RU2375951C2 - Vacuum cleaner (versions) - Google Patents

Abstract

FIELD: personal demand items.

SUBSTANCE: inventions are related to vacuum cleaner. Vacuum cleaner comprises body, where mount part of dust collection device is arranged, with the possibility to be fixed and disconnected from mount part of dust collection device and inside it has compartment for accumulation of contaminating particles. In vacuum cleaner there is at least one pressing element arranged, which lowers volume of contaminating particles accumulated in compartment for accumulation of contaminating particles, and arranged with the possibility of displacement in compartment for accumulation of contaminating particles. Device for power transfer is connected to pressing element, to transfer motive force to press element from external side and comprising slave gear connected with press element. Horizontal section of slave gear axis has the shape that differs from round shape. Vacuum cleaner has control device, which identifies number of contaminating particles accumulated in compartment for accumulation of contaminating particles. In version of design vacuum cleaner comprises dust collection device selectively installed in its body, at least one press element, which reduces volume of contaminating particles accumulated inside and is arranged inside dust collection device. Press element is put in motion by driving device, which is connected to press element in compliance with installation of dust collection device, drive gear of which is connected to press element. On dust collection device there is the first guide element, which guides dust collection device in process of installation, and on vacuum cleaner body there is the second guide element, which interacts with the first guide element. When installed in vacuum cleaner body, slave gear is inserted into location slot. In another version of design vacuum cleaner comprises dust separation device, which separates contaminating particles from air sucked into vacuum cleaner body, dust collection device connected to vacuum cleaner with the possibility of detachment and having compartment for accumulation of contaminating particles, at least one pressing element that reduces volume of contaminating particles, accumulated in compartment for accumulation of contaminating particles, and interacting with fixed element. Pressing element is installed in compartment for accumulation of contaminating particles with the possibility of displacement. Vacuum cleaner has at least one gear arranged with the possibility of driving force transfer to pressing element. At least one gear contains multiple teeth, having at least one rounded side surface.

EFFECT: increased dust collection volume of dust collection device due to compaction of contaminating particles accumulated in it.

28 cl, 21 dwg

Description

The present invention relates to a vacuum cleaner and, more particularly, to a vacuum cleaner in which a dust collecting volume of a dust collecting device is maximized.

Typically, a vacuum cleaner is a device that filters contaminants in a device case after suctioning air containing pollutants by using a vacuum created by a suction motor installed in the case.

A conventional vacuum cleaner comprises a suction brush for sucking in air containing contaminants, a vacuum cleaner body connected to the suction brush, a sliding tube, a guide air drawn in through the suction brush to the vacuum cleaner body, and a connecting pipe for directing air passing through the sliding tube into the body vacuum cleaner.

A suction opening of a brush of a predetermined size is formed in the lower part of the suction brush for drawing air containing contaminants from the floor.

On the other hand, a drive device generating a suction force is installed in the housing of the vacuum cleaner for suctioning outside air containing contaminants through the suction brush.

In addition, a dust collector for separating and storing air is separately provided in the cleaner body. The dust collecting device performs the function of separating and storing contaminants contained in the air drawn in through the suction brush.

In more detail, the dust collecting device comprises a dust collecting body, an inlet for sucking air into the dust collecting body, a cyclone device for separating the contaminants from the air sucked into the dust collecting body, a compartment for accumulating polluting particles separated in the cyclone device, and an air outlet for discharging air, separated from the contaminants in the cyclone device, out.

On the other hand, contaminants accumulated in the lower space of the dust collecting case, i.e. compartments for the accumulation of polluting particles, continuously rotate along the inner peripheral surface of the dust collecting case under the action of the circulation flow in the dust collecting case during operation of the vacuum cleaner.

In addition, contaminants accumulate with low density and settle to the bottom of the dust collecting case when the vacuum cleaner is turned off.

Therefore, the contaminants in the prior art dust collector pass into a cyclone formed in the upper space of the dust collector when rotating and lifting upward along the inner surface of the dust collector when contaminants of a predetermined amount accumulate in the dust collector during operation of the vacuum cleaner and, in ultimately, the collection efficiency of pollutants is reduced, since pollutants that have not separated from the air pass through you air outlet inlet.

In addition, contaminants accumulate in the lower part of the low-density dust collecting case when the vacuum cleaner is turned off. Therefore, a conventional vacuum cleaner is inconvenient in that the user has to empty the dust collecting case in order to maintain the efficiency of collecting the dust particles, since the dust particles occupy too much space due to their weight in the dust collecting case.

Therefore, developers have recently improved the usability of a vacuum cleaner to increase the efficiency of collecting pollutants, as well as maximize the amount of pollutants collected in a dust collecting case.

The present invention addresses these drawbacks, and an object of the present invention is to provide a vacuum cleaner with an increased dust collecting volume of a dust collecting device.

An additional objective of the present invention is to provide a vacuum cleaner with an increased dust collecting volume, in which pollutants accumulated automatically in the dust collecting device are compacted.

Another objective of the present invention is the creation of a vacuum cleaner in which it is easy to install the housing of the dust collecting device.

A vacuum cleaner in accordance with the present invention comprises a vacuum cleaner body in which an installation portion of a dust collecting device is formed; a dust collecting device configured to be removed from the installation part of the dust collecting device and comprising a compartment inside for accumulating contaminant particles; at least one pressing element that reduces the amount of pollutant particles accumulated in the compartment for accumulating pollutant particles, arranged to move in the compartment for accumulating pollutant particles; a device for transmitting force for transmitting a driving force to the clamping element from the outside, connected to the clamping element; and a control device for determining an accumulated amount of pollutant particles in a compartment for accumulating pollutant particles.

A vacuum cleaner in accordance with another aspect of the present invention comprises a vacuum cleaner body; a dust collecting device, optionally installed in the cleaner body; at least one clamping element that reduces the amount of contaminant particles accumulated in the dust collector, rotatably disposed in the dust collector; a drive device driving the clamping element and connected to the clamping element optionally in accordance with the installation of the dust collecting device; a first guide member guiding the dust collector during installation located on the dust collector; and a second guide member cooperating with the first guide member located on the cleaner body.

A vacuum cleaner in accordance with another aspect of the present invention comprises a vacuum cleaner body; a dust separation device for separating polluting particles from air passing into the vacuum cleaner body; a dust collecting case including a compartment for accumulating polluting particles; a fixed element fixed in the compartment for the accumulation of polluting particles; and at least one pressure member that reduces the amount of contaminants accumulated in the contaminant storage compartment by interacting with a fixed element disposed to move in the contaminant storage compartment; and a drive device driving the pressure member. In addition, an outlet for discharging the separated contaminants from the dust separation device to the dust accumulation compartment is formed on the lower side of the dust separation device, and the fixed member is located at a location adjacent to the exhaust opening.

In accordance with the present invention, the vacuum cleaner has an advantageous effect in that the dust collecting volume for the dust particles accumulated in the dust collecting device is maximized since the volume of the dust particles is minimized since the dust particles accumulated in the dust collecting device are compacted by a plurality of pressure members.

