferably, the vacuum cleaner further comprises a second clamping member fixed in the dust collecting container, wherein the first clamping member cooperates with the second clamping member to reduce the amount of contaminant particles.

Preferably, the fixed shaft is made in a dust collecting container, and the rotational shaft is connected to the fixed shaft.

Preferably, the second clamping element is completely fixed either on the inner peripheral surface of the dust collecting container or on a fixed shaft located on the same axis as the rotating shaft of the clamping element.

Preferably, the drive motor is provided in the main body, and the drive device further comprises:

the driven gear connected to the rotational shaft of the second clamping member, and the driving gear connected to the rotational shaft of the drive motor for transmitting the driving force to the driven gear.

Preferably, the driven gear is connected to the rotational shaft of the drive motor on the outside of the dust collecting container, and the drive gear is connected to the drive motor and open to the outside of the main body.

Preferably, the contaminant storage part comprises a first part for storing contaminant particles for storing contaminant particles separated in the dust separating device, and a second part for storing contaminant particles for storing contaminant particles separated in the auxiliary dust separating device installed in the main body.

Preferably, the pressing elements are installed in the first part for storing contaminants.

You must understand that both the specified General description and the following detailed description of the present invention are illustrative and explanatory and are intended to provide an additional explanation of the present invention, as claimed.

The accompanying drawings, which are included to provide a further understanding of the present invention and form part of this application, show embodiments of the present invention and together with the description serve to explain the principle of the present invention. In the drawings:

1 is a perspective view illustrating a dust collecting device disconnected from a vacuum cleaner in accordance with an embodiment of the present invention;

FIG. 2 is a perspective view illustrating a dust collecting device disconnected from a receiving portion for a dust collecting device used in a vacuum cleaner; FIG.

figure 3 is a perspective view in section of a dust collecting device;

figure 4 is an enlarged view of part "A" in figure 3;

5 is a perspective view illustrating the relationship between the drive device for sealing contaminants stored in the dust collector and the dust collector;

6 and 7 are top views illustrating the process of compacting contaminant particles in a dust collecting device;

Fig. 8 is a view of a dust separating device and a dust collecting container disconnected from the dust collecting device; and

Fig.9 is a perspective view from below of the dust separation device of Fig.8.

Reference will be made in detail to preferred embodiments of the present invention, examples of which are illustrated in the accompanying drawings.

1 is a perspective view illustrating a dust collecting device disconnected from a vacuum cleaner in accordance with an embodiment of the present invention.

As shown in FIG. 1, a vacuum cleaner in accordance with an embodiment of the present invention comprises a vacuum cleaner main body 100 including a suction generator, and a dust collecting device 200 for separating and storing contaminants contained in the intake air.

The vacuum cleaner further comprises a suction brush (not shown) for suctioning air containing contaminants, and a connecting channel (not shown) for connecting the suction brush to the main body 100.

In the present invention, the suction brush and the connecting channel have a basic structure similar to that of the prior art, and thus a description thereof will be omitted.

In more detail, an inlet 110 of the main body is formed in the front lower part of the main body 100. Air containing contaminants is drawn in from the suction brush through the inlet 110 of the main body.

An outlet 120 of the main body is formed on one side of the main body 100. Air separated from the contaminants is discharged from the main body 100 through the outlet 120 of the main body.

The dust collecting device 200 comprises a dust separation device 210 for separating the polluting particles from the intake air and a dust collecting tank 220 for storing the polluting particles separated in the dust collecting device 210.

The dust separation device 200 comprises a cyclone device 211 (see FIG. 3) for separating the contaminants from the intake air using a centrifugal force difference between the air and the pollutants (principle of operation of the cyclone).

The dust collecting device 200 may be configured to maximize its ability to store contaminants. For this reason, the dust collecting device 200 may further comprise a device for reducing the amount of contaminant particles contained in the dust collecting container 220.

Below with reference to figures 2-5 in accordance with the present invention will be described a vacuum cleaner containing a dust collecting device, which maximizes its ability to store polluting particles.

