KR20030094871A - Cyclone dust collector - Google Patents

Abstract

PURPOSE: A cyclone dust collector is provided to improve dust collecting efficiency by smoothly collecting dust in a dust chamber, and to prevent dust from scattering. CONSTITUTION: A cyclone dust collector is composed of a cyclone body(110), an air suction tube(120) connected to one end of the cyclone body, an air discharge tube(130) connected to the top or bottom of the cyclone body, a first dust discharge hole(161) formed at the circumference of the cyclone body, and a first dust chamber(141) communicated with the first dust discharge hole and collecting the dust discharged through the first dust discharge hole, a second dust discharge hole(162) formed at predetermined intervals from the first dust discharge hole, and a second dust chamber(142) communicated with the second dust discharge hole and collecting the dust discharged through the second dust discharge hole.

Description

Cyclone dust collector

The present invention relates to a cyclone dust collector that can collect contaminants using the cyclone principle.

In general, the cyclone dust collector uses a cyclone principle to discharge air out of the pollutants that rotate with the air and collect only the pollutants by separating them from the air.

FIG. 1 is a schematic longitudinal cross-sectional view illustrating an example of the cyclone dust collector, and FIG. 2 is a cross-sectional view taken along line II of FIG. 1.

As can be seen through this, the conventional cyclone dust collector has a cyclone body 10 formed in a conical shape, an air inlet pipe 20 through which air and various contaminants are sucked, and the air introduced into the cyclone body is discharged. The air discharge pipe 30 and the cyclone body is largely composed of a dust collecting container 40 in which the dust is separated from the air in the cyclone body.

At this time, the air inlet pipe 20 is connected to the upper end of the circumferential surface of the cyclone body (10).

In addition, the air discharge pipe 30 is connected to the penetrating state so as to pass through the upper surface of the cyclone body 10 to reach the inner upper end of the cyclone body 10.

In addition, the other end of the air discharge pipe 30 is connected to the suction force generating means 50 for transmitting the air suction force.

At this time, the suction force generating means 50 is a means for generating the suction force by the rotation of the fan 52 in accordance with the driving of the motor 51, the detailed illustration and detailed description thereof will be omitted.

In addition, the dust collecting container 40 is provided to communicate with the pollutant discharge hole 11 formed on the bottom surface of the cyclone body 10.

Referring to the operation of the conventional cyclone dust collector made of the above-described configuration is as follows.

First, when the suction force generating means 50 is driven, outside air containing contaminants is sucked into the cyclone body 10.

At this time, the air containing the contaminant is sucked in a tangential direction with respect to the cyclone body 10 through the air inlet pipe 20 of the cyclone body 10, the inside of the cyclone body 10 Descend by turning along the wall.

In this process, air and contaminants are separated from each other under different centrifugal forces due to their weight differences.

That is, the relatively heavy contaminants flow down the inner wall surface of the cyclone body 10 while being subjected to centrifugal force to be discharged to the dust collector 40 through the contaminant discharge hole 11, and the relatively heavy Small air is discharged to the outside of the cyclone body 10 through the air discharge pipe (30).

In this case, the air having almost no weight is raised while forming an air flow along the center of the cyclone body 10 by hitting the bottom surface of the cyclone body 10 by the suction force generated through the air discharge pipe 30. By being discharged to the outside of the cyclone body 10 through the air discharge pipe (30).

However, according to the conventional cyclone dust collector which performs the above-described structure and operation, the dust flows down along the inner wall surface of the cyclone body as the turning flow path of the incoming dust is long. There is a problem in that the time of contact with the inner wall surface is long and the contact noise cannot be minimized.

In addition, as described above, since the overall air flow path is made long, there is a problem that the pressure loss must be increased.

In addition, since the turning force remains in the process of introducing various contaminants collected in the dust collecting container, fine dust, which has been collected, is scattered.

Accordingly, a problem that the scattered fine dust is discharged to the outside of the cyclone body through the air discharge pipe in the ascending air flow formed at the bottom of the cyclone body is also generated, and the dust collection efficiency is inevitably lowered as well. There was a problem that caused the failure of the suction force generating means caused.

