KR102180323B1 - Multi-stage filter device for selecting the size of fine particles - Google Patents

Abstract

The present invention relates to a filter device, and more particularly, to a multi-stage filter device for liquid collection capable of selecting the size of fine particles.
The present invention includes a pre-filter 100 for absorbing gas from the outside, centrifuging fine particles of a first size range contained in the sucked gas, and adsorbing through a collection solution (ℓ); A collection solution (ℓ) by additionally centrifuging the fine particles of the second size range from the gas in which the fine particles of the first size range are separated through the prefilter 100, which is disposed at the bottom of the prefilter 100 A cyclone unit 200 adsorbed through; At least one collection solution storage unit 300 for storing the collection solution (ℓ) supplied to the pre-filter 100 and the cyclone unit 200; Disclosed is a multi-stage filter device for selecting the size of fine particles and collecting liquid, including a drive control unit 400 for inhaling external gas into the pre-filter 100 and the cyclone unit 200 and controlling the suction flow rate.

Description

Multi-stage filter device for selecting the size of fine particles and collecting liquids

The present invention relates to a filter device, and more particularly, to a multi-stage filter device for liquid collection capable of selecting the size of fine particles.

The atmosphere contains microscopic substances such as microbes, dust, etc., including bacteria, and these microscopic substances are subject to research as they can cause diseases or transmit diseases to others.In a crowded indoor space, microscopic substances are filtered out. There is a need to pay.

Conventionally, air purifiers or ventilation devices generally use a cyclone or filter to filter out fine particles in the atmosphere, but in the case of filters, when a large amount of dust accumulates, the pressure load increases or the suction flow rate changes. In the case of a cyclone, there is a problem that a periodic maintenance action in the form of emptying the dust bin when the dust bin is full must be accompanied.

In addition, despite the necessity of selective sampling according to size for the study of fine substances, the collection device using a filter has a problem in that it cannot perform sampling by selecting the size due to the characteristics of the filter that filters up to several microparticles.

Accordingly, in order to collect particles by selecting the size, a multi-stage inertial impactor was initiated in which several inertial impactors were constructed vertically and then the particles caught in the collection plate of each stage were analyzed.However, in the case of this method, each time collection is performed. The collection plate needs to be replaced or cleaned, and there is a problem that it is difficult to analyze the collected sample.

In addition, in the case of a multi-stage inertial impactor, since it is a method of collecting particles colliding on a plate, if a certain level of samples is accumulated, collection cannot proceed, and thus continuous sampling is difficult.

An object of the present invention is to provide a multi-stage filter device for sorting the size of fine particles and collecting the liquid phase, capable of collecting fine particles by selecting the size in order to solve the above problems.

The present invention was created in order to achieve the object of the present invention as described above, and in the present invention, gas is sucked from the outside, and fine particles of the first size range contained in the sucked gas are centrifuged to separate a collection solution (ℓ ) And a pre-filter 100 that is adsorbed through; It is disposed at the lower end of the prefilter 100, and the microparticles of the second size range are additionally centrifuged from the gas in which the microparticles of the first size range are separated through the prefilter 100 to collect the solution a cyclone unit 200 adsorbed through (ℓ); At least one collection solution storage unit 300 for storing the collection solution (ℓ) supplied to the prefilter 100 and the cyclone unit 200; The pre-filter 100 and the cyclone unit 200 sucks external gas into the interior, and discloses a multi-stage filter device for sorting the size of fine particles and collecting liquid, including a drive control unit 400 for controlling the suction flow rate. do.

The prefilter 100 has a cylindrical shape, and external gas to be sucked may be sucked in a direction tangential to the inner diameter.

The cyclone unit 200 comprises: a cyclone 210 for centrifuging the fine particles of the second size range by forming a rotating airflow in the gas flowing from the prefilter 100; It may include an adsorption unit 220 disposed at the bottom of the cyclone 210 to adsorb the fine particles of the second size range centrifuged through the cyclone 210 through the collection solution (ℓ).

The cyclone 210 includes a cyclone chamber 213 having a gas inlet 211 at an upper end and a gas discharge port 212 at a lower end; It is installed in the inside of the cyclone chamber 213, a plurality of guide vanes 214 may be formed to include a guide portion 215 for forming a rotational air flow in the gas introduced from the gas inlet 211.

The adsorption unit 220 includes a cylindrical adsorption chamber 221 provided at a lower end of the cyclone chamber 213; A gas discharge passage (S3) installed through the lower end of the adsorption chamber 221 to discharge gas from which the fine particles of the second size range have been removed, and between the outer wall and the inner wall of the adsorption chamber 221 It may include discharge pipes 222 each forming an adsorption space (S4) in which the fine particles of the second size range separated in are adsorbed.

The size range of the fine particles separated through the size of the inner diameter of the discharge pipe 222 may be determined.

The adsorption chamber 221 includes an inclined portion 221a whose inner diameter decreases from an upper side to a lower side, and an extension portion that increases an inner diameter at an end of the inclined portion 221a to form the adsorption space S4 ( 221b) may be included.

The adsorption space S4 may temporarily store a collection solution (ℓ) in which fine particles of the second size range separated from external gas are collected.

