KR102065891B1 - Wet dust collector - Google Patents

Abstract

The present invention relates to a wet dust collector, which comprises: a cyclone which receives waste, in which dust and water are mixed, separates the waste by centrifugal force based on a vortex, and makes water in the waste moved upwards and dust in the waste collected downward; a cylinder which is installed at an upper center portion of the cyclone to provide vertical reciprocating force of an inner piston; and a compression device which is installed along the inner vertical direction of the cyclone, and connected to the cylinder to interlock with the vertical reciprocating motion of the piston in the cylinder to perform compression and discharge of dust collected on the lower side of the cyclone. According to the present invention, discharge of polluted water can be minimized.

Description

Wet Dust Collector {WET DUST COLLECTOR}

The present invention relates to a wet dust collector.

The dust collector is a device that separates and collects various dusts such as harmful particulate contaminants or dust contained in the exhaust gas under certain conditions. Various methods such as filtration, gravity settling, centrifugal separation, electric, and wet type are available depending on the dust collection method. exist.

Particularly, in the case of the wet dust collector, the particles are separated and collected in a state in which water or a chemical liquid is attached or dissolved to various dusts such as particulate contaminants or dust to be collected to promote aggregation between the particles.

Such a wet dust collector is more suitable when the particles to be collected inside contain moisture, and not only provide a high dust collection efficiency, but also add various treatment agents in the liquefaction process of the dust collector such as odor or corruption. Additional problems can be solved at the same time and are used in various fields.

Therefore, various attempts and efforts are being made to reinforce the functional aspect of the wet dust collector or to add a specific function, and an attempt has been made to variously modify the internal dust collector structure of the wet dust collector.

In this regard, the prior art document related to the prior art prepared to improve the filtration and dust collection efficiency of the wet dust collector is a "wet dust collector" (hereinafter referred to as "prior art") of Republic of Korea Patent Publication No. 10-0729442.

However, in the case of the conventional wet dust collector including the prior art, the separation process of the waste mixed with water and dust adopts a mechanical driving method, and thus the configuration of performing the mechanical driving frequently fails in the liquid waste.

Moreover, in the conventional wet dust collector including the prior art, even if the dust is collected through the separation of the waste mixed with water and dust, the water is not properly separated and the collected dust contains a considerable amount of water, thereby disposing of the basin. Municipal polluted water was also thrown away, causing environmental pollution, and there was an inconvenience in that the dust in the wet state stuck to the space inside the dust collector, so that a person had to directly enter the dust collector to perform the removal work.

In addition, in the case of the conventional wet dust collector including the prior art, the separation operation is performed as described above, but the person directly into the dust collector to solve the problem that dust containing a considerable amount of moisture does not stick to the dust collector and is removed. Since the dust collector should be shut down in the situation that needs to be entered, there is also a problem that directly leads to a decrease in work efficiency.

The present invention was created to solve the above problems, an object of the present invention is a wet dust collector that can effectively collect the dust only by separating the liquid waste mixed with dust and water through a centrifugal separation method rather than a mechanical drive type. To provide.

In addition, another object of the present invention is to separate the dust and water from the waste so that the separated dust can be collected in a state containing only a minimum of water, and further provides a wet dust collector capable of automatically discharged separated dust after compression. It is.

In order to achieve the above object, the wet dust collector of the present invention is a waste mixed with dust and water is introduced through the centrifugal force by the vortex (Vortex), so that the water in the waste is moved to the upper side and dust in the waste to the lower side Cyclone for collecting dust; A cylinder installed at an upper center portion of the cyclone to provide a vertical reciprocating force of the inner piston; And a compression device installed along the inner vertical direction of the cyclone and connected to the cylinder to interlock with a lifting motion of the piston in the cylinder, to compress and discharge dust collected on the lower side of the cyclone.

Here, the compression device is located in the cyclone from the upper side to the lower side, the upper end is connected to the cylinder rod compression rod; An upper plate portion provided in a plate shape and connected to a lower end of the compression rod portion and having at least two water outlets open up and down; A lower plate portion provided in a plate shape corresponding to the upper plate portion and spaced apart from the upper plate portion by a predetermined interval; A plate connection part having an upper end fixedly coupled to the upper plate part and a lower end coupled to the lower plate part in a flowable manner; And a dust discharge part connected to a lower central part of the lower plate and having a structure in which a diameter becomes wider and inclined toward a lower side over a predetermined area in a vertical direction.

In addition, the lower plate portion may be moved upward toward the upper plate portion along the plate connection portion in contact with the dust collected on the lower side in the cyclone as the compression rod portion moves downward in conjunction with the downward movement of the piston in the cylinder. have.

In addition, the dust discharge portion, the dust discharge portion having a truncated conical structure that is tapered (Taper) to the diameter wider toward the lower side; And a connecting portion for fixing the lower side of the lower plate and the upper side of the dust discharge portion to each other.

