KR20210026857A - A vacuum cleaner - Google Patents

Abstract

A vacuum cleaner of the present invention includes: a cleaner main body having a suction motor inside, a dust container provided at a lower side of the suction motor, and a handle at the outside; a suction nozzle connected to the cleaner main body; an extension pipe connecting the cleaner main body and the suction nozzle; and a ground wire made of a conductive material with one end positioned on the inner side of the dust container and the other end positioned on the outside of the dust container to discharge static electricity of the dust container to the outside of the dust container.

Description

A vacuum cleaner

The present invention relates to a vacuum cleaner capable of preventing static electricity generated in a dust bin of a vacuum cleaner from being transmitted to a user.

A vacuum cleaner refers to a device that sucks dust and air by using a suction force generated by a suction motor installed inside the cleaner body, and separates and collects dust from the air.

These vacuum cleaners are classified into canister cleaners, upright cleaners, stick cleaners, handy cleaners, and robot cleaners. In the case of the canister cleaner, a suction nozzle for sucking dust is provided separately from the cleaner body, and the cleaner body and the suction nozzle are connected to each other by a connecting device. In the case of the upright cleaner, the suction nozzle is rotatably connected to the cleaner body. In the case of stick vacuum cleaners and handy vacuum cleaners, the user is used while holding the vacuum cleaner body by hand. However, in the case of a stick cleaner, the suction motor is disposed close to the suction nozzle (load center), and in the case of the handy cleaner, the suction motor is disposed close to the gripping part (upper center). The robot vacuum cleaner performs self-cleaning while driving itself through an autonomous driving system.

The suction nozzle refers to the part that touches the floor and directly inhales dust and air. The suction power generated by the suction motor installed inside the cleaner body is transmitted to the suction motor, and by this suction power, dust and air are sucked into the suction nozzle.

A rotary cleaning unit (or agitator) is installed on the suction nozzle. The rotary cleaner rotates and scrapes off dust from the floor or carpet to improve cleaning performance. A brush is attached to the rotating cleaning unit, which causes friction with the floor or carpet.

When the brush causes friction with the floor, static electricity is naturally generated by friction. In particular, if the brush causes friction with the carpet, the frequency of static electricity is even higher.

As described above, when a vacuum cleaner is used, the agitator rotating in the suction nozzle sucks dust and is charged by friction, and the sucked dust is stored in the dust bin.

As described above, as charged dust is stored in the dust bin, static electricity is accumulated in the dust bin, and the accumulated static electricity is discharged by the user's hand, causing a problem that static electricity is generated in the user's hand when the user holds the handle .

Therefore, it is necessary to cancel out the static electricity stored in the dust bin by discharging it in advance so that the static electricity stored in the dust bin is not transmitted to the user.

Korean Patent Application Publication No. 10-2012-0027357 (2012.03.21.)

An object of the present invention is to propose a vacuum cleaner having a structure capable of preventing static electricity from being transmitted to a user by grounding the static electricity charged in a dust bin in which sucked dust is stored to the outside of the dust bin.

Another object of the present invention is to propose a vacuum cleaner having a structure capable of preventing the static electricity generated by the rotation of the rotary cleaning unit from being transmitted to the user.

Another object of the present invention is to provide a vacuum cleaner having a configuration capable of improving the reliability of an antistatic structure.

The vacuum cleaner of the present invention includes a suction motor on the inside, a dust bin on the lower side of the suction motor, a cleaner body having a handle on the outside, a suction nozzle connected to the cleaner body, the cleaner body and the suction It includes an extension tube connecting the nozzles.

In addition, one end is located on the inner surface of the dust bin, the other end is located on the outside of the dust bin, and includes a ground wire made of a conductive material for discharging static electricity from the dust bin to the outside of the dust bin.

In addition, the other side of the ground line is positioned at the suction nozzle side via the extension tube, and static electricity of the dust bin is discharged to the bottom surface through the ground line.

In addition, the other side of the ground wire is located on a rear wheel provided in the suction nozzle.

In addition, the other side of the ground wire is connected to the rotation shaft of the rear wheel, and the rear wheel is made of a conductive material, one side is connected to the rotation shaft, and the other side passes through the rear wheel and is exposed to the outer surface of the rear wheel. Includes a second ground line.