The collection solution storage unit 300 includes a storage chamber 310 in which the collection solution (ℓ) is stored, and between the storage chamber 310 and the prefilter 100 or the cyclone unit 200. It may include a connection passage 320 provided to exchange the collection solution (ℓ).

The connection passage 320 includes a supply passage 321 for supplying the collection solution (ℓ) to the prefilter 100 or the cyclone unit 200, and the prefilter 100 or the The cyclone unit 200 may include a discharge passage 322 for discharging the collection solution (ℓ) in which fine particles are adsorbed from the inner space.

The pre-filter 100, the cyclone unit 200, and the driving control unit 400 are connected to each other through a flange 10, a clamp 600 installed on the flange 10 Can be fixedly coupled.

In addition, in the multi-stage filter device for sorting the size of fine particles and collecting liquid according to the present invention, gas is sucked from the outside, and the collecting solution (ℓ) is collected by centrifuging the fine particles of the first size range contained in the sucked gas. Pre-filter 100 and adsorbed through; It is disposed at the lower end of the prefilter 100, and the microparticles of the second size range are additionally centrifuged from the gas in which the microparticles of the first size range are separated through the prefilter 100 to collect the solution a cyclone unit 200 adsorbed through (ℓ); At least one collection solution storage unit 300 for storing the collection solution (ℓ) supplied to the prefilter 100 and the cyclone unit 200; The pre-filter 100 and the cyclone unit 200 include a driving control unit 400 that sucks external gas into the interior and controls the suction flow rate, and allows the separation of fine particles of different size ranges in sequence. , A plurality of the cyclone units 200 for separating microparticles of different size ranges discloses a multi-stage filter device for separating the size of microparticles and collecting the liquid phase, which are continuously installed in series.

The multi-stage filter device for size selection and liquid collection of fine particles according to the present invention is configured in multiple stages as a cyclone to which liquid collection is applied, and has an advantage that can serve as a size-selective fine particle filter.

In addition, the multi-stage filter device for sorting the size of fine particles and collecting liquids according to the present invention can be operated in a form that can recycle or exchange the collection solution used for liquid collection, so that it can be used without periodic maintenance and repair. There is this.

In particular, the multi-stage filter device for selecting the size of fine particles and collecting liquid according to the present invention automatically discharges the collected solution using a circulation system and fills a new solution according to the program setting. As a result, there is an advantage that it can be used without periodic intervention for user maintenance and repair.

In addition, the multi-stage filter device for size selection and liquid collection of microparticles according to the present invention has the advantage of being able to stably sample desired in areas with high microparticle contamination through selective particle collection according to the size of the multi-stage configuration, Furthermore, there is an advantage of being able to analyze by simply discharging the sampled product of which the size is selected to the outside.

In addition, the multi-stage filter device for size selection and liquid collection of fine particles according to the present invention has the advantage of being able to subdivide the size section for selection of the particles to be collected into a desired stage by using a multi-stage structure that can be easily detached. .

1 is a front view showing a state of a multi-stage filter device for sorting the size of fine particles and collecting liquid according to the present invention.
FIG. 2 is a cross-sectional view showing the interior of the multi-stage filter device for sorting the size of fine particles and collecting liquid according to FIG. 1.
3 is a cross-sectional view showing another embodiment of a multi-stage filter device for sorting the size of fine particles and collecting liquid according to the present invention.
4 is a perspective view showing a state in which a support part of the multi-stage filter device for sorting the size of fine particles and collecting liquid according to FIG. 1 is installed.
FIG. 5 is a perspective view showing a guide portion of the multi-stage filter device for sorting the size of fine particles and collecting liquid according to FIG. 1.
6A and 6B are graphs showing the effect of selecting the size of fine particles and selecting the size of the fine particles of the multi-stage filter device for liquid collection according to FIG. 1, and FIG. 6A is a graph showing the selection effect according to the size of the fine particles of a single layer structure. 5B is a graph showing the screening effect according to the size of fine particles of the multilayer structure according to FIG. 1.
FIG. 7 is a perspective view illustrating a cyclone type omnidirectional pre-filter among the multi-stage filter device for sorting the size of fine particles and collecting liquid according to FIG. 1.
FIG. 8 is a cross-sectional view in the Ⅱ-Ⅱ direction showing the interior of the cyclone type omnidirectional prefilter according to FIG. 7.
9 is a sectional view in the Ⅲ-Ⅲ direction showing the state of the filter body of the cyclone type omnidirectional prefilter according to FIG. 7.
10 is a schematic diagram showing a centrifugation process of the cyclone type omnidirectional prefilter according to FIG. 7.
11 is a graph showing dust collection efficiency according to a fine particle size range of the cyclone type omnidirectional prefilter according to FIG. 7.

Hereinafter, referring to the accompanying drawings, a multi-stage filter device for sorting the size of fine particles and collecting liquid according to the present invention will be described in detail.