In addition, the vacuum cleaner of the present invention has an advantageous effect in that the inconvenience that the user often has to discharge the contaminants accumulated in the dust collecting device is eliminated since the dust collecting volume of the dust collecting device is maximized due to the sealing action of the plurality of pressure members.

In addition, the vacuum cleaner of the present invention has an advantageous effect in that the contaminants accumulated in the dust collector are easily discharged to the outside of the dust collector when unloading the contaminants, since the pollutants accumulated in the dust collector are held, sealed even after the vacuum cleaner is turned off.

In addition, the vacuum cleaner of the present invention has an advantageous effect in that the user can easily know the time for unloading the pollutants, since the time for unloading the pollutants from the dust collector is displayed when an amount larger than a predetermined amount of pollutants is collected in the dust collector.

In addition, the vacuum cleaner of the present invention has an advantageous effect that the vibration of the dust collecting device is prevented during operation of the vacuum cleaner when the dust collecting device is installed, and the user can easily install the dust collecting device equipped with the device for guiding the dust collecting device during installation.

In addition, the vacuum cleaner of the present invention has the advantage of increasing the reliability of collecting contaminants, since the driven gear does not idle, but rotates with the first clamping element, since the shape of the inner peripheral surface of the rotating shaft formed on the first clamping element is horizontal sections of the outer peripheral surface of the pinion gear rotating the first pressure member are not round.

In addition, the vacuum cleaner of the present invention has the advantage that the installation convenience for the user is enhanced since each gear is easily connected when installing the dust collector, improving the configuration of the plurality of gears transmitting force to the first pressing member.

Brief Description of the Drawings

The drawings are provided below to provide a further understanding of the present invention:

figure 1 depicts a perspective view of a vacuum cleaner in accordance with a preferred embodiment of the present invention;

2 is a perspective view illustrating a state in which a dust collecting device is disconnected from a vacuum cleaner;

figure 3 depicts a perspective view of a dust collecting device in accordance with a preferred embodiment of the present invention;

Fig. 4 is a cross-sectional view taken along line I-I 'in Fig. 3;

5 is a perspective view of a first pressing member in accordance with the present invention;

6 is a perspective view of the bottom of a dust collecting device in accordance with a preferred embodiment of the present invention;

Fig.7 depicts a cross-sectional view along the line II-II 'in Fig.4;

Fig. 8 is a perspective view of a mounting portion of a dust collecting device in accordance with a preferred embodiment of the present invention;

Fig.9 depicts a perspective view of the lower part of the driven gear in accordance with the present invention;

10 is a view illustrating a relationship between locations of a driven gear and a microswitch;

11 is a block diagram illustrating a control device of a vacuum cleaner in accordance with the present invention;

12 and 13 are views illustrating a state in which the microswitch is turned on when the first pressing member is adjacent to the side of the second pressing member to seal contaminants;

14 and 15 are views illustrating a state in which the micro switch is turned off when the first pressure member and the second pressure member are in a straight line;

FIGS. 16 and 17 are views illustrating a state in which the micro switch is turned on when the first pressure member is adjacent to the other side of the second pressure member;

Fig. 18 is a view illustrating the entire rotation operation of the first pressing member illustrated in Figs. 12-17;

Fig. 19 is a flowchart illustrating a method of controlling a vacuum cleaner in accordance with the present invention;

Fig.20 depicts a perspective view of the lower part of the dust collecting device in accordance with the second embodiment of the present invention;

Fig.21 depicts a perspective view of the installation part of the dust collecting device in accordance with the second embodiment of the present invention.

Detailed description of the present invention

Below, reference will be made in detail to embodiments of the present invention with reference to the accompanying drawings.

FIG. 1 is a perspective view of a vacuum cleaner in accordance with a preferred embodiment of the present invention, FIG. 2 is a perspective view illustrating a state in which the dust collector is disconnected from the vacuum cleaner, and FIG. 3 is a perspective view of a dust collector in accordance with a preferred embodiment of the present inventions.

As shown in FIGS. 1-3, a vacuum cleaner 10 in accordance with the present invention comprises a vacuum cleaner body 100 including a suction motor (not shown) that generates suction power inside, and a dust separator separating contaminants contained in the air sucked into the body 100 vacuum cleaner.

In addition, although not illustrated, a suction brush is provided through which air containing contaminants is sucked, and a connecting pipe connecting the suction brush to the vacuum cleaner body 100.

A detailed description of the main configuration of the suction brush and connecting tube of the present embodiment is omitted, since it is similar to the description of the main configuration of the suction brush and connecting tube of the prior art.

In detail, an inlet 110 of a vacuum cleaner body for sucking in air containing pollutants sucked through the suction brush is formed at a lower end of a front part of the vacuum cleaner body 100, and an exhaust device of a vacuum cleaner body, which is not illustrated, for discharging air separated from the polluting particles is formed on the side of the housing 100 of the vacuum cleaner.

A handle 140 is formed on the upper part of the vacuum cleaner body 100 to be gripped by users.

In addition, the guide cover 160 is connected to the rear side of the vacuum cleaner body 100 to direct air separated from contaminants in the dust separator to the vacuum cleaner body 100.

The dust separating device includes a dust collecting device 200 containing a first cyclone device (it will be described below) for primary separation of pollutants contained in the air drawn inwardly, and a second cyclone device 300, secondly separating the polluting particles from air primarily separated from the polluting particles in the first cyclone device, and located on the housing 100 of the vacuum cleaner.

In more detail, the dust collecting case 200 is selectively mounted in a mounting part 170 of the dust collecting device formed in front of the vacuum cleaner body 100.

The release lever 142 is located on the handle 140 of the vacuum cleaner body for attaching and detaching the dust collecting device 200 to and from the vacuum cleaner body 100, and the engagement end 279 engaged with the release lever 142 is formed in the dust collecting device 200.

In addition, the dust collecting device 200 comprises a first cyclone device generating cyclone movement and a dust collecting case 210 including a compartment for storing contaminant particles, in which pollutants separated in the first cyclone device are accumulated.

The dust collector 200 is mounted so that it can be attached to and disconnected from the cleaner body 100 as described above, and the dust collector 200 is connected to the cleaner body 100 and the second cyclone device 300 when the dust collector is installed in the cleaner body 100.

In detail, an air outlet 130 for discharging air drawn into the vacuum cleaner body 100 to the dust collecting device 200 is formed in the vacuum cleaner body 100, and a first air intake opening 218 for sucking air from the air outlet 130 is formed in the dust collecting device 200.

It is necessary that the first air inlet 218 is formed in the connection direction of the dust collector 200 to generate cyclone movement in the dust collector 200.

In addition, a first air outlet 252 for discharging air separated from contaminants in the first cyclone device is formed in the dust collecting device 200, and a connecting passage 114 for sucking air exiting through the first air outlet 252 is formed on the cleaner body 100.

In addition, air drawn into the connecting channel 114 is drawn into the second cyclone device 300.