The present invention has been made to solve the above-mentioned conventional problems, and an object thereof is to provide a new type of cyclone dust collector using inertial force and centrifugal force generated in the process of inhaling foreign matter.

1 is a schematic longitudinal cross-sectional view showing an example of a cyclone dust collector according to the prior art;

2 is a cross-sectional view taken along line II of FIG. 1.

Figure 3 is an exploded perspective view schematically showing a cyclone dust collector according to the present invention

Figure 4 is a cross-sectional view schematically showing a cyclone dust collector according to the present invention

5 is a cross-sectional view taken along the line II-II of FIG. 4.

Explanation of symbols for main parts of the drawings

110. Cyclone Body 120. Air inlet pipe

130.Air exhaust line 140. Dust collector

141. First dust collector 142. Second dust collection

161. First pollutant discharge hole 162. Second pollutant discharge hole

According to the present invention to achieve the above object, the cyclone body; An air inlet pipe connected to one end of the circumferential surface of the cyclone body and configured to introduce external air and various contaminants; An air discharge pipe connected to one of an upper surface and a lower surface of the cyclone body and through which air introduced into the cyclone body is discharged; A first pollutant discharge hole formed in a direction of the air inlet pipe toward a circumferential surface of the cyclone body; A first dust collecting passage connected to communicate with the first pollutant discharge hole, wherein the pollutant discharged through the first pollutant discharge hole is collected; A second contaminant discharge hole formed on a turning path of the contaminant introduced into the cyclone body at a predetermined interval from the first contaminant discharge hole in the circumferential surface of the cyclone body; The cyclone dust collector is connected to communicate with the second pollutant discharge hole, and the second dust collector is collected: the pollutants discharged through the second pollutant discharge hole are provided.

Hereinafter, preferred embodiments of the present invention will be described in more detail with reference to FIGS. 3 to 5.

First, FIGS. 3 to 5 schematically show a cyclone dust collecting apparatus according to an embodiment of the present invention.

As can be seen through the cyclone dust collector according to the present invention, the cyclone body 110, the air inlet pipe 120, the air discharge pipe 130, a plurality of pollutant discharge holes, a plurality of dust collector 140 It is composed largely, including).

The cyclone body 110 is formed to form a cylindrical shape as a whole.

In addition, the air inlet pipe 120 serves to guide the sucked external air and various dust collected into the cyclone body 110 and penetrates one end of the circumferential surface of the cyclone body 110. Connected.

At this time, the air inlet pipe 120 is formed so that a portion is rounded along the circumferential surface of the cyclone body 110, so that the mutually communicating portions are tangential to the cyclone body 110. Connected.

In particular, the air inlet pipe 120 is rounded so that the outlet end, which is a portion communicating with the inside of the cyclone body 110, and the inlet end, which is a portion where the external air is introduced, form a substantially vertical direction.

In addition, the air discharge pipe 130 serves to discharge external air introduced into the cyclone body 110, and one end of the air discharge pipe 130 is connected through an upper surface (or lower surface) of the cyclone body 110. The other end is connected in communication with a space in which the suction force generating means 150 for generating an air suction force, such as a fan motor, is located.

In particular, the embodiment of the present invention suggests that the air discharge pipe 130 is in communication with the upper center portion of the cyclone body (110).

The pollutant discharge hole includes a first pollutant discharge hole 161 and a second pollutant discharge hole 162.

At this time, the first pollutant discharge hole 161 is proposed to be formed in a position opposite to the direction in which the first air of the air inlet pipe 120 is introduced from the circumferential surface of the cyclone body (110).

In particular, the first pollutant discharge hole 161 is formed so as to be located in a direction opposite to the inlet end of the outside air of the air inlet pipe 120 of the circumferential surface of the air inlet pipe 120.

That is, the first pollutant discharge hole 161 as described above is formed to collect the introduced pollutant primarily by the inertial force given when the pollutant is introduced through the air inlet pipe 120.

