KR100606794B1 - Cyclone Collector - Google Patents

Abstract

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a cyclone dust collector, and more particularly, to a cyclone dust collector of a new structure in which a dust collection amount of foreign matter collected in a dust collecting space can be maximized.

To this end, the present invention is a first inlet air is introduced; A first body separating foreign matters from the air introduced through the first inlet; A dust collecting part formed in the bottom space of the first body and collecting foreign matter separated in the first body; A compression unit provided in the dust collecting unit to forcibly compress the collected foreign matter; A first outlet part through which air in the first body flows out; And a secondary cyclone dust collecting unit for collecting the foreign matters by introducing the air leaked through the first outlet to the outside of the first body. Characterized in that comprises a.

Cyclone Dust Collector, Dust Collector, Compressor, Pressure Plate, Lift

Description

Cyclone Dust Collector {Cyclone Collector}

1 is a longitudinal sectional view schematically showing a conventional multi-cyclone dust collector

Figure 2 is a longitudinal sectional view schematically showing a first embodiment of a cyclone dust collector according to the present invention;

3A and 3B are schematic longitudinal cross-sectional views for explaining the operating state of the compression unit forming the cyclone dust collector of FIG.

Figures 4a to 4c is a longitudinal sectional view schematically showing the structure of the second embodiment of the cyclone dust collector according to the present invention and its operating state

Figure 5 is a longitudinal sectional view schematically showing a third embodiment for explaining the multi-cyclone dust collector to which the compression unit of the present invention is applied;

Explanation of symbols for main parts of the drawings

100. 1st cyclone dust collector 110. 1st inlet

120. First Body 130. Dust Collector

131.Rib 140.First Outflow

141. Perforations 142. Perforations

200. Compression unit 210. Pressure plate

211,212. Foreign material discharge hole 220.Pressure handle

230. Restoration member 240. Spring bobbin

250. Plunger 260. Solenoid part

The present invention relates to a cyclone dust collector, and more particularly, to a cyclone dust collector of a new structure to maximize the amount of dust collected in the dust collecting space.

In general, a cyclone dust collector is a device for collecting dust, dust, and the like (hereinafter referred to as “foreign material”) contained in the air by using a cyclone principle, and is mainly applied to a vacuum cleaner.

Recently, in order to improve dust collection performance, a multi cyclone collector (Multi Cyclone Collector) is used.

In the multi-cyclone dust collector, an upstream cyclone that collects relatively large dust by sucking air (hereinafter referred to as “polluted air”) containing dust, and the like, is connected to the upstream cyclone, And a downstream cyclone for collecting dust.

Usually, in the multi-cyclone dust collector, one upstream cyclone and one downstream cyclone are used, respectively, but in some cases, the downstream cyclone uses a plurality of small cyclones. An example of such a multi-cyclone dust collector is disclosed in Japanese Utility Model Laid-Open No. 52-14775 and the like.

Referring to Figure 1, a conventional multi-cyclone dust collector is described as follows.

The multi-cyclone dust collector is connected to the cyclone (1) (hereinafter referred to as "primary cyclone dust collector") that collects relatively large dust by sucking polluted air from the outside, and is connected to the primary cyclone dust collector (1). It consists of the cyclone 3 which collects a small dust (hereinafter, "secondary cyclone dust collector"). The secondary cyclone dust collector 3 in the multiple cyclones is a collection of a plurality of small cyclones.

This will be described in more detail as follows.

First, a secondary cyclone dust collecting part 3 composed of a plurality of small cyclones is installed at the outer circumference of the primary cyclone dust collecting part 1.

In addition, a first inflow part 11 is formed at an upper portion of the first body 12 of the primary cyclone dust collecting part 1 to introduce external polluted air in a tangential direction, and is primarily filtered at approximately the center of the interior. A first outlet 14 for discharging air to the secondary cyclone dust collector 3 is formed. The first outlet 14 is generally cylindrical, the lower portion 14b is open, and the circumference of the upper portion 14a is closed. In some cases, the filter 16 may be provided in the lower opening 14b.