The second cyclone device 300 comprises a plurality of cone-shaped cyclones. In addition, the second cyclone device 300 is located on the upper side of the rear of the cleaner body 100. That is, the second cyclone device 300 is inclined at a predetermined angle to the cleaner body 100.

As described above, the space efficiency is improved due to the design of the vacuum cleaner, which requires miniaturization of the suction motor, etc., when the second cyclone device 300 is located on the housing 100 of the vacuum cleaner.

In addition, the configuration of the dust collector 200 is simplified, and users may need less effort to handle the dust collector 200, since the weight of the dust collector 200 becomes lighter since the second cyclone device 300 is separated from the dust collector 200 and located on the cleaner body 100.

Pollutants separated in the second cyclone device 300 are accumulated in the dust collector 200. For this, an inlet 254 for the intake of pollutants for sucking the pollutants separated in the second cyclone device 300, and a compartment for accumulating pollutants for accumulating pollutants separated in the second the cyclone device 300 is further formed in the dust collector 210.

That is, the debris storage compartment formed in the dust collecting case 210 is comprised of a first debris storage compartment for accumulating debris separated in the first cyclone device and a second debris storage compartment for accumulating debris to separate the debris separated in the second cyclone device 300.

That is, the second cyclone device 300 is formed in the vacuum cleaner body 100 separated from the dust collector 200, but contaminants separated in the second cyclone device 300 are accumulated in the dust collector 200 in the present embodiment.

It is necessary that the second cyclone device 300 is positioned at an angle to the dust collector, so that the separated contaminants can easily move into the dust collector 200.

In addition, it is necessary that the dust collecting device 200 be formed in such a way as to maximize the dust collecting volume for the contaminants accumulated inside. For this, it is necessary that means that reduce the amount of contaminant particles accumulated in the dust collecting case 210 are added to the dust collecting device 200.

A reference will be made in detail to a vacuum cleaner comprising a dust collecting device in which the dust collecting volume is maximized.

Figure 4 depicts a cross-sectional view along the line I-I 'in figure 3.

As shown in FIGS. 4 and 5, the dust collecting device 200 in accordance with the present invention comprises a dust collecting housing 210 defining an appearance, a first cyclone device 230 selectively disposed in the dust collecting housing 210 and separating contaminants from the intake air, and a cover 250 for selective opening and closing the upper part of the dust collecting case 210.

In detail, the dust collecting case 210 is formed in an almost circular shape and comprises a compartment for storing contaminant particles for storing separated contaminant particles inside.

The pollutant storage compartment comprises a first pollutant storage compartment 214 for accumulating pollutant particles separated in the first cyclone device 230, and a second pollutant storage compartment 216 for accumulating pollutant particles separated in the second cyclone device 300.

The dust collecting case 210 comprises a first wall 211 forming a first compartment 214 for storing particulate matter and a second wall 212 forming a second compartment 216 for storing particulate matter connected to the first wall 211. That is, the second wall 212 covers a predetermined portion of the outside of the first wall 211.

Therefore, a second pollutant storage compartment 216 is formed on the outside of the first pollutant storage compartment 214.

The dust collection volume of the first pollutant storage compartment 214 is maximized because the size of the first pollutant storage compartment 214 is maximized by the location of the second pollutant storage compartment 216 on the outside of the first pollutant storage compartment 214.

The bent portion 219 supporting the lower end of the first cyclone device 230 located on the first wall 211 is formed on the first wall 211 in a circumferential direction. Therefore, the upper part of the first compartment 214 for accumulating contaminant particles has a diameter larger than the diameter of the lower part on the final protrusion 219 as a standard.

The upper part of the dust collecting case 210 is open so that users can discharge contaminants when the dust collecting case 210 is turned over, and the lid 250 is connected to the upper part of the dust collecting case 210.

In addition, the first cyclone device 230 is connected on the underside of the lid 250 to disconnect with the lid 250 when unloading contaminants accumulated in the dust collecting case 210.

The present embodiment is configured such that the first cyclone device 230 is connected to the cover 250, but it is possible that the first cyclone device 230 and the cover 250 are integrally formed.

A channel 232 for guiding the pollutant particles, guiding the pollutant particles separated from the air to pass to the first compartment 214 for accumulating pollutant particles, is formed in the first cyclone device 230.

A channel 232 for guiding the pollutants directs the separated pollutants to move downward after passing tangentially.

Therefore, an inlet 233 of the channel 232 for directing contaminant particles is formed on the side surface of the first cyclone device 230, and an outlet 234 is formed in the lower part of the first cyclone device 230.

The cover 250 is connected to the upper side of the dust collecting case 210, as described above. That is, the lid 250 opens and closes the first compartment 214 for accumulating contaminants and the second compartment 216 for accumulating contaminants at the same time.

Therefore, the upper part of the dust collecting case 210 is opened by the cavity when the user disconnects the cover 250 connected to the first cyclone device 230 from the dust collecting case 210 for discharging the pollutants accumulated in the first compartment 214 for accumulating the polluting particles and the second compartment 216 for collecting the polluting particles out . In addition, when the user flips the dust collecting case 210, the contaminants are easily discharged.

This prevents re-contamination of the cleaned interior of the room, as the user disconnects the lid 250 from the dust collecting case 210 from the outside or above the dustbin to empty the dust collecting case 210.

In addition, the outlet 251 for discharging air separated from the contaminants in the first cyclone device 230 passes through the lower part of the cover 250. In addition, the outlet 251 is connected to the upper part of the filter element 260 containing a plurality of openings 262 of a predetermined size on the outer peripheral surface.

Therefore, the air that underwent the primary process of separating the contaminants in the first cyclone device 230 moves to the outlet 251 after passing through the filter element 260.

In addition, a channel 253 is formed in the lid 250 for directing air in the first cyclone device 230 exiting the outlet 251 to pass to the first air outlet 252. That is, the channel 253 is a channel connecting the outlet 251 to the first air outlet 252.

Meanwhile, a pair of pressure members 270 and 280 are located in the dust collecting case 210 to increase the dust collecting volume while decreasing the amount of contaminants accumulated in the first contaminant storage compartment 214.

A pair of pressure members 270 and 280 reduces the amount of contaminants as a result of interaction with each other, and therefore increases the maximum dust collection volume of the dust collecting case 210 while increasing the density of the polluting particles accumulated in the dust collecting case 210.

One of the pair of pressing elements 270 and 280 is called the first pressing element 270, and the other is called the second pressing element 280 hereinafter for convenience of description.

In the present embodiment, at least one of the pressing elements 270 and 280 seals the contaminants and is disposed to move in the dust collecting case 210.

When the first clamping member 270 and the second clamping member 280 are adapted to rotate in the dust collecting case 210, the first clamping member 270 and the second clamping member 280 rotate towards each other. In addition, the distance between the side of the first pressure member 270 and the side of the second pressure member 280 corresponding to the side of the first pressure member 270 becomes minimal when the pressure elements 270 and 280 are rotated towards each other, and therefore, contaminants located between the first pressure element 270 and the second clamping element 280 are sealed.

