KR101282449B1 - Suction nozzle of vacuum cleaner - Google Patents

Abstract

The present invention relates to a suction nozzle of a vacuum cleaner, and more particularly, to a suction nozzle of a vacuum cleaner to adjust the rotation of the cleaning member according to the state of the surface to be cleaned.

The suction nozzle of the vacuum cleaner according to the present invention, the suction nozzle of the vacuum cleaner according to the present invention includes a main body rotatably provided with a cleaning member to facilitate cleaning of the surface to be cleaned therein; A rotating member rotated by the air sucked into the main body; A power transmission unit for transmitting the rotational power of the rotating member to the cleaning member; A rotation controller configured to adjust the flow of air so that the rotation of the rotation member is adjusted according to the state of the surface to be cleaned; And an operation lever connected to the rotation control unit to enable a user's operation.

According to such a structure, the rotation of the cleaning member which shakes off the foreign material of the to-be-cleaned surface can be adjusted by the adjustment means, and it becomes possible to perform appropriate cleaning according to the state of the to-be-cleaned surface.

Suction Nozzle, Cleaning Member, Rotation Adjustable

Description

Suction nozzle of vacuum cleaner

1 is an external perspective view of a vacuum cleaner suction nozzle according to the spirit of the present invention;

2 is an exploded perspective view of the suction nozzle;

3 is a perspective view of a state in which a predetermined portion of the partition constituting the suction nozzle is cut away;

4 is a perspective view of an operation lever according to the spirit of the present invention.

5 is a rear perspective view of the nozzle body in accordance with the teachings of the present invention.

Figure 6 is a rear perspective view of the rotation control unit according to the spirit of the present invention.

7 is a bottom perspective view of the suction nozzle;

FIG. 8 is a view showing an operating state of the suction nozzle when cleaning the surface to be cleaned such as a floor is performed. FIG.

9 is a view showing an operating state of the suction nozzle when performing cleaning of a surface to be cleaned such as a carpet.

<Explanation of symbols for the main parts of the drawings>

100: body 200: nozzle body

210: compartment 220: guide rib

230: cleaning member 240: rotating member

250: transmission belt 260: rotation control unit

280: operation lever 300: cover member

400: suction pipe

The present invention relates to a suction nozzle of a vacuum cleaner, and more particularly, to a suction nozzle of a vacuum cleaner to adjust the rotation of the cleaning member according to the state of the surface to be cleaned.

In general, a vacuum cleaner is a device that sucks air contained in a foreign material by using a vacuum pressure generated by a vacuum motor mounted inside the main body, and then filters the foreign material in the main body.

The vacuum cleaner is divided into a canister method in which a suction nozzle which sucks air containing foreign substances on the surface to be cleaned is provided separately from the main body and connected by a connecting pipe, and an upright method in which the suction nozzle is integrally formed with the main body. can do.

On the other hand, the canister vacuum cleaner includes a cleaner main body having a built-in vacuum motor for generating a suction force, a suction nozzle for suctioning foreign substances on the surface to be cleaned by the suction force generated by the cleaner main body, and a suction of the main body and the suction nozzle. It is configured to include an extension pipe and a connection hose.

The operation of the vacuum cleaner constituting the above-described configuration will be described briefly. When the power is applied to the cleaner body and the vacuum motor is driven, suction force is generated, and air containing foreign matter on the surface to be cleaned is sucked by the suction nozzle by the suction force. do.

And, the air containing the foreign material is introduced into the cleaner body through the extension tube and the connection hose. Then, the air containing the foreign matter sucked into the cleaner body flows therein, and the foreign matter is separated, and the separated foreign matter is stored in the cleaner body, and the separated air is discharged to the outside of the cleaner body.

By the way, the conventional suction nozzle is configured to simply suck the foreign material of the surface to be cleaned, there is no problem in performing the cleaning when cleaning the foreign material of the surface to be cleaned, such as the floor, but when cleaning the surface to be cleaned such as carpet Foreign matter adsorbed on the carpet is not easily removed, there is a problem that the cleaning is not made completely.

Therefore, in recent years, in order to make cleaning of the to-be-cleaned surface like a carpet easy, the suction nozzle is equipped with the agitator rotated by a rotating motor. The agitator functions to shake off the foreign matter adsorbed on the carpet while rotating, and is configured to operate together with the operation of the vacuum cleaner.

