RU2300303C2 - Sucking-in washer and vacuum cleaner equipped with sucking-in washer - Google Patents

Abstract

FIELD: domestic appliances.

SUBSTANCE: sucking-in washer and vacuum cleaner equipped with such washer can be used for cleaning floor at regulated speed of rotation of sweeping unit corresponding to condition of floor. First air-receiving opening is made in lower part of case of washer; dusted air is sucked in by means of sucking-in force generated when starting sucking-in device. Sweeping-in unit is mounted for rotation inside first air receiving opening to sweep dust from floor in. Washer has contrivance for adjusting speed of rotation of sweeping unit corresponding to condition of floor onto which floor the case of washing is disposed. Device for adjusting speed of rotation has device for regulation of air flow, which unit is mounted in case of washer to change speed of rotation of sweeping unit by means of regulation of air flow introduced into first air receiving opening. Device for regulation of air flow has opening for supplying external air, through which opening the external air enters through one side of case of washer. It also has opening contrivance, which regulates degree of opening to supply external air to regulate air flow passing through first air receiving opening. Opening contrivance has shutter, which opens and closes opening for supplying external air and lever unit to regulate position of shutter; level unit is connected with shutter. Lever unit improves air flow sucked in through first air receiving opening to increase speed of rotation of sweeping unit if the latter is pressed against floor when case of washer lowers onto floor, and it reduces air flow, sucked in through first air receiving opening to decrease speed of rotation of sweeping unit is case of washer stays aside floor. Washer is placed inside vacuum cleaner, which has case equipped with dust collector collecting dust by means of dust separation. Sucking-in washer communicates with dust collector and it moves along floor for sucking dust-containing air in.

EFFECT: improved comfort; regulated suck-in power.

21 cl, 8 dwg

Description

The present invention relates to a vacuum cleaner, and more particularly to a suction nozzle and a vacuum cleaner with such a nozzle. Although the present invention is suitable for a wide range of applications, it is particularly applicable for adjusting the rotation speed of a sweeping device.

In general, a vacuum cleaner is a device for cleaning a carpet, a floor in a room, and the like. Contaminated air containing particles is sucked into the vacuum cleaner by starting a suction device installed in the cleaner body that generates suction force, the particles are separated from the contaminated air to collect particles, and the cleaned air is then released from the vacuum cleaner to the outside.

The vacuum cleaner consists of a vacuum cleaner body (not shown), equipped with a suction device (not shown), including an electric motor and fan, as well as a dust collector (not shown) for collecting particles separated from contaminated air, a suction nozzle 10 moving along the floor to be cleaning, to suck in contaminated air containing particles, and a connecting tube (not shown) that guides the air sucked in by the suction nozzle into the dust collector of the vacuum cleaner body.

Wheels are provided on both sides of the cleaner body to facilitate movement of the cleaner body. In addition, the dust collector of the vacuum cleaner body includes a cyclone-type dust chamber or a conventional dust filter bag.

The connecting tube includes an extension tube 5 connected at one end to a suction nozzle, a flexible connection sleeve connected at one end to the other end of the extension tube, and at the other end connected to a vacuum cleaner body, and a handle provided at the other end of the extension tube.

A suction nozzle provided in a conventional vacuum cleaner is described in accordance with the prior art with reference to FIG. 1 below.

As shown in FIG. 1, the known suction nozzle 10 includes a nozzle body consisting of an upper case (not shown) forming an appearance and a lower case 11 in which there is a hollow space, an air inlet 12 provided in the lower part of the nozzle body, those. in the lower part of the lower housing sweeping device 13, supported with the possibility of rotation by both edges of the air inlet 12, and a rotating turbine 14 provided in the nozzle body, for rotating the sweeping device 13.

On the sides of the front side of the lower case, rollers 15 are provided for smooth movement of the suction nozzle 10.

Rotational axes (not shown) supported by both edges of the air inlet 12 protrude from both ends of the sweeping device 13 of the suction nozzle and are used as the center of rotation of the sweeping device 13. A spiral brush 13a is provided on the periphery of the sweeping device 13 of the suction nozzle, which facilitates the separation of particles from gender.

Meanwhile, the rotary turbine 14 has such a configuration that it rotates under the action of air entering through the first air inlet 12, which extends into the extension tube 5. The rotary turbine 14 is connected to the sweeping device via a belt 16. The driven pulley 17 and the driving pulley 18 are provided for sweeping device 13 and the axis of rotation of the rotating turbine 14, respectively. The belt 16 is firmly fixed to the driven and driving pulleys 17 and 18. Therefore, the rotation force of the rotating turbine 14 is transmitted to the sweeping device 13.

The operation of said known suction nozzle 10 is explained below.

First of all, when air is supplied through the air inlet by means of a controlled suction device, the incoming air passes into the extension tube 5 and rotates the rotating turbine 14.