On the other hand, the secondary cyclone dust collector 3 is a plurality of small cyclones installed around the outer circumference of the primary cyclone dust collector 1. Of course, each secondary cyclone dust collector 3 also has a second inlet (not shown) and a second outlet 34.

In addition, a buffer space 56 is usually defined between the primary cyclone dust collecting part 1 and the secondary cyclone dust collecting part 3, and the primary cyclone dust collecting part 1 passes through the buffer space 56. The released air flows into the secondary cyclone dust collector (3).

In addition, an upper portion of the secondary cyclone dust collector 3 is provided with a discharge space 52 communicating with the second outlet 34 of the plurality of secondary cyclone dust collectors 3, and the discharge space 52 is disposed. The air is discharged to the outside through the discharge pipe 54 via. Reference numeral 5 which is not described is a case for accommodating the primary cyclone dust collector 1 and the secondary cyclone dust collector 3.

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

When the multiple cyclone dust collector is operated to drive the suction force generating means, for example, a suction fan (not shown) of the vacuum cleaner, external contamination is caused through the first inlet 11 of the primary cyclone dust collector 1. Air is introduced into the primary cyclone dust collector 1. At this time, the contaminated air is sucked along the tangential direction, and is rotated on the inner wall surface of the first body 12 of the primary cyclone dust collector 1, in which dust is separated by centrifugal force.

At this time, the relatively heavy and large dust is collected in the lower portion of the primary cyclone dust collector (1), the small dust that is not separated by turning inside the primary cyclone dust collector (1) and then rises through the first outflow portion (14) Discharged.

On the other hand, the air containing the small dust discharged from the primary cyclone dust collector 1 (hereinafter "some polluted air") is the second body of the secondary cyclone dust collector 3 through the second inlet (not shown) (32) flows into the interior.

Therefore, the fine dust is separated once again from the secondary cyclone dust collector 3 and the purified air is discharged to the outside through the second outlet 34, the discharge space 52, and the discharge pipe 54.

However, the above-described conventional multi-cyclone dust collector has the following problems.

First, in the conventional multi-cyclone, since the air introduced into the first body 12 of the primary cyclone dust collector 1 descends to the lower portion of the first outlet 14, the bottom space in the first body 12. There has been a disadvantage in that there is a high possibility that the dust already collected on the bed will be scattered again.

Second, since the space where the foreign matter is collected cannot exceed the bottom space of the first body 12, a limitation of the dust collection space is generated, which causes inconvenience of frequent discharge of foreign matter.

Of course, in order to increase the space in which the foreign matter is collected, it may be achieved by forming a higher height of the first body 12, but the vacuum cleaner to which the multi-cyclone dust collector is usually applied, the height is limited. It is difficult to increase.

In addition, by increasing the diameter of the first body 12 as a whole, it is possible to increase the space in which the foreign matter is collected, but in this case, there is another problem that the mounting space of the secondary cyclone dust collecting part 3 must be narrowed. This is caused.

SUMMARY OF THE INVENTION The present invention has been made to solve the above-mentioned problems, and an object of the present invention is to provide a cyclone dust collector of a new structure to maximize the amount of dust collected in the dust collecting space.

In order to achieve the above object, the present invention is a first inlet air is introduced; A first body separating foreign matters from the air introduced through the first inlet; A dust collecting part formed in the bottom space of the first body and collecting foreign matter separated in the first body; A compression unit provided in the dust collecting unit to forcibly compress the collected foreign matter; A first outlet part through which air in the first body flows out; And a secondary cyclone dust collecting unit for collecting the foreign matters by introducing the air leaked through the first outlet to the outside of the first body. Characterized in that comprises a.