By the way, when the agitator is provided in the suction nozzle as described above, cleaning of the surface to be cleaned such as a carpet becomes easy, but when cleaning the foreign material of the surface to be cleaned such as a floor, cleaning performance is deteriorated by rotation of the agitator. Problems will arise.

That is, the foreign matter on the surface to be cleaned is not sucked into the suction port of the suction nozzle by the rotation of the agitator, and the foreign material remains on the surface to be cleaned even when cleaning is performed because it is shaken out of the suction nozzle. Done.

Therefore, there is a need for a suction nozzle that allows proper cleaning to be performed in accordance with the condition of the surface to be cleaned.

The present invention has been proposed to solve the above problems, and an object of the present invention is to propose a suction nozzle of a vacuum cleaner capable of completely performing the cleaning of the surface to be cleaned regardless of the state of the surface to be cleaned.

In addition, an object of the present invention is to propose a suction nozzle of a vacuum cleaner in which the rotation of the cleaning member can be adjusted by a user's operation according to the state of the surface to be cleaned.

The suction nozzle of the vacuum cleaner according to the present invention for achieving the object as described above, the main body is rotatably provided with a suction port for the air suction, and a cleaning member to facilitate the cleaning of the surface to be cleaned; A first air flow path formed inside the main body and through which air may flow; A second air flow path formed inside the main body and through which air may flow; A rotating member which may be rotated by air sucked into the main body and disposed on the second air flow path; A power transmission unit for transmitting the rotational power of the rotating member to the cleaning member; A first connection flow path for guiding air introduced from the outside of the main body into the first air flow path; A second connection flow path for guiding air introduced from the outside of the main body to the second air flow path; A rotation controller configured to adjust the flow of air so that the rotation of the rotation member is adjusted according to the state of the surface to be cleaned; And an operation lever connected to the rotation control unit to enable a user's operation, wherein the rotation control unit simultaneously opens the first connection channel and the second connection channel according to an operation of the operation lever. It is characterized by blocking one and opening the other.

Hereinafter, specific embodiments of the present invention will be described with reference to the drawings. However, the spirit of the present invention is not limited to the embodiments presented, and those skilled in the art who understand the spirit of the present invention can easily suggest other embodiments within the scope of the same idea.

1 is an external perspective view of a vacuum cleaner suction nozzle according to the spirit of the present invention, FIG. 2 is an exploded perspective view of the suction nozzle, and FIG.

1 to 3, the suction nozzle 10 according to the spirit of the present invention is rotatably coupled to the main body 100 and the rear side of the main body 100 to suck the foreign matter on the cleaning surface largely, Suction pipe 400 is included to allow the air containing the foreign matter sucked into the main body 100 to be moved to the cleaner body.

In addition, the main body 100 is coupled to the nozzle body 200 forming the lower appearance of the suction nozzle 10 and the upper side of the nozzle body 200 to form the upper appearance of the suction nozzle 10. It consists of a cover member 300.

In addition, the main body 100 inside the cleaning member 230 to facilitate the cleaning of the surface to be cleaned, such as carpet, the rotating member 240 to enable the rotation of the cleaning member 230, and the state of the surface to be cleaned According to the user's operation includes a control means for adjusting the rotation of the rotating member 240.

In detail, a suction port 202 (see FIG. 7) is formed at a lower front end of the nozzle body 200 to allow foreign substances on the surface to be cleaned to be sucked. In addition, an upper side of the suction port 202 (see FIG. 7) is provided with the cleaning member 230 to facilitate cleaning of a carpet or the like.

In addition, the cleaning member 230 is configured to be rotatable in a state seated on the nozzle body 200.

The cleaning member 230 is coupled to both sides of the body 232 is formed in a substantially cylindrical shape, the brush 234 is provided spirally formed on the outer peripheral surface of the body 232, the body 232 A coupling part 236 is included to allow the cleaning member 230 to be coupled to the nozzle body 200.

At this time, the body 232 is rotatably coupled to the coupling portion 236 in order to enable the cleaning member 230 to rotate.

In addition, a connection pulley 238 is formed at one side of the body 232 so that the transmission belt 250 for transmitting the rotational power of the rotating member 240 to be described later is maintained while maintaining the tensile force.

Here, in order to fix the coupling part 236 to the nozzle body 200, a coupling part seating end 204 on which the coupling part 236 is seated is formed in the nozzle body 200.