The rotation force of the rotating turbine 14 is transmitted to the sweeping device 13 through the belt 16, which rotates the sweeping device 13. When the device 13 is rotated, the brush 13a can separate particles from the floor.

Particles separated from the floor in this way enter the air inlet along with the air directed into the dust collector of the vacuum cleaner body through the extension tube.

After that, the dust collector removes particles from the contaminated air entering the dust collector, and releases the cleaned air from the vacuum cleaner body to the outside.

However, since in this prior art configured suction nozzle 10, the suction nozzle sweeping device rotates at a constant number of revolutions per minute regardless of the condition of the floor to be cleaned, there has recently been a growing need for a vacuum cleaner suction nozzle equipped with a sweeping device rotating with a variable speed.

Therefore, the present invention directly relates to a suction nozzle and a vacuum cleaner with such a nozzle, which, to a large extent, eliminates one or more problems due to limitations and disadvantages of the prior art.

An object of the present invention is to provide a suction nozzle and a vacuum cleaner with such a nozzle, due to which it is possible to change the rotation speed of the sweeping device.

Additional advantages, objectives and distinguishing features of the present invention will be partially considered later in the description and partly will become clear to those who are familiar with this technical field after studying the following or practical application of this invention. The objectives and advantages of this invention can be realized and achieved thanks to the design, discussed in detail in the description and claims, as well as shown in the accompanying drawings.

To achieve these objectives and other advantages, and in accordance with the objective of the present invention, as embodied and described herein in general terms, the suction nozzle of a vacuum cleaner in accordance with the present invention includes a nozzle body, a first air inlet opening provided in a lower portion of the body of the nozzle for air intake, containing dust, by means of a suction force generated when the suction device is started, a sweeping device mounted to rotate in the first air inlet ond sweeps dust from the floor, and a device for speed control, variable speed agitator.

Preferably, the speed adjusting device increases the rotation speed of the sweeping device of the suction nozzle if the nozzle body is pressed against the floor, and reduces the rotation speed of the sweeping device of the suction nozzle if the nozzle body is separated from the floor.

Preferably, the speed adjusting device changes the rotation speed of the sweeping device of the suction nozzle in accordance with the state of the floor on which the suction nozzle is located.

Preferably, the speed adjusting device includes a rotary turbine provided in an air passage formed in the nozzle body that rotates the sweeping nozzle device of the suction nozzle, a rotary turbine rotated by the air flow entering through the first air inlet, and a device for adjusting the air flow supplied into the nozzle body, which changes the rotation speed of a rotating turbine by adjusting the flow of air entering the first air inlet stie.

More preferably, the device for adjusting the air flow includes a chamber provided in the air channel of the nozzle body, in which a second air inlet is provided through which air entering through the first air inlet is provided, and an opening for supplying external air through which the air passes, entering through one side of the nozzle body, a chamber accommodating a rotating turbine driven by air entering through a second air inlet, and blurring ayuschee device regulating the opening degree of opening for supplying external air to adjust the air flow passing through the second air inlet.

More preferably, the opening device includes a damper opening / closing an opening for supplying external air, and a lever device connected to the damper that controls the damper, the lever device increasing the flow of air drawn into the first air inlet when the suction nozzle is pressed against the floor .

More preferably, the lever device includes a first lever connected at one end to the shutter, and at the other end connected movably to the axis of rotation provided in the nozzle body, and a second lever at which one end can exert pressure on the first lever and the other end is designed that protrudes under the nozzle body and can be pressed to the floor.

More preferably, the first lever is resiliently supported by the first spring, and the first spring moves the shutter in the direction of opening the opening for supplying external air.

More preferably, a predetermined position between both ends of the second arm is rotatably connected to the lower portion of the nozzle body.

More preferably, an indicator window is provided on the upper side of the nozzle body to check the degree of opening of the opening for supplying external air.

More preferably, the second lever moves the shutter connected to the first lever to a position near the opening for supplying external air.

More preferably, the shutter completely covers the opening for supplying external air under the action of a suction force in the chamber in a position near the opening for supplying external air.

More preferably, the device for adjusting the air flow further includes an additional air channel directing outside air into the chamber that rotates the rotating turbine, and an opening / closing part of the channel selectively opening the additional air channel to prevent blocking of the air channel.

More preferably, the opening / closing part of the channel includes an elastic element that opens / closes as a result of the difference between the pressure in the chamber and the atmospheric pressure outside the nozzle body.

In another embodiment of the present invention, the vacuum cleaner includes a vacuum cleaner housing, in which there is provided a dust collector for collecting dust by dust separation, and a suction nozzle in communication with the dust collector of the vacuum cleaner and moving along the floor to suck in air containing dust. The suction nozzle includes a nozzle body, a first air inlet provided in the lower part of the nozzle body for sucking dust under the action of a suction force generated when the suction device is started, a sweeping device provided for rotation in the first air inlet for separating dust from the floor, and a device for adjusting the speed, changing the speed of rotation of the sweeping device.