In addition, the second pollutant discharge hole 162 has a predetermined interval with the first pollutant discharge hole 161 of the circumferential surface of the cyclone body 110, the contaminants introduced into the cyclone body 110. It is proposed to form on the turning path of.

In particular, the second pollutant discharge hole 162 is formed to be located in a direction opposite to the communication portion between the cyclone body 110 and the air inlet pipe 120.

That is, the second pollutant discharge hole 162 as described above is not discharged to the first pollutant discharge hole 161 and is formed to discharge a relatively light pollutant that rotates inside the cyclone body 110. It is formed long along the height direction of the body (110).

In addition, the dust collector 140 is composed of a first dust collector 141 and a second dust collector 142 so as to correspond to each of the pollutant discharge holes (161, 162), the overall circumferential surface of the cyclone body 110 It is formed to wrap.

At this time, the first dust collector 141 is connected to communicate with the first pollutant discharge hole 161, and collects the pollutants discharged through the first pollutant discharge hole 161.

In addition, the second dust collecting container 142 is connected to communicate with the second pollutant discharge hole 162, and collects the pollutants discharged through the second pollutant discharge hole 162.

Each of the dust collecting cylinders 141 and 142 may be formed separately, but it is more advantageous in terms of manufacturing it as a whole in the form of a single cylinder as shown in the embodiment of the present invention.

At this time, each of the dust collecting cylinders (141, 142) formed as a single body of the cylinder integrally forms a partition wall (143) for partitioning the space between each space of the site where the respective contaminant discharge holes (161, 162) are formed.

The reason why the dust collecting container 140 is formed to have two dust collecting spaces corresponding to the respective pollutant discharge holes 161 and 162 as described above, is because various contaminants introduced into the dust collecting container 140 are collected in the dust collecting container 140. This is to prevent contaminants from scattering again by not turning inside.

Particularly, in the present invention, both edge portions of the dust collector 140 as described above are formed in a round shape to guide the flow of contaminants toward the partition walls in the dust collector 140.

In addition, the cyclone dust collector of the present invention, in addition to the above-described series of configurations, the portion of the cyclone body 110 through which the air discharge pipe 130 is connected and its internal space communicate with each other, the circumferential surface of the filter It further suggests that the configuration further comprises a filter body 160 made.

At this time, the shape of the filter body 160 has a substantially cylindrical shape and the top thereof is in communication with the air discharge pipe 130.

In particular, both ends of the filter body 160 are fixed to the upper and lower surfaces of the cyclone body 110, respectively, and the filter body 160 includes fine dust in the air discharged through the air discharge pipe 130. To improve the dust collection efficiency.

Since the filter constituting the filter body 160 may be formed in various shapes, the filter is not limited to a specific filter.

Of course, the filter body 160 is not necessarily provided, and even if only the structure according to the existing air discharge pipe is formed, it does not matter much in the present invention.

Hereinafter, a brief description of the operation process of the cyclone dust collector of the present invention configured as described above will be described later.

First, when the suction force generating means 150 is driven, external air containing contaminants is sucked into the cyclone body 110 through the air inlet pipe 120.

At this time, the air containing the contaminant is subject to a predetermined inertia force before being introduced into the cyclone body 110 due to the characteristics of the air inlet pipe 120.

Therefore, the contaminants to which the inertial force is applied do not flow into the cyclone body 110, and the air which is a portion communicating with the inside of the cyclone body 110 among the respective portions of the air inlet pipe 120. The first pollutant discharge hole 161 formed at the outlet end side of the inlet pipe 120 is discharged to the first dust collecting container 141.

At this time, the contaminants collected in the first dust collecting container 141 becomes a kind of contaminants having a relatively heavy weight.

In addition, contaminants that are less subject to application of inertia force in the above process, that is, relatively light weight contaminants pass through the first contaminant discharge hole 161 by the suction force generated from the cyclone body 110 and then the air inlet pipe. Pass through the outlet end of the 120 is introduced into the cyclone body (110).