Therefore, the cleaning member 230 is rotatable by the power transmitted by the transfer belt 250 in a state seated on the nozzle body 200 by the coupling portion 236.

On the other hand, the rear of the cleaning member 230 is provided with a rotating member 240 to enable the rotation of the cleaning member 230.

In detail, the rotating member 240 is configured to be rotatable by air introduced from the outside. To this end, the blade 240 is provided with a plurality of blades 242 at regular intervals.

In addition, a rotation shaft 244 penetrates and is coupled to a central portion of the rotation member 240. And, one side of the rotating shaft 244 is surrounded by a transmission belt 250 for transmitting the rotational power of the rotating member 240 to the cleaning member 230.

Therefore, when the rotating member 240 is rotated, the transmission belt 250 surrounded by the rotating shaft 244 is rotated, the rotational power of the rotating member 240 by the transmission belt 250 is the cleaning member And the cleaning member 230 is rotated.

Here, the nozzle body 200 has a partition portion 210 that partitions the space in which the cleaning member 230 is provided and the space in which the rotating member 140 is provided to the left and right.

That is, the cleaning member 230 is provided in front of the partition 210, and the rotating member 240 is provided at the rear of the partition 210.

In addition, the rear portion of the compartment 210 is spaced apart from the compartment 210 by a predetermined distance, and the air containing the foreign matter sucked through the suction port 202 (see FIG. 7) moves to the suction pipe 400 side. Guide ribs 220 are formed which form an air flow path 226 that can be formed.

In detail, a through-hole is formed in the central portion of the partition 210 so that the air containing the foreign matter sucked through the suction port 202 can be moved to the rear side.

The through hole includes a left through hole 212 formed at the left side based on the center of the air flow path 226, and a right through hole 214 formed at the right side based on the center of the air flow path 226. Included.

In addition, the guide rib 220 is formed with a left inlet hole 222 through which the air passing through the left through hole 212 is introduced into a position corresponding to the left through hole 212, and the right side of the guide rib 220. The right inlet hole 224 is formed to allow the air passing through the right through hole 214 to flow into a position corresponding to the through hole 214.

At this time, the rotating member 240 is located on the air flow path 226, immediately after the left inlet hole 222. That is, the rotating member 240 is formed to be biased toward the left inlet hole 222 in the air passage 226.

In other words, the thickness of the rotating member 240 is approximately half the width of the air flow path 226, and the rotating member 240 is located at the rear side of the left inlet hole 222.

By such a configuration, when the air containing the foreign matter sucked through the suction port 202 (see FIG. 7) flows into the air flow path 226 through the left inlet hole 222, it flows into the air flow path 226. Air containing the foreign matter is moved to the rear side, while rotating the rotating member 240.

On the other hand, when the air containing the foreign matter sucked through the inlet 202 flows into the air passage 226 through the right inlet hole 224, the air including the foreign substance introduced into the air passage 226. Does not pass through the rotating member 240, it is immediately moved to the suction pipe 400 side.

That is, when air flows into the air passage 226 through the left through hole 212 and the inlet hole 222, the rotating member 240 is rotated by the introduced air and the right through hole 214. When the air flows into the air passage 216 through the inlet hole 224 and the inlet hole 224, the rotating member 240 is maintained in a stopped state.

In this case, the through holes 212 and 214 and the inlet holes 222 and 224 allow air to be introduced into the single air flow path 226, and thus the left and right through holes 212 and 214 and the left and right sides. In the state in which the inlet holes 222 and 224 communicate at the same time, the rotating member 240 is always rotated. In the present invention, a passage through which air does not pass through the rotating member may be referred to as a first air passage, and a passage through which air passes through the rotating member may be referred to as a second air passage.

Therefore, in the present invention, in order to control the rotation of the rotating member along the surface to be cleaned, an adjusting means is provided so that the through holes 212 and 214 and the inlet holes 222 and 224 communicate selectively.

Specifically, in the case of cleaning the surface to be cleaned such as the floor, the right through hole 214 and the right inlet hole 224 are communicated by the adjusting means, while the left inlet hole 222 is shielded. Thus, the rotating member 240 is to be stopped.

On the other hand, in the case of cleaning the carpet and the surface to be cleaned, the left through hole 212 and the left inlet hole 222 are communicated by the control means, while the right inlet hole 224 is closed so that the rotating member Allow 240 to rotate.