2 is a perspective view illustrating a dust collector disconnected from a receiving portion for a dust collector used in a vacuum cleaner. Figure 3 depicts a perspective view in section of a dust collecting device. Figure 4 depicts an enlarged view of part "A" in figure 3. 5 is a perspective view illustrating a relationship between a drive device for sealing contaminants contained in a dust collector and a dust collector.

As shown in FIGS. 2-5, the dust collector 200 according to an embodiment of the present invention is removably mounted in the main body 100.

The main body 100 includes a receiving part 130 for a dust collecting device for installing a dust collecting device 200.

A pair of pressure members 310 and 320 are provided in the dust collector 200 to reduce the amount of contaminants contained in the dust collector 220 in order to increase the dust collector.

A pair of pressure members 310 and 320 cooperate with each other to compact the contaminants and reduce their volume, so that the density of the contaminants contained in the dust collector 220 can be increased, thereby increasing the maximum dust collector in the dust collector 220.

Hereinafter, a pair of pressing elements 310 and 320 will be called the first pressing element 310 and the second pressing element 320, respectively, for the sake of simplification of the description.

In the present embodiment, at least one of the pair of pressure members 310 and 320 is provided to move in the dust container 220 to seal contaminants stored between the pair of pressure members 310 and 320.

In other words, when the first and second clamping elements 310 and 320 are rotatably provided in the dust container 220, the first and second clamping elements 310 and 320 rotate towards each other, so that the space between one side of the first clamping element 310 and one side of the second the pressure member 320 facing one side of the first pressure member 310 becomes narrower, thereby sealing the contaminants stored between the first and second pressure members 310 and 320.

However, in the present embodiment, the first pressing member 310 is rotatably mounted in the dust collecting container 220, and the second pressing member 320 is fixed in the dust collecting container 220.

That is, the first pressing member 310 serves as a rotating member, and the second pressing member 320 serves as a fixed member.

Part 221 for storing contaminants is provided in the dust collecting container 220 to form a space for storing contaminants. Part 221 for storing contaminants is made to surround the trajectory described by the free end 311 of the first clamping element 310 when it rotates in part 221 for storing pollutants.

A second clamping member 320 may be installed between the inner peripheral surface of the particulate storage portion 221 and a rotary shaft 312 serving as a center of rotation of the first clamping member 310.

In other words, the second pressing member 320 is located on a plane connecting the rotational shaft 312 to the inner peripheral surface of the portion 221 for storing contaminants. In this case, the second clamping element 320 completely or partially covers the space formed between the inner peripheral surface of the part 221 for storing contaminants and the axis of the rotary shaft 312, for sealing the contaminants together with the first clamping element 310 when pressing the polluting particles with the first clamping element 310.

To this end, the end 321 of the second clamping element 320 can be made integral with the inner peripheral surface of the part 221 for storing contaminants, and the other end can be made integral with the stationary shaft 322, located on the same axis with the rotational shaft 312 of the first clamping element 310.

Only the end 321 of the second clamping element 320 can be integral with the inner peripheral surface of the part 221 for storing contaminants, or only the other end of the second clamping element 320 can be integral with the stationary shaft 322. In other words, the second clamping element 320 is fixed at least on the inner peripheral surface of the part 221 for storing contaminants, or on a fixed shaft 322.

However, even if the end 321 of the second pressing member 320 is not integrally formed with the inner peripheral surface of the particulate storage part 221, the end 321 of the second pressing member 320 may be located adjacent to the inner peripheral surface of the particulate storage part 221.

In addition, even if the other end of the second clamping member 320 is not integrally formed with the fixed shaft 322, the other end of the second clamping member 320 may be located adjacent to the fixed shaft 322.

The reason for the above is to minimize the amount of contaminants that are pressed by the first pressure member 310 to pass through gaps formed on the side of the second pressure member 320.

The first and second clamping elements 310 and 320 with this design can be made in the form of a rectangular plate. In addition, the rotational shaft 312 of the first pressing member 310 can be mounted on the same axis as the center of the part 221 for storing contaminants.