You must understand that both the above General description and the following detailed description of the present invention are exemplary and explanatory and are intended to further explain the invention, as claimed in the claims.

The accompanying drawings, which are included in the application for further understanding of the invention and form part of this application, illustrate embodiment (s) of the invention and together with the description serve to explain the principle of the invention. In these drawings:

figure 1 is a perspective view of the suction nozzle of a vacuum cleaner in accordance with the prior art;

figure 2 is a perspective view of a vacuum cleaner equipped with a suction nozzle in accordance with the present invention;

3 is a perspective view of a suction nozzle in accordance with one embodiment of the present invention;

5 is a view of the lower part of the suction nozzle in accordance with the present invention;

FIG. 6 is a cross-sectional view of the suction nozzle of FIG. 4 along a cut line extending in the center of the lever portion from right to left;

Fig.7 is a cross-sectional view of the suction nozzle in Fig.4 along the cut line in the direction from the front side to the rear side; and

Fig is a perspective view of the suction nozzle of a vacuum cleaner in accordance with the present invention, in which the suction nozzle has a maximum suction force.

Reference will be made in detail to preferred embodiments of the present invention, examples of which are illustrated in the accompanying drawings. It should be understood that similar reference numerals in the drawings, as a rule, refer to similar or similar elements.

First of all, in general, vacuum cleaners are divided into container-type vacuum cleaners and vertical-type vacuum cleaners.

A container-type vacuum cleaner includes a vacuum cleaner body, a suction nozzle detachable from the vacuum cleaner body, and a connecting tube connecting the vacuum cleaner body and the suction nozzle together.

The vertical type vacuum cleaner includes a suction nozzle and a vacuum cleaner body connected to the upper part of the suction nozzle.

In the present embodiment, a container-type vacuum cleaner is described as a vacuum cleaner equipped with a suction nozzle in accordance with one embodiment of the present invention.

As shown in FIGS. 2-5, a vacuum cleaner equipped with a suction nozzle in accordance with one embodiment of the present invention includes a suction nozzle 100 moving along the floor to suck in air containing particles, a vacuum cleaner body 200, and a connecting pipe 300 connecting the suction nozzle together nozzle 100 and the housing 200 of the vacuum cleaner, for directing polluted air into the housing 200 of the vacuum cleaner. In the vacuum cleaner body 200, a suction device (not shown) generating a suction force and an electric / electronic device (not shown) for controlling the vacuum cleaner are provided.

The suction device includes an electric motor and a fan. The wheels 220 are rotatably mounted on both sides of the vacuum cleaner body 200 to ensure smooth movement of the vacuum cleaner body 200 on the floor, respectively. An exhaust portion 221 is provided for each of the wheels 220 for discharging purified air.

A dust collector 210 for separating and storing solid particles such as dust and the like is provided with a possibility of removal in the front side of the vacuum cleaner body 200. A space is provided on the front side of the vacuum cleaner body 200 for mounting the dust collector 210.

In this case, solid particles such as dust and the like enter the dust collector 210 and are collected by a cyclone system or a filter system using a filter device.

Optionally, dust collector 210 can collect dust using both a cyclone system and a filter system using a filter device.

The connection tube 300 includes a rigid extension tube 310 connected at one end to a suction nozzle 100, a flexible connection sleeve 330, at one end connected to the second end of the extension tube 310, and at the other end connected to a vacuum cleaner body 200, and a handle 320 provided at the other end of the extension tube 310.

The design of the suction nozzle 100 in accordance with the present invention is described with reference to figures 3-8 below.

As shown in FIGS. 3-6, the suction nozzle 100 includes a nozzle body forming an appearance, a first air inlet 120 provided in a lower portion of the nozzle body 110, a sweeping device 130 rotatably provided in the first air inlet 120 for separating particles from the floor, and a device for adjusting the speed, regulating the speed of rotation of the sweeping device 130.

In this case, the nozzle housing 110 consists of an upper housing 111 and a lower housing 112 provided under the upper housing 111. A predetermined space is provided in the nozzle housing 110 for accommodating a speed adjusting device that controls the speed of rotation of the sweeping device 130, and the like.

The movable wheels 110a are rotatably provided in both the lower front and lower rear of the lower housing 112, respectively, to facilitate the movement of the suction nozzle 110.

The first air inlet 120 is formed long from right to left to perforate the front of the lower housing 112. Therefore, under the action of the suction force generated when the suction device is started, external air enters the nozzle body 110 together with the particles polluting the floor through the first air inlet 120 and then enters the extension tube 310 through the air channel provided in the nozzle body 110.

