KR20060032357A - Nozzle assembly for vacuum cleaner - Google Patents

Abstract

The present invention relates to a nozzle assembly for a vacuum cleaner, so that the cleaning of the carpet and the floor cleaning can be easily performed in one nozzle assembly without replacing the nozzle assembly.

To this end, the present invention, the nozzle body is formed with a connection port connected to the suction port and the vacuum cleaner body is sucked air and foreign matter; An agitator rotatably installed on the inlet side of the nozzle body to scrape foreign substances from the bottom surface; A turbine rotatably installed in front of the connector and rotated by air flowing through the suction port to the connector; A power transmission device for transmitting rotation of the turbine to an agitator; A partition wall disposed between the turbine and the agitator and having first and second vent holes formed at each of the front position of the turbine and one side position spaced apart from the turbine by a predetermined distance; A bypass passage having one end connected in communication with the second vent hole of the partition wall and the other end connected in communication with one side of the connector to guide air sucked from the suction port toward the connector; It provides a nozzle assembly for a vacuum cleaner comprising a flow path switching device for selectively opening and closing the first vent and the second vent.

Vacuum cleaner, nozzle assembly, agitator, turbine, flow path changer, brake

Description

Nozzle Assembly for Vacuum Cleaner

1 is a longitudinal sectional view showing the structure of an embodiment of a nozzle assembly for a vacuum cleaner according to the present invention;

FIG. 2 is a cross sectional view of the nozzle assembly for the vacuum cleaner of FIG. 1. FIG.

3 is a cross-sectional view illustrating a state in which a flow path of the nozzle assembly of FIG. 1 is switched.

4 is a perspective view schematically showing the structure of the flow path switching plate of the nozzle assembly of FIG.

5A and 5B are operational views showing the stopper and brake operation of the nozzle assembly of FIG. 1, respectively.

Explanation of symbols on the main parts of the drawings

10: nozzle body 11: inlet

12: connector 15: partition wall

16, 17: first and second vent 20: agitator

21: brush 30: turbine

32: shaft 50: flow path conversion plate

51, 52: first and second communication hole 55: operating knob

61: stopper 62: fixed groove

65: brake 66: connecting bar

67: fixed piece 70: bypass euro

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a vacuum cleaner, and more particularly, to a nozzle assembly for a vacuum cleaner, which allows the cleaning of the carpet to be performed while rotating the agitator while cleaning the carpet without rotating the agitator for cleaning the floor.

As is well known, a vacuum cleaner is a household appliance that collects and collects foreign substances such as dust on the floor by a strong suction force generated by the rotational force of the fan motor installed in the cleaner body. Inhalation of foreign substance.

Normally, the nozzle assemblies of these vacuum cleaners are designed to simply suck dust, and thus cleaning is not performed properly because the dust in the carpet cannot be scraped if the carpet is to be cleaned.

In the past, an agitator, which is a rotating brush with a brush attached to the suction port of the nozzle assembly, has been developed so that the agitator can be cleaned while scraping dust in the carpet while the agitator rotates.

In the Republic of Korea Utility Model Publication No. 1995--0006817 (announced August 21, 1995), a turbine that rotates by suction air is installed on a flow path through which air is sucked, and is connected by the turbine and a belt on an upper side of a suction port. Disclosed is a nozzle assembly provided with an agitator installed so as to rotate in conjunction with a turbine.

However, the conventional carpet cleaning nozzle assembly as described above has a problem in that it cannot be used on a general floor, for example, because the brush of the agitator keeps rotating.

Therefore, in order to perform the floor cleaning after the user performs the carpet cleaning, the nozzle assembly needs to be separated from the cleaner body or the extension pipe connected thereto, and then the cleaning is performed using the floor floor dedicated nozzle assembly. Since there are two nozzle assemblies to be prepared, the cost is increased and there is a problem in that the use is inconvenient.