Here, the compression unit may be configured to include a lifting plate configured to be capable of lifting in the dust collecting part to pressurize the foreign matter collected in the dust collecting part, and a lifting portion for forcibly lifting the pressure plate.

The lifting unit is preferably configured to include a pressing handle for pressing the pressing plate, and a restoring member for restoring the pressing plate to its original position when the pressing force is removed.

The elevating portion includes a plunger whose one end is integrally connected to a central portion of the bottom surface of the pressure plate, and the other end of the elevating portion penetrates the bottom surface of the dust collecting portion and protrudes to the outside, and a solenoid portion for elevating the plunger by input of power. This is preferred.

In addition, it is preferable that a second cyclone dust collector is further provided on the outside of the first body to introduce the air discharged through the first outlet and perform dust collection again.

Hereinafter, with reference to the accompanying Figures 2 to 5 will be described the most preferred embodiments of the present invention.

2 is a cyclone dust collector according to a first embodiment of the present invention.

That is, the cyclone dust collector according to the first embodiment of the present invention is largely the first inlet 110, the first body 120, the dust collector 130, the compression unit 200, the first outflow It is configured to include a portion 140.

Here, the first inlet 110 is a portion in which air is introduced from the outside, but is connected to a suction hose that forms a vacuum cleaner although not shown.

The first body 120 is formed to form a space in which foreign matter is separated from the air introduced through the first inlet 110.

At this time, the first inlet 110 is connected to the flow of air in a tangential direction with respect to the first body (120).

The first body 120 may be formed in various shapes, but most preferably, the inner wall is made of a cylindrical shape formed in a curved surface.

In addition, the dust collecting unit 130 is formed in the bottom space of the first body 120, and forms a space in which the foreign matter separated in the first body 120 is collected.

At this time, the dust collecting unit 130 may be configured separately from the first body 120, it is more advantageous to be made integral with the first body 120.

In addition, the compression unit 200 is provided in the dust collecting unit 130 to operate to forcibly compress the foreign matter collected in the dust collecting unit 130.

That is, the compression unit 200 is configured to allow the dust collecting unit 130 of a limited size to collect a larger amount of foreign matter through the compression of the collected foreign matter.

In other words, considering that foreign matters such as tissues and hair need only a large dust collection space because they are bulky, the foreign substances such as tissues and hair can be compressed so that a large amount of foreign substances can be collected even with a small dust collection space. It is.

In the present invention, the compression unit 200 is configured to be liftable in the dust collector 130, the pressure plate 210 to pressurize the foreign matter collected in the dust collector 130, and forcibly lifting the pressure plate 210 It is proposed to include a lift unit.

At this time, the pressing plate 210 may be formed of a plate having a diameter smaller than the inner diameter of the dust collecting unit 130, but is formed of a plate having a diameter substantially the same as the inner diameter of the dust collecting unit 130, at least around More preferably, one or more foreign substance discharge holes 211 are formed.

Particularly, in the first embodiment of the present invention, the lifting handle 220 presses the pressure plate 210 by manual operation, and a restoring member restores the pressure plate 210 to its original position when the pressing force is removed. 230, characterized in that configured to.

At this time, the pressing handle 220 is formed to be integrally connected to the central portion of the bottom surface of the pressing plate 210 through the bottom of the dust collecting unit 130, the restoration member 230 is the bottom surface of the pressing plate 210 And a bottom surface of the dust collecting unit 130 are configured to be compressed and restored.

Of course, the pressing knob 220 may be any configuration as long as it can pressurize the pressing plate 210 from the outside of the dust collector 130. For example, the pressure knob 220 may be mounted to vertically move through the side surface of the dust collecting unit 130.

In addition, the restoring member 230 may be formed of a general coil spring, or may be formed of a leaf spring.

In addition, in the first embodiment of the present invention, it is preferable that a spring protection part 240 made of a compressible material is further provided around the restoration member 230.

This is to prevent a problem that smooth compression and restoration are difficult due to entanglement of hair when the restoration member 230 is formed of a coil spring or a leaf spring.