Only in the present embodiment, the first clamping member 270 is mounted in the dust collecting case 210, and the second clamping member 280 is fixed in the dust collecting housing 210.

Therefore, the first pressing member 270 becomes a rotating member, and the second pressing member 280 becomes a fixed member.

In detail, it is necessary that the second clamping member 280 is mounted between the rotating shaft 272 and the axis, the center of rotation of the inner peripheral surface of the dust collecting case 210 and the first clamping member 270.

That is, the second pressing member 280 is located on a surface connecting the axis of the rotating shaft 272 and the inner peripheral surface of the first compartment 214 for accumulating contaminants. In this case, the second clamping element 280 seals the contaminants with the first clamping element 270 when closing the entire space or part of the space between the inner peripheral surface of the first compartment 214 for the accumulation of contaminants and the axis of the rotating shaft, when the contaminants come close to the second clamping element 280, pushed by the first clamping element 270.

For this, it is necessary that the end of the second clamping element 280 be formed as a whole on the inner peripheral surface of the dust collecting case 210, and that the other end is formed on the rotary shaft 272 of the first clamping element 270 and the stationary shaft 282 located on the rotary shaft 272 as a whole .

In addition, it is possible that only one end of the second clamping member 280 is integrally formed with the inner peripheral surface of the dust collecting housing 210, or that the other end is integrally formed with the stationary shaft 282. That is, the second clamping member 280 is at least least fixed element between the inner peripheral surface of the dust collecting housing 210 and the stationary shaft 282.

However, it is necessary that the end of the second clamping member 280 is adjacent to the inner peripheral surface, although the end of the second clamping member 280 is not integrally formed with the inner peripheral surface of the dust collecting case 210.

In addition, it is necessary that the other end of the second clamping member 280 is adjacent to the fixed shaft 282, although the other end of the second clamping member 280 is not integrally formed with the fixed shaft 282.

This is necessary to minimize the leakage of contaminants pushed by the first clamping member 270 to the outside through a gap formed in the side of the second clamping member 280.

It is necessary that the first clamping member 270 and the second clamping member 280 are formed in the form of square plates. In addition, it is necessary that the rotary shaft 272 of the first clamping member 270 is located on an axis that is the center of the dust collecting case 210 of the same shaft.

In addition, it is necessary that a plurality of clamping protrusions 276 are formed on the outer surface of the first clamping member 270. The clamping protrusions 276 effectively compact the contaminants when compacting the contaminants when the first clamping member 270 moves toward the second clamping member 280.

In addition, it is necessary that the chamfer 274, taken at a predetermined angle, was formed on the upper end of the first clamping element 270. The chamfer 274 provides for easy discharge of contaminants through the outlet 234 when the space between the outlet 234 and the first clamping element 270 is formed when the upper end of the first clamping element 270 is located on the lower side of the outlet 234.

The fixed shaft 282 protrudes inside from the end of the dust collecting case 210, and a cavity extending in the direction of the shaft is formed in the fixed shaft 282 for assembling the rotating shaft 272. In addition, a predetermined portion of the rotating shaft 272 is inserted into the cavity 283 from the upper side of the fixed shaft 282.

In detail, a step 272c supported on the upper part of the fixed shaft 282 is formed on the rotating shaft 272, and the rotating shaft 272 is divided into an upper shaft 272a on which the first pressure member 270 is mounted, and a lower shaft 272b with which the driven gear is described below, connected to rotate the first clamping member 270 with a stage 272c as a standard.

In addition, a groove 275 for preventing moving parts from grazing is formed on the first clamping member 270 to prevent grazing of the fixed shaft 282 and the first clamping member 270 when connecting the lower shaft 272b to the stationary shaft 282. That is, a predetermined distance between the lower shaft 272b and the first is provided clamping element 270.

In addition, the vacuum cleaner in accordance with the present invention further comprises a drive device that rotates the first clamping member 270 selectively connected to the rotating shaft 272 of the first clamping member 270.

In detail, reference will be made to the connection between the dust collector 200 and the drive device.

FIG. 6 is a perspective view of the bottom of the dust collector in accordance with a preferred embodiment of the present invention, FIG. 7 is a cross-sectional view taken along line II-II ′ of FIG. 4, and FIG. 8 is a perspective view of the mounting portion of the dust collector in in accordance with a preferred embodiment of the present invention.

As shown in Fig.6-8, the drive device for rotating the first clamping element 270 contains a compression motor, illustrated below, to generate operating power and elements 410 and 420 for transmitting power for transmitting power of the compression motor to the first clamping element 270.

In detail, the power transmitting elements 410 and 420 comprise a driven gear 410 connected to a rotating shaft 272 of the first pressure member 270, and a pinion gear 420 transmitting power of the compression motor to the driven gear 420 connected to the compression motor.

Therefore, the drive gear 420 connected to the compression motor rotates when the compression motor rotates, and the driven gear 410 rotates when the power of the compression motor is transmitted to the driven gear 410 by driving the gear 420, and ultimately the first pressure member 270 rotates as a result of rotation of the driven gear 410.

In detail, the axis 414 of the driven gear 410 is connected to the rotating shaft 272 of the first pressing member 270 on the underside of the dust collecting case 210.

In addition, it is necessary that the inner peripheral surface of the rotating shaft and the horizontal cross section of the outer peripheral surface of the axis 414 of the driven gear 410 are polygonal, so that the driven gear 410 does not idle, but rotates simultaneously with the first clamping member 270 when the driven gear 410 rotates.

7 illustrates a rotating shaft 272 and an axis 414 of a driven gear 410 with an octagonal horizontal section.

However, the horizontal sectional shape of the rotating shaft 272 and the gear axis 414 is not limited to what is described above, and may be different. That is, it is necessary that the horizontal sections of the rotary shaft 272 and the gear axle 414 are formed in a non-circular shape and rotate the first clamping member 270 uniformly while the driven gear 410 rotates.

In addition, it is possible that the connecting member 278 is connected on the upper side of the rotating shaft 272 in a position in which the driven gear 410 is connected to the rotating shaft 272. Therefore, it is possible that the driven gear 410 and the rotating shaft 272 are connected firmly, and idle rotation is further prevented. driven gear 410.

A compression motor is located at the bottom of the mounting portion 170 of the dust collecting device, and a pinion gear 420 is located at the base of the mounting portion 170 of the dust collecting device connected to the rotating shaft of the compression motor.

In addition, part of the outer peripheral surface of the rotary gear 420 is open outward at the base of the mounting portion 170 of the dust collector. For this, a hole 173 is formed to open part of the outer peripheral surface of the pinion gear 420 in the mounting portion 170 of the dust collector.

According to the connection of the driven gear 410 on the lower side of the dust collecting case 210, the driven gear 410 is open to the outside of the dust collecting housing 210, and the driven gear 410 is engaged with the driving gear 420 in accordance with the fact that the dust collecting device 200 is installed in the mounting part 170 of the dust collecting device .

It is necessary that the compression motor be an electric motor suitable for rotation in the forward and reverse directions.

That is, an electric motor suitable for rotation in the forward and reverse directions is used as a compression electric motor.