The sweeping device 130 includes a cylindrical body 131, a rotation axis (not shown) protruding laterally from both ends of the body 131, and sweeping part 132 separating dust from the floor to be cleaned.

The axis of rotation is mounted to be removable on both sides of the first air inlet 120 and is rotatably connected to the loading portion 133 of the axis of rotation fixed by the lower and upper bodies 112 and 111.

In particular, the rotation axis is rotatably mounted in a receiving recess (not shown) provided in the loading part 133 of the rotation axis.

The sweeping portion 132 includes a large number of V-grooves formed on the outer periphery of the sweeping device body 131 in the longitudinal direction. Alternatively, the sweeping portion 132 may include a groove formed on the outer periphery of the housing 131 in a spiral direction, a brush provided on the outer circumference of the housing 131 in a spiral direction, or the like.

Meanwhile, the speed adjusting device increases the rotation speed of the sweeping device 130 if the suction nozzle body 110 is pressed against the floor, or reduces the rotation speed of the sweeping device 130 if the nozzle body 110 is separated from the floor.

Alternatively, the speed adjusting device may be configured to vary the rotational speed of the sweeping device 130 in accordance with the state of the floor on which the nozzle body 110 is located. That is, the rotation speed of the sweeping device 130 varies in accordance with the degree of pressure applied to the bottom of the nozzle body 110 to the floor.

For this purpose, the speed adjusting device includes a rotary device driven by a stream of air sucked through the first air inlet 120 that rotates the sweeping device, and an air flow adjusting device that changes the rotation speed of the rotary device by adjusting the air flow drawn through the first air inlet hole 120.

The rotary device includes a rotary turbine 140 provided in the nozzle body 110 to direct air drawn through the first air inlet 120 into the extension tube 310.

The rotary turbine 140 rotates under the influence of air flow through the first air inlet 120, and a large number of blades 141 are provided on the circumference of the rotary turbine 140.

In particular, the rotary turbine 140 is rotatably mounted in a predetermined chamber 113 provided in the air passage in the nozzle body 110.

Therefore, a chamber 113 is provided between the first air inlet 120 and the extension tube 310 through which air is drawn in through the first air inlet 120.

When passing through the chamber 113, the air entering through the first air inlet 120 acts on the blades 141 of the rotary turbine 140 and rotates the rotary turbine 140.

In this case, the rotation speed of the sweeping device 130 changes in proportion to the change in the rotation speed of the turbine. In the present embodiment, the rotary turbine 140 transmits the rotational force to the sweeping device 130 through the belt 142.

In particular, a rotation axis 143 of the turbine extending in one direction to a predetermined length is provided in the center of the rotating turbine 140, and the belt 142 is mounted on a drive pulley 144 provided on the axis of rotation 143 of the turbine and a driven pulley provided on the axis of rotation of the sweeping device 130 by which the rotational power of the rotating turbine is transmitted to the sweeping device 130.

Preferably, rough portions (not shown) are provided on the outer peripheral surfaces of the driving and driven pulleys 144 and 134 and on the inner surface of the belt 142 to prevent slipping of the belt 142. Preferably, the diameter of the driving pulley 144 is less than the diameter of the driven pulley 134.

The rotation axis 143 of the turbine is rotatably mounted in the sealing portion 145, which must be supported. In this case, the sealing portion 145 is supported by the first support member 114 provided in the lower housing 112 and the second support member (not shown) provided in the upper housing 111.

The device for adjusting the air flow, which is provided in the nozzle body 110, regulates the flow of air rotating the rotary turbine 140, thereby changing the rotation speed of the sweeping device 130, in accordance with whether the nozzle body 110 is pressed against the floor and / or in accordance with the state gender.

Under the condition of the floor refers to the state of its surface to be cleaned, i.e. it is a hard floor - wooden, laminated or the like, or a soft floor covered with a carpet, flooring or the like.

Meanwhile, the device for adjusting the air flow includes a second air inlet 150 provided in a predetermined position of the wall of the chamber 113, in which air entering through the first air inlet 120 passes through the second air inlet 150 and rotates the rotary turbine 140, and the adjustment member 160 a flow regulating the flow of air passing through the second air inlet 150, which rotates the rotating turbine 140.

In the present embodiment, a second air inlet 150 is provided on the front side of the chamber 113. The front wall of the chamber 113 extends from right to left and divides the interior of the nozzle body 110 into front and rear spaces.

Therefore, the air entering through the first air inlet 120 passes into the chamber 113 through the second air inlet 150 and rotates the rotating turbine 140.

The flow adjusting member 160 includes an outside air inlet 161 provided on one side of the chamber 113 that allows outside air to flow through one side of the nozzle body 110, and an opening device 162 that controls the opening degree of the outside air inlet 161, which controls the flow of air entering the second air inlet 150.

