KR20050102228A - A suction nozzle for vacuum clearner - Google Patents

Abstract

The present invention relates to a suction nozzle of a vacuum cleaner in which a rotary turbine or turbine blade is made of a soft material.

The present invention for achieving the above object, the air intake port 112 and the air and foreign matter is sucked; A rotary turbine 130 which rotates by the action of the air sucked through the air suction port 112; In conjunction with the rotation of the rotary turbine 130, has a configuration including an agitator (114) for separating the foreign matter attached to the bottom surface; The rotary turbine 130 is composed of a soft elastic body. The rotary turbine 130 has a configuration including a turbine shaft 132 serving as a rotational center and a turbine blade 134 formed on an outer circumferential surface of the turbine shaft 132. It is characterized by consisting of a soft elastic material. According to such a structure, there exists an advantage that operation | movement of a vacuum cleaner becomes smooth and noise is prevented.

Description

Suction nozzle for vacuum cleaner {A suction nozzle for vacuum clearner}

The present invention relates to a vacuum cleaner, and more particularly, to a suction nozzle of a vacuum cleaner in which a turbine blade of a rotary turbine is made of a soft material.

1 shows a configuration of a general vacuum cleaner. As shown in the drawing, the vacuum cleaner includes a main body 1 having suction means for sucking air in the room, and a suction nozzle 2 into which air on the bottom surface is introduced by suction force generated in the main body 1. Has a configuration to include.

On the other hand, the main body 1, the lower body (5) to which the suction means is received and fastened, and the parts embedded in the lower body (5) so as not to be exposed to the outside, the electric part for controlling the vacuum cleaner (not shown) It is composed of an upper body (6) that is built.

In addition, wheels 8 are fastened to both sides of the body so that the main body 1 can smoothly move the bottom surface, and the wheels 8 are separated from foreign substances sucked from the air sucked through the suction nozzles 2. A discharge portion 8a through which air of the air is discharged from the main body 1 is constituted.

Between the main body 1 and the suction nozzle 2, a suction hose 3b made of a flexible material, an operation unit 4 connected to an end of the suction hose 3b, and the operation unit 4 ) And an extension tube 3a for connecting the suction nozzle 2 are sequentially installed, so that the suction force generated in the main body 1 can be transmitted to the suction nozzle 2.

Therefore, when electricity is applied through the wire 9 connected to the power supply unit (not shown) built in the main body 1, the vacuum cleaner is in a standby state. At this time, if the user adjusts the suction step by using the button of the operation unit 4, the suction force suitable for each step is generated by the suction means built in the main body.

The suction force generated through the suction means is transmitted to the suction nozzle 2 via the suction hose 3b and the extension pipe 3a which are fastened to the suction connector 3c. The air containing the foreign matter such as dust or lint is sucked by the suction force transmitted to the suction nozzle 2, and the air containing the fine dust and the like is separated by the dust collecting container 10 from the sucked air. The cleaning is performed while discharging to the outside of the main body 1 through 8a).

2 shows the inside of the suction nozzle 2. As shown in the drawing, the bottom surface of the suction nozzle 2 is formed so that the air intake opening 20 through which air and foreign matter are sucked, and the agitator scraping the foreign material of the bottom surface on the upper side of the air suction opening 20. 22 is installed.

The agitator 22 is connected to the rotary turbine 24 and the connecting belt 26 installed on the rear side. Therefore, when the air sucked through the air suction port 20 and introduced into the extension pipe 3a rotates the rotary turbine 24, the agitator 22 connected to the connecting belt 26 also rotates. . In this case, the foreign material on the bottom surface is removed by the brush 22 'formed on the outer circumferential surface of the agitator 22 and is sucked through the air suction port 20.

However, the prior art as described above has the following problems.

The agitator 22 provided in the suction nozzle 2 rotates by the rotary turbine 24, and the rotary turbine 24 is sucked by the air sucked through the air suction port 20 from the outside. Is rotated. However, foreign matter is contained in the air sucked through the air intake 20, and this foreign matter hits the rotary turbine 24, thus preventing rotation of the rotary turbine 24 and causing noise.

That is, since the rotary turbine 24 is made of a solid material, foreign substances sucked from the outside are not caught by the rotary turbine 24 or pass, or noise is generated by the collision.

Accordingly, an object of the present invention is to provide a suction nozzle of a vacuum cleaner, in which a turbine blade of a rotary turbine, in particular a rotary turbine, is made of a soft elastic material.

According to a feature of the present invention for achieving the above object, the present invention includes an air intake port through which air and foreign matter is sucked; A rotary turbine rotating by the action of the air sucked through the air inlet; In conjunction with the rotation of the rotary turbine, has a configuration including an agitator for separating the foreign matter attached to the bottom surface; The rotary turbine is characterized by consisting of a soft elastic body.