That is, the restoring member 230 is wrapped with the spring protector 240 to prevent the hair or other foreign matter from entering the restoration member 230.

At this time, the spring protection unit 240 is preferably formed of a flexible material, it is more preferably formed of a crimped tube that can be compressed.

And, the first outlet 140 is provided on the central space in the first body 120, and serves to guide the outflow flow so that the air flowing in the first body 120 flows out Perform.

The first outflow portion 140, but the circumferential surface is closed as in the prior art, but may be formed as a tube with an open bottom, as shown, a plurality of through holes 141 are formed on the circumferential surface at the same time It is preferable to form a closed perforated tube.

This is to maintain the dust collection performance, but to reduce the pressure loss.

That is, even if the air introduced into the first body 120 through the first inlet 110 does not come down to the lower portion of the first outlet 140, the outflow is possible to reduce the pressure loss. will be.

Of course, it is conventionally considered that the first outlet portion 14 should be shaped such that the lower portion is opened and the upper portion is free of holes. This is because, in order to collect dust using the principle of cyclone, the inflowing air has to be discharged by separating the dust while again turning down the inner wall of the first body 12 and rising from the center. Therefore, it was thought that the upper portion of the first outflow portion 14 should be blocked. However, as in the embodiment of the present invention, even when the lower portion of the first outlet portion 140 is blocked and a plurality of through holes 141a are formed on the upper side, dust collection can be effectively performed, thereby reducing pressure loss. .

Referring to the operation of the embodiment of the multi-cyclone dust collector according to the present invention described above are as follows.

First, when the cyclone dust collector is operated, external polluted air is sucked into the first body 120 through the first inlet 110.

At this time, the polluted air is sucked in the tangential direction of the first body 120, and is rotated in the first body 120 while having a constant turning force, the foreign matter is relatively heavy and large weight separated from the air by the turning force The inner wall surface of the first body 120 is lowered.

In addition, the foreign matter separated from the air in the process is discharged into the dust collecting unit 130 through the foreign matter discharge hole 211 of the pressure plate 210 provided on the bottom of the first body 120, the dust is made, the air It flows out of the first body through the first outlet 140.

At this time, the pressure plate 210 also serves to block the air flow in the first body 120 to be delivered to the dust collector 130, the scattering of foreign matter in the dust collector 130 is prevented.

On the other hand, the foreign matter collected in the dust collector 130 by the above-described series of processes should be discharged before the dust collection amount exceeds the allowed capacity, or the dust collection capacity should be reduced.

At this time, to reduce the dust collecting capacity of the foreign matter collected in the dust collecting unit 130, it is performed by operating the compression unit 200.

That is, the dust collecting unit is operated by the pressing force of the pressing plate 210 by performing a series of processes of vertically moving the pressing plate 210 as shown in FIGS. 3A and 3B by operating the pressing knob 220 constituting the compression unit 200. The foreign matter collected in the 130 is compressed, the dust collecting capacity is reduced.

At this time, even if the user does not move the pressing knob 220 upward, the pressing plate 210 may be smoothly raised by the restoring force of the restoring member 230.

In particular, due to the compression of the foreign matter, it is possible to further reduce the scattering of the foreign matter collected in the dust collecting unit 130 when the dust collecting process is performed later.

On the other hand, the compression unit 200 according to the embodiment of the present invention is not limited to be configured to be operated only by manual operation.

That is, it is more preferable to configure to automatically compress the foreign matter collected in the dust collector 130 when the dust collecting process is completed.

For example, as in the second embodiment of the present invention illustrated in FIGS. 4A to 4C, the lifting unit constituting the compression unit 200 may include the plunger 250 and the solenoid unit 260.

In this case, one end of the plunger 250 is integrally connected to the central portion of the bottom surface of the pressure plate 210, and the other end penetrates the bottom surface of the dust collecting part 130 to protrude to the outside, and the solenoid portion ( 260 is preferably provided at the bottom of the dust collecting unit 130 to be configured to lift the plunger 250 by the input of power.