Hereinafter, the adjusting means for selectively shielding the through holes 212 and 214 and the inlet holes 222 and 224 as described above will be described in detail.

Figure 4 is a perspective view of the operation lever according to the spirit of the present invention, Figure 5 is a rear perspective view of the nozzle body according to the spirit of the present invention, Figure 6 is a rear perspective view of the rotation control unit according to the spirit of the present invention.

4 to 6, the adjusting means 260, 280 according to the spirit of the present invention is an operation lever 280 for allowing a user to operate, and the through hole in cooperation with the operation lever 280. 212, 214 and the inlet hole 222, 224 includes a rotation control unit 260 for selectively communicating.

In detail, the manipulation lever 280 may include a pressurizing part 282 for allowing a user to pressurize, a side support part 284 for supporting both sides of the pressing part 282, and a lower end of the side support part 284. A bottom portion 286 connecting the side support portion 284 is included.

In addition, the pressing portion 282 is exposed to the upper portion of the upper cover 300, as shown in Figure 1 so that the user can operate from the outside of the suction nozzle (10).

To this end, a through hole 302 (see FIG. 2) is formed on the upper cover 300 to expose the pressing part 282 to the outside.

In addition, the pressing unit 280 is provided on the upper cover 300 to be rotatable. In detail, hinge shafts 285 are formed at both sides of the pressing unit 282, and hinge grooves 304 into which the hinge shafts 285 are inserted are formed in the upper cover 300.

Therefore, as the pressing part 282 is rotatably provided on the upper cover 300, and a predetermined portion of the pressing part 282 is exposed to the outside of the upper cover 300, the user simply presses the manipulation lever. 280 can be operated.

At this time, the manipulation of the manipulation lever 280 may be made by pressing with the foot of the user, and thus the manipulation lever 280, in particular, the pressing portion 282 preferably has a strength that can withstand the pressing force. Do.

In addition, the upper portion of the pressing portion 282 is formed to be rounded to a predetermined portion to the lower side to facilitate the user's operation. That is, the concave portion 283 is formed above the pressing portion 282.

At this time, the concave portion 283 may be provided with a display for allowing a user to accurately operate the pressing portion 282 according to the state of the surface to be cleaned. Such an indication may for example be a floor representing a carpet and a general floor.

On the other hand, the bottom portion 286 is formed with a guide groove 288 for guiding the movement of the rotation control unit 260. That is, as the rotation control unit 260 is coupled to the guide groove 288, the operation of the rotation control unit 260 is enabled according to the operation of the operation lever 280.

In detail, the guide groove 288 extends from the left rear end of the bottom portion 286 to the right rear end of the bottom portion. That is, the guide groove 288 is formed in a diagonal shape on the bottom portion 286.

The rotation controller 260 is provided between the partition 210 and the guide rib 220 to selectively communicate the through holes 212 and 214 and the inlet holes 222 and 224. And a connection member 270 coupled to the flow path control member 262 in a direction perpendicular to the flow path control member 262 so that the operation force of the operation lever 280 is transmitted to the flow path control member 262. .

In detail, the flow path adjusting member 262 is provided substantially perpendicular to the nozzle body 200, and is moved left and right between the partition portion 210 and the guide rib 220 to pass through the holes 212 and 214. ) And inlet holes (222, 224) are selectively communicated.

To this end, the passage adjusting member 262 has a left side communication hole 263 to communicate the left through hole 212 and the left inlet hole 222, the right through hole 214 and the left inlet hole 224 ) Is formed so that the right communication hole 264 is communicated.

In addition, a shielding part 265 is formed between the left communication hole 263 and the right communication hole 264 to shield another communication hole during communication of one communication hole.

That is, when the left through hole 212 and the left inlet hole 222 are communicated by the left communication hole 263, the right inlet hole 224 is shielded by the shielding part 265. When the right through hole 214 and the right inlet hole 224 communicate with each other by the right communication hole 264, the left inlet hole 222 is shielded by the shielding part 265.

In other words, air is introduced into the air flow path 226 through any one of the inflow holes by the flow path adjusting member 260, and the other inflow hole is shielded, thereby allowing the rotation member 240 to be blocked. The rotation of the is controlled.