The rotary turbine has a configuration including a turbine shaft which is a rotational center and a turbine blade formed on an outer circumferential surface of the turbine shaft, wherein the turbine blade is made of a soft elastic material.

According to such a structure, there exists an advantage that operation | movement of a vacuum cleaner becomes smooth and noise is prevented.

Vacuum cleaners are widely used in general households, and the demand is increasing due to the necessity of cleaning carpets and sofas, and a canister type in which a nozzle part, which is a suction port, is provided separately from the main body and connected by a connecting pipe. And it can be roughly divided into an upright method (Upright type) in which the nozzle unit is formed integrally with the main body.

The filter assembly of the vacuum cleaner performs the function of separating and collecting the foreign matter in the inhaled air. Hereinafter, the canister type and the upright type as well as the agitator that can be mounted on all types of vacuum cleaners are provided. The suction nozzle will be described.

3 is a side cross-sectional view of the vacuum cleaner suction nozzle according to the present invention. As shown, the appearance of the suction nozzle 100 according to the present invention is provided on the upper cover 105 and the lower side of the upper cover 105 to form an upper appearance to form a lower appearance and the upper cover 105 It is composed of a lower cover 110 for supporting.

The air inlet 112 is formed to penetrate up and down in the first half of the lower cover 110. The air inlet 112 is formed in a predetermined size from side to side, and becomes an inlet through which outside air and foreign matter are sucked.

An agitator 114 is installed above the air suction port 112. The agitator 114 is composed of a cylindrical body 114 'and a brush 114 " spirally formed at regular intervals on the outer circumferential surface of the body 114'. The left side of the body 114 ' The inferred end is rotatably mounted on the left and right ends of the lower cover 110.

The rear wall of the air inlet 112 is formed with a separation wall 120 of a predetermined height. The separation wall 120 partitions the inside of the suction nozzle 100 back and forth, and an air through hole 122 penetrates back and forth in the center portion. Therefore, the air sucked through the air inlet 112 is moved rearward through the air through hole 122.

A rotary turbine 130 is installed at the rear of the air through hole 122. The rotary turbine 130 has a configuration including a turbine shaft 132 formed on the left and right in the central portion and a turbine blade 134 formed on the outer circumferential surface of the turbine shaft 132, the air inlet 112 It is rotated by the action of air that is sucked through.

That is, the air sucked into the air inlet 112 passes through the lower end of the rotary turbine 130 through the air inlet 122 and flows into the connection pipe 140 provided at the rear of the suction nozzle 100. At this time, the air hits the turbine blade 134 formed in the rotary turbine 130 and the rotary turbine 130 is rotated by the impact of the air.

The turbine blade 134 protrudes laterally from the outer peripheral surface of the turbine shaft 132, it is configured to be round. That is, the air flowing through the air through hole 122 is formed to be rounded to one side so as to more easily contact and collide.

The rotary turbine 130 is formed of a soft elastic body. That is, it is composed of soft material having relatively strong elasticity. In particular, the turbine blade 134 is necessarily composed of a soft elastic material. Therefore, even when foreign matter is caught between the turbine blades 134 and the lower cover 110 when the rotary turbine 130 rotates, the foreign material is easy because the turbine blades 134 are bent by their elasticity. It passes through a lot and reduces noise caused by collision.

A connecting belt 150 is installed between the rotary turbine 130 and the agitator 114 to allow the agitator 114 to rotate in conjunction with the rotary turbine 130. That is, the rotary turbine 130 is rotated by the air sucked from the outside, the rotary force of the rotary turbine 130 is transmitted to the agitator 114 to remove the foreign material on the bottom surface.

The connection belt 150 is preferably made of a rubber material, the inner surface has a shape corresponding to the outer surface of each pulley (not shown) provided in the rotary turbine 130 and the agitator 114. That is, it is preferable that the pulley outer circumferential surface of the rotary turbine 130 and the agitator 114 and the inner side of the connecting belt 150 form a tooth surface corresponding to each other to be engaged with each other.

In addition, it will be possible to transfer the rotation of the connecting belt 150 to the agitator 114 by installing other power transmission means such as a chain (chain) instead of the connecting belt 150.

At the rear end of the lower cover 110, moving wheels 160 for facilitating the movement of the suction nozzle 100 are installed at both ends. In addition, an auxiliary wheel 170 for facilitating the movement of the suction nozzle 100 is installed at both ends of the front end of the lower cover 110, and the auxiliary wheel 170 has a smaller diameter than the moving wheel 160. It is generally formed to have.

Hereinafter, the operation of the vacuum cleaner suction nozzle having the above configuration will be described with reference to FIGS. 3 and 4.

First, although not shown, when an external power source is applied to a vacuum cleaner, a motor provided inside the main body rotates to generate a suction force, and foreign substances and air are sucked through the suction nozzle 100 by the suction force. .