Therefore, the first clamping member 270 is suitable for forward and reverse rotation, and contaminants on both sides of the second clamping member 280 are compacted in accordance with the fact that the first clamping member 270 rotates back and forth.

On the other hand, a guide rib 290 is formed on the lower side of the dust collecting case 210 for guiding the dust collecting device 200 during installation, and a mounting groove 172 into which the guide rib 290 is inserted is formed on the mounting part 170 of the dust collecting device.

In addition, the guide rib 290 covers a portion of the driven gear 410, made in the form C on the outer side of the driven gear 410. That is, the guide rib 290 is formed by covering the part of the driven gear 410 to open the part of the driven gear outward, since the driven gear 410 and the pinion gear 420 should be connected to each other when the dust collector 200 is installed in the mounting portion 170 of the dust collector, as described above.

A guide rib 290 protects the driven gear 410 and prevents contaminants from moving onto the driven gear 410.

In addition, a separation preventing hole 174 is formed in the mounting portion 170 of the dust collecting device to prevent the vacuum cleaner body 10 from being disconnected in the forward direction in a position in which the dust collecting device 200 is installed in the mounting portion of the dust collecting device 170, and a separation preventing protrusion 294 inserted into the opening 174 to prevent separation, formed on the guide rib 290.

Therefore, the separation of the dust collecting device 200 is prevented when the protrusion protrusion 294 is engaged with the opening 174 to prevent separation, even if the dust collecting device 200 moves in the forward direction when it is mounted in the mounting portion 170 of the dust collecting device near the opening 174 to prevent separation.

In addition, the mounting member 176 is formed on the mounting portion 170 of the dust collecting device for guiding the guide rib 290 during installation, and the mounting groove 295 corresponding to the mounting member 176 is formed on the guide rib 290.

The dust collecting device 200 is easily installed in the mounting portion 170 of the dust collecting device by the mounting member 290 and the mounting groove 295, and vibration of the dust collecting device 200 installed in the mounting portion 170 of the dust collecting device is prevented.

The microswitch described below is located on the lower portion of the mounting portion 170 of the dust collector for registering the position when the driven gear 410 rotates. In addition, the lever 440 is open in the mounting portion 170 of the dust collecting device to turn on and off the microswitch that is in contact with the driven gear 410.

For this, a penetration hole 177 is formed in the mounting portion 170 of the dust collecting device for opening the lever portion 440. In addition, an inner rib 178 and the outer rib 179 are formed on the mounting portion 170 of the dust collecting device for protecting the lever 440 in which the portion is open.

A link will be made in detail to the working connection between the driven gear and the microswitch.

Fig.9 depicts a perspective view of the lower part of the driven gear in accordance with the present invention.

As shown in FIGS. 9 and 10, the microswitch 430 is located at the bottom of the driven gear 410 so that the lever 440 enables the on / off switch 430 facing the lower side of the driven gear 410.

The driven gear 410 comprises a central plate-shaped central part 412, a contact rib 413 in contact with the lever 440 extending downward from a lower portion of the central part 412, and a plurality of gear teeth 416 formed along a circumference of a side surface of the central part 412.

In detail, a control recess 415 is formed on the contact rib 413 for registering a location when the driven gear 410 rotates while preventing the driven gear 410 from contacting the lever 440 in a position in which the driven gear 410 is rotated to a predetermined location. When the lever 440 and the contact rib 413 are not in contact with each other, this means that the lever 440 is not in contact with the bottom of the contact rib 413, since part of the lever 440 is inserted into the control recess 415.

In addition, the lever 440, opened through the penetration hole 177, presses on the contact point 432 of the microswitch 430, which contacts the lower part of the contact rib 413 when the dust collector 200 is installed in the installation part 170 of the dust collector. In addition, when the driven gear 410 moves to a predetermined location during rotation, the lever 440 moves away from the contact point 432, as part of the lever 400 is inserted into the recess 415 for position control.

The micro switch 430 is turned off when the lever 440 is located in the recess 415 for position control, and in all other cases, the micro switch 430 is turned on, except in this case, in contact with the rib 413.

A groove 417 for preventing trapping of moving parts is formed on the underside of the gear tooth 416 to prevent grazing of the outer rib 178 during installation of the dust collector 200.

Therefore, the outer ridge 179 is located in the groove 417 to prevent trapping of moving parts, and the inner ridge 178 is located in the space formed by the contact rib 413 when the dust collector 200 is installed in the installation part 170 of the dust collector.

In addition, each of the gear teeth 416 has both sides rounded at a predetermined curvature. Both sides of the tooth 416 of the driven gear 410 are rounded to easily connect the driven gear 410 and the working gear 420, since the driven gear 410 is connected to the drive gear 420 when the dust collector 200 is installed in the mounting part 170 of the dust collector.

In addition, a pair of bevel planes 419 are formed on the lower side of each gear tooth 416 for easily connecting the driven gear 410 and the drive gear 420. A pair of bevel planes 419 intersect with each other in the center of the gear tooth 416.

The pinion gear 410 and the pinion gear 420 are precisely connected to each other, since the inclined plane 419 of the gear tooth 416 and the pinion gear tooth 420 are slid, while the pinion gear 410 and the pinion gear 420 are connected due to this configuration.

The tooth of the pinion gear 420 is formed in a shape corresponding to the tooth of the driven gear 410, and a detailed description thereof is omitted.

11 is a block diagram illustrating a control device of a vacuum cleaner in accordance with the present invention.

As shown in FIG. 11, the vacuum cleaner in accordance with the present invention essentially comprises a control device 810, an operating signal input device 820 for selecting a suction power for contaminants (eg, high, medium, low power modes), a signal display device 830 about unloading pollutants to display a signal informing about the time of unloading of pollutants collected in the dust collector 200 by means of a light emitting element, such as an LED, a suction drive device 840 an electric motor for driving the suction electric motor 850, which is a working electric motor for sucking contaminant particles inward in accordance with the operating modes (e.g., high, medium, low power modes) inputted to the operating signal input device 820, a compression electric motor driving device 860 for driving a compression motor 870 used to seal the contaminants accumulated in the dust collector 200, a pinion gear 420, dimuyu compression motor 870 into motion, a rotatable driven gear 410 meshed with the pinion gear 420, and the microswitch switches on and off in accordance with the rotation of the driven gear 410.

In detail, the control device 810 controls the drive unit 840 of the suction motor for driving the suction motor 850 with suction power corresponding to the high, medium, low power modes when the user selects one of the high, medium, low power modes indicating suction power through the device 820 input of a working signal. That is, the suction motor drive device 850 drives the suction motor 850 with a predetermined suction power in accordance with a signal transmitted from the control device 810.

The control device 810 drives the compression motor 870 when the drive device 860 of the compression motor is driven, while driving the drive device 840 of the suction motor or after driving the drive device 840 of the suction motor.

Here, a synchronous motor can be used as a compression motor 870 to provide forward and reverse rotation of the first clamping member 270, as described above.

