KR20000074149A - multi-cyclone dust collector - Google Patents

Abstract

PURPOSE: Multi-cyclone dust collection equipment executes smoothly dust collection working of various dirty matter like dust by decreasing pressure loss of the whole multi-cyclone dust collection equipment. CONSTITUTION: Multi-cyclone dust collection equipment comprises first cyclone dust collection equipment to dust-collect dirty matter inside of induced air by using gravity after intaking air contained in dirty matter through air suction side from the outside; second cyclone dust collection equipment to dust-collect again dirty matter inside of induced air by using cyclone working after intaking air separated from dirty matter firstly through the first cyclone dust collection equipment, to discharge dust-collected air to the outside through air discharge side. And the equipment is characterized by being situated air suction side of the first cyclone dust collection equipment and air discharge side of the second cyclone dust collection equipment in identical line; discharging induced air through air discharge side for direct direction.

Description

Multi-cyclone dust collector

The present invention relates to a cyclone dust collector capable of collecting various contaminants such as dust by using a cyclone principle, and more particularly, to a structure of a multi-cyclone dust collector configured to perform a dust collecting operation many times instead of once. It is about.

In general, the cyclone dust collector is a pollutant that rotates with the air by using a centrifugal force to discharge the air to the outside and collect only the pollutant from the air, it is mainly applied to a vacuum cleaner mainly for home use.

There are many types of cyclone dust collectors as described above, but among them, the first cyclone dust collector and the secondary cyclone dust collector are connected in series to form a single cyclone dust collector, so that a single cyclone dust collector can perform dust collection once again. It is possible to exhibit better dust collection performance than a single cyclone dust collector configured only.

That is, the primary cyclone dust collector performs the primary dust collection of the contaminant using gravity of the contaminant, and the secondary cyclone dust collector performs the secondary dust collection of the contaminants using the cyclone action.

Hereinafter, the multi-cyclone dust collector as described above will be described in more detail with reference to FIG. 1.

First, the inside of the body 1 of the multi-cyclone dust collector is divided into the first space portion 10 and the second space portion 20 by the partition wall 1a.

One side of the upper portion of the first space portion 10 in the cyclone body 1 is provided with a first air intake passage 11 through which air and dust are sucked from the outside, and the first central portion at the upper center side of the first space portion 10 is provided. A first air discharge passage 12 for guiding air and dust flowing through the space 10 to the second space 20 is provided.

At this time, the filter 13 is provided on the air inlet side of the first air discharge passage to prevent the discharge of bulky dust.

In addition, the second space portion 20 of the cyclone body (1) is provided with an air flow path guide 23 is gradually condensed toward the bottom portion, the first air discharge flow path 11 at the upper end of the air flow path guide And a second air suction passage 21 connected to the second air suction passage 21, and the air and the dust flowing through the air passage guide 23 are discharged to the outside of the cyclone body 1 at the upper center side of the second space part. An air discharge passage 22 is provided.

At this time, the second air discharge passage is connected to a suction force generating means (not shown) for generating a suction force so that external contaminants can be sucked through the first air suction passage 11. In general, as a well-known means for generating a suction force by using the suction force of the fan according to the driving of the motor, the illustration and detailed description thereof are omitted.

In addition, a dust collecting part 24 for collecting dust is formed at the bottom of the air passage guide 23.

Referring to the operation of the multi-cyclone dust collector configured in this way in more detail as follows.

First, when the suction force is transmitted through the second air discharge passage 22, dust and air are sucked into the cyclone body 1 from the outside through the first air suction passage 11, and the sucked dust and air are first While flowing inside the space 10, the air is discharged to the second air intake passage 21 through the first air discharge passage 12.

At this time, in the process of discharging the dust and air through the first air discharge passage 12, dust having a relatively large particle size or heavy weight is collected in the lower portion of the first space part 10.

This is because the filter 13 is provided on the air inlet side of the first air exhaust passage 12 so that relatively large dusts collide with the filter in the process of passing through the first air exhaust passage 12 together with the air. Accordingly, the dust can be collected at the bottom of the first space portion 10 by its own weight.

In addition, among the dust flowing in the first space portion, the dust whose volume is relatively small, that is, fine dust smaller than each of the through holes 13a of the filter 13 provided in the first air discharge passage 12, together with the air It is discharged to the 1st air discharge flow path 12 through each through hole 13a of a filter.