At this time, the outside air and foreign matter is sucked through the air suction port 112 formed in the lower cover 110 of the suction nozzle 100, the suction air passes through the separation wall 120 through the air through hole 122. To be guided backwards.

The air passing through the air through hole 122 is moved to the rear and flows through the connecting pipe 140 into the connection hose (not shown) and the main body of the vacuum cleaner (not shown), wherein the air through hole 122 The air flowing into the connecting pipe 140 through the () is hit by the turbine blades 134 of the rotary turbine 130. That is, when the air passing through the air through hole 122 hits the turbine blades at the lower end of the rotary turbine 130, the rotary turbine 130 is counterclockwise around the turbine shaft (132) (that is, when viewed from the right side, Rotate at 4).

When the rotary turbine 130 rotates, the agitator 114 connected thereto also rotates. That is, since the agitator 114 and the rotary turbine 130 are connected to each other by the connecting belt 150, the agitator 114 rotates according to the rotation of the rotary turbine 130, such a rotary turbine 130 The rotational speed ratio of the agitator 114 is dependent on the mutual size of the pulley diameter formed in the rotary turbine 130 and the agitator 114, respectively.

On the other hand, since the agitator 114 is exposed to the lower portion through the air inlet 112, the dust or dirt attached to the bottom surface is separated by the rotation of the agitator 114. Therefore, dust or dirt is introduced into the suction nozzle 100 through the air suction port 112.

In addition, in the case of a foreign material (D) having a relatively large size in the air sucked through the air inlet 112, in particular, the size of the foreign material D is not easily passed through the rotary turbine 130, and the state at this time is 4 is shown in detail.

First, as shown in (a) of FIG. 4, when a solid foreign material D from the outside comes into contact with the turbine blade 134 while moving backward, the turbine blade 134 is relatively more foreign than the foreign material D. Turbine blade 134 is bent because it is a soft material.

At this time, the rotary turbine 130 continues to rotate in the counterclockwise direction (in Figure 4), the turbine blade 134 in contact with the foreign material (D) in accordance with the rear movement of the foreign material (D) is shown in FIG. gradually bent as in c). In the end, the foreign material D completely exits the rotary turbine 130, and the turbine blade 134 recovers its original shape.

The scope of the present invention is not limited to the above-exemplified embodiments, and many other modifications based on the present invention will be possible to those skilled in the art within the above technical scope.

In the vacuum cleaner suction nozzle according to the present invention as described above, the rotary turbine is made of a soft material or at least the turbine blades of the rotary turbine is made of a soft elastic body.

Therefore, even when a solid foreign material from the outside is easily passed through the turbine, clogging of the vacuum cleaner suction nozzle is prevented. As a result, the lowering of the suction force of the vacuum cleaner due to foreign matters is prevented.

In the present invention, the rotary turbine is made of a soft material to further improve the elastic force and the restoring force. Therefore, there is also an effect to prevent the damage or wear of the rotary turbine due to foreign matter.

In addition, the relatively hard foreign material collided with the strong rotary turbine, the noise was severe, but in the present invention, the rotary turbine is made of a soft material has the advantage of reducing the collision noise with the foreign material.

As a result, in the present invention, while the noise of the vacuum cleaner is reduced, the deterioration of the cleaning performance of the vacuum cleaner is prevented, thereby improving the purchasing desire of the consumer.

1 is a perspective view showing an appearance configuration of a general vacuum cleaner.

Figure 2 is a perspective view showing the inside of the vacuum cleaner suction nozzle according to the prior art.

Figure 3 is a cross-sectional view showing the internal configuration of a preferred embodiment of the vacuum cleaner suction nozzle according to the present invention.

Figure 4 is a state showing the process of the foreign material passes through the rotary turbine constituting a preferred embodiment of the vacuum cleaner suction nozzle according to the present invention.

Explanation of symbols on the main parts of the drawings

100. Suction nozzle 110. Lower cover

112. Air intake 114. Agitator

114 '. Body 114 ". Brush

120. Separation Wall 122. Air Vent

130. Rotary Turbines 132. Turbine Shafts

134. Turbine wing 140. Connector

150. Connecting belt 160. Moving wheel

170. Second Wheel D. Foreign Body

Claims (2)

An air intake port through which air and foreign matter are sucked; A rotary turbine rotating by the action of the air sucked through the air inlet; In conjunction with the rotation of the rotary turbine, has a configuration including an agitator for separating the foreign matter attached to the bottom surface; The rotary turbine is a suction nozzle of the vacuum cleaner, characterized in that composed of a soft elastic body. According to claim 1, The rotary turbine, The turbine shaft to be the center of rotation, Has a configuration including a turbine blade formed on the outer peripheral surface of the turbine shaft, The turbine blade is a suction nozzle of the vacuum cleaner, characterized in that made of a soft elastic material.