In addition, a coupling rib 266 for engaging the connection member 270 positioned in the nozzle body 200 in the horizontal direction in the flow path adjusting member 262 is perpendicular to the flow path adjusting member 262. Is molded by extension. In addition, a protrusion insertion hole 268 into which the coupling protrusion 274 of the connection member 270 is inserted is formed at the coupling rib 266.

Accordingly, the flow path adjusting member 262 is coupled to the connection member 270 by the protrusion insertion hole 268 and the coupling protrusion 274, so that the operation lever 280 of the manipulation lever 280 is operated when the manipulation lever 280 is operated. The operating force can be transmitted to the flow path adjusting member 262.

On the other hand, the connection member 270 is disposed perpendicular to the flow path adjusting member 262, and is moved left and right on the nozzle body 200.

In this case, a movement guide protrusion 272 is formed under the connection member 270 so that the connection member 270 can be easily moved on the nozzle body 200, and the nozzle body 200 has the movement guide protrusion 272. A protrusion moving groove 203 is formed to move the movement guide protrusion 272 therein.

In addition, a coupling protrusion 274 inserted into the protrusion insertion hole 268 of the flow path adjusting member 262 is formed at one side of the upper surface of the connection member 270, and the operation is formed at the other side of the upper surface of the connection member 270. The guide protrusion 276 is inserted into the guide groove 288 of the lever 280 is formed.

By the above configuration, when the operation lever 280 is rotated by a user at a predetermined angle, the guide projection 276 of the connecting member 270 coupled to the guide groove 288 of the operation lever 280 As a result, the connecting member 270 is movable left and right with respect to the nozzle body 200, and the flow path adjusting member 262 is movable left and right by the left and right movement of the connecting member 270.

7 is a bottom perspective view of the suction nozzle.

Referring to FIG. 7, an opening and closing member 290 may be detachably provided under the suction nozzle 10 to allow the inside of the air flow path 226 or the rotating member 240 to be cleaned.

In detail, the air including the foreign matter on the surface to be cleaned flows through the left inlet hole 222 or the right inlet hole 224 as described above. The foreign matter may remain in the air flow path 226, in particular, the rotating member 240 while the air containing the foreign matter on the surface to be cleaned flows inside the air flow path 226.

As such, when foreign matter remains in the air passage 226 or the rotating member 240, the flow of air in the air passage 226 and the rotation of the rotating member 240 may not be smoothly performed. In the present invention, the opening and closing member 290 is detachably provided at the lower side of the suction nozzle 10 to enable the user to clean the air flow path 226 and the rotating member 240.

Hereinafter, the operation of the suction nozzle 10 of the vacuum cleaner having the above configuration will be described.

FIG. 8 is a view showing an operation state of the suction nozzle when cleaning the surface to be cleaned such as a floor, and FIG. 9 is a view showing an operation state of the suction nozzle when cleaning the surface to be cleaned such as a carpet. to be.

First, with reference to FIG. 8, the operation state of the said suction nozzle at the time of cleaning the to-be-cleaned surface like a floor is demonstrated. At this time, it is preferable that the cleaning member 230 is not rotated when the surface to be cleaned such as the floor is performed.

When the suction force generated by the vacuum cleaner is generated, air containing foreign matter on the surface to be cleaned is sucked through the suction port 202. In this process, the user presses the rear side of the manipulation lever 280 to clean the surface to be cleaned such as the floor.

Then, the operation lever 280 is rotated at a predetermined angle in the clockwise direction. And, when the operation lever 280 is rotated in the clockwise direction, the rotational force of the operation lever 280 is transmitted to the flow path control member 262 by the connection member 270 to the flow path control member 262 It is moved to the left.

In detail, when the user presses the rear side of the manipulation lever 280, the guide protrusion 276 of the connection member 270 inserted into the guide groove 288 of the manipulation lever 280 is the guide groove 288. It is located at the rear side of the guide groove 288 while moving along the inside. In this way, the connecting member 270 is moved to the left in the process of the guide protrusion 276 is moved to the rear side of the guide groove 288 along the guide groove 288.

At this time, the connection member 270 may be easily moved with respect to the nozzle body 200 by the movement guide protrusion 272 formed on the lower side of the connection member 270.

When the connection member 270 is moved to the left side, the flow path adjusting member 262 coupled with the connection member 270 is moved to the left together.

Then, the right through hole 214 and the right inlet hole 224 communicate with each other by the right communication hole 264 of the flow path adjusting member 262, while the left inlet hole 222 is the shield 265. Shielded by).