The rotation shaft of the rear wheel is made of a metal material.

The suction nozzle is provided in the housing in which at least a portion of the front is opened, and at least a portion of the housing is exposed through the opened portion of the housing, and a rotating cleaning unit is formed to clean the floor surface by a rotating operation. Includes.

The other side of the ground wire is exposed to the outside of the rotary cleaning unit and contacts the bottom surface.

The rotary cleaning unit includes a cylindrical nozzle body rotatably installed inside the housing, and fibrous hair and metal hair disposed on an outer circumferential surface of the nozzle body.

The other side of the ground wire is connected to the metal wool.

The metal hair includes a fiber hair and a conductive coating layer coated on the outer circumferential surface of the fiber hair.

The conductive coating layer is formed of brass or digenite (Cu9S5).

The nozzle body is formed of an extruded product made of a metal material.

The other side of the ground wire is connected to the PCB substrate provided in the cleaner body, and static electricity of the dust bin is discharged from the PCB substrate through the ground wire.

The PCB substrate is provided with a resistance means connected to the other side of the ground line so as to discharge static electricity from the ground line.

A bidirectional Zener diode is mounted on the PCB substrate.

The dust bin is formed of a cylindrical body, and one side of the ground wire is attached to the inside of the dust bin in parallel with the longitudinal direction of the dust bin.

A conductive tape is attached to the inner surface of the dust bin so that at least a portion of the ground wire overlaps.

The conductive tape includes a vertical portion attached in a direction parallel to the ground line, and a horizontal portion at least partially overlapping the vertical portion and attached along an inner circumferential surface of the dust bin.

According to the present invention having the above configuration, static electricity generated in the dust bin in which charged dust accumulates while being sucked is discharged to the outside of the dust bin, so that static electricity in the dust bin is not transmitted to the user, thereby solving the inconvenience felt by the user. There is an advantage.

In addition, there is an advantage of preventing the PCB adjacent to the dust bin from being damaged by static electricity accumulated in the dust bin.

In addition, there is an advantage of preventing static electricity from being transmitted to the user by discharging static electricity generated from the fiber hair included in the rotating cleaning unit through the metal wool.

1 is a perspective view of a vacuum cleaner according to an embodiment of the present invention.
FIG. 2 is a cross-sectional view of a suction nozzle taken along line I-I' of FIG. 1.
3 is a view showing a state in which the side cover of the suction nozzle is removed.
4 is an exploded perspective view of a driving unit.
6 is a perspective view of a vacuum cleaner according to another embodiment of the present invention.
7 is a cross-sectional view of a connection portion of a rear wheel of a suction nozzle.
8 is a perspective view of a vacuum cleaner according to another embodiment of the present invention.
9 is a cross-sectional view of a rotary cleaning unit of a suction nozzle.
10 is a perspective view of a vacuum cleaner according to another embodiment of the present invention.
11 is a view as viewed from the side of the main body of the cleaner.
12 is a cross-sectional view of the dust container.
13 is a view as viewed from the radial direction of the inner surface of the dust bin.

Hereinafter, some embodiments of the present invention will be described in detail through exemplary drawings. In adding reference numerals to elements of each drawing, it should be noted that the same elements are assigned the same numerals as possible, even if they are indicated on different drawings. In addition, in describing an embodiment of the present invention, when it is determined that a detailed description of a related known configuration or function interferes with an understanding of an embodiment of the present invention, the detailed description thereof will be omitted.

In addition, in describing the constituent elements of the embodiment of the present invention, terms such as first, second, A, B, (a), and (b) may be used. These terms are for distinguishing the constituent element from other constituent elements, and the nature, order, or order of the constituent element is not limited by the term. When a component is described as being "connected", "coupled" or "connected" to another component, the component may be directly connected or connected to that other component, but another component between each component It should be understood that may be “connected”, “coupled” or “connected”.

1 is a perspective view of a vacuum cleaner according to an embodiment of the present invention.