The synchronous electric motor is designed in such a way that direct and reverse rotation is possible only due to the electric motor itself, and the direction of rotation of the electric motor changes to another direction when the power applied to the electric motor becomes larger than a predetermined value when the electric motor rotates in one direction.

In this case, the power applied to the electric motor is the torque that is created when the first pressing member 270 compresses the contaminants, and the rotation direction of the electric motor changes when the torque reaches a predetermined value.

A detailed description of a synchronous electric motor is omitted, as it is well known in the field of electric motor manufacturing technologies. Meanwhile, one of the technical ideas of the present invention is that direct and reverse rotation of the electric motor is possible due to the synchronous electric motor.

In addition, it is necessary for the first clamping member 270 to continuously contaminate contaminants during rotation for a predetermined time, even when the first clamping member 270 reaches a limit position in which it is impossible for the first clamping member 270 to rotate.

A limit position in which it is not possible for the first pressing member 270 to rotate means a case in which the torque reaches a predetermined value.

In addition, when the torque reaches a predetermined value, the power rotating the first clamping member 270, the power applied to the compression motor 870 ceases to operate for a predetermined time to maintain a state in which the contaminants are compacted in a state in which the first clamping member 270 is stopped, and the first clamping member 270 can again be activated after a predetermined time has elapsed when power is applied to the compression motor 870.

The direction of rotation of the compression motor 870 changes to the opposite direction before shutting off when the compression motor 870 is again driven, since there is a time during which no power is supplied to the compression motor 870 when the torque reaches a predetermined value.

In addition, it is necessary that the compression motor 870 continuously rotate the first pressure member 270 in the left and right directions at the same speed for easy compaction of the contaminants.

Contaminant particles are compacted by a first pressure member 270, which moves continuously as it rotates back and forth when the compression motor 870 is driven as described above. In addition, the rotation time in the left and right directions of the first pressing member 270 is reduced, since the amount of contaminants compacted in the dust collecting device 200 is increased. When the rotation time in the left and right directions of the first clamping member 270 becomes shorter than the predetermined time, since the amount of compacted contaminants sucked into the dust collector 200 accumulates to a predetermined amount, the control device 810 sends a signal indicating the emptying time of the dust collector a device 200 containing the collected contaminants to the device 830 displaying a signal for the discharge of contaminants based on the data.

FIGS. 12 and 13 are views illustrating a state in which the microswitch is turned on when the first pressure member is adjacent to the side of the second pressure member for compressing contaminants, FIGS. 14 and 15 are views illustrating a state in which the microswitch is turned off when the first the pressing member and the second pressing member are in a straight line, and FIGS. 16 and 17 are views illustrating a state in which the micro switch is turned on when the first pressing member is adjacent to the other side. oh the second pressing member.

As shown in FIGS. 12-17, the lever 440 is located in the recess 415 for controlling the location of the driven gear 410 in the present invention when the first clamping member 270 is in a straight line when rotated 180 ° relative to the second clamping member 280 as a standard. In this case, the microswitch 430 is turned off, since the lever 440 is located at a distance from the contact point 432.

The location of the first pressure member 270, illustrated in FIG. 14, in which the micro switch 430 is turned off, is called the reference location for convenience of description.

The microswitch 430 is turned on, as illustrated in FIG. 13, when the lever 440 presses on the contact point 432 because it is in contact with the contact rib 413 of the drive gear 410, while the first pressure member 270 seals the dust particles in the dust collecting case 210 when rotating in the opposite direction relative to the clockwise direction from the reference location.

When it is not possible that the first pressing member 270 rotated in the opposite direction with respect to the clockwise direction rotates due to contaminants, the first pressing member 270 rotates in the clockwise direction. Therefore, the first pressing member 270 seals the contaminants in the dust collecting case 210 while rotating in the right direction to the second pressing member 280, as illustrated in FIG. 16, after passing through the reference location illustrated in FIG.

In addition, when it is not possible for the first clamping member 270 to rotate in a clockwise direction to rotate due to contaminants, the compression motor 870 compresses the contaminants in the dust collecting case 210 when the first clamping member 270 rotates in the opposite direction from the clockwise direction arrow when repeating the specified process.

Fig. 18 is a view illustrating the entire rotation operation of the first clamping member illustrated in Figs. 12-17.

The time TD1 required for the first pressing member 270 to return to the reference location when rotating in a clockwise direction from the reference location, and the time TD2 required for the first pressing member 270 to return to the reference location when rotating in the opposite direction relative to clockwise directions from a reference location, illustrated in FIG. For convenience of description, the time interval TD1 is called the first reverse time interval and the time interval TD2 is called the second reverse time interval. In general, the first back-off time interval TD1 and the second back-off time interval TD2 are almost the same, since the contaminants spread evenly in the dust collecting case 210.

On the other hand, the larger the amount of contaminants compacted by the first pressure member 270, the shorter the back-off time intervals TD1 and TD2 become.

In the present invention, a pollutant discharge signal is displayed when it is determined that a sufficient amount of pollutant particles has been accumulated in the dust collector 210 when one of the return time intervals TD1 and TD2 reaches a predetermined reference time.

Reference will be made in detail to the operation and compaction process of the contaminant particles of a vacuum cleaner in accordance with the present invention.

19 is a flowchart illustrating a method for controlling a vacuum cleaner in accordance with the present invention.

As shown in FIG. 19, the user activates the vacuum cleaner when one of the suction powers of the high, medium, low power modes displayed on the operating signal input device 820 is selected. Then, the control device 810 drives the suction motor drive device 840 to drive the suction motor 850 in accordance with the suction power mode selected by the user (S110).

When the suction motor 850 is driven, the contaminants are sucked through the suction brush by the suction force of the suction motor 850. Then, the air sucked through the suction brush passes into the vacuum cleaner body 100 through the suction device 110, and the transmitted air is sucked into the dust collector 200 when passing through multiple channels.

In detail, air containing contaminants is sucked towards the contact line of the first cyclone device 230 through the first air inlet 218 of the dust collecting case 210. Then, the suction air passes down during circulation along the inner peripheral surface of the first cyclone device 230, and air and pollutants are separated from each other at this stage under the influence of different centrifugal forces due to the difference in weight.

Then, the air separated from the contaminant particles enters the outside of the dust collector 200 through the outlet 251 and the first air outlet 252 after filtration through the openings 262 of the filter element 260.

On the other hand, the separated pollutants are sucked into the channel 232 to direct the pollutants towards the contact line during the rotation step along the inner peripheral surface of the first cyclone device 230.

Then, the contaminants that are sucked into the channel 232 to direct the pollutants pass along the outer peripheral surface of the first cyclone device 230, since the direction of movement changes in the channel 232 to direct the pollutants, and accumulate in the first compartment 214 to accumulate pollutants when passing down through outlet 234.

Air exiting through the first air outlet 252 is sucked into the cleaner body 100. Air sucked into the vacuum cleaner body 100 is sucked into the second cyclone device 300 after passing through the connecting channel 114.