In particular, the side of the chamber 113 is perforated to form an opening 161 for supplying outside air. An outside air inlet 115 is formed on one side of the nozzle body and communicates with an outside air inlet 161.

In this case, the external air inlet opening 115 is preferably formed in a predetermined position of the nozzle body 110 and, more preferably, on one side of the rear portion of the upper housing 110 so that external air entering the rear space of the brush body can pass into the chamber through hole 161 for supplying external air.

In other words, the trip device 162 controls the current speed and air flow that passes through the second air inlet 150.

The air entering the chamber 113 through the hole 161 for supplying external air is not directed to a rotating turbine.

Therefore, if the opening degree of the opening 161 for supplying external air increases, the flow of air entering the second air inlet opening 150 is reduced. If the degree of opening of the opening 161 for supplying external air decreases, the flow of air entering the second air inlet 150 increases.

Therefore, if the flow and current velocity of the air entering the second air inlet 150 per unit time increases in accordance with the lesser degree of opening of the external air inlet 161, then the rotational speeds of both the rotating turbine 140 and the sweeping device 130 increase.

For this, the opening device 162 includes a shutter 162a opening or closing the opening 161 for supplying external air, and a lever device 163 connected to the shutter 162a, which controls the degree of opening of the opening 161 for supplying external air.

The lever device 163 acts on the shutter 162a, increasing the flow of air drawn into the first air inlet 120 if the suction brush is pressed against the floor.

In particular, whether the nozzle body 110 is pressed against the floor and / or in accordance with the state of the floor to which the nozzle body 110 is pressed, by regulating the air flow sucked through the external air inlet 161, the air flow entering the chamber 113 through the second air inlet 150.

In this case, the lower edge of the external air inlet 161 is preferably located at a considerable distance from the lower edge of the side wall of the chamber 113 and, more specifically, from the upper side of the lower housing 112 with a predetermined height between them, and the lower end of the shutter 162a is preferably located from the upper side of the lower housing 112 with a predetermined height.

This is necessary to prevent operational failure due to the accumulation of dust particles on the upper side of the lower housing 112 when moving the shutter 162a.

The lever device 163 includes a first lever 163a and a second lever 163b connected to the first lever 163a.

In the present embodiment, the lever device 163 moves the shutter 162a in the direction of the outdoor air inlet 161 so that the flow of air passing through the outdoor air inlet 161 is reduced if the suction nozzle body 100 is pressed against the floor.

On the contrary, the lever device 163 is arranged so that it moves the shutter 162a, opening the hole 161 for supplying outside air, thereby increasing the flow of air passing through the hole 161 for supplying outside air if the body 110 of the nozzle is separated from the floor.

Therefore, if the nozzle body is pressed against the floor, the rotation speed of the sweeping device 130 is increased. When the nozzle body is separated from the floor, the rotation speed of the sweeping device 130 decreases.

In particular, one end of the lever 163a is connected to the shutter 162a, and the other end of the lever 163a is movably connected to the first axis of rotation 112a, protruding upward from the inner part of the nozzle body 110 and, more specifically, from the rear inner part of the lower housing 112.

One end of the second lever 163b is configured to press the first lever 163a. The other end of the second lever 163b is designed so that it protrudes from the lower part of the nozzle body 110 and can be pressed against the floor.

In the present embodiment, if the second lever 163b is pressed against the floor so that the nozzle body 110 is on the floor, the second lever 163b rotates the first lever 163a so that the shutter 162a reduces the degree of opening of the external air inlet 161.

Therefore, to reduce the flow of air entering the hole 161 for supplying external air, while pressing the body 110 of the nozzle to the floor, the second lever 163b moves the shutter 162a connected to the first lever 163a to the hole 161 for supplying external air.

Preferably, the predetermined position between both ends of the second lever 163b is rotatably connected to the lower housing 112. More preferably, the predetermined position between both ends of the second lever 163b corresponds to the middle position of the second lever 163b.

Therefore, if the other end of the second lever 163b protruding from the lower side of the lower housing 112 is pressed against the floor, the first lever 163a is rotated by the second lever 163b so that the shutter 162a moves toward the outside air inlet 161 and approaches it , as a result, the flow of air entering the hole 161 for supplying external air is reduced.

For this, the second lever 163b is strongly bent and forms a ∟ ′ bent portion 163c and is connected to the lower body 112 via a second axis of rotation 163d provided in the bent portion 163c for rotating the bent portion 163c.

That is, one end of the second arm 163b protrudes upward in the center of the curved portion 163c, and the other end of the second arm 163b extends laterally, centered in the curved portion 163c in order to selectively press against the floor to be cleaned. Thus, the second lever 163b pivots.

Furthermore, it is preferable that a roller 163e is provided at the other end of the second floor contact lever 163b. Therefore, this minimizes friction between the second lever 163b and the floor.