Referring to FIG. 1, a vacuum cleaner 1 according to an embodiment of the present invention sucks air containing dust and a cleaner body 10 having a suction motor (not shown) therein for generating a suction force. It may include a suction nozzle 100 and an extension pipe 17 connecting the cleaner body 10 and the suction nozzle 100.

Meanwhile, although not shown, the suction nozzle 100 may be directly connected to the cleaner body 10 without the extension pipe 17.

The cleaner body 10 may include a dust bin 200 in which dust separated from air is stored. Accordingly, dust introduced through the suction nozzle 100 may be stored in the dust bin 200 through the extension pipe 17.

A handle 13 for gripping by a user may be provided outside the cleaner body 10. The user may perform cleaning while holding the handle 13.

The cleaner body 10 may be provided with a battery (not shown), and the cleaner body 10 may be provided with a battery accommodating portion 15 in which the battery (not shown) is accommodated. The battery accommodating part 15 may be provided under the handle 13. The battery (not shown) may be connected to the suction nozzle 100 to supply power to the suction nozzle 100.

When using the cleaner configured as described above, the rotary cleaning unit 130 rotating in the suction nozzle 100 sucks dust and is charged by friction, and the sucked dust is stored in the dust bin 200.

In addition, as the dust charged as described above is stored in the dust container 200, static electricity is accumulated in the dust container 200.

In addition, when the user holds the handle 13, static electricity stored in the dust bin 200 is discharged by the user's hand, and there is an inconvenience that static electricity is generated in the user's hand.

As the static electricity accumulated in the dust bin 200 is transferred to the user's hand through the handle 13 as described above, in order to eliminate the inconvenience of generating static electricity in the user's hand, the static electricity accumulated in the dust bin 200 is discharged in advance. And need to be offset.

In the case of the present invention, in order to eliminate static electricity accumulated in the dust bin 200, various discharge structures are proposed.

For example, by connecting the dust bin 200 and the suction nozzle 100 with a separate ground line, static electricity accumulated in the dust bin 200 is transferred through the rotation cleaning unit 130 of the suction nozzle 100, and the rotation cleaning unit 130 It can be discharged to the bottom surface in contact with.

As another example, by connecting the dust bin 200 and the suction nozzle 100 with a separate ground line, static electricity accumulated in the dust bin 200 is transferred through the rear wheel 118 of the suction nozzle 100, and the rear wheel 118 It can be discharged to the bottom surface in contact with.

As another example, by connecting the dust bin 200 and the PCB 300 of the cleaner body 10 with a separate ground line, static electricity accumulated in the dust bin 200 may be discharged through the PCB 300.

For reference, the PCB 300 may be disposed on the upper side of the handle 13 provided for gripping on one side of the cleaner body 10.

According to this, as the static electricity accumulated in the dust bin 200 is discharged by the user's hand, the static electricity accumulated in the dust bin 200 is discharged and canceled out before the user feels the static electricity. When holding the handle, the discomfort caused by static electricity can be prevented.

Hereinafter, the suction nozzle 100 will be described in detail.

FIG. 2 is a cross-sectional view of a suction nozzle taken along line I-I' of FIG. 1.

1 to 2, the suction nozzle 100 includes a housing 110, a connection pipe 120, and a rotation cleaning unit 130.

The housing 110 includes a body part 111 in which chambers 112a and 112b are formed. A front opening 111a for sucking air containing contaminants may be formed in the main body 111. Air introduced through the front opening 111a due to the suction force generated from the cleaner body 10 may move to the connection pipe 120 through the chambers 112a and 112b.

The front opening 111a is formed to extend in the left and right direction of the housing 110 and may be formed to extend to a front portion of the housing 110 as well as a bottom portion of the housing 110. Accordingly, since the suction area can be sufficiently secured, it is possible to clean evenly from the bottom surface to the portion adjacent to the wall surface.

The housing 110 may further include an internal pipe 1112 communicating with the front opening 111a. Due to the suction force generated by the cleaner body 10, external air may move to the inner flow path 1112a of the inner pipe 1112 through the front opening 111a.