In the multi-stage filter device for sorting the size of fine particles and collecting liquid according to the present invention, as shown in FIG. 1, gas is sucked from the outside, and the fine particles of the first size range contained in the sucked gas are centrifuged. A pre-filter 100 for adsorbing through the collection solution (ℓ); It is disposed at the lower end of the prefilter 100, and the microparticles of the second size range are additionally centrifuged from the gas in which the microparticles of the first size range are separated through the prefilter 100 to collect the solution a cyclone unit 200 adsorbed through (ℓ); At least one collection solution storage unit 300 for storing the collection solution (ℓ) supplied to the prefilter 100 and the cyclone unit 200; The prefilter 100 and the cyclone unit 200 include a drive control unit 400 for sucking external gas into the interior and controlling the suction flow rate.

In addition, the multi-stage filter device for size selection and liquid collection of fine particles according to the present invention is installed at the bottom of the cyclone unit 200 and included in the gas passing through the cyclone unit 200, as shown in FIG. It may include a filter 500 for additionally filtering fine particles.

In addition, the multi-stage filter device for sorting the size of fine particles and collecting liquid according to the present invention, as shown in FIG. 4, includes a support body 930 coupled and installed between the cyclone unit 200 and the driving control unit 400 , One end is coupled to the support body 930 and the other end may be supported by being spaced apart from the ground through a support portion 900 including at least three support legs 920 in contact with the ground.

Here, the microparticles may be particles contained in the gas having a specific size, such as fine dust of a fine size contained in the gas, microorganisms including viruses or airborne bacteria.

In particular, the fine particles may contain fine dust that has recently emerged as a social issue, and may be separated and studied according to the size.

The prefilter 100 is a configuration in which gas is sucked from the outside, and the fine particles of the first size range contained in the sucked gas are centrifuged and adsorbed through a collection solution (ℓ), and various configurations are possible. .

The prefilter 100 has a cylindrical shape, and the external gas to be sucked can be sucked in a tangential direction to the inner diameter, through which the fine particles of the first size range are centrifuged to be adsorbed through the collection solution (ℓ). I can.

In this case, the first size range may be approximately 10 μm or more, and through this, the prefilter 100 may perform a role of filtering relatively large fine particles contained in the external gas.

On the other hand, a detailed description of the prefilter 100 will be described later.

The cyclone unit 200 is disposed at the lower end of the prefilter 100 to further add microparticles of the second size range from the gas in which the microparticles of the first size range are separated through the prefilter 100 It is a configuration that is centrifuged and adsorbed through a collection solution (ℓ), and various configurations are possible.

At this time, the cyclone unit 200 may separate fine particles of a second size range different from the first size range described above, and more specifically, may separate fine particles of a level of 1 μm to 10 μm. I can.

Through this, the cyclone unit 200 can separate only the fine particles of a specific size range by stepwise separating the fine particles of the size range desired by the user together with the prefilter 100.

For example, as shown in FIG. 2, the cyclone unit 200 forms a rotational airflow in the gas flowing from the prefilter 100 to centrifuge the fine particles of the second size range ( 210) and an adsorption unit 220 disposed at the bottom of the cyclone 210 and adsorbing the fine particles of the second size range centrifuged through the cyclone 210 through the collection solution (ℓ).

The cyclone 210 is a configuration for centrifuging fine particles by forming a rotating airflow in the incoming gas, and various configurations are possible.

For example, the cyclone 210 is installed in the cyclone chamber 213 in which a gas inlet 211 and a gas outlet 212 are formed at an upper end, and a plurality of guides The vanes 214 may be formed to include a guide part 215 for forming a rotating airflow in the gas flowing from the gas inlet 211.

More specifically, the cyclone chamber 213 is a cylindrical chamber with both ends open, and a gas inlet 211 through which gas from which fine particles of the first size range are removed through the pre-filter 100 at the top enters Is formed, and a gas outlet 212 through which the centrifuged gas is discharged may be formed at the bottom.

The guide part 215 is a configuration that is installed inside the cyclone chamber 213 to form a rotating airflow in the gas flowing into the cyclone chamber 213, and various configurations are possible.

For example, the guide part 215 is installed inside the cyclone chamber 213, and a plurality of guide vanes 214 may be formed at regular intervals by coaxial with the virtual axis of the cyclone chamber 213. .

That is, the gas flowing vertically through the gas inlet 211 formed at the upper end of the cyclone chamber 213 passes through a plurality of guide vanes 214 formed in a vortex shape, thereby forming a rotating airflow.

Meanwhile, the guide part 215 has a conical shape whose center protrudes upward so that gas flowing into the cyclone chamber 213 through the gas inlet 211 spreads to the edge and passes through the guide vanes 214. It can be a prize.

The adsorption unit 220 is a configuration that is disposed at the bottom of the cyclone 210 and adsorbs fine particles of a second size range centrifuged through the cyclone 210 through a collection solution (ℓ), and various configurations are possible. .

For example, the adsorption unit 220 is installed through a cylindrical adsorption chamber 221 provided at a lower end of the cyclone chamber 213 and a lower end of the adsorption chamber 221, so that the second size range therein A gas discharge passage (S3) for discharging the gas from which the fine particles are removed, and an adsorption space (S4) in which fine particles of a second size range separated between the outer wall and the inner wall of the adsorption chamber 221 are adsorbed. It may include a discharge pipe 222.