The fixed shaft 322 may protrude inward from one end of the part 221 for storing contaminants. A cavity is formed to mount the rotational shaft 312 in the stationary shaft 322 in the axial direction. A predetermined portion of the rotary shaft 312 is inserted into the cavity from the upper side of the fixed shaft 322.

In addition, the vacuum cleaner in accordance with the present invention comprises a drive device 400 selectively connected to a rotational shaft 312 of the first pressing member 310 to rotate the first pressing member 310.

Below, with reference to FIGS. 4 and 5, the relationship between the dust collecting device 200 and the driving device 400 will be described.

The drive device 400 includes a drive motor 430 for generating a driving force and a driving mechanism 410 and 420, which transmits the driving force of the drive motor 430 to the first pressing member 310.

In detail: the driving mechanisms 410 and 420 include a drive gear connected to the rotational shaft 312 of the first pressure member 310, and a drive gear transmitting the driving force to the driven gear 410.

The drive gear is connected to the rotational shaft of the drive motor 430 and rotated by the drive motor 430.

Therefore, when the drive motor 430 is rotated, the drive gear 420 connected to the drive motor 430 rotates, and the rotation force of the drive motor 430 is transmitted to the driven gear 410 through the drive gear 420, thereby rotating the driven gear 410 that rotates the first pressure member 310.

The drive motor 430 is located under the receiver portion 130 for the dust collector, and the drive gear 420 is connected to the rotational shaft of the drive motor 430 and is located on the lower surface of the receiver portion 130 for the dust collector.

The outer peripheral surface of the drive gear 420 is partially open outwardly at the bottom of the receiving portion 130 for the dust collector. To this end, a receiving part (not shown) for an electric motor for mounting a driving motor 430 may be formed under the lower part of the receiving part 130 for the dust collecting device. A hole 131 is formed approximately in the center of the lower part of the receiving part 130 for the dust collecting device for partially opening the outer peripheral surface of the lead gear wheel 420.

Meanwhile, the rotational shaft 312 of the first clamping member 310 is inserted into the cavity of the stationary shaft 322 from the top of the stationary shaft 322, and the driven gear 410 is inserted into the cavity of the stationary shaft 322 from the lower end of the dust collecting container 220 and connected to the rotational shaft 312.

In addition, a part 312c with different widths is formed on the rotary shaft 312 and supported by the upper end of the fixed shaft 322. A part 312c with different widths divides the rotary shaft 312 into an upper shaft 312a connected to the first pressure member 310 and a lower shaft 312b connected to the follower gear wheel 410.

The lower shaft 312b includes a recess 312d for mounting the pinion shaft of the driven gear 410, so that the lower shaft 312b is connected to the driven gear 410.

The recess 312d may have various shapes, such as a circular shape and a rectangular shape, and the gear shaft of the driven gear 410 is configured to engage with the recess 312d.

Therefore, when the driven gear 410 is connected to the rotational shaft 312, the driven gear 410 opens to the outside of the dust collecting container 220.

Since the driven gear 410 opens to the outside of the dust collecting container 220 when the dust collecting device 200 is installed in the receiving part 130 for the dust collecting device, the driven gear 410 is engaged with the driving gear 420.

The drive motor 430 may be an electric motor that provides operation in the forward and reverse directions. In other words, the driving motor 430 is an electric motor that rotates in one of two directions.

The drive motor 430 can rotate in both forward and reverse directions. In other words, the drive motor 430 may be an electric motor capable of rotating in two directions.

Therefore, as shown in FIGS. 6 and 7, the first clamping member 310 can rotate in the forward / reverse direction, and thus, compacted contaminants accumulate on both sides of the second clamping member 320.

To ensure rotation of the drive motor 430 in two directions, a synchronous motor can be used as the drive motor 430.

The synchronous motor is designed to rotate in the forward / reverse directions by itself. When a force greater than the set value is applied to the synchronous motor while rotating in one direction, the synchronous motor rotates in the opposite direction.