The rotary cleaning unit 130 may be accommodated in the chamber 112a of the main body 111. At least a portion of the rotary cleaning unit 130 may be exposed to the outside through the front opening 111a. The outer circumferential surface of the rotary cleaning unit 130 may be made of a fabric or felt material such as jung (絨). Accordingly, foreign substances such as dust accumulated on the floor surface when the rotary cleaning unit 130 is rotated can be effectively removed by being trapped on the outer peripheral surface of the rotary cleaning unit 130.

The body part 111 may cover at least a part of the upper side of the rotation cleaning part 130. In addition, the inner circumferential surface of the main body 111 may have a curved shape to correspond to the outer circumferential shape of the rotary cleaning unit 130. Accordingly, the main body 111 may perform a function of preventing the rise of foreign matters removed from the floor by rotating the rotary cleaning unit 130.

The rotation cleaning unit 130 may rotate in a counterclockwise direction based on the cross-sectional view of FIG. 2. That is, the rotation cleaning unit 130 rotates so as to push it in the direction of the inner pipe 1112 at a point of contact with the bottom surface. Accordingly, the foreign matter removed from the bottom surface of the rotary cleaning unit 130 is moved toward the inner pipe 1112 and is sucked into the inner pipe 1112 by a suction force. Cleaning efficiency may be improved by rotating the rotary cleaning unit 130 backward based on a contact point with the floor surface.

A partition member 160 may be provided in the chamber 112. The partition member 160 may be formed to extend from an upper side to a lower side of the chamber of the housing 110.

The partition member 160 may be provided between the rotary cleaning unit 130 and the inner pipe 1112. Accordingly, the partition member 160 moves the chamber of the housing 110 into a first region 112a in which the rotation cleaning unit 130 is provided and a second region 112b in which the inner pipe 1112 is provided. Can be divided. As shown in FIG. 2, the first region 112a may be provided at a front part of the chamber 212, and the second region 112b may be provided at a rear part of the chamber 212.

Meanwhile, the connection pipe 120 may connect the housing 110 and the extension pipe 17 (see FIG. 1 ). That is, one side of the connection pipe 120 is connected to the housing 110, and the other side of the connection pipe 120 is connected to the extension pipe 17.

The connection pipe 120 may be rotatably connected to the housing 110.

Meanwhile, the suction nozzle 100 may further include a rear wheel 118. The rear wheel 118 is rotatably provided on the bottom surface of the housing 110 and may be disposed behind the rotation cleaning unit 130.

3 is a view showing a state in which the side cover of the suction nozzle is removed, and FIG. 4 is an exploded perspective view of the driving unit.

Hereinafter, a detailed configuration of the driving unit 140 will be described.

A driving unit 140 for rotating the rotary cleaning unit 130 is coupled to the main body 111 of the housing 110. At least a portion of the driving unit 140 may be inserted into one side of the rotary cleaning unit 130.

The driving unit 140 includes a motor 143 and a motor supporter 141 for generating a driving force. The motor 143 may include a BLDC motor. A motor PCB 1432 for controlling the motor 143 may be provided at one side of the motor 143

The motor 143 may be coupled to the motor supporter 141 by a fastening member such as a bolt. A fastening hole 1434 for fastening bolts to the motor supporter 141 may be formed in the motor 143. Further, the motor supporter 141 may also have a fastening hole 1414 for fastening the motor 143 and the bolt.

The fastening holes 1414 and 1434 may be fastened with bolts 150.

The driving unit 140 may further include a gear unit 145 for transmitting the power of the motor 143.

The motor 143 may be inserted into the gear unit 145. To this end, a hollow may be formed inside the gear part 145. The gear part 145 may be bolted to the motor supporter 141, and for this purpose, a fastening hole 1454 may be formed at one side of the gear part 145. By fastening the gear part 145 and the motor 143 to the motor supporter 141 using a bolt 150, it is possible to reduce the occurrence of vibration during the operation of the motor 143.

The motor supporter 141 may be made of a polycarbonate material. Polycarbonate material is characterized by high insulation and impact resistance. Accordingly, the motor supporter 141 is strong against external shocks, and it is possible to reduce transmission of static electricity generated from the outside to the motor 143.

The driving part 140 may further include a cover part 147 surrounding the gear part 145. The cover part 147 has a function of protecting the gear part 145.