As such, the fine dust and air discharged through the first air discharge passage 12 are guided by the second air suction passage 21 communicating with the first air discharge passage. It is sucked into the guide 23.

In addition, the air sucked into the air flow path guide is lowered while turning along the inner circumference of the air flow path guide 23 under the influence of the suction force continuously generated through the second air discharge flow path 22. Fine dust is separated from the air by the application of the centrifugal force.

The dust can be separated from the air is due to the influence of the centrifugal force according to the difference in mass.

In other words, air close to zero by F = me {omega} ^ {2} (F; centrifugal force, m; mass, e; distance from the center of the cyclone body to the inner wall of the cyclone body, ω; angular acceleration) Almost no centrifugal force is generated, but massy dust is subject to centrifugal force so that the dust can be separated from the air.

As described above, the fine dust separated from the air flows down the inner wall surface of the air flow path guide 23 and is collected at the dust collecting part 24, and the air from which the fine dust is separated rises again while the second air discharge passage ( It is discharged to the outside of the cyclone body 1 through 22) to perform a continuous operation to perform the dust collection.

Meanwhile, as shown in FIG. 2, the cyclone body is not divided into two spaces by a partition, such as the multi-cyclone dust collector of the above-described type. There is also a form to perform.

That is, the primary cyclone dust collector is provided on the outer body 30, the first air suction flow path 31 is provided on one side of the upper body of the outer body to suck the outside air, and the air flowing in the outer body is discharged It consists of a first air discharge flow path (32) to guide as possible.

In addition, the secondary cyclone dust collector is connected to the inner body 40 provided in the outer body 30 of the primary cyclone dust collector, and the first air discharge passage 32 of the outer body in a state in which the first A second air intake passage 41 for guiding the air discharged through the one air discharge passage into the inner body 40, an air passage guide 43 provided in the inner body and configured to be lowered toward the lower portion thereof; A second air discharge passage 42 is provided in the central portion in the body and guides the air flowing in the inner body 40 to be discharged to the outside in a state penetrating the upper portion thereof, and is provided at the bottom in the inner body. Consists of a dust collector 44 for collecting the contaminants introduced through the guide 43.

At this time, the inner body and the outer body is a state in which the whole is sealed except for the suction side and the discharge side of the air.

The multi-cyclone dust collector of this type also performs dust collection by a function substantially similar to the multi-cyclone dust collector of the above-described embodiment, so a detailed description thereof will be omitted and briefly described.

First, when suction power is transmitted through the second air discharge passage 42, air including dust is sucked into the outer body 30 through the first air suction passage 31.

Air and dust sucked into the outer body 30 as described above flows along the outside of the outer body and the inner body 40, the air is received by the suction force through the first air discharge passage 32 the inner body ( 40 is sucked into the dust, and dust is collected at the bottom in the outer body 30 by its own weight.

At this time, the fine dust in the dust is also included in the flow of air is sucked into the inner body 40 through the first air discharge flow path 32, the fine dust and air sucked in this way is turned inside the inner body In the process of being separated from each other by the difference in centrifugal force.

Therefore, the dust separated as described above and the dust in the air descends on the inner wall surface of the air flow path guide 43 by its own weight and is collected in the dust collector 44, and the air is generated at the center side of the air flow path guide. It is discharged to the outside through the second air discharge pipe 42 while rising in the rising air flow.

Conventionally, each of the multi-cyclone dust collectors that perform the above-described operation separates dust from air and collects dust again as described above, which is superior to the case of using a single cyclone dust collector in terms of dust collection efficiency.

However, while each of the conventional multi-cyclone dust collector has its efficient excellence as described above, it contains a number of problems, each of these problems will be described later.

First, the conventional multi-cyclone dust collector as described above has caused an increase in the overall pressure loss by continuously using the reverse cyclone dust collector in its arrangement.

This is because a general reverse cyclone dust collector has a strong suction force for intake of the air because the flow is reversed when the air flows in and out, and the flow reverses in the course of the air flow. This caused a lot of pressure loss at the moment.

Therefore, the overall dust collection efficiency is lowered by the pressure loss as described above, and also includes a problem in that noise is severely generated.

Second, there is little weight in the process of the air discharged to the first air discharge passage of the first space portion, the area is large, and the inflow of air into the first air discharge passage while the non-vented vinyl or toilet paper flows with the air Attached to the side has caused a problem to close the flow path.