The force exerted on the synchronous electric motor is the torque that is generated when the contaminants are compressed by the first pressing member 310. The synchronous electric motor is designed to rotate in the opposite direction when the torque reaches the set value.

Since a synchronous motor is well known to those skilled in the art, a detailed description thereof will be omitted. It is worth noting, however, that the drive motor 430 rotates in the forward / reverse direction by means of a synchronous motor.

Even if the first pressing member 310 condenses the contaminants and reaches the limit position when it can no longer rotate, the first pressing member 310 can continuously compact the contaminants for a predetermined time.

The limit position when the first clamping member 310 can no longer rotate means that the torque has reached the set value.

When the torque reaches the set value, the driving force that rotates the first clamping member 310, i.e., the power applied to the drive motor 430, is interrupted for a predetermined time, keeping the contaminants compacted in a state in which the first clamping member 310 does not rotate. After a predetermined time, power is supplied to the drive motor 430, so that the first clamping member 310 can rotate.

The moment of shutdown of the power supplied to the drive motor 430 is the time when the torque reaches the set value. Therefore, when the drive motor 430 is again driven, the direction of rotation of the drive motor 430 will be opposite to the direction of rotation before turning off the power.

The drive motor 430 can rotate the first clamping member 310 in the forward / reverse directions at a constant angular velocity for easier compaction of contaminants.

When an amount of contaminant particles in excess of a predetermined amount is collected in the dust collecting container 220, the user can be informed about the time to empty the dust collecting container 220 to prevent a decrease in the suction capacity and overload of the drive motor.

For this reason, a display device (not shown) is provided on the main body 100, the dust collector 200, or on a handle (not shown). When contaminants in excess of a predetermined amount are collected in the dust collecting container 220, and thus the rotation angle of the first pressing member becomes lower than the predetermined angle, the display device can inform the user about the time to empty the dust collecting container 220.

6 and 7 are top views illustrating the process of compacting contaminant particles in a dust collector.

Below, with reference to Fig.6 and 7, will be described the process of compaction of pollutants collected in the dust container 220.

When the user performs a cleaning operation using a vacuum cleaner, the contaminants separated in the cyclone device 211 are stored in the part 221 for storing the contaminants. A pair of pressure members 310 and 320 compress the contaminants stored in the contaminant storage portion 221.

In more detail, when the drive motor 430 rotates in one direction, the rotational force of the drive motor 430 is transmitted to the driven gear 410 through the drive gear 420. Therefore, the driven gear 410 rotates, thereby rotating the rotary shaft 312 and the first pressure member 310.

Since the drive gear 420 is engaged with the driven gear 410, when the drive motor 430 rotates in one direction, the drive gear 420 rotates in the same direction as the direction of rotation of the drive motor 430, and the driven gear 410 rotates in the opposite direction relative to directions of rotation of the drive motor 430.

That is, the rotation direction of the driven gear 410 and the rotational shaft 312 is opposite to the rotation direction of the drive motor 430.

When the first pressure member rotates in the other direction (counterclockwise direction), the first pressure member 310 presses the contaminants collected between the first and second pressure members 310 and 320 towards one side of the second pressure member 320, thereby sealing the dirt particles. The first clamping member 310 rotates continuously until the torque created during compaction of the contaminants reaches a predetermined value.

When the torque reaches the set value, the power supplied to the drive motor is turned off, stopping the first pressure member 310 in the position in which the contaminants are compacted. After a predetermined time, the drive motor 430 is again driven by rotating the first clamping member 310.

Since the first clamping member 310 stops in a position in which the torque reaches the set value, its rotation direction changes to the clockwise direction, as shown in Fig.7.

When the first clamping member 310 rotates in a clockwise direction, the first clamping member 310 presses the contaminants collected between the first and second clamping members 310 and 320 towards the other side of the second clamping member 320, thereby sealing the contaminants.

The compaction operation is performed repeatedly until the rotation angle of the first pressing member 310 is less than a predetermined angle.