Hereinafter, a structure capable of preventing the static electricity stored in the dust bin 200 from being transmitted to the user will be described.

5 is a conceptual diagram showing an example of the rotary cleaning unit 130.

The rotary cleaning unit 130 includes a nozzle body 131, a fiber layer 134, a fiber hair 132, and a metal hair 133.

The nozzle body 131 has a hollow cylindrical shape. The hollow of the nozzle body 131 is formed along the rotation axis direction of the rotation cleaning unit 130.

The nozzle body 131 is rotatably installed inside the housing 110. The nozzle body 131 includes at least one protrusion 131a and 131b on an inner circumferential surface. When the rotary cleaning unit 130 is installed inside the housing, the protrusions 131a and 131b of the nozzle body 131 are engaged with the driving unit 140 (see FIG. 4). Accordingly, the nozzle body 131 may receive rotational driving force from the driving unit.

The nozzle body 131 may be formed of a metal (extrusion molding) or plastic (injection molding) material.

The fibrous layer 134 is formed to surround the outer peripheral surface of the nozzle body 131. However, depending on the design, the rotary cleaning unit 130 may not include the fiber layer 134, and in this case, the fiber hair 132 and the metal hair 133 may be directly coupled to the outer circumferential surface of the nozzle body 131. .

The fibrous hair 132 and the metal hair 133 are disposed on the outer circumferential surface of the nozzle body 131. The metal hair 133 is an organic conductive fiber. The fibrous hair 132 and the metallic hair 133 may be coupled to the nozzle body 131 or to the fibrous layer 134.

When the nozzle body 131 is rotated by the rotational driving force transmitted from the driving unit, the fibrous hair 132 and the metal hair 133 rotate together with the nozzle body 131. The fibrous hair 132 and the metal hair 133 collide with the floor or carpet to remove debris, dust, etc. existing on the floor or carpet.

When the rotary cleaning unit 130 rotates, the fibrous hair 132 and the floor (or carpet) to be cleaned collide with each other, and static electricity due to friction is generated in the process.

When the metal hair 133 is provided in the rotary cleaning unit 130 as in the present invention, since the metal hair 133 has conductivity, static electricity generated by the fiber hair 132 is discharged through the metal hair 133 or anti-static. Can be. Since the metal hair 133 serves as a charging passage connected to the floor or carpet, or acts as an antistatic, it is possible to prevent static electricity from being transmitted to the user.

The metal hair 133 may include a fiber hair and a conductive coating layer coated on the outer circumferential surface of the fiber hair.

In addition, the conductive coating layer may be formed of brass or digenite (Cu9S5).

On the other hand, even when the metal hair 133 is not provided or the metal hair 133 is provided, some static electricity is inevitably stored in the dust bin.

As described above, the static electricity accumulated in the dust bin 200 needs to be discharged and canceled.

6 is a perspective view of a vacuum cleaner according to another embodiment of the present invention, and FIG. 7 is a cross-sectional view of a connection portion of a rear wheel of a suction nozzle.

For reference, FIG. 7 may be understood as an enlarged view of area “A” of FIG. 2.

6 to 7, in the vacuum cleaner, an extension pipe 17 connecting the cleaner body 10 and the suction nozzle 100 and one end thereof are located on the inner side of the dust container 200, and the other side An end portion may include a ground wire 400 made of a conductive material that is located outside the dust container 200 and discharges static electricity from the dust container 200 to the outside of the dust container 200.

For example, the ground wire 400 may be formed of various materials including brass.

The ground wire 400 may pass through the inner side of the extension tube 17 or may pass through the outer side of the extension tube 17. The ground wire 400 may be passed through the extension pipe 17 in a buried manner.

In addition, one side of the extension pipe 17 and one side of the cleaner body 10 may be detachably connected. In addition, a ground terminal may be formed at a portion in contact with one side of the extension pipe 17 and one side of the cleaner body 10. In addition, the ground wire 400 has one side located inside the dust bin 200, the other side connected to the main ground wire connected to the ground terminal of the cleaning machine body 10, and one side connected to the ground terminal of the extension tube 17 And, the other side may include an auxiliary ground line positioned on the suction nozzle (100).