Then, air is directed to the contact line of the inner wall of the second cyclone device 300 through a second air inlet (not shown) connected to the end of the connecting channel 114, and is secondly separated from the contaminants.

Then the air, second separated from the polluting particles, is sucked into the vacuum cleaner body 100. Further, the air sucked into the vacuum cleaner body 100 exits through the outlet of the vacuum cleaner body 100 after passing through the suction motor.

On the other hand, the separated pollutants are sucked into the dust collector 200 through the pollutant inlet 254 and finally accumulate in the second pollutant storage compartment 216.

During this process, in which pollutants contained in the air accumulate in the compartment for accumulating pollutants after being separated from the air, as described above, a pair of pressure members 270 and 280 compresses the pollutants accumulated in the first compartment 214 for accumulating pollutants.

That is, the control device 810 drives a compression motor 870 for sealing the contaminants accumulated in the dust collecting case 210 (S120).

The present invention employs a method in which the compression motor 870 is driven after the suction motor 850 is driven, however, it is possible that the suction motor 850 and the compression motor 870 are driven simultaneously as another preferred embodiment.

In addition, when the compression motor 870 is driven, the operating gear 420 connected to the compression motor 870 rotates. When the working gear 420 rotates, the driven gear 410 rotates in connection with the rotation of the working gear 420. When the driven gear 410 rotates, the first pressing member 270 connected to the driven gear 410 seals the particles, automatically rotating towards the second pressing member 280.

The control device 810 checks whether the first pressing member 270 is located at the reference location (S130). It is necessary to check whether the first clamping member 270 is located at the reference location during the first operation, since in the present invention, the first and second back-off time intervals are measured for the reference location of the first clamping member 270 as the reference location. When the first pressing member 270 is located at the reference location, this means a point in time when the micro switch 430 is turned off during the first time interval during the first operation.

Therefore, the control device 810 measures the first and second time intervals of the return stroke relative to the time point when the micro switch 430 is turned off during the first time interval as a standard.

In addition, the control device 810 measures the first interval TD1 and the second interval TD2 of the reverse time in accordance with the movement of the first clamping element 270 in the opposite direction relative to the clockwise direction or the clockwise direction relative to the time point when the first clamping element 270 is moved to the reference location as a reference (S140).

When the amount of contaminants sealed by the first pressing member 270 and the second pressing member 280 is increased in the dust collecting case 210, the back-off time interval in the left and right directions is shortened.

The control device 810 determines whether the first return time interval TD1 or the second return time interval TD2 reaches a predetermined reference time interval when measuring the first return time interval TD1 and the second return time interval TD2 of the first pressure member 270 via the micro switch 430. The preset the reference time interval is the time interval set in the projector control device, and this becomes the basis for determining that sculpt particulate accumulated over a predetermined number of the dusts in the dust collection body 210. The reference time interval is obtained by experimentation projector several times and is different in accordance with the volume of the vacuum cleaner.

The present invention employs a method in which it is determined that the amount of contaminants reaches a predetermined amount when one of the first return time interval TD1 and the second return time interval TD2 reaches the reference time, however, it is possible that in another embodiment the basis of the determination is the case in which both the first back-off time interval TD1 and the second back-off time interval TD2 reach a predetermined belt.

As a result of determining in step S150, if any of the first return time interval TD1 and the second return time interval TD2 is larger than the reference time interval, then they return to step S140 and the previous step is performed.

On the other hand, if the first back-off time interval TD1 or the second back-off time interval TD2 reaches the reference time, the control device 810 controls so that the contaminants are no longer absorbed when the suction motor 850 is turned off (S160). The reason for forcing the suction motor to stop is because the suction efficiency of the contaminants is reduced, and the suction motor 850 is overloaded if the suction of contaminants continues forcibly when the amount of contaminants in the dust collecting case 210 is greater than a predetermined amount. At this time, it is necessary to turn off the compression motor 870 with a suction motor.

Then, the control device 810 notifies the user of the time for unloading the pollutants by transmitting a signal indicating the time for unloading the pollutants located in the dust collecting case 210 to the device for displaying the signal for unloading the pollutants (S170). In another preferred embodiment of the present invention, it is possible that the signal for discharging contaminant particles is displayed using a pre-set sound signal using the sound signaling circuit.

A vacuum cleaner in accordance with the present invention has several advantages that increase user convenience, since the time for emptying the dust collector 200 containing the polluting particles is communicated to the users, and thereby preventing a decrease in the operating efficiency of the vacuum cleaner due to excessive absorption of the polluting particles during operation control the suction motor in the process, performing a function informing about emptying the dust collector.

On the other hand, the technical idea of the present invention described above can be applied to vertical type vacuum cleaners and robotic vacuum cleaners.

FIG. 20 is a perspective view of a lower part of a dust collecting device according to a second embodiment of the present invention, and FIG. 21 is a perspective view of a mounting part of a dust collecting device according to a second embodiment of the present invention.

As shown in FIGS. 20 and 21, a guide rib 520 is formed on the underside of the dust collecting case 510 in accordance with the present invention for guiding the dust collecting device 500 when installed in the vacuum cleaner body 100, and a mounting groove 572 into which the guide rib 520 is inserted is formed on installation part 570 of the dust collector.

A guide rib 520 is located on the outside of the driven gear 410 in the shape of C and covers part of the driven gear 410. In addition, at least a pair of guide protrusions 530 are formed on the underside of the dust collecting case for guiding the dust collecting device 500 upon installation, and an insertion groove 574 the protrusion into which the guide protrusion 530 is inserted is formed on the mounting portion 570 of the dust collecting device.

In addition, the anti-vibration rib 522 is formed by extending on the guide rib 520 on the underside of the dust collector to prevent vibration of the dust collector installed in the mounting portion 570 of the dust collector, and also the direction of the dust collector 500 during installation.

In addition, a groove 576 for inserting a rib into which a rib 522 is inserted to prevent vibration is formed on the mounting portion 570 of the dust collecting device. A groove for inserting a rib 576 is formed at a location farther than the groove 574 for inserting a protrusion when viewed from the front of the cleaner body 100. That is, the intended line connecting the groove 574 for inserting the protrusion and the groove 576 for inserting the ribs forms a triangle.

Therefore, when the dust collecting device 500 is installed in the position in which the guide protrusion 530 and the groove for inserting the protrusion are located, first of all the guide protrusion 530 is inserted into the groove 574 for inserting the protrusion, then the dust collecting device 500 is easily and correctly installed in accordance with that the rib 522 to prevent vibration is inserted into the groove 576 to insert the ribs.

In addition, vibration of the dust collector 500 is effectively prevented during operation of the vacuum cleaner in accordance with the fact that the guide protrusion 530 and the anti-vibration rib 522 protruding to the outside of the dust collector are inserted into the groove 574 for inserting the protrusion and the groove 576 for inserting the ribs, formed on the installation part 570 of the dust collecting device.

The idea of the present invention is not limited to this description, therefore, another preferred embodiment is further included, such as the following.

It is possible that a magnetic element generating magnetism in the lower part of the mounting part of the dust collecting device and a magnetic material suitable for connecting to the magnetic element on the dust collecting device are provided. It is possible that, for example, a metal element is used as a magnetic material.