In the lower case 112, a perforated hole is preferably provided through which one end of the second arm 163b extends vertically and a receiving recess in which the other end of the second arm 163b is pressed against the floor.

In addition, the first lever 163a is resiliently supported by the first spring 163f, which rotates the shutter 162a in the direction of opening of the external air inlet 161.

That is, when the force pressing the other end of the second lever 163b ceases to act, the first spring 163f acts on the first lever 163a, and that in turn rotates the damper 162a so that the air flow through the hole 161 for supplying external air can increase .

In this case, the first spring 163f is a torsion spring located on the first axis of rotation 112a.

In addition, the second spring 163g is preferably located in the lower housing 112 and serves to push the second lever 163b so that the other end of the second lever 163b protrudes from the lower side of the lower housing 112.

In this case, the second spring 163g is located in the receiving recess in which the second lever 163b is mounted to press the upper part of the other end of the second lever 163b.

A connecting hole 163h provided in the first lever 163a serves to communicate between the first and second levers 163a and 163b. In this case, one end of the second lever 163b is mounted in the connecting hole 163h.

Meanwhile, when pressing the suction nozzle with maximum force on the floor, the second lever 163b moves the shutter 162a installed in the same housing with the first lever 163a close to the hole 161 for supplying external air.

When the shutter 162a is moved close to the outdoor air supply opening 161, the outdoor air supply opening 161 is completely closed by the shutter 162a due to the suction force in the chamber 113.

Moreover, the thickness of one end of the second lever 163b is preferably less than the width of the connecting hole 163h.

Meanwhile, on the upper side of the upper nozzle body 110, i.e. on the upper side of the upper case, an indicator window 111a is provided for checking the degree of opening of the opening 161 for supplying external air.

In this case, the indicator window 111a is made of a transparent material. The control element 111b protruding in one housing from the lever device 163 and, more specifically, from the first lever 163a, is placed in the indicator window 111a.

Therefore, if the control element 111b is completely moved in the direction of the outdoor air inlet 161, this indicates that the external air inlet 161 is closed.

In addition, the suction nozzle 100 in accordance with the present invention is preferably formed to prevent overload of the electric motor and reduce the rotation speed of the sweeping device 130 when cleaning a carpeted or carpeted floor.

As shown in FIG. 7, an additional air channel 164 is provided in the nozzle body 110, selectively directing outside air into the chamber 113 to rotate the rotating turbine 140, and an opening / closing channel part 165 that selectively opens / closes the additional air channel 164.

In this case, the additional air channel 164 includes an additional air inlet 164a formed in the center of the upper side of the upper housing 111, and an additional air inlet 164b provided above the second air inlet 150 for passing air to the rotary turbine 140 to rotate the rotary turbine 140.

In the present embodiment, the opening / closing part 165 of the channel opens / closes as a result of the difference between the atmospheric pressure outside the nozzle body and the internal pressure inside the chamber 113.

In particular, the opening / closing part 165 of the channel may include an elastic element.

In this case, one side of the elastic element is preferably connected to a predetermined position of the additional air channel 164 and, more specifically, to the upper edge of the additional air supply hole 164b, and the other side of the elastic element is preferably supported by the edge of the additional air supply hole 164b air, which is bent into the chamber 113.

In this case, when the elastic coefficient of the opening / closing part 165 of the channel decreases, the opening / closing part 165 of the channel can open more easily. If the coefficient of elasticity of the opening / closing part 165 of the channel becomes higher, the opening / closing part 165 of the channel can open, if only a high vacuum is created inside the chamber.

Therefore, the material for the opening / closing part 165 of the channel must be properly selected in accordance with the operating parameters of the electric motor, the cross-sectional area of the additional air channel and the like.

For the specified configuration of the vacuum cleaner when cleaning the carpeted floor, the roller 163e of the second lever 163b is pressed against the carpet so that the hole 161 for supplying external air is closed by the shutter 162a. In this case, the suction force in the first air inlet 120 increases and the rotation speed of the sweeping device 130 increases.

In addition, if a high vacuum is created inside the chamber 113 due to the carpet blocking the first air inlet 120, the opening / closing part 165 of the channel is bent inward of the chamber 113 in order to open the additional air inlet 164b.

Therefore, outside air enters the chamber 113 to rotate the rotary turbine 140, and the rotational power of the rotary turbine is transmitted to the sweeping device 130 through a belt 142, which rotates the sweeping device 130. Then, particles from the carpet are sucked into the first air inlet 120.

The operation of a vacuum cleaner equipped with a suction nozzle 100 of the specified configuration in accordance with the present invention is described below.

First of all, when external power is supplied to the vacuum chamber, the electric motor and fan provided in the vacuum cleaner body rotate and generate a suction force. External air enters the suction nozzle 100 under the action of the suction force.