The adsorption chamber 221 is a cylindrical chamber provided at the lower end of the cyclone chamber 213 and having an internal space, and may have various configurations.

In particular, the adsorption chamber 221 may be configured such that the inner space has a conical shape, and further, an inclined portion 221a whose inner diameter decreases from an upper side to a lower side, and an end of the inclined portion 221a It may include an expansion portion (221b) that increases the inner diameter of the adsorption space (S4) is formed.

That is, the adsorption chamber 221 is configured such that the inner diameter decreases from the upper side to the lower side, so that the fine particles of the second size range adsorbed by the collection solution ℓ flow down through the inclined portion 221a, and thus the adsorption space ( S4) can be temporarily stored.

The expansion part 221b is a part in which the inner diameter of the adsorption chamber 221 increases at the end of the inclined part 221a, so that the adsorption space S4 is formed between the outer wall of the discharge pipe 222 through this. can do.

The discharge pipe 222 is a configuration installed through the lower end of the adsorption chamber 221 so that the gas discharge passage S3 and the adsorption space S4 are respectively formed, and various configurations are possible.

For example, the discharge pipe 222 may have a gas discharge passage (S3) through which the gas from which the fine particles of the second size range are removed may be formed, and pass through the lower end of the adsorption chamber 221. By being installed, the gas from which the fine particles in the second size range have been removed can be delivered through the gas discharge passage S3.

On the other hand, in this case, the discharge pipe 222 is installed through the lower end of the adsorption chamber 221 so that the fine particles of the second size range separated between the outer wall and the inner wall of the adsorption chamber 221 are adsorbed. It is possible to form the adsorption space (S4) to be stored.

That is, the gas in which the rotating airflow is formed through the cyclone 210 is relatively large and heavy fine particles of the second size range by centrifugal force are located at the edge of the inner space of the adsorption chamber 221, and the relatively light gas is the adsorption chamber ( Since it is located in the center of the inner space of 221), the gas from which the fine particles are removed is delivered through the gas discharge passage (S3) inside the discharge pipe 222, and the fine particles of the second size range are located in the adsorption space (S4). can do.

That is, the size range of the fine particles separated through the size of the inner diameter of the discharge pipe 222 may be determined.

By reducing the size of the inner diameter of the discharge pipe 222, the larger the distance between the inner wall of the adsorption chamber 221 and the outer wall of the discharge pipe 222, the wider the size range of the separated fine particles. Particles can be separated, and as the size of the inner diameter of the discharge pipe 222 is increased and the distance between the inner wall of the adsorption chamber 221 and the outer wall of the discharge pipe 222 is decreased, the size range of the separated fine particles is narrower. The user can separate the fine particles of a specific size range desired by the user.

On the other hand, in the multi-stage filter device for sorting the size of fine particles and collecting liquid according to the present invention, a plurality of cyclone units 200 may be provided, and a plurality of cyclone units 200 may be continuously installed in series.

That is, a plurality of cyclone units 200 separating microparticles of different size ranges may be installed in series in succession so that microparticles of different size ranges can be sequentially separated, whereby As the external gas passes through a plurality of consecutively connected cyclone units 200, fine particles of different size ranges may be sequentially removed.

In this case, by making the inner diameters of the discharge pipes 222 inside the cyclone units 200 different from each other, the size range of the fine particles separated at each stage can be set differently.

For example, by installing a cyclone unit 200 having a discharge pipe 222 of a second inner diameter (D2) at the bottom of the cyclone unit 200 having a discharge pipe 222 of the first inner diameter (D1), a multistage structure It is possible to separate the fine particles of different size ranges.

The collection solution storage unit 300 is configured to store a collection solution (ℓ) supplied to the prefilter 100 and the cyclone unit 200, and various configurations are possible.

That is, the collection solution storage unit 300 receives a collection solution (ℓ) used for collecting fine particles from the outside, and discharges the used collection solution (ℓ) to the outside, and the prefilter 100 And by exchanging the cyclone unit 200 and the collection solution (ℓ), it is possible to circulate the collection solution (ℓ).

For example, the collection solution storage unit 300 is collected between the storage chamber 310 in which the collection solution (ℓ) is stored, and the storage chamber 310 and the prefilter 100 or the cyclone unit 200 It may include a connection channel 320 provided to exchange the solution (ℓ).

In addition, the collection solution storage unit 300 is connected to the storage chamber 310 to receive a collection solution (ℓ) from the outside or an external flow path 330 for discharging the used collection solution (ℓ) to the outside. It may contain additionally.

The storage chamber 310 is a configuration in which a collection solution (ℓ) supplied from the outside is stored, or a collection solution (ℓ) used from the prefilter 100 or the cyclone unit 200 is stored, and various configurations are provided. It is possible.

The storage chamber 310 may communicate with the prefilter 100 or the cyclone unit 200 through the connection passage 320, and may be fixedly installed through the connection passage 320 on the side of the device.

Meanwhile, the storage chamber 310 includes a first storage chamber 311 in which a collection solution (ℓ) is stored before being supplied to the prefilter 100 or the cyclone unit 200 by being supplied from the outside, and It may include a second storage chamber 312 that is supplied into the filter 100 or the cyclone unit 200 and used for collecting fine particles, thereby storing the collection solution ℓ in which the fine particles are collected.