Fig. 8 is a view of the dust separating device and the dust collecting container disconnected from the dust collecting device, and Fig. 9 is a bottom perspective view of the dust collecting device in Fig. 8.

As shown in FIGS. 8 and 9, the dust separator 210 is connected to the upper side of the dust collector 220. The contaminants separated in the dust separator 210 are moved down and stored in the dust collector 220.

In detail, an intake port 211a for sucking in air containing contaminants is formed tangentially to the dust separation device 210 on the upper outer peripheral surface of the dust separation device 210. A cover 211d is provided with a possibility of removal in the upper part of the dust separation device 210.

An outlet 211b is formed in the central portion of the cap 211d. The purified air that is separated in the dust separation device 210 (i.e., the cyclone device 211) is discharged through the outlet 211b.

The cavity-shaped filter element 211c is connected to the outlet 211b. The outer peripheral surface of the filter element 211c contains a plurality of through holes formed therein to release air that has undergone a process of separating contaminants in the cyclone device 211.

The separation plate 230 is mounted horizontally in the lower part of the dust separation device 210. The separation plate 230 separates the dust separation device 210 and the dust collecting container 220 from each other.

In addition, the separation plate 230 prevents the entry of contaminants stored in the dust collecting container 220 into the dust collecting device 210 when the dust collecting device 210 is connected to the dust collecting container 220.

The separation plate 230 comprises an opening 231 for discharging contaminants. Contaminant particles separated in the cyclone device 211 pass into the dust collecting container 220 through an opening 231 for discharging the contaminant particles.

The hole 231 for the release of contaminants can be located on the side opposite the second clamping element 320. The basis for the above is that the number of contaminants sealed on each side of the second clamping element 320 is maximized in order to minimize the spread of pollutants during the storage process particles in the dust container 220 while maximizing the dust volume of the portion 221 for storing the particles and providing easy passage Nia dust separated in the dust separating apparatus 210 in the dust collection container 220.

The dust separation device 210 and the dust collecting container 220 comprise an upper handle 212 and a lower handle 223, respectively, for connecting the dust separation device 210 and the dust collecting container 220 to each other.

In addition, the dust collecting device 200 includes a hook fastening means, so that the dust collecting container 220 is connected to the dust separation device 210 when the dust collecting device 220 is mounted on the dust separation device 210.

In detail, a hook slot 241 is provided on the outer lower peripheral surface of the dust separator 210, and a hook 242 is provided on the outer upper peripheral surface of the dust collecting container 220 and selectively engages with the hook slot 241.

Meanwhile, when the cyclone device 211 is called the main cyclone device, and the particle storage part 221 is called the main storage compartment, the present invention may further comprise at least one auxiliary cyclone device 140 provided in the main body 100 of the vacuum cleaner, and an auxiliary storage compartment 224 provided in the dust collector 200.

The auxiliary cyclone device 140 secondarily separates the contaminants from the air leaving the main cyclone device, and the auxiliary storage part 224 stores the contaminants separated by the auxiliary cyclone device 140.

An auxiliary storage part 224 is provided on the outer peripheral surface of the dust collector 200 with its open upper surface.

In the present embodiment, the auxiliary storage part 224 is provided on the outer peripheral surface of the dust collecting container 220, and the auxiliary particle inlet 213 communicating with the auxiliary storage part 224 is provided on the outer peripheral surface of the dust separator 210.

Auxiliary particle inlet openings 213a that are selectively coupled to an auxiliary particle discharge holes 141 of the auxiliary cyclone device 140 are formed on the outer wall of the auxiliary particle inlet 213, and the lower surface of the auxiliary particle inlet 213 is open for communication with the upper side of the auxiliary part 224 for storage.

Therefore, when the main cyclone device 211 is installed in the main body 100 of the vacuum cleaner, the auxiliary holes 213a for the intake of pollutant particles are connected to the holes 141 for the release of polluting particles of the auxiliary cyclone device 140.