In this case, the air containing the foreign matter sucked into the suction nozzle 10 through the suction port 202 flows into the air passage 226 through the right inlet hole 224.

In this case, since the rotating member 240 is located at the rear side of the left inlet hole 222, the air introduced into the air flow path 226 through the right inlet hole 224 is connected to the rotating member 240. It does not pass, but is moved to the suction pipe 400 side.

Accordingly, the rotating member 240 is in a stopped state, and as a result, the cleaning member 230 is in a stopped state.

The air moved to the suction pipe 400 is finally introduced into the cleaner body.

As such, the cleaning member 230 is not rotated when cleaning the surface to be cleaned, such as a floor, so that foreign matters on the surface to be cleaned are swept out of the suction nozzle 10 by the rotation of the cleaning member 230. Therefore, there is an effect that the cleaning of the surface to be cleaned can be made completely.

On the other hand, in order to clean the surface to be cleaned such as a carpet, the user presses the front side of the manipulation lever 280 with his feet.

Then, the operation lever 280 is rotated at a predetermined angle in the counterclockwise direction. And, when the operation lever 280 is rotated in the counterclockwise direction, the rotational force of the operation lever 280 is transmitted to the flow path control member 262 by the connection member 270 to the flow path adjustment member 262. ) Is moved to the right.

In detail, when the user presses the front side of the manipulation lever 280, the guide protrusion 276 of the connection member 270 inserted into the guide groove 288 of the manipulation lever 280 is the guide groove 288. It is located in the front side of the guide groove 288 while moving along the inside. In this way, the connecting member 270 is moved to the right in the process of the guide protrusion 276 is moved to the front side of the guide groove 288 along the guide groove 288.

When the connection member 270 is moved to the right side, the flow path adjusting member 262 coupled with the connection member 270 is moved to the right together.

Then, the left through hole 212 and the left inlet hole 222 communicate with each other by the left communication hole 263 of the flow path adjusting member 262, while the right inlet hole 264 is the shielding part 265. Shielded by).

In this case, the air containing the foreign matter sucked into the suction nozzle 10 through the suction port 202 flows into the air passage 226 through the left inlet hole 222.

At this time, since the rotating member 240 is located at the rear side of the left inlet hole 222, the air introduced into the air flow path 226 through the left inlet hole 222 is connected to the rotating member 240. While passing through the air flow path 226 is moved to the rear side, the rotating member 240 is rotated by the air.

Here, since the left inlet hole 222 is located in front of the lower side of the rotating member 240, the rotating member 240 is rotated in the counterclockwise direction.

When the rotation member 240 is rotated in the counterclockwise manner as described above, the transmission belt 250 coupled to the rotation shaft 244 of the rotation member 240 is rotated, and the rotation member is rotated by the transmission belt 250. Rotational power of the 240 is transmitted to the cleaning member 230 so that the cleaning member 230 is rotated counterclockwise.

Then, the suction suction foreign material is shaken off by the rotation of the cleaning member 230, the foreign matter is sucked into the suction nozzle 10 through the suction port 202.

In addition, the air sucked into the suction nozzle 10 is introduced into the air passage 226 through the left inlet hole 222, and moves to the suction pipe 400 through the rotating member 240. do.

Therefore, when cleaning the surface to be cleaned such as a carpet, the rotary member 240 is rotated by the outside air, and as the cleaning member 230 is rotated, foreign matter adsorbed on the carpet or the like is easily removed from the carpet or the like. Removed.

As the foreign matter adsorbed on the carpet is removed from the carpet or the like, the cleaning can be completely performed.

In order to clean the inside of the air passage 226 or the rotating member 240 in the process of cleaning as described above, the user may separate the opening / closing member 290 from the suction nozzle 10.

Here, the embodiment is characterized in that the rotating member 240 is located immediately after the left inlet hole 222, on the contrary, the rotating member 240 is immediately after the right inlet hole 224 It may be located at.

In this case, the manipulation direction of the manipulation lever 280 described above will be reversed. That is, by pressing the front side of the operation lever 280 to clean the surface to be cleaned, such as a floor, the operation lever 280 is rotated in the clockwise direction, and the operation lever (to clean the surface to be cleaned such as carpet) Pressing the rear side of the 280, the operation lever 280 is rotated in the counterclockwise direction.