In addition, the storage chamber 310 is supplied into the prefilter 100 or the cyclone unit 200 to enable recycling of the collection solution (ℓ) in which fine particles are collected, the first storage chamber 311 and the second It may have a structure in which the collection solution (ℓ) can be circulated between the storage chambers 312.

The connection passage 320 is provided to exchange a collection solution (ℓ) between the storage chamber 310 and the prefilter 100 or the cyclone unit 200, and various configurations are possible.

For example, the connection flow path 320 includes a supply flow path 321 for supplying a collection solution (ℓ) to the prefilter 100 or the cyclone unit 200, and a prefilter 100 or a cyclone The unit 200 may include a discharge passage 322 for discharging the collection solution (ℓ) in which fine particles are adsorbed from the inner space.

More specifically, the connection passage 320 may be installed through the side of the adsorption chamber 221 to exchange the cyclone unit 200 and the collection solution (ℓ).

In particular, the supply passage 321 is provided at the top of the adsorption chamber 221 so that the collection solution (ℓ) is sprayed to the fine particles rotating at the edge of the inner space of the adsorption chamber 221 through the cyclone 210. I can.

Meanwhile, the discharge passage 322 communicates with the adsorption space S4 to allow the collection solution ℓ in which the microparticles temporarily stored in the adsorption space S4 are collected to be discharged to the storage chamber 310.

In this case, the discharge passage 322 may be installed between the adsorption chamber 221 and the storage chamber 310, and an extension passage 323 is additionally formed between the adsorption space S4 and the discharge passage 322 Can be.

On the other hand, as another example, both the supply passage 321 and the discharge passage 322 are in communication with the adsorption space S4, so that a certain amount of the collection solution (ℓ) is stored and maintained in the adsorption space S4, Accordingly, the fine particles centrifuged through the cyclone 210 can be collected by the collection solution (ℓ) in the adsorption space (S4).

The external flow path 330 is a flow path connected to the storage chamber 310 to discharge the used collection solution (ℓ) to the outside or to receive a new collection solution (ℓ) from the outside, and may have various configurations.

The collection solution storage unit 300 may be installed in plural so as to provide an effective collection solution (ℓ) and separate and discharge only the collection solution (ℓ) in which fine particles of a specific size range are collected, and more specifically One can be installed at each stage to separate and adsorb fine particles.

That is, the collection solution storage unit 300 may be installed in correspondence with each of the prefilter 100 and the cyclone unit 200, and when a plurality of cyclone units 200 are arranged and installed in series, each A plurality of cyclones may be installed corresponding to the cyclone units 200.

On the other hand, of course, it is also possible to supply the collection solution (ℓ) to one storage chamber 310 through a plurality of connection passages 320.

The drive control unit 400 sucks external gas into the prefilter 100 and the cyclone unit 200 and controls the suction flow rate, and various configurations are possible.

For example, the drive control unit 400 includes a chamber 430 disposed at the lower end of the cyclone unit 200, a prefilter 100 installed inside the chamber 430 to suck external gas into the interior, and A drive motor 440 that controls the pressure in the inner space of the cyclone unit 200, a control unit 420 that controls the flow rate of external gas sucked into the inner space through the control of the drive motor 440, and the chamber 430 It may include a manipulation display unit 410 that manipulates an operation from the side or displays an operation state to the user.

The chamber 430 is a configuration disposed below the cyclone unit 200, and various configurations are possible.

For example, the chamber 430 may be configured to have a cylindrical inner space corresponding to the cyclone unit 200, and the upper end contacted with the cyclone unit 200 is a flange 10 for easy fixed coupling. ) Can be.

The driving motor 440 is installed inside the chamber 430 to suck external gas into the interior, and various configurations are possible.

The driving motor 440 may control not only the suction of the external gas but also the flow rate of the suctioned gas through the pressure control of the internal space.

The drive motor 440 sucks external gas into the internal space, and any configuration currently used can be applied as long as it is a configuration capable of controlling the flow rate.

The control unit 420 may be configured in any configuration as long as it controls the drive motor 440 to control the flow rate of gas sucked into the internal space.

For example, the control unit 420 may receive a user's input value through the manipulation display unit 410 and control the driving motor 440.

In addition, the control unit 420 controls the collection solution storage unit 300 based on the remaining amount in the storage chamber 310 and the adsorption space S4 of the collection solution (ℓ), so that the collection solution (ℓ) is circulated or It can be automatically controlled so that it can be discharged.

To this end, a residual amount collecting means such as a level sensor and a pressure sensor may be installed in the adsorption space S4 and the storage chamber 310 to determine the remaining amount of the collecting solution ℓ.

Through this, in the present invention, the automatic circulation system of the collection solution (ℓ) is applied, so that the user grasps the remaining amount of the collection solution (ℓ) to overcome the problem of having to periodically repair, and periodic maintenance and repair are not required. There is.