Thus, the contaminants separated in the auxiliary cyclone device 140 pass through the auxiliary openings 213a for the intake of the polluting particles and are stored in the auxiliary storage part 224.

Below in accordance with the present invention will be described the operation of a vacuum cleaner of this design.

When power is applied to the vacuum cleaner, the suction generator generates a force to suck in air, and air containing contaminants is sucked into the suction brush using force.

Air that is sucked in through the suction brush passes into the inlet 221a of the main cyclone device 211 through the inlet 110 of the main body. Air that flows through the inlet 221a of the main cyclone device 211 is guided tangentially along the inner wall of the main cyclone device 211 in a spiral fashion, and thus the contaminants are separated from the air by the centrifugal force difference between the air and the pollutant particles and fall way down.

Thus, the contaminants contained in the air spiral in a spiral along the inner wall of the main cyclone device 211 and are lowered through the hole 231 to release the contaminants of the separation plate 230, and are stored in the main part 221 for storage.

The air, initially cleaned by the main cyclone device 211, passes through the outlet 211c and exits through the outlet 211b. Then the air passes into the auxiliary cyclone device 140.

Thus, the contaminants separated from the air using the cyclone principle in the auxiliary cyclone device 140 are stored in the auxiliary storage part 224, and the air cleaned in the auxiliary cyclone device 140 leaves the auxiliary cyclone device 140 and passes to the main body 100 and is discharged from the main body 100 through an outlet 120 of the main body.

Meanwhile, a larger amount of contaminants passed into the vacuum cleaner is stored in the main body 221 for storage during the cleaning operation. In addition, since the contaminants stored in the main storage part 221 are sealed with the first and second pressure members 310 and 320 to a minimum volume, a large amount of contaminants can be stored in the main storage part 221.

The operation of the first clamping member 310 and the interaction between the first and second clamping members 310 and 320 have already been described, and thus, a description thereof will be omitted.

When an amount of contaminants in excess of a predetermined amount is stored in the dust container 220 during the cleaning operation, a signal is generated in the display device and the signal can inform the user about the time to empty the dust container 220.

The user then disconnects the dust collector 200 from the main body 100 and empties the dust collector 220.

As shown in the drawings, in accordance with the present invention, a container-type vacuum cleaner has been described above as an example. However, the present invention is not limited to this and can be applied to a vertical type vacuum cleaner, a robot vacuum cleaner, or another type of vacuum cleaner.

In addition, a pair of clamping elements has been described above, but in the present embodiment, a plurality of clamping elements may be provided, or a plurality of rotating clamping elements may be provided.

In accordance with the present invention, the contaminants that are stored in the dust collector can be compacted and minimized in volume using a plurality of pressure elements, maximizing the dust collecting volume of the dust collector.

Since the dust collecting volume of the dust collecting device is maximized as a result of the sealing operation of the plurality of pressing elements, the user does not often need to empty the dust collecting device.

Since the contaminants collected in the dust collector are kept sealed, the compacted contaminants can be easily discharged from the dust collector when emptying the dust collector.

When an amount of contaminant particles in excess of a predetermined amount is collected in the dust collecting container, the display device informs the user of the time to empty the dust collecting device, so that the user can easily know the time to empty the dust collecting device.

Those skilled in the art will understand that various modifications and changes to the present invention are possible. Thus, it is intended that the present invention include such modifications and variations of this invention provided they come within the scope of the appended claims and their equivalents.

Claims (22)