As a result, the inability to inhale deepens and the internal pressure of the cyclone dust collector increases, as well as the overall dust collection efficiency.

The present invention has been made to solve the above-described problems, the object of the present invention is to reduce the pressure loss of the overall multi-cyclone dust collector to achieve a smooth dust collection operation.

Still another object according to the present invention is the flow of air flowing out to the secondary cyclone dust collector by blocking the air discharge side of the primary cyclone dust collector by the pollutants in the process of collecting the pollutants of the multi-cyclone dust collector first The purpose is to prevent degradation.

Figure 1 is a longitudinal cross-sectional view showing an embodiment of a conventional multi-cyclone dust collector

Figure 2 is a longitudinal sectional view showing another embodiment of the conventional multi-cyclone dust collector

Figure 3 is a longitudinal cross-sectional view showing a multi-cyclone dust collector according to the present invention

Figure 4 is a longitudinal sectional view showing an embodiment of the contaminant catching means constituting the multi-cyclone dust collector according to the present invention

Figure 5 is a longitudinal sectional view showing an embodiment of the contaminant catching means constituting the multi-cyclone dust collector according to the present invention

Figure 6 is a longitudinal cross-sectional view showing a third embodiment of the contaminant catching means constituting the multi-cyclone dust collector according to the present invention

Figure 7 is a longitudinal cross-sectional view showing an embodiment of the contaminant catching means constituting the multi-cyclone dust collector according to the present invention

Figure 8 is a longitudinal sectional view showing a fifth embodiment of the contaminant catching means constituting the multi-cyclone dust collector according to the present invention

Figure 9 is a longitudinal sectional view showing another embodiment of the multi-cyclone dust collector according to the present invention

Explanation of symbols for main parts of the drawings

100. 1st cyclone body 110. 1st air suction flow path

120. Means for generating turning force

131, 132, 133, 134, 135, 136. Pollution catching means

140. Euroguide 200. Second cyclone body

210. Second air discharge flow path 220. Pollutant discharge hole

230. Dust collection

According to an aspect of the present invention for achieving the above object, the first cyclone dust collector for collecting the contaminants in the sucked air using gravity after sucking the air containing the contaminants through the air suction side from the outside, and The primary cyclone dust collector is used to suck the air from which the pollutants are separated first, and then the cyclone (cyclone) action is used to recollect the contaminants in the sucked air, and the collected dust is discharged to the outside through the air discharge side. In the secondary cyclone dust collector, the air suction side of the primary cyclone dust collector and the air discharge side of the secondary cyclone dust collector are positioned on the same line so that the air sucked through the air suction side is forwarded. The multi-cyclone dust collector is provided so that it can be discharged through the air discharge side.

Hereinafter, with reference to the accompanying Figures 3 to 9 showing an embodiment of the present invention in more detail as follows.

Figure 3 is a longitudinal cross-sectional view showing a multi-cyclone dust collector according to the present invention, Figure 4 is a longitudinal cross-sectional view showing one embodiment of the contaminant catching means constituting the multi-cyclone dust collector according to the present invention.

In addition, Figure 5 is a longitudinal sectional view showing a second embodiment of the contaminant catching means constituting the multi-cyclone dust collector according to the present invention, Figure 6 is a third embodiment of the contaminant catching means constituting the multi-cyclone dust collector according to the present invention Figure 7 is a longitudinal cross-sectional view showing a four embodiment of the contaminant catching means constituting the multi-cyclone dust collector according to the present invention, Figure 8 is a contaminant catching means constituting a multi-cyclone dust collector according to the present invention 9 is a longitudinal cross-sectional view showing a fifth embodiment of the present invention, Figure 9 is a longitudinal cross-sectional view showing another embodiment of the multi-cyclone dust collector according to the present invention, the present invention is the air intake side and secondary cyclone dust collector of the primary cyclone dust collector The air discharge side is positioned on the same line with each other so that the air sucked through the air suction side forms a forward direction and discharges the air. It is the one to be discharged through.

At this time, the primary cyclone dust collector is provided with a first cyclone body 100, a first air suction flow path 110 is provided on one side of the first cyclone body in which air containing contaminants are sucked from the outside, A turning force generating means 120 provided on the other side of the first cyclone body in a state corresponding to the direction in which the first air intake passage is directed to impart turning force to the air discharged to the secondary cyclone dust collector, and the turning force It is composed of the pollutant catching means provided on the air inlet side of the generating means to prevent relatively large pollutants from being discharged to the secondary cyclone dust collector.