Of course, even at this time, when the power supplied to the solenoid portion 260 is cut off between the bottom of the pressure plate 210 and the bottom of the dust collector 130 to return the pressure plate 210 to its original position by its elasticity. It is preferable that the restoration member 230 is further provided.

In addition, it is preferable that a spring protection part 240 made of a compressible material is further provided around the restoration member 230 to surround the restoration member 230.

Compression unit 200 according to the second embodiment of the present invention is a series of supplying or disconnecting power to the solenoid unit 260 when the generation of air suction force for dust collection in the initial state as shown in FIG. It is most preferable to control to lower and raise the plunger 250 as shown in FIGS. 4B and 4C by repeating the process of FIG.

At this time, it is understood that the pressing plate 210 is also lowered by the lowering of the plunger 250 to compress the foreign matter collected in the dust collecting unit 130.

On the other hand, the compression unit 200, which is presented as the biggest feature of the present invention, is not applicable only to a single cyclone dust collector as in the first and second embodiments described above.

That is, the present invention can be applied to a multiple cyclone dust collector having a plurality of cyclone dust collectors.

5 is a multi-cyclone dust collector according to a third embodiment of the present invention to which the compression unit 200 of the present invention is applied, wherein the compression unit 200 collects foreign matter primarily. Characterized in that it is provided in the primary cyclone dust collector (100).

At this time, the primary cyclone dust collector 100 is a cyclone dust collector of the type presented in the first embodiment of the present invention described above, and the secondary cyclone dust collector 300 further presented is the primary cyclone. The outflow of the air leaked through the first outlet 140 to the outside of the first body 120 constituting the dust collecting unit 100 is configured to perform the dust collection again.

The secondary cyclone dust collecting unit 300 is smaller than the first body 120 and at least one or more, respectively disposed along the outer circumference of the first body 120, the foreign matter is discharged The portion is preferably formed in communication with the dust collecting part 130 of the primary cyclone dust collecting part (100).

Of course, the foreign matter separated from the air by the secondary cyclone dust collector 300 may be configured to collect on a separate dust collecting space. However, it is most preferable to configure the dust collecting space on the same dust collecting space as the primary cyclone dust collecting part 100 because it can form a larger dust collecting space.

In this case, an inlet portion (not shown) through which air is introduced into the secondary cyclone dust collector 300 is provided to be in communication with the first outlet 140 of the primary cyclone dust collector 100. The communication space between the inlet and the first outlet 140 is referred to as a buffer space 560, the space through which the air passing through the secondary cyclone dust collecting unit 300 is discharged 520, The discharge space 520 is configured to communicate with the discharge pipe 540 in communication with the space in which the suction force is generated.

In addition, the pressure plate 210 constituting the compression portion is formed to block the space between the first body 120 and the secondary cyclone dust collector 300 of the primary cyclone dust collector 100 does not communicate with each other. More preferably, in this case, it is preferable to further form a separate foreign matter discharge hole (212) in the communication with the site where the foreign matter discharge of the secondary cyclone dust collector 300 is made.

In addition, reference numeral 500 denotes a case in which the primary cyclone dust collector 100 and the secondary cyclone dust collector 300 are jointly accommodated.

Hereinafter, an operation process of the multi-cyclone dust collector according to the third embodiment of the present invention will be described.

First, the process of collecting the foreign matter primarily by the operation of the primary cyclone dust collecting part 100 is the same as the series of processes described in the first and second embodiments of the present invention.

However, the air flowing out through the first outlet 140 forming the primary cyclone dust collecting part 100 and the fine foreign matter piggybacked thereon are leaked into the buffer space 560 and then introduced into the secondary cyclone dust collecting part 300. After the separation of foreign matters again, only clean air is discharged to the outside while sequentially passing through the discharge space 520 and the discharge pipe 540.