Accordingly, the present invention has been made to solve the above problems, it is an object of the present invention to provide a nozzle assembly for a vacuum cleaner to enable both general floor cleaning and carpet cleaning with a simple structure and operation.

The present invention for achieving the above object, the nozzle body is formed with a suction port is formed in the air inlet and the air inlet is connected to the cleaner body in the rear portion; An agitator rotatably installed on the inlet side of the nozzle body to scrape foreign substances from the bottom surface; A turbine rotatably installed in front of the connector and rotated by air flowing through the suction port to the connector; A shaft extending outward from the center of the turbine and rotating together with the turbine; A power transmission belt coupled to the shaft and the agitator to transmit rotational force of the shaft to an agitator; It is installed between the turbine and the agitator and partitions the space in which the agitator is installed and the space in which the turbine is installed, the first and second vent holes are formed in each of the front position of the turbine and one side spaced apart from the turbine by a certain distance Partition walls; A bypass passage having one end connected in communication with the second vent hole of the partition wall and the other end connected in communication with one side of the connector to guide air sucked from the suction port toward the connector; It provides a nozzle assembly for a vacuum cleaner comprising a flow path switching device for selectively opening and closing the first vent and the second vent.

Hereinafter, with reference to the accompanying drawings a preferred embodiment of the vacuum cleaner nozzle assembly according to the present invention will be described in detail.

1 to 3 are views illustrating a structure of a nozzle assembly for a vacuum cleaner according to the present invention, wherein an inlet 11 through which air and foreign substances are sucked into the bottom surface of the nozzle body 10 constituting the case of the nozzle assembly is shown. The connector 12 is formed at the rear end of the nozzle body 10 to which an extension tube (not shown) end connected to the cleaner body (not shown) is connected.

On the inlet 11 side, the agitator 20 is formed rotatably on the outer circumferential surface of the sole 21, the turbine 30 is rotated by the suction air flows directly in front of the connector 12 This is installed.

The turbine 30 may be configured in the form of a kind of sirocco fan or turbo fan formed with a plurality of blades on the outer circumferential surface.

In addition, a side wall 13 is installed at one side of the turbine 30, and the side wall 13 is provided with a bearing 31 rotatably supporting the turbine 30.

On one side of the turbine 30, the shaft 32 extends horizontally outward and rotates together with the turbine 30, and a main gear portion 41 is installed at the end of the shaft 32. In addition, a driven gear 42 is provided at the end of the agitator 20, and a timing belt 43 for power transmission is coupled to the main gear 41 and the driven gear 42.

Therefore, when the turbine 30 rotates, the shaft 32 rotates together, and thus the agitator 20 connected by the shaft 32 and the timing belt 43 rotates.

On the other hand, the nozzle body 10 is provided with a partition wall 15 for partitioning a space in which the turbine 30 is installed and a space in which the agitator 20 is installed. A first vent hole 16 communicating with the turbine 30 is formed immediately in front of the turbine 30, and the second vent hole 17 is positioned at a predetermined distance from the first vent hole 16. Is formed.

The second vent hole 17 communicates with one side portion of the turbine 30 by a bypass passage 70.

And, the front surface of the partition wall 15 is provided with a flow path switching plate 50 for selectively opening and closing the first and second vent holes 16, 17 while reciprocally sliding sideways.

As shown in more detail in FIG. 4, the flow path switching plate 50 is formed with two first and second communication holes 51 and 52 selectively communicating with the first and second vent holes 16 and 17. do. In this case, the first and second communication holes 51 and 52 may have a slightly larger interval than the gap between the first and second communication holes 16 and 17, and thus, the first and second communication holes 51 and 52 may be spaced apart from each other. When 16 is in communication with each other, the flow path switching plate 50 closes the second vent hole 17, and the flow path switching plate 50 slides to one side so that the second communication hole 52 and the second vent hole are closed. When 17 are in communication with each other, the flow path switching plate 50 is configured to close the first vent hole 16.