1. A dust collecting device comprising: a dust separation device for separating airborne contaminants, a dust collecting container comprising a part for storing contaminants separated by a dust separation device, a fixed element fixed in a dust container, at least one clamping element mounted to move in a dust collecting container and interacting with a fixed element to reduce the amount of contaminant particles stored in the part for storing contaminant particles, and a drive device for driving the clamping element, while the clamping element has a rotational shaft, movably associated with the dust container, and the drive device is connected to the rotational shaft of the clamping element. 2. The dust collecting device according to claim 1, wherein the dust collecting device is detachably connected to the upper part of the dust collecting container. 3. The dust collecting device according to claim 2, wherein a separation plate is installed in the lower part of the dust separation device for separating the dust separation device and the part for storing the polluting particles. 4. The dust collecting device according to claim 1, in which the rotational shaft is located on the same axis as the center of the dust collecting container. 5. The dust collecting device according to claim 4, wherein the fixed shaft is formed in the dust collecting container, and the rotational shaft is connected to the fixed shaft. 6. The dust collecting device according to claim 4, in which the clamping element is made to rotate in two directions to seal contaminants on both sides of the fixed element. 7. The dust collecting device according to claim 6, in which the clamping element is rotated using a drive device connected to a rotational shaft. 8. The dust collecting device according to claim 7, in which the drive device comprises: electric drive motor; driven gear connected to the rotational shaft of the pressing member; and a drive gear selectively connected to a rotational shaft of a drive motor for transmitting a driving force to the driven gear. 9. The dust collecting device of claim 8, wherein the driven gear is connected to the rotational shaft of the pressure member on the outside of the dust collecting container. 10. The dust collecting device according to claim 1, wherein the fixed element is permanently attached either to the inner peripheral surface of the dust collecting container or to a fixed shaft mounted on the same axis as the rotational shaft of the pressing member. 11. A vacuum cleaner containing: a main body including an air suction device for generating a suction force for air, a dust separation device for separating pollutants contained in the air, detachably connected to the main body, a dust collecting container comprising a part for storing contaminants separated by a dust separation device, a first clamping member located inside the dust collecting container to reduce the amount of contaminants stored in the dust collecting container, and a drive motor for driving the first clamping element. 12. The vacuum cleaner according to claim 11, additionally containing a second clamping element, made in one piece with the dust collecting capacity. 13. The vacuum cleaner according to item 12, in which the first clamping element rotates together with a rotational shaft mounted on the same axis in the center of the dust container. 14. The vacuum cleaner according to claim 12, wherein the drive device comprises a drive motor, a driven gear connected to the first pressure member on the outside of the dust collecting container, and a drive gear connected to the drive motor to transmit rotation power of the drive motor to the driven gear. 15. A vacuum cleaner containing: a main body including an air suction device for generating a suction force for air, a dust collecting device detachably connected to the main body and comprising a dust separating device for separating the pollutants contained in the air, and a dust collecting container comprising a part for storing the polluting particles for storing the polluting particles separated by the dust separating device, and a first pressure member installed in the dust collecting container to reduce the amount of contaminants in the dust collecting container, and a drive device for driving a first pressure member having a drive motor, wherein the first clamping element is connected to the drive motor by installing a dust collecting device on the main body. 16. The vacuum cleaner according to claim 15, further comprising a second clamping member fixed in the dust collecting container, wherein the first clamping member cooperates with the second clamping member to reduce the amount of contaminant particles. 17. The vacuum cleaner according to clause 15, in which the fixed shaft is made in a dust container, and the rotational shaft is connected to the fixed shaft. 18. The vacuum cleaner according to claim 17, in which the second clamping element is permanently attached either to the inner peripheral surface of the dust collecting container or to a fixed shaft mounted on the same axis as the rotational shaft of the clamping element. 19. The vacuum cleaner according to clause 15, in which the drive motor is provided in the main body, and the drive device further comprises: driven gear connected to the rotational shaft of the second clamping element; and a drive gear connected to a rotational shaft of a drive motor for transmitting a driving force to the driven gear. 20. The vacuum cleaner according to claim 19, in which the driven gear is connected to the rotational shaft of the drive motor from the outside of the dust collecting container and the drive gear is connected to the drive motor and open to the outside of the main body. 21. The vacuum cleaner according to clause 15, in which the part for storing pollutant particles contains a first part for storing pollutant particles for storing pollutant particles separated in the dust separation device, and a second part for storing pollutant particles for storing pollutant particles separated in the auxiliary dust separation device, installed in the main body. 22. The vacuum cleaner according to item 21, in which the clamping elements are installed in the first part for storing contaminant particles.

Images