At this time, the fine foreign matter separated from the air in the secondary cyclone dust collector 300 is passed to the dust discharge hole 212 of the pressure plate 210 while being lowered to the bottom is collected in the dust collector 130, the dust collector The fine foreign matter collected in the 130 is compressed together with the foreign matters collected by the operation of the primary cyclone dust collecting part 100 when the foreign matter dust collecting process is completed.

Meanwhile, in each of the above-described embodiments, the single cyclone dust collector having one cyclone dust collector and the multi-cyclone dust collector comprising the secondary cyclone dust collector are composed of a plurality of small cyclones, but the present invention is limited thereto. It doesn't work. That is, it is of course possible to apply the present invention to a general double cyclone dust collector connected to two cyclone dust collectors.

On the other hand, the cyclone dust collector according to the present invention described above can be used in both canister type vacuum cleaners and upright cleaners.

As described above, the multi-cyclone dust collector according to the present invention has an effect that a larger amount of foreign matter dust collection is possible through compression of the foreign matter collected without increasing the dust collecting space.

In addition, the present invention has an effect that the dust collection space can be made as large as possible by configuring the foreign matter separated from the air by the secondary cyclone dust collector to be collected on the same dust collecting space as the primary cyclone dust collector.

Claims (12)

A first inlet through which air is introduced; A first body separating foreign matters from the air introduced through the first inlet; A dust collecting part formed in the bottom space of the first body and collecting foreign matter separated in the first body; A compression unit provided in the dust collecting unit to forcibly compress the collected foreign matter; A first outlet part through which air in the first body flows out; And A secondary cyclone dust collecting unit configured to perform dust collection of the foreign matter by introducing air discharged through the first outlet to the outside of the first body; Cyclone dust collector, characterized in that comprises a. The method of claim 1, The compression unit A pressurizing plate configured to be liftable in the dust collecting part and pressurizing the foreign matter collected in the dust collecting part; Cyclone dust collecting device, characterized in that it comprises a lifting unit for forcibly lifting the pressure plate. The method of claim 2, The lifting unit A pressure knob for pressing the pressure plate, And a restoring member for restoring the pressure plate to its original position when the pressing force is removed. The method of claim 3, wherein The pressure knob is formed to be integrally connected to the central portion of the bottom surface of the pressure plate through the bottom of the dust collector, The restoring member is provided between the bottom surface of the pressure plate and the bottom surface of the dust collecting unit cyclone dust collector, characterized in that configured to be compressed and restored. The method of claim 4, wherein Cyclone dust collector, characterized in that the circumference of the restoration member is further provided with a spring protector made of a compressible material surrounding the restoration member. The method of claim 2, The lifting unit A plunger having one end integrally connected to a central portion of the bottom surface of the pressing plate, and the other end penetrating the bottom surface of the dust collecting part to protrude outward; And a solenoid portion for elevating the plunger by input of a power source. The method of claim 6, Between the bottom of the pressure plate and the bottom of the dust collecting part And a restoring member for restoring the pressure plate to its original position by its elasticity when the power supplied to the solenoid portion is cut off. The method of claim 7, wherein Cyclone dust collector, characterized in that the circumference of the restoration member is further provided with a spring protector made of a compressible material surrounding the restoration member. The method of claim 2, The pressure plate is Cyclone dust collector, characterized in that formed of a plate having a diameter smaller than the inner diameter of the dust collector. The method of claim 2, The pressure plate is Cyclone dust collector, characterized in that formed of a plate having a diameter substantially the same as the inner diameter of the dust collector, at least one foreign material discharge hole is formed around the dust collector. delete The method of claim 1, The secondary cyclone dust collecting unit is smaller than the first body and at least one or more, and is disposed along the outer circumference of the first body, and a portion where the foreign matter is discharged is formed in communication with the dust collecting unit. Cyclone dust collector.

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