An operating knob 55 exposed to the outside through the guide groove 18 formed on the upper surface of the nozzle body 10 is installed at the upper end of the flow path switching plate 50. Therefore, the flow path switching plate 50 is slidably moved laterally by the user to move the operation knob 55 along the guide groove 18.

On the other hand, the turbine 30 is to be rotated and stopped in conjunction with the operation of the flow path switching plate 50, for this purpose, a stopper 61 is installed in the middle portion of the shaft 32, the flow path The switching plate 50 is provided with a brake 65 for controlling the rotation of the turbine 30 by fixing and releasing the stopper 61.

5A and 5B, the stopper 61 is formed in a disc shape in which fixing grooves 62 of a predetermined shape are formed at an outer side thereof, and the brake 65 is the flow path switching plate 50. And a connection piece 66 connected to the connection bar 66 and fixed to an end of the connection bar 66 and inserted into the fixing groove 62 of the stopper 61.

Therefore, when the flow path switching plate 50 is moved and the fixing piece 67 of the brake 65 is inserted into the fixing groove 62 of the stopper 61, the shaft 32 is restrained to stop the turbine 30. When the fixing piece 67 of the brake 65 comes out of the fixing groove 62 of the stopper 61, the restraint of the shaft 32 is released to rotate the turbine 30.

Referring to the operation of the nozzle assembly configured as described above in detail.

First, when cleaning the carpet, as shown in Figure 2, when the user pushes the operation knob 55 of the flow path switching plate 50 to the left in the drawing, the first communication hole 51 of the flow path switching plate 50 As the second vent hole 17 communicates with each other, the flow passage in front of the turbine 30 is opened, and the second vent hole 17 is closed to close the bypass passage 70.

At this time, the brake 65 and the stopper 61 are in a state where the restraint is released as shown in FIG. 5A, so that the rotation of the turbine 30 is free.

When power is applied in this state and suction force is generated in the cleaner body (not shown), air and foreign substances are sucked through the suction port 11 of the nozzle body 10, and the sucked air is first communication hole 51. And rotates the turbine 30 while flowing through the first vent hole 16 and then flows toward the cleaner body through the connector 12.

As the turbine 30 rotates, the shaft 32 rotates, and accordingly, the agitator 20 connected by the shaft 32 and the timing belt 43 rotates to scrape dust and the like into the carpet.

Next, when the user wants to clean a hard floor surface such as a general floor, moving the operating knob 55 to the right as shown in Figure 3, the flow path switching plate 50 moves to the right while The second communicating hole 52 and the second communicating hole 17 communicate with each other, the bypass flow path 70 is opened, and the first ventilation hole 16 is closed to close the flow path toward the front of the turbine 30. As a result, a flow path connected to the connector 12, the bypass passage 70, and the suction port 11 is formed.

At this time, as shown in Figure 5b, the fixing piece 67 of the brake 65 is inserted into the fixing groove 62 of the stopper 61, the shaft 32 is constrained, the turbine 30 is further It will not rotate anymore.

When suction force is generated in the cleaner body in this state, air and foreign matter introduced through the suction port 11 flow through the bypass passage 70 to the connector 12 to be cleaned.

Therefore, according to the present invention, the user can control the rotation of the agitator 20 and switch the flow path at the same time by a simple operation of operating the operation knob 55, so that the carpet is cleaned without replacing the nozzle assembly itself. And floor cleaning is possible.

Meanwhile, in the above-described embodiment, the flow path switching plate 50 is operated manually by a user's operation. Alternatively, a motor capable of bidirectional rotation is installed inside the nozzle body, and the pinion gear is axially coupled to the motor. Rotation gear is installed on the flow path switching plate and the pinion gear is engaged. When the user applies power to the motor, the pinion gear rotates in both directions, and the rack gear reciprocates in both directions. It may be possible to activate the switchboard automatically.