Moreover, if the suction nozzle 100 is separated from the floor to be cleaned, the air entering through the first air inlet 120 and the outdoor air inlet 115 passes through the second air inlet 150 and the external air inlet 161, respectively, so that the flow and current velocity of the air entering the second air inlet 150 are reduced. Therefore, the sweeping device 130 driven by the rotational turbine 140 rotates at a low rotational speed.

Then, when the suction nozzle 100 is on the floor to be cleaned, the roller 163e of the second lever 163b is pressed against the floor and pivots upward, being located in the center of the bent portion 163c of the second lever 163b.

When one end of the second arm extending upward in the center of the bent portion 163c rotates the first arm 163a in the direction of the outdoor air inlet 161, the shutter 163 reduces the opening degree of the outdoor air inlet 161. Therefore, the flow and current velocity of the air coming from the first air inlet 120, which passes through the second air inlet 150, increase.

Accordingly, the rotational speeds of the rotary turbine 140 and the sweeping device 130 are increased, and thereby the efficiency of separating particles from the floor is increased.

In this way, the contaminated air entering through the first air inlet 120 passes through the chamber 113, is directed to the dust collector 210 of the vacuum cleaner body through the connecting pipe 300, and then discharged outward through the wheel blower 221. In this case, particles from the polluted air are removed by means of a dust collector 210.

In this case, the rotation speed of the sweeping device 130 and the suction efficiency of the particles of the first air inlet opening 120 reach their maximum values, respectively, if the opening 161 for supplying external air is completely closed.

Meanwhile, when cleaning the carpeted floor with a vacuum cleaner, the flow of air entering the chamber 113 decreases if the opening 161 for supplying outside air is closed by the shutter 162a, and if the first air inlet opening 120 is blocked by the carpet.

If the internal pressure in the chamber 113 becomes equal to a predetermined pressure or less, the opening / closing part 165 of the additional air channel 164 is opened to direct outside air into the chamber 113. Air directed to the chamber 113 rotates the rotary turbine 140.

Therefore, the rotation speed of the sweeping device 130 is increased, which facilitates the absorption of particles from the carpet into the first air inlet 120 and prevents overloading of the electric motor.

In the case of separating the suction nozzle from the floor to clean another place, the hole 161 for supplying external air is fully opened and the flow and current speed of the air drawn into the second air intake hole 150 are reduced.

Therefore, the rotation speed of the sweeping device 130, as well as the suction force and noise emitted by the suction nozzle, are reduced.

Thus, the present invention describes the following effects or advantages.

First of all, since the rotation speed of the sweeping device changes, the present invention improves the efficiency of the cleaning operation.

Secondly, if the suction nozzle is pressed to the floor, the rotation speed of the sweeping device increases. If the suction nozzle is separated from the floor, the rotation speed of the sweeping device is reduced. The rotation speed of the sweeping device changes in accordance with the state of the floor on which the suction nozzle is located. Therefore, the present invention improves the efficiency of separating dust from the floor.

Thirdly, if the suction nozzle is separated from the floor, to carry the vacuum cleaner, the sweeping device rotates with low power at low speed. Therefore, the present invention prevents damage to the user's hands by the sweeping device.

Fourth, if the suction nozzle is separated from the floor when changing the place to be cleaned, the flow and current speed of the air entering the first air inlet are reduced and the noise of air intake is reduced.

Finally, if the suction nozzle is separated from the floor when moving the vacuum cleaner, the suction force of the suction nozzle is reduced. Therefore, when the user holds the suction nozzle to move to another place to be cleaned, the present invention does not suck the user's clothes, curtains and the like into the suction nozzle.

Those skilled in the art will understand that various modifications and changes are possible in the present invention without departing from the spirit and scope of the invention. Thus, modifications and changes should be considered as falling within the scope of the present invention defined by the appended claims and their equivalents.

Claims (20)