In addition, a plurality of ground wires 400 may be provided in a form capable of being separated and combined.

On the other hand, the other end of the ground wire 400, one side of which is located inside the dust bin 200, is located on the side of the suction nozzle 100 via the extension pipe 17, and the static electricity of the dust bin 200 May be discharged to the bottom surface F through the ground line 400.

For example, the other end of the ground wire 400 may be connected to the rear wheel 118 of the suction nozzle 100 after passing through the extension pipe 17. Accordingly, static electricity accumulated in the dust bin 200 may be discharged to the bottom surface F in contact with the rear wheel 118 through the ground line 400 and the rear wheel 118 of the suction nozzle 100.

The rear wheel 118 includes a rotation shaft 118a. The rear wheel 118 rotates around a rotation shaft 118a.

In addition, the rotation shaft 118a may be formed of a conductive metal material. The other end of the ground wire 400 may be connected to the rotation shaft 118a.

The rear wheel 118 has one side connected to the rotation shaft 118a, the other side passing through the rear wheel 118, and a second grounding line 118b made of a conductive material exposed to the outer surface of the rear wheel 118 It may include.

The second ground line 118b may be disposed radially with respect to the rotation shaft 118a.

Accordingly, static electricity of the dust bin 200 may be charged to the bottom surface F in contact with the second ground line 118b through the ground line 400, the rotation shaft 118a, and the second ground line 118b. .

Meanwhile, the other end of the ground wire 400 may be rotatably connected to the rotation shaft 118a.

Outside of the rotation shaft 118a, a rotation ring (not shown) made of a metal material that idles while in contact with the rotation shaft 118a is fitted, and the other end of the ground wire 400 is connected to the rotation ring (not shown). I can.

Accordingly, when the rotation shaft 118a rotates, the problem of the ground wire 400 being tangled or wound on the rotation shaft 118a can be solved.

In this case, the static electricity of the dust bin 200 is a bottom surface in contact with the second ground line 118b through the ground line 400, the rotation ring (not shown), the rotation shaft 118a, and the second ground line 118b. Can be charged with (F).

8 is a perspective view of a vacuum cleaner according to another embodiment of the present invention, and FIG. 9 is a cross-sectional view of a rotary cleaning unit of a suction nozzle.

8 to 9, one end of the ground line 400 is located inside the dust bin 200, and the other end is through the inside or outside of the extension pipe 17, and the suction nozzle 100 ) May be connected to the rotary cleaning unit 130. Accordingly, static electricity accumulated in the dust bin 200 may be discharged to the bottom surface F in contact with the rotary cleaning unit 130 through the ground wire 400 and the rotary cleaning unit 130 of the suction nozzle 100.

For example, the other end of the ground wire 400 may be exposed to the outside of the nozzle body 131 after passing through the nozzle body 131 of the rotary cleaning unit 130 to directly contact the bottom surface F. have.

As another example, the other end of the ground wire 400 may be connected to the nozzle body 131 of the rotary cleaning unit 130.

In this case, the rotation cleaning unit 130 includes a nozzle body 131. Fiber hair 132 and metal hair 133 are disposed outside the nozzle body 131.

The metal hair 133 may be disposed radially with respect to the nozzle body 131.

In addition, the nozzle body 131 may be formed of a conductive metal material. The other end of the ground line 400 may be connected to the nozzle body 131.

Accordingly, static electricity of the dust bin 200 may be charged to the bottom surface F in contact with the metal hair 133 through the ground wire 400, the nozzle body 131, and the metal hair 133.

Meanwhile, the other end of the ground line 400 may be connected to the nozzle body 131 through a bolt 150 (see FIG. 4) for fastening the driving unit 140.

For example, by connecting the other end of the ground wire 400 to the bolt 150 (see FIG. 4), and extending the length of the bolt 150 (see FIG. 4), The end may contact the nozzle body 131 or the metal hair 133. Accordingly, static electricity of the ground line 400 may be charged to the bottom surface F through the bolt 150 (see FIG. 4 ), the nozzle body 131 and/or the metal hair 133.