The pollutant catching means provided in the first cyclone body 100 is composed of a mesh 131 made of a mesh form.

In addition, the second cyclone dust collector is formed to face the same direction as the first cyclone body facing the second cyclone body 200 through which the air inside the first cyclone body flows through the turning force generating means 120 ), A second air discharge passage 210 positioned in a state corresponding to a direction in which the air inflow side of the second cyclone body faces, and the air flowing in the second cyclone body 200 is discharged; The contaminant discharge hole 220 is formed in the vicinity of the second air discharge passage 210 of the cyclone body to discharge the pollutant separated from the air flowing in the second cyclone body 200, and is in communication with the pollutant discharge hole. It is provided with a dust collecting container 230, the pollutants are collected.

The operation according to the present invention configured as described above will be described in more detail.

First, when suction force from the outside is generated through the second air discharge passage 210, external air and dust are sucked into the first cyclone body through the first air suction passage 110 of the first cyclone body 100. .

The air sucked in this way passes through the pollutant catching means in the first cyclone body 100 on the flow path of the air during the continuous flow along the suction direction delivered through the second air discharge passage 210.

At this time, the pollutant catching means is composed of a mesh net 131, the dust larger than each of the through holes of the net is caught by the net is not discharged by the first cyclone body (by simply its own weight ( 100 is collected in the lower part.

In addition, dust that is relatively smaller in size than each through-hole of the mesh is sucked into the second cyclone body 200 through the turning force generating means 120 while passing through the pollutant catching means together with air.

As described above, air and fine dust sucked into the second cyclone body 200 are subjected to centrifugal force while turning in the second cyclone body by the turning force generated in the process of passing through the turning force generating means 120 described above. .

At this time, the air and the fine dust subjected to the centrifugal force are separated by the difference in the centrifugal force, respectively, which is a conventional cyclone principle described above, the detailed description thereof will be omitted.

In addition, the dust separated from the air as described above is collected in the dust collecting container 230 through the pollutant discharge hole 220 formed on the flow path of the dust in the process of flowing along the inner wall surface of the second cyclone body (200) The dust separated air is discharged to the outside through the second air discharge flow path 210 of the second cyclone body 200.

As a result, the above-described double cyclone dust collector of the present invention not only makes the flow direction of the air in the forward direction as a whole, but also prevents the overall pressure loss as the air intake side and the air outlet side of the double cyclone dust collector are located on the same line. It becomes possible.

That is, considering that the pressure loss of the conventional multi-cyclone dust collector is largely generated as the flow direction of air flowing in the inside of the multi-cyclone dust collector is reverse, in the present invention, the inside of the multi-cyclone dust collector It is understood that the above-described pressure loss can be prevented as much as possible by configuring the flow direction of air to be generally forward.

On the other hand, the first air intake passage 110 and the second air discharge passage 210 in the multi-cyclone dust collector of the present invention as described above is not necessarily configured to be located on the same line.

However, the center point of the direction in which the first air intake passage 110 is directed and the center point of the direction in which the second air discharge passage 210 faces are located in the same linear range may reduce pressure loss received by the flowing air. More preferred as possible.

That is, when the air discharge side is in the forward direction with respect to the flow direction of the air sucked from the air intake side, considering that there is little change in the flow of air, the pressure loss received by the flowing air will be greatly reduced It becomes possible.

On the other hand, the pollutant catching means of the multi-cyclone dust collector according to the present invention can be configured in various forms in addition to the mesh 131 presented in one embodiment as described above.

That is, as shown in FIG. 4, the contaminant catching means is composed of a mesh 132 made of a mesh shape, but has a predetermined internal space so that one end thereof can cover the air inlet side of the turning force generating means 120. Can be.

In such a form, the net 132 constituting the contaminant catching means such as vinyl or a toilet paper having a large area and having a large area and having no ventilation, while dust and air are sucked into the second cyclone body 200. Even if some of the through hole is blocked, it is a form that allows the smooth flow of air through the through hole of the other part.

This is because the net is formed with a certain space portion therein, the through-holes are formed in a wider range as described above, the through-holes blocked by the large dust as described above can be limited to only a part of the entire through-holes, thereby preventing the inability to suck It can be prevented.