As described above, according to the present invention, since the rotation of the agitator is controlled by a simple structure and operation, and the suction flow path is changed according to the cleaning mode, smooth air suction and foreign material suction can be performed in any cleaning mode. This can be done by easily switching between carpet cleaning and floor cleaning with one nozzle assembly without replacement.

Claims (7)

A nozzle body having a suction port through which air and foreign matter are sucked in the front part, and a connection part connected to the cleaner body at the rear part; An agitator rotatably installed on the inlet side of the nozzle body to scrape foreign substances from the bottom surface; A turbine rotatably installed in front of the connector and rotated by air flowing through the suction port to the connector; A shaft extending outward from the center of the turbine and rotating together with the turbine; A power transmission belt coupled to the shaft and the agitator to transmit rotational force of the shaft to an agitator; It is installed between the turbine and the agitator and partitions the space in which the agitator is installed and the space in which the turbine is installed, the first and second vent holes are formed in each of the front position of the turbine and one side spaced apart from the turbine by a certain distance Partition walls; A bypass passage having one end connected in communication with the second vent hole of the partition wall and the other end connected in communication with one side of the connector to guide air sucked from the suction port toward the connector; The nozzle assembly for a vacuum cleaner comprising a flow path switching device for selectively opening and closing the first vent and the second vent. The nozzle assembly of claim 1, further comprising a turbine restraining device interlocking with the flow path switching device to restrain and release the rotation of the turbine. According to claim 1 or 2, wherein the flow path switching device, A flow path switching plate which is slidably installed in both sides of the front wall of the partition wall and has first and second communication holes selectively communicating with the first and second holes in accordance with a moving direction; The vacuum cleaner nozzle assembly comprising a moving means for sliding the flow path switching plate. According to claim 3, The moving means, the long groove-shaped guide groove formed laterally on the upper surface of the nozzle body, one end is fixed to the flow path switching plate and the other end is exposed to the outside through the guide groove Nozzle assembly for a vacuum cleaner, characterized in that the operating knob is configured to be held by hand. 4. The motor of claim 3, wherein the moving unit includes a motor capable of bidirectional rotation, a pinion gear axially coupled to the motor to rotate, and a pinion gear fixed to the flow path switching plate and engaged with the pinion gear to rotate in a straight line. A nozzle assembly for a vacuum cleaner, characterized by comprising a reciprocating rack gear. The stopper of claim 2, wherein the turbine restraint device is fixed to the shaft, and has a stopper having at least one fixing groove formed on an outer circumference thereof, and one end of which is reciprocated laterally and fixed to the other end thereof. Nozzle assembly for a vacuum cleaner comprising a brake for fixing the stopper is inserted corresponding to the groove. A nozzle body having a suction port through which air and foreign matter are sucked in the front part, and a connection part connected to the cleaner body at the rear part; An agitator rotatably installed on the inlet side of the nozzle body to scrape foreign substances from the bottom surface; A turbine rotatably installed in front of the connector and rotated by air flowing through the suction port to the connector; A shaft extending outward from the center of the turbine and rotating together with the turbine; A power transmission belt coupled to the shaft and the agitator to transmit rotational force of the shaft to an agitator; A partition wall installed between the turbine and the agitator to partition the space in which the agitator is installed and the space in which the turbine is installed, and the first and second air holes formed in the front position of the turbine and the one side position spaced apart from the turbine. and; A bypass passage having one end connected in communication with the second vent hole of the partition wall and the other end communicating with one side of the connector to guide air sucked from the suction port toward the connector; A flow path switching plate which is slidably installed in both sides of the front wall of the partition wall and has first and second communication holes selectively communicating with the first and second holes in accordance with a moving direction; Moving means for slidingly moving the flow path switching plate; Turbine restraining device that is fixed to the shaft and formed of a stopper having at least one fixing groove formed on the outer periphery, and a brake that is fixed to the flow path switching plate and the other end is inserted corresponding to the fixing groove of the stopper Nozzle assembly for a vacuum cleaner comprising a.

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