As another example, the other end of the ground line 400 is connected to the bolt 150 (see FIG. 4), and the end of the bolt 150 (see FIG. 4) is through a separate third ground line (not shown), It may be connected to the nozzle body 131. According to this, static electricity of the ground line 400 may be charged to the bottom surface F through the bolt 150 (see FIG. 4), the third ground line (not shown), the nozzle body 131, and the metal hair 133. have.

10 is a perspective view of a vacuum cleaner according to another embodiment of the present invention.

Referring to FIG. 10, the other end of the ground line 400 is connected to the PCB substrate 300 provided in the cleaner body 10, and static electricity of the dust bin 200 is transmitted through the ground line 400. It is discharged from the PCB substrate 300.

The PCB substrate 300 may be provided with a resistance means (not shown) connected to the other side of the ground line 400 so as to discharge static electricity from the ground line 400.

In addition, a bidirectional Zener diode may be mounted on the PCB substrate 300.

For example, the PCB substrate 300 may be provided on the upper side of the cleaner body 10. In this case, the ground wire 400 may be connected to the PCB substrate 300 provided on the upper side of the cleaner body 10 without passing through the extension tube 17.

As another example, the ground wire 400 may be connected to the PCB 1432 of the driving unit 140 after one end of the ground wire 400 is located inside the dust bin 200 and the other end of the ground wire 400 passes through the extension pipe 17.

In this case, a discharge circuit is provided on the PCB substrate 300 or the PCB 1432.

Accordingly, static electricity of the dust bin 200 is induced to the PCB substrate 300 or the PCB 1432 through the ground line 400, and may be discharged from the PCB substrate 300 or the PCB 1432.

According to this, as the static electricity accumulated in the dust bin 200 is discharged by the user's hand, the static electricity accumulated in the dust bin 200 is discharged and canceled out before the user feels the static electricity. When holding the handle, the discomfort caused by static electricity can be prevented.

11 is a view of the main body of the cleaner as viewed from the side. 12 is a cross-sectional view of the dust container. 13 is a view of the inner surface of the dust container as viewed from the inner center of the dust container.

11 to 13, the dust container 200 is formed of a cylindrical body, and one end of the ground wire 400 is parallel to the longitudinal direction of the dust container 200 (in the vertical direction based on FIG. 13). 200) can be attached to the inside.

In general, a cylindrical inner space 201 is formed inside the dust bin 200.

In addition, a cyclone part and a filter part are disposed in the inner space 201.

In addition, when the cleaner is operated, a circular flow is generated in the inner space 201 along the inner surface 202 of the dust container 200.

Further, dust, foreign matter, etc. in the dust bin 200 are also rotated in a circular shape along the inner surface 202 of the dust bin 200. In addition, while the dust rotates in the dust container 200, it may be discharged to the outside of the dust container 200 through the ground wire 400 attached to the inner surface 202 of the dust container 200.

The ground wire 400 may be fixed to the dust container 200 in various ways within a range that can protrude into the dust container 200.

The ground wire 400 may be fixed to the inner surface of the dust bin 200 through a separate means.

11 to 13, conductive tapes 410 and 420 may be attached to the inner surface of the dust bin 200 so that at least a portion of the ground wire 400 overlaps with each other.

The conductive tapes 410 and 420 may be formed of a carbon material.

In addition, the conductive tapes 410 and 420 have a vertical portion 410 attached in a direction parallel to the ground line 400, at least a portion of which overlaps the vertical portion 410, and the inner surface of the dust bin 200 ( It may include a horizontal portion 420 attached along the 202.

Therefore, when the cleaner is operated, while the dust rotates in the dust bin 200, it is discharged to the outside of the dust bin 200 through the conductive tapes 410 and 420 attached to the inner surface 202 of the dust bin 200 and the ground wire 400. I can.

In particular, since the vertical portion 410 is attached in the vertical direction (based on FIG. 16), and the horizontal portion 420 is attached in a horizontal direction (based on FIG. 16), dust and conductive tape ( The contact of the 410 and 420 may be made more reliably, and accordingly, static electricity of the dust stored in the dust bin 200 may be discharged more quickly and reliably.