The operation display unit 410 includes an operation unit 412 that controls gas intake of a desired flow rate by transmitting a signal to the control unit 420 by a user, and is installed on the side of the chamber 430 to display the current state of the device. It may include a display 411 to display.

The filter 500 is installed at the lower end of the cyclone unit 200 to further filter fine particles contained in the gas that has passed through the cyclone unit 200, and various configurations are possible.

For example, the filter 500 is installed between the cyclone unit 200 and the drive control unit 400, and allows the gas that has passed through the cyclone unit 200 to pass, thereby further filtering fine particles. .

The filter 500 is applicable to any configuration currently used to filter out fine particles.

The support unit 900 is a configuration that is installed so that the pre-filter 100, the cyclone unit 200, and the driving control unit 400 are spaced apart from the ground and supported, and various configurations are possible.

For example, the support part 900 has a support body 930 coupled to and installed between the cyclone unit 200 and the driving control unit 400, and one end is coupled to the support body 930 and the other end is in contact with the ground. It may include at least three support legs 920.

In addition, the support part 900 may include at least three hinge parts 910 at an edge of the support body 930 so that the support legs 920 may be hingedly coupled with the support body 930.

The support body 930 is coupled and installed between the cyclone unit 200 and the drive control unit 400 so that the device can be supported apart from the ground through at least three support legs 920 in contact with the ground. I can.

The support legs 920 are configured to be adjustable in length, and at least three may be installed, and for more stable support, each of the support legs 920 may be installed at equal intervals.

A plurality of the hinge portions 910 may be provided at the edge of the support body 930 to correspond to the plurality of support legs 920 so that the support leg 920 and the support body 930 are hinged to each other. .

Through this, by adjusting the coupling angle of the support legs 920, more stable support is possible.

In addition, the multi-stage filter device for sorting the size of fine particles and collecting liquid according to the present invention includes a flange 10 in which the pre-filter 100, the cyclone unit 200, and the driving control unit 400 are connected to each other. , It may be fixedly coupled to each other through a clamp 600 installed on the flange 10.

More specifically, the lower end of the prefilter 100, both ends of the cyclone unit 200, and the upper end of the drive control unit 400 may be a flange 10, furthermore, both ends of the support body 930 are flanges ( It is composed of 10) and is fixedly coupled to each other to achieve a multistage structure.

The clamp 600 is a configuration for fixing the flanges 10 in contact with each other, and various configurations are possible.

For example, the clamp 600 includes a clamp body 610 having a groove fitted to both flanges 10 in contact with each other to surround the outer circumferential surface of the flange 10, and screw grooves at both ends of the clamp body 610 It is bolted to the clamp body 610 may include a clamp screw 620 for pressing the outer peripheral surface of the flange (10).

On the other hand, the multi-stage filter device for size selection and liquid collection of fine particles according to the present invention includes a cyclone type omnidirectional pre-filter for centrifuging fine particles contained in the inhaled gas while gas is sucked from the outside, Hereinafter, a cyclone-type omnidirectional prefilter according to the present invention will be described in detail with reference to the accompanying drawings.

Cyclone type omnidirectional pre-filter according to the present invention, as shown in Figure 7, the gas is sucked from the outside, forming a rotational air flow in the sucked external gas to centrifugally separate the fine particles cylindrical filter body ( 700) and; It is provided at the lower end of the filter main body 700, and includes a dust collecting unit 800 that absorbs and stores the separated fine particles through a collection solution (ℓ), and the filter main body 700 protrudes on a plane. In order to prevent this, at least one gas inlet 720 through which the external gas is sucked is formed on the side surface 710.

The cyclone-type omnidirectional prefilter according to the present invention is a configuration for separating fine particles contained in gas sucked from the outside by using a rotating air flow, and more specifically, is installed in a gas inlet such as a suction pipe or a cyclone device, It can play a role of first separating microparticles of a relatively large size range contained in the gas that is first inhaled.

The filter body 700 is a cylindrical configuration in which gas is sucked from the outside and a rotating air flow is formed in the sucked external gas to centrifugally separate fine particles, and various configurations are possible.

In particular, the filter main body 700 may be coupled to a pipe, a pipe, or other gas intake device, and in this case, there is no protruding part on a plane, so it may be a configuration that can be coupled and installed without deformation of the device while minimizing the volume.

That is, the filter main body 700 may be formed on the side surface 710 rather than having at least one gas inlet 720 through which an external gas is sucked to prevent protrusion on a plane.

In this case, the filter body 700 may be fixedly coupled with the flange 10 of the upper end of the dust collecting unit 800 to be described later by the upper end is closed, the lower end is open, and the flange 10 is formed at the lower end.

For example, the filter main body 700 may have at least one gas inlet 720 through which external gas is sucked by making a hole or a groove in the side surface 710.

On the other hand, in this case, the filter main body 700, as shown in Figs. 8 and 9, so that the external gas sucked through the gas inlet 720 is sucked in a tangential direction to the inner diameter to form a rotating airflow, It may include at least one guide groove 712 and 713 formed on the side surface 710.