The cyclone may include a first body having a cylindrical shape having an inner space, the waste in which dust and water are mixed to form a swirl flow, and having an inlet of the waste introduced into one side; A second body part which is narrowed in diameter from a lower end of the first body part and extends in a hollow conical shape having an inner space; It is provided in the form of a tube having a diameter smaller than the diameter of the first body portion is installed in the form communicating with the internal space of the first body portion in the upper central portion of the first body portion, the internal space of the first body portion and the second body portion A third body part having a discharge port of water in the waste water flowing into the pipe by separating through centrifugal force due to the swirl flow generated in the pipe; And a hollow cylinder extending from the lower end of the second body portion to form an inner space, separated by centrifugal force caused by swirl flow generated in the inner space of the first body portion and the second body portion, and being collected and moved downward. And a fourth body part through which dust in the waste is discharged through the inner space, wherein the cylinder is installed above the third body part, and an upper part of the upper part of the compression rod part connected to the cylinder inside the tube of the third body part. Can be accommodated.

In addition, the lowermost structure of the dust discharge portion in the dust discharge portion is provided in a form that can be moved up and down in the inner space of the fourth body portion, in conjunction with the upward movement of the piston in the cylinder the compression rod portion to the upper side When the dust discharge portion moves to the uppermost side as it moves, the lowest end of the dust discharge portion in the dust discharge portion may be located at the upper end of the inner space of the fourth body portion.

In addition, a first packing member may be installed on the side outer circumferential surface of the dust discharge part in the dust discharge part to prevent leakage through a coupling gap with the inner space of the fourth body part, and the first packing member may be mounted on the cylinder. As the compression rod is lifted in conjunction with the vertical movement of the inner piston, the dust discharge part is elastically deformed when the dust discharge part is lifted from the inner space of the fourth body part, so that the outer peripheral surface of the side of the dust discharge part in the dust discharge part and the fourth body are the lowest. Watertightness between sub-spaces can be maintained continuously.

In addition, a second packing member may be installed on the side outer circumferential surface of the lower plate part to prevent leakage through a coupling gap with the inner space of the fourth body part, and the second packing member may be disposed in a vertical motion of the piston in the cylinder. As the compression rod portion is lifted up and down, the lower plate portion is elastically deformed when being lifted from the inner space of the fourth body portion to continuously maintain the watertight state between the side outer peripheral surface of the lower plate portion and the inner space of the fourth body portion. I can keep it.

And the wet dust collector, one side is in communication with the inlet of the first body portion, the other side is in communication with the waste storage tank, the output pump is installed on one side of the first body from the waste storage tank by the pressure of the output pump A waste inlet pipe providing a movement path for allowing the waste mixed with dust and water to be introduced into the unit; And one side is in communication with the outlet of the third body portion, the other side is in communication with the water reservoir and the water discharge pipe for providing a movement path for the discharge of water in the centrifuged waste; may further comprise a.

According to the present invention has the following effects.

First, water and dust in the waste can be separated by centrifugal separation without a separate driving mechanism, and the separated and collected dust can be automatically compressed and discharged.

Second, through the effects described above, the problem of eliminating the inconvenience that a worker has to go inside the dust collector to perform cleaning to remove dust collected in the dust collector, and ultimately, to stop operation for dust removal work in the dust collector. Can be solved at the same time can be expected to increase the work efficiency.

Third, the process of separating the dust in the waste from water is effectively carried out, and the additional moisture is also removed through a separate compression device to minimize the water content of the collected dust, which can act as a water pollution source when the dust is disposed of. Water emissions can also be minimized.

1 is a front view showing the overall coupling structure of the wet dust collector of the present invention.
Fig. 2 is a combined perspective view showing a cyclone, a cylinder, and a compression device in the wet dust collector of the present invention.
Figure 3 is a conceptual diagram for explaining the centrifugation and dust collection method of the waste introduced into the wet dust collector of the present invention.
4 is a conceptual view illustrating a compression method of dust collected in a wet dust collector of the present invention.
FIG. 5 is a conceptual view illustrating a moving method for discharging compressed dust after dust collection in a wet dust collector of the present invention.
6 is a conceptual view illustrating a discharge method of compressed dust after dust collection in the wet dust collector of the present invention.

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS Preferred embodiments of the present invention will be described in more detail with reference to the accompanying drawings, but the well-known technical parts will be omitted or compressed for brevity of description.

1. Description of structure of wet dust collector

Referring to Figures 1 to 3, the wet dust collector 100 of the present invention is a waste storage tank 110; Output pump 120; Waste inlet pipe 125; Cyclone 130; Cylinder 140; Compression device 150; Water discharge pipe 160; Water storage tank 170; Exhaust nozzle 180; And an exhaust body 190.

The waste storage tank 110 is a storage tank space in which a liquid waste (WD) in which dust (D) and water (W) are mixed is connected to a specific processing equipment, and particulate contaminants generated during the operation of the equipment. Alternatively, as a material to be disposed of, such as various dusts, such as dust, the expression 'dust' expressed throughout the specification including the claims refers to all the fine contaminants generated during the operation of a specific facility. The concept is set.

One side of the waste