In addition, the ground wire 400 may be fixed to the dust bin 200 in various ways within a range in which at least a portion of the ground wire 400 is exposed to the inner surface 202 of the dust bin 200.

The ground wire 400 may be coupled to the dust container 200 in a form in which at least a part of the inner surface 202 of the dust container 200 is buried.

In addition, the ground wire 400 may be coupled to the dust bin 200 by an insert method.

The vacuum cleaner described above is not limited to the configuration and method of the above-described embodiments, and the embodiments may be configured by selectively combining all or part of each of the embodiments so that various modifications may be made.

Claims (20)

A vacuum cleaner body having a suction motor on the inside, a dust bin on a lower side of the suction motor, and a handle on the outside; And
A suction nozzle connected to the cleaner body;
An extension pipe connecting the cleaner body and the suction nozzle;
A vacuum cleaner including a ground wire made of a conductive material having one end positioned on the inner surface of the dust bin and the other end positioned outside the dust bin, discharging static electricity from the dust bin to the outside of the dust bin. The method of claim 1,
The other side of the ground line is positioned at the suction nozzle side via the extension tube, and static electricity of the dust bin is discharged to the bottom surface through the ground line. The method of claim 1,
The other side of the ground wire is positioned on a rear wheel provided in the suction nozzle via the extension tube, and static electricity from the dust bin is discharged to the bottom surface through the ground wire and the rear wheel. The method of claim 3,
The other side of the ground wire is connected to the rotation shaft of the rear wheel, and the rear wheel has one side connected to the rotation shaft, and the other side passes through the rear wheel and is exposed to the outer surface of the rear wheel. Vacuum cleaner with ground wire. The method of claim 4,
The rotary shaft of the rear wheel is a vacuum cleaner made of a metal material. The method of claim 1,
The suction nozzle,
A housing in which at least a portion of the front is opened; And
A vacuum cleaner including a rotary cleaning unit installed inside the housing, at least partially exposed through the open portion of the housing, and configured to clean a floor surface by a rotary operation. The method of claim 6,
The other side of the ground wire is exposed to the outside of the rotary cleaning unit via the extension pipe, and is in contact with a bottom surface. The method of claim 6,
The rotary cleaning unit,
A cylindrical nozzle body rotatably installed inside the housing; And
A vacuum cleaner comprising fibrous wool and metal wool disposed on an outer circumferential surface of the nozzle body. The method of claim 8,
The other side of the ground wire is a vacuum cleaner connected to the metal wool. The method of claim 8,
The metal hair is,
Fibroblasts; And
A vacuum cleaner comprising a conductive coating layer coated on the outer circumferential surface of the fiber wool. The method of claim 10,
The conductive coating layer is a vacuum cleaner, characterized in that formed of brass (brass) or digenite (digenite, Cu ₉ S _{5 ).} The method of claim 6,
The nozzle body is a vacuum cleaner, characterized in that formed of an extruded product made of a metal material. The method of claim 1,
The other side of the ground wire is connected to a PCB substrate provided in the cleaner body, and static electricity of the dust bin is discharged from the PCB substrate through the ground wire. The method of claim 13,
The vacuum cleaner having a resistance means connected to the other side of the ground line so as to discharge static electricity from the ground line on the PCB substrate. The method of claim 13,
A vacuum cleaner in which a bi-directional Zener diode is mounted on the PCB substrate. The method of claim 13,
The PCB substrate is a vacuum cleaner disposed on an upper side of a handle provided for gripping on one side of the cleaner body. The method of claim 1,
The dust bin is formed of a cylindrical body, and one side of the ground wire is attached to the inside of the dust bin in parallel with the longitudinal direction of the dust bin. The method of claim 1,
A vacuum cleaner to which a conductive tape for fixing the ground wire to the inner surface of the dust bin is attached to an inner surface of the dust bin. The method of claim 18,
One side of the ground wire is attached to the inside of the dust bin in parallel with the length direction of the dust bin,
The conductive tape,
A vacuum cleaner including a vertical portion attached in a direction parallel to the ground line. The method of claim 19,
The conductive tape,
At least a portion of the vacuum cleaner overlapping the vertical portion and including a horizontal portion attached along the inner circumferential surface of the dust bin.

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