1. A suction nozzle of a vacuum cleaner comprising a nozzle body, a first air inlet opening provided in a lower portion of the nozzle body for suctioning dust containing air by a suction force generated when the suction device is started, a sweeping device mounted to rotate in the first air inlet for dust from the floor and a device for adjusting the speed, including a device for adjusting the air flow installed in the nozzle body for changing the speed the rotation axis of the sweeping device by regulating the flow of air introduced into the first air inlet, the device for adjusting the air flow contains a hole for supplying external air through which external air flows through one side of the nozzle body, and a disconnecting device that controls the degree of opening of the hole for supplying outside air, for regulating the flow of air passing through the first air inlet opening, the opening device there is a damper opening / closing the hole for supplying outside air and a lever device connected to the damper for regulating the damper, the lever device increasing the flow of air drawn into the first air inlet to increase the rotation speed of the sweeping device if the sweeping device is pressed to the floor while lowering the nozzle body to the floor. 2. The suction nozzle according to claim 1, in which the lever device reduces the flow of air drawn into the first air intake opening to reduce the rotation speed of the sweeping device if the nozzle body is separated from the floor. 3. The suction nozzle according to claim 1, in which the device for adjusting the speed changes the speed of rotation of the sweeping device in accordance with the state of the floor on which the nozzle body is located. 4. The suction nozzle according to claim 1, in which the device for adjusting the speed comprises a rotating turbine provided in the air channel formed in the nozzle body for rotating the sweeping device and driven by the flow of air entering through the first air inlet. 5. The suction nozzle according to claim 4, in which the device for adjusting the air flow comprises a chamber provided in the air channel of the nozzle body adjacent to the hole for supplying external air and accommodating a rotating turbine. 6. The suction nozzle according to claim 5, in which the chamber contains a second air inlet through which air entering through the first air inlet passes, and the rotating turbine is driven by air introduced through the second air inlet. 7. The suction nozzle according to claim 1 or 2, in which the lever device comprises a first lever connected at one end to the shutter, and the other end connected movably to the axis of rotation provided in the nozzle body, and a second lever at which one end is made in this way that can put pressure on the first lever, and the other end is made in such a way that it protrudes from the bottom of the brush body and can be pressed against the floor. 8. The suction nozzle according to claim 7, in which the first lever is elastically supported by the first spring and in which the first spring moves the flap in the direction of opening the hole for supplying external air. 9. The suction nozzle according to claim 7, in which a predetermined position between both ends of the second lever is rotatably connected to the lower part of the nozzle body. 10. The suction nozzle according to claim 7, in which an indicator window is provided on the upper side of the nozzle body to check the degree of opening of the opening for supplying external air. 11. The suction nozzle according to claim 7, in which the second lever moves the flap connected to the first lever to a position near the hole for supplying external air. 12. The suction nozzle according to claim 5, in which the shutter completely closes the hole for supplying external air under the action of a suction force in the chamber in a position near the hole for supplying external air. 13. The suction nozzle according to claim 5, in which the device for adjusting the air flow further comprises an additional air channel directing outside air into the chamber for driving the rotating turbine, and an opening / closing part of the channel selectively opening the additional air channel to prevent blocking of the air channel. 14. The suction nozzle according to item 13, in which the opening / closing part of the channel contains an elastic element open / close as a result of the difference between the pressure in the chamber and atmospheric pressure outside the nozzle body. 15. A vacuum cleaner comprising a vacuum cleaner body, equipped with a dust collector collecting dust by separating dust, and a suction nozzle communicating with the vacuum cleaner dust collector and moving along the floor to suck in air containing dust that contains the nozzle body, a first air inlet opening provided in a lower part of the body nozzles for suctioning dust-containing air by means of a suction force generated when the suction device is started, a sweeping device configured to rotate in ohm air inlet hole for sweeping dust from the floor, and a speed adjusting device including an air flow adjusting device mounted in a nozzle body for changing a rotational speed of the sweeping device by controlling the air flow introduced into the first air intake opening, wherein the adjustment device the air stream contains a hole for supplying external air, through which external air flows through one side of the nozzle body and opens a control device that controls the degree of opening of the opening for supplying external air, for regulating the flow of air passing through the first air intake opening, the disconnecting device comprising a shutter opening / closing the opening for supplying external air, and a lever device connected to the shutter for regulating the shutter, moreover, the lever device increases the flow of air drawn into the first air inlet to increase the rotation speed of the sweeping device, if I notice its structure is pressed to the floor by lowering the nozzle body on the floor. 16. The vacuum cleaner according to clause 15, in which the device for adjusting the speed contains a rotating turbine provided in the air channel formed in the brush body for rotating the sweeping device and driven by the flow of air entering through the first air inlet. 17. The vacuum cleaner according to clause 16, in which the device for adjusting the air flow comprises a chamber provided in the air channel of the nozzle body adjacent to the hole for supplying external air and accommodating a rotating turbine, an additional air channel directing the external air into the chamber for driving a rotating turbine, and an opening / closing part of the channel selectively opening an additional air channel to prevent blocking of the air channel. 18. The vacuum cleaner according to claim 17, wherein the chamber comprises a second air inlet through which air coming from the first air inlet passes, the rotary turbine being driven by air introduced through the second air inlet. 19. The vacuum cleaner according to clause 15, in which the lever device comprises a first lever connected at one end to the damper, and the other end is movably connected to the axis of rotation provided in the nozzle body, the second lever, in which one end is made so that it affects on the first lever, and the other end is made in such a way that it protrudes from the bottom of the nozzle body and can be pressed against the floor, and the first spring, elastically supporting the first lever, to move the shutter in the direction of opening the hole for external of air. 20. The vacuum cleaner according to claim 19, in which the second lever moves the shutter connected to the first lever to a position near the hole for supplying external air.

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