In this case, it is possible to simplify the base of the dust collecting device and the configuration of the installation part of the dust collecting device.

In addition, if the dust collecting device is adjacent to the mounting part of the dust collecting device for installing the dust collecting device, the dust collecting device can be guided during installation due to the interaction of the magnetic element and the metal element, and the vibration of the dust collecting device is further prevented since the dust collecting device is magnetically connected to the mounting part the dust collector in a position in which the dust collector is installed in the dust collector ystv.

It is possible that the magnetic element is located in the dust collecting device, and the magnetic material is located in the lower portion of the mounting portion of the dust collecting device.

Claims (28)

1. A vacuum cleaner containing:
a vacuum cleaner body in which an installation part of the dust collecting device is formed;
a dust collecting device configured to attach and detach from the installation part of the dust collecting device and having a compartment inside for accumulating contaminant particles;
at least one pressing element that reduces the amount of pollutant particles accumulated in the compartment for accumulating pollutant particles, arranged to move in the compartment for accumulating pollutant particles;
a device for transmitting power transmitting a driving force to the clamping element from the outside, connected to the clamping element; and
a control device that determines the amount of contaminant particles accumulated in the compartment for accumulating contaminant particles, the device for transmitting power includes a driven gear connected to the clamping element, and a horizontal section of the axis of the driven gear has a shape other than round. 2. The vacuum cleaner according to claim 1, in which the device for transmitting power further comprises a drive gear transmitting a driving force to the driven gear when it is installed in the installation part of the dust collecting device. 3. The vacuum cleaner according to claim 2, in which a compression electric motor generating a driving force is installed in the housing of the vacuum cleaner. 4. The vacuum cleaner according to claim 2, in which the driven gear is connected to the rotating shaft of the clamping element in the lower part of the dust collecting device. 5. The vacuum cleaner according to claim 1, in which the guide element comprises a rotating shaft connected to the driven gear, and the horizontal section of the inner peripheral surface of the rotating shaft has a shape other than round. 6. The vacuum cleaner according to claim 5, in which the horizontal section of the axis of the drive gear is polygonal. 7. The vacuum cleaner according to claim 1, which further comprises a connecting element attached on the side of the clamping element in a position in which the clamping element and the driven gear are connected. 8. The vacuum cleaner according to claim 2, further comprising a recording device for recording the location of the pressing member, and the control device determines the amount of contaminant particles accumulated in the contaminant storage compartment based on information from the location registration device. 9. The vacuum cleaner of claim 8, in which the device for recording location includes a micro switch located in the housing of the vacuum cleaner; and a lever in contact with the driven gear when its part is open to the mounting part of the dust collector, and selectively pressing the contact point of the microswitch. 10. The vacuum cleaner according to claim 9, in which the driven gear comprises a contact protrusion in contact with the lever, and a groove preventing contact between the lever and the gear formed on the contact protrusion. 11. The vacuum cleaner of claim 10, in which the lever presses on the contact point when the lever is in contact with the contact rib, and the lever is at a distance from the contact point when the lever is located in the groove. 12. The vacuum cleaner of claim 10, in which the determination of the amount of accumulated contaminants is carried out by checking that the pressure element is located in the reference location, and measuring the time interval of the return stroke of the pressure element from the reference location back to the reference location after moving clockwise during rotation arrow or in the opposite direction relative to the clockwise direction and returning when rotating in the clockwise direction or in the opposite direction ION with respect to the clockwise direction. 13. The vacuum cleaner according to item 12, in which the reference location is the location in which the lever is located in the groove. 14. The vacuum cleaner according to item 12, in which the signal about the discharge of polluting particles is displayed outside when the return time interval is slightly less than the reference time interval. 15. The vacuum cleaner according to claim 10, in which at least one rib protecting the lever, open from the outside, is formed on the installation part of the dust collecting device, and a groove for preventing grazing of moving parts, preventing grazing on the rib, is formed on the lower side of the driven gear . 16. A vacuum cleaner containing:
vacuum cleaner body;
a dust collecting device selectively mounted in the cleaner body;
at least one pressure element that reduces the amount of contaminant particles accumulated inside and located inside the dust collector;
a drive device driving the clamping element and connected to the clamping element in accordance with the installation of the dust collecting device, in which the drive gear is connected to the clamping element;
a first guide member guiding the dust collector during installation located on the dust collector; and
a second guide member cooperating with the first guide member located on the cleaner body, and
installation groove into which the drive gear is inserted when installed in the vacuum cleaner body. 17. The vacuum cleaner according to clause 16, in which the first guide element is at least one of the protrusions protruding from the dust collecting device, and the second guide element is a mounting groove in which a protruding element formed on the vacuum cleaner body is inserted. 18. The vacuum cleaner according to clause 16, in which the first guide element is the installation groove formed on the lower side of the dust collector, and the second guide element is the installation element inserted into the installation groove formed on the cleaner body. 19. The vacuum cleaner according to clause 16, in which one guide element is a magnetic element and the other guide element is a magnetic material that interacts with the magnetic element. 20. The vacuum cleaner according to clause 16, in which the drive device further comprises a drive gear, optionally connected to the driven gear when it is placed in the housing of the vacuum cleaner; and a compression electric motor transmitting the driving force to the pinion gear. 21. The vacuum cleaner according to claim 20, in which the rib is formed on the dust collecting device to prevent the passage of contaminant particles towards the driven gear, and the rib is inserted into the installation groove. 22. The vacuum cleaner according to item 21, in which the first guide element is a protrusion formed on the rib, and the second guide element is a groove for introducing the protrusion into which the protrusion formed on the vacuum cleaner body is inserted. 23. The vacuum cleaner according to claim 20, in which the driven gear is connected to the rotating shaft of the clamping element on the outside of the dust collector and at least a portion of the drive gear is open outward. 24. The vacuum cleaner according to item 23, in which both sides of each of the gear teeth are rounded to smoothly connect the driven gear and the pinion gear. 25. The vacuum cleaner according to item 23, in which an inclined plane is formed on the lower side of at least the driven gear for smoothly connecting the driven gear and the driving gear. 26. A vacuum cleaner containing:
vacuum cleaner body;
a dust separation device separating the polluting particles from the air drawn into the vacuum cleaner body;
a dust collecting device connected to the vacuum cleaner body with a possibility of removal and having a compartment for accumulating polluting particles;
at least one clamping element that reduces the amount of pollutant particles accumulated in the compartment for accumulating pollutant particles as a result of interaction with a fixed element installed in the compartment for accumulating pollutant particles with the possibility of movement; and
at least one gear configured to transmit a drive force to the pressure member,
wherein at least one gear comprises a plurality of gear teeth having at least one rounded side surface. 27. The vacuum cleaner according to claim 26, wherein both side surfaces of each of the plurality of gear teeth are rounded with a predetermined curvature. 28. The vacuum cleaner according to claim 26, wherein the plurality of teeth of the at least one gear has at least one plane of inclination.

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