In addition, the present embodiment is characterized in that the rotating member 240 is located in a single air flow path 226, in contrast, the flow path for air for rotating the rotating member 240 and the rotation The flow path through which air which does not rotate the member 240 flows may be formed separately.

That is, the partition ribs for partitioning the air flow path 226 are partitioned into a first air flow path not provided with the rotation member 240 and a second air flow path provided with the rotation member 240, and the floor and Air may be flowed into the first air flow path when cleaning the same surface to be cleaned, while air may be flowed into the second air flow path when cleaning the surface to be cleaned, such as a carpet.
To summarize the contents of the present invention, the right communication hole 214 of the compartment rib 210 and the right inlet hole 224 of the guide rib 220 in the present invention the air sucked from the outside of the main body is not provided with the rotating member And a first connection flow path leading to the air flow path (first air flow path), and the left communication hole 212 of the partition rib 210 and the left inflow hole 222 of the guide rib 220 are formed from outside the main body. It can be described as forming a second connection flow path that guides the sucked air to the air flow path (second air flow path) provided with the rotating member. The rotation control unit is configured to open the first connection channel and the second connection channel at the same time or block one of them and open the other.

According to the present invention as proposed, the rotation of the cleaning member to shake off the foreign matter on the surface to be cleaned can be controlled by the adjusting means, so that proper cleaning can be performed according to the state of the surface to be cleaned.

That is, when cleaning the surface to be cleaned such as a floor, the user operates the adjusting means so that the cleaning member is not rotated, so that foreign matters on the surface to be cleaned are shaken off by the rotation of the cleaning member to the outside of the suction nozzle. Is prevented.

On the other hand, in the case of cleaning the surface to be cleaned, such as a carpet, the user operates the adjusting means so that the cleaning member is rotated so that foreign matter adsorbed on the carpet can be easily removed from the carpet or the like to enable a complete cleaning of the surface to be cleaned. do.

In addition, according to the present invention, the operation lever is rotatably coupled to the suction nozzle, the user presses the pressure lever with the foot as the pressure portion of the operation lever is exposed to the upper side of the suction nozzle to facilitate the adjustment lever. Can be manipulated.

In addition, according to the present invention, since the opening and closing member is detachably provided at the lower side of the suction nozzle, the air flow path and the rotating member can be periodically cleaned, so that the rotating member can be smoothly rotated to maintain the cleaning performance. It becomes possible.

Claims (7)

A main body rotatably provided with an air inlet for sucking air and a cleaning member to facilitate cleaning of the surface to be cleaned; A first air flow path formed inside the main body and through which air may flow; A second air flow path formed inside the main body and through which air may flow; A rotating member which may be rotated by air sucked into the main body and disposed on the second air flow path; A power transmission unit for transmitting the rotational power of the rotating member to the cleaning member; A first connection flow path for guiding air introduced from the outside of the main body into the first air flow path; A second connection flow path for guiding air introduced from the outside of the main body to the second air flow path; A rotation controller configured to adjust the flow of air so that the rotation of the rotation member is adjusted according to the state of the surface to be cleaned; And It is connected to the rotation control unit, and includes a control lever to enable the user's operation, According to the operation of the operation lever, the rotation control unit suction nozzle of the vacuum cleaner to open the first connection passage and the second connection passage at the same time or to block any one and open the other one. The method of claim 1, The main body has a partition portion for partitioning the space in which the cleaning member and the rotating member is located, And a guide rib spaced apart from the partition by a predetermined distance to form the first air flow path and the second air flow path. The method of claim 2, The partition is formed with a plurality of through holes through which the air sucked through the inlet is formed, And a plurality of inflow holes are formed in the guide rib at positions corresponding to the through holes. The method of claim 3, wherein The rotating member is a suction nozzle of the vacuum cleaner, characterized in that located immediately after the inlet of any one of the inlet. The method of claim 3, wherein The rotation control unit and the flow path adjusting member is formed a plurality of communication holes to selectively communicate with the through hole and the inlet hole, A suction nozzle of the vacuum cleaner includes a connection member for transmitting the operating force of the operation lever to the flow path control member. 6. The method of claim 5, The flow passage adjusting member is a suction nozzle of the vacuum cleaner which is movable between the partition and the guide rib. 6. The method of claim 5, The flow passage adjusting member may include a shielding portion that shields the other inflow hole when the through-hole and the inflow hole communicate with each other.

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