For more effective centrifugal separation, a guide groove having an inclination angle with respect to the inner diameter from the outer wall portion 711 of the side 710 so that the external gas sucked through the side 710 can be sucked in a tangential direction to the inner diameter ( 712 and 713 may be formed, and the external gas sucked through the guide grooves 712 and 713 may be sucked tangentially with respect to the inner diameter due to the suction path.

In addition, the filter main body 700 may have a plurality of gas intake ports 720 formed at regular intervals along the circumference of the side surface 710 so that the external gas can be sucked in all directions.

That is, a plurality of gas intake openings 720 are formed at regular intervals along the periphery of the side surface 710, so that gas can be sucked in all directions of the cylindrical filter body 700.

In this case, a plurality of gas intake openings 720 formed at predetermined intervals along the circumference of the side surface 710 are formed so that each of the guide grooves 712 and 713 faces the same direction (clockwise or counterclockwise). It is possible to allow external gases to form a rotating airflow in space.

The dust collecting unit 800 is provided at the lower end of the filter main body 700 and is configured to store the separated fine particles after adsorption through the collection solution (ℓ), and various configurations are possible.

For example, the dust collecting part 800 may include a cylindrical dust collecting chamber 810 in which an internal space is formed; The internal space is separated into a dust collecting space (S1) in which fine particles are collected along the inner wall 811 of the dust collecting chamber 810 and a flow path space (S2) of gas in which fine particles are centrifuged through the filter body 700. To do this, it may include a separating portion 820 protruding from the inner wall 811.

The dust collecting chamber 810 has a cylindrical configuration in which an internal space is formed, and various configurations are possible.

The dust collecting chamber 810 has flanges 10 formed at both ends, and in particular, in the case of the upper flange 10, it is in contact with the flange 10 provided at the lower end of the filter body 700 through the clamp 600. Can be fixedly coupled.

On the other hand, as another example, the dust collecting chamber 810 may be formed extending to the lower end of the filter main body 700, and thus, the dust collecting part 800 and the filter main body 700 may be extended and formed as one body. Yes, of course.

The separating part 820 protrudes from the inner wall 811 of the dust collection chamber 810 in order to separate the dust collection space S1 in which fine particles are collected and the flow path space S2 of the gas from which the fine particles are centrifuged. As a configuration formed, various configurations are possible.

For example, the separating portion 820 may include a protruding portion 821 protruding from the inner wall 811 of the dust collecting chamber 810 and extending from the protruding portion 821 in the axial direction of the dust collecting chamber 810. Separation portion 822 may be included.

The protruding portion 821 protrudes from the inner wall of the dust collection chamber 810 to form a dust collection space S1 between the inner wall of the dust collection chamber 810 and the outer wall of the separation unit 820 in which the centrifuged fine particles are collected. You can do it.

The separating portion 822 is formed extending from the protruding portion 821 to the upper end in the axial direction of the dust collecting chamber 810, and is a dust collecting space in which fine particles are collected along the inner wall 811 of the dust collecting chamber 810 (S1) and through the filter body 700, the fine particles may be separated into a flow path space S2 of the centrifuged gas.

In particular, the separating part 822 may adjust the size range of the fine particles to be separated by adjusting the outer diameter.

The dust collecting space S1 is a space in which fine particles centrifuged through the filter body 700 are stored, and various configurations are possible.

In the dust collection space S1, a collection solution (ℓ) for collecting adsorbed fine particles is temporarily stored, so that the microparticles may be collected and stored in the collection solution (ℓ).

In this case, the collection solution storage unit 300 may be installed on the side of the pre-filter, the supply passage 321 is installed through the side of the filter body 700, and the discharge passage 322 is provided with the dust collecting unit ( 800) It can be installed to communicate with the dust collection space (S1).

Accordingly, the collection solution (ℓ) sprayed on the filter body 700 through the supply passage 321 can collect the fine particles, and the collected fine particles are placed in the dust collection space (S1) together with the collection solution (ℓ). It can be stored temporarily.

On the other hand, when a certain amount of the collection solution (ℓ) and the collected fine particles are stored in the dust collection space (S1), the collection solution (ℓ) can be discharged to the collection solution storage unit 300 by opening the discharge passage 322. .

The filter body 700 and the dust collecting part 800 have a flange 10 connected to each other, and may be fixedly coupled to each other through a clamp 600 installed on the flange 10.

Since the above has been only described with respect to some of the preferred embodiments that can be implemented by the present invention, the scope of the present invention as well known should not be limited to the above embodiments and should not be interpreted, the technical of the present invention described above It will be said that all the thoughts and the technical thoughts together with the fundamentals are included in the scope of the present invention.