At this time, considering that the outlet end of the air inlet pipe 120 is located in a direction tangential to the cyclone body 110, the contaminants introduced into the cyclone body 110 is the cyclone body It pivots along the inner wall surface of 110.

In this process, the contaminants have a centrifugal force and thus complete separation from the air having almost no weight, and only the air passes through the filter body 160 and is discharged through the air discharge pipe 130.

In addition, various contaminants orbiting the cyclone body 110 inside the second dust collecting tube 142 through the second pollutant discharge hole 162 formed on the inner wall surface of the cyclone body 110 during the turning. Flows inside.

Meanwhile, the contaminants introduced into the first dust collector 141 through the first pollutant discharge hole 161 during the series of processes described above are the first dust collector 141 which is opposite to the direction in which the inflow is made. Discharge is made straight through the edge of

However, considering that the corner portion is formed to be rounded toward the partition wall, the contaminant flows along the rounded wall surface, and in the flow process, the force to flow while hitting the partition wall 143 partitioning each dust collecting space from each other. The reduction is achieved, resulting in a state collected in the bottom of the first dust collector (141).

In addition, the contaminants introduced into the second dust collecting container 142 through the second pollutant discharge hole 162 may be rounded corners of the second dust collecting container 142 corresponding to the direction in which the contaminants are introduced. After being discharged through, the partition wall 143 flows along the rounded wall surface.

Accordingly, it is understood that the turning force of the contaminants introduced into the second dust collecting container 142 is reduced, and the contaminants having the reduced turning power are collected at the bottom of the second dust collecting container 142.

Therefore, it is possible to prevent the re-splash of the various contaminants introduced into the respective dust collecting bins (141, 142).

As described above, according to the cyclone dust collector according to the structure of the present invention, various contaminants can be smoothly collected in the dust collector during the operation of the cyclone dust collector, thereby improving the dust collection performance.

In particular, the various types of contaminant dust collection is made to be completely separated from the air by the inertial force and centrifugal force, and has the effect that it is possible to classify dust by the size or weight of the contaminant.

That is, scattering of fine dust and the like due to bulky contaminants among the contaminants collected can be prevented.

Claims (7)

A cyclone body; An air inlet pipe connected to one end of a circumferential surface of the cyclone body and configured to introduce external air and various contaminants; An air discharge pipe connected to one of an upper surface and a lower surface of the cyclone body and through which air introduced into the cyclone body is discharged; A first pollutant discharge hole formed at a position opposite to a direction in which the first air of the air inlet pipe is introduced among the circumferential surfaces of the cyclone body; A first dust collecting passage connected to communicate with the first pollutant discharge hole, wherein the pollutant discharged through the first pollutant discharge hole is collected; A second contaminant discharge hole formed on a turning path of the contaminant introduced into the cyclone body at a predetermined interval from the first contaminant discharge hole in the circumferential surface of the cyclone body; And a second dust collector connected to communicate with the second pollutant discharge hole and collecting the pollutants discharged through the second pollutant discharge hole. The method of claim 1, Air inlet pipe The cyclone dust collecting apparatus, characterized in that the portion is formed so as to be rounded along the circumferential surface of the cyclone body and the mutually communicating portions are tangential to the cyclone body. The method of claim 2, Air inlet pipe Cyclone dust collecting device, characterized in that the round end is formed so that the exit end and the inlet end, which is a portion in which the outside air is in communication with the inside of the cyclone body in a substantially vertical direction. The method according to claim 1 or 2, The first pollutant discharge hole Cyclone dust collecting device, characterized in that formed in the direction of the circumferential surface of the air inlet pipe facing the inlet end to the outside air inlet. The method of claim 1, The second pollutant discharge hole A cyclone dust collecting device, characterized in that it is formed so as to be located in a direction opposite to the communication portion between the cyclone body and the air inlet pipe. The method of claim 1, The first dust collector and the second dust collector Cyclone dust collecting device, characterized in that formed in one piece. The method of claim 6, Each dust collector formed in a single body Cyclone dust collecting device, characterized in that the partition is formed between each of the dust collection space so that the mutual dust collection spaces.