In addition, as shown in Figure 5, the contaminant catching means according to the present invention is composed of a porous body 133 of a material that almost does not deform, but has a constant internal space, one end of the air inflow of the turning force generating means 120 It may be formed so as to cover the side.

Such a shape is similar to that of FIG. 4 described above, but is composed of the porous body 133 of a material which is not deformed as a whole, instead of the mesh 132, thereby preventing deformation due to air receiving strong suction force, and thus preventing air emissions and contaminants. It is to ensure that the jamming action of the smoothly.

In addition, the form as shown in Figure 6 is a form to enable more effective use of the contaminant locking means of each material shown in the above-described Figures 4 and 5.

That is, the air inlet side of the pollutant catching means of each material is formed to be inclined at a predetermined angle toward the bottom surface of the first cyclone body 100 so that the air and dust having a minute size are each through hole 134a of the polluting catching means. The dust is similar to or larger than the size of each through hole (134a) while smoothly passing through the inclined surface 134, which is the air inlet side of the contaminant catching means to the lower portion in the first cyclone body (100) It's a form that can fall.

The inclination angle of the air inlet side of the contaminant catching means is preferably about 45 ° to smoothly perform the operation.

In addition, the shape shown in Figure 7 is a surface corresponding to the first air intake passage 110 of the contaminant catching means is closed, and the periphery is composed of a perforated pipe 135 formed with a plurality of through-holes (135a) Form.

That is, each of the through holes 135a formed along the circumferential surface of the perforated pipes through which the air sucked into the second cyclone body 200 is prevented by closing the surface corresponding to the first air intake passage 110 to prevent direct transfer of suction force. By passing through it, the turning force of the intake air can be made stronger.

In addition, as shown in FIG. 8, the surface corresponding to the first air intake passage 110 is closed, and a plurality of blades 136a are bent along the circumferential direction of air along the circumference of the blade 136. It consists of).

Such a shape allows the blade body 136 to perform the same action as that of the embodiment shown in FIG. It hits each wing 136a of the) to form a dust to be smoothly collected in the first cyclone body (100).

This is because each blade 136a constituting the blade body is bent to face the same direction as the flow direction of air, so that the air flows smoothly while the dust flows with the flow of air, but the dust is bent. It is possible to hit each of the blades 136a of the blade body 136 so that the inflow thereof can be prevented as much as possible.

On the other hand, the present invention can perform a certain cyclone action even in the first cyclone body in addition to the above-described forms, it is possible to more smoothly separate the air and dust.

This is possible by providing the flow path guide 140 bent while having a predetermined slope on the air outlet side of the first air intake passage 110 as shown in FIG. 9.

That is, the cyclone action can be smoothly performed by having a predetermined turning force by the guide of the flow path guide 140 in the process of inhaling the air sucked through the first air suction flow path into the first cyclone body 100. .

At this time, it is understood that the flow path guide 140 as described above can be changed into various forms by simply configuring to increase the turning force of the air sucked into the first cyclone body 100.

In addition, this invention is not necessarily limited to only one form like each Example mentioned above.

That is, each of the above-described embodiments is merely an additional embodiment according to a form in which the air intake side of the primary cyclone dust collector and the air discharge side of the secondary cyclone dust collector presented by the present invention are located on the same line. .

As a result, the present invention can be applied not only to the various forms of the embodiments described above, but also to achieve the object of the present invention by the combination of the embodiments or a slight change in shape. It is a useful invention that anyone can easily apply.

As described above, the present invention improves the structure of the multi-cyclone dust collector, thereby reducing the overall pressure loss generated in the air passing through the multi-cyclone dust collector, thereby increasing the dust collection efficiency.

In addition, there is an effect that the air flow to the secondary cyclone dust collector of the primary cyclone dust collector by the shape of the pollutant holding means provided in the primary cyclone dust collector.

Claims (1)

A primary cyclone dust collector which collects contaminants contained in the air through the air intake side from the outside and collects the pollutants in the sucked air using gravity, and the pollutants are first separated through the primary cyclone dust collector In the case of having a secondary cyclone dust collector which collects air and collects contaminants in the sucked air by using a cyclone action, and collects the collected air to the outside through the air discharge side. The air suction side of the primary cyclone dust collector and the air discharge side of the secondary cyclone dust collector are positioned on the same line with each other so that the air sucked through the air suction side may be discharged through the air discharge side while forming a forward direction. Multi-cyclone dust collector, characterized in that.