100: prefilter 200: cyclone unit
300: collection solution storage unit 400: drive control unit
500: filter 600: clamp
700: filter body 800: dust collecting unit
900: support

Claims (12)

A pre-filter (100) in which gas is sucked from the outside, and the fine particles of the first size range contained in the sucked gas are centrifuged and adsorbed through a collection solution (ℓ);
It is disposed at the lower end of the prefilter 100, and the microparticles of the second size range are additionally centrifuged from the gas in which the microparticles of the first size range are separated through the prefilter 100 to collect the solution a cyclone unit 200 adsorbed through (ℓ);
At least one collection solution storage unit 300 for storing the collection solution (ℓ) supplied to the prefilter 100 and the cyclone unit 200;
The pre-filter 100 and the cyclone unit 200 includes a driving control unit 400 for sucking external gas into the interior and controlling the suction flow rate,
The cyclone unit 200,
A cyclone 210 for centrifuging the fine particles of the second size range by forming a rotating airflow in the gas flowing from the prefilter 100;
It includes an adsorption unit 220 disposed at the bottom of the cyclone 210 for adsorbing the fine particles of the second size range centrifuged through the cyclone 210 through the collection solution (ℓ),
The adsorption unit 220,
The inner diameter decreases as the inner space goes from the top to the bottom, and the inner diameter of the inclined portion 221a to which the collecting solution (ℓ) is supplied, and the inner diameter of the inclined portion 221a increases to prevent reverse flow while preventing the collection solution (ℓ). ), a multi-stage filter device for sorting the size of microparticles and collecting liquid, characterized in that it comprises an expansion part (221b) to form an adsorption space (S4) in which microparticles adsorbed through) are temporarily stored. The method according to claim 1,
The pre-filter 100,
A multi-stage filter device for sorting the size of fine particles and collecting liquids, characterized in that it has a cylindrical shape and is sucked in a tangential direction to the inner diameter of the sucked external gas. delete The method according to claim 1,
The cyclone 210,
A cyclone chamber 213 having a gas inlet 211 at the top and a gas outlet 212 at the bottom;
It is installed in the inside of the cyclone chamber 213, characterized in that it comprises a guide portion 215 for forming a rotational air flow in the gas introduced from the gas inlet 211 by forming a plurality of guide vanes 214 Multi-stage filter device for sorting the size of fine particles and collecting liquid. The method of claim 4,
The adsorption unit 220,
A cylindrical adsorption chamber 221 provided at a lower end of the cyclone chamber 213;
A gas discharge passage (S3) installed through the lower end of the adsorption chamber 221 to discharge gas from which the fine particles of the second size range have been removed, and between the outer wall and the inner wall of the adsorption chamber 221 A multi-stage filter device for sorting the size of fine particles and collecting liquid, characterized in that it comprises a discharge pipe (222) each forming an adsorption space (S4) in which the fine particles of the second size range separated in are adsorbed. The method of claim 5,
A multi-stage filter device for sorting the size of fine particles and collecting liquid, characterized in that the size range of the separated fine particles is determined through the size of the inner diameter of the discharge pipe 222. delete delete The method according to claim 1,
The collection solution storage unit 300,
Provided to exchange the collection solution (L) between the storage chamber 310 in which the collection solution (L) is stored, and between the storage chamber 310 and the prefilter 100 or the cyclone unit 200 A multi-stage filter device for sorting the size of fine particles and collecting liquid, characterized in that it comprises a connecting passage (320). The method of claim 9,
The connection passage 320,
From the supply passage 321 for supplying the collection solution (ℓ) to the pre-filter 100 or the cyclone unit 200, the internal space of the pre-filter 100 or the cyclone unit 200 A multi-stage filter device for sorting the size of fine particles and collecting liquid, comprising a discharge passage 322 for discharging the collection solution (ℓ) in which fine particles are adsorbed. The method according to claim 1,
The pre-filter 100, the cyclone unit 200 and the drive control unit 400,
A coupling part connected to each other is a flange 10, and a multi-stage filter device for size selection and liquid collection of fine particles, characterized in that they are fixedly coupled with each other through a clamp 600 installed on the flange 10. A pre-filter (100) in which gas is sucked from the outside, and the fine particles of the first size range contained in the sucked gas are centrifuged and adsorbed through a collection solution (ℓ);
It is disposed at the lower end of the prefilter 100, and the microparticles of the second size range are additionally centrifuged from the gas in which the microparticles of the first size range are separated through the prefilter 100 to collect the solution a cyclone unit 200 adsorbed through (ℓ);
At least one collection solution storage unit 300 for storing the collection solution (ℓ) supplied to the prefilter 100 and the cyclone unit 200;
The pre-filter 100 and the cyclone unit 200 includes a driving control unit 400 for sucking external gas into the interior and controlling the suction flow rate,
A plurality of the cyclone units 200 separating fine particles of different size ranges are sequentially installed in series so that the fine particles of different size ranges can be sequentially separated,
The cyclone unit 200,
A cyclone 210 for centrifuging the fine particles of the second size range by forming a rotating airflow in the gas flowing from the prefilter 100;
It includes an adsorption unit 220 disposed at the bottom of the cyclone 210 for adsorbing the fine particles of the second size range centrifuged through the cyclone 210 through the collection solution (ℓ),
The adsorption unit 220,
The inner diameter decreases as the inner space goes from the top to the bottom, and the inner diameter of the inclined portion 221a to which the collecting solution (ℓ) is supplied, and the inner diameter of the inclined portion 221a increases to prevent reverse flow while preventing the collection solution (ℓ). ), a multi-stage filter device for sorting the size of microparticles and collecting liquid, characterized in that it comprises an expansion part (221b) to form an adsorption space (S4) in which microparticles adsorbed through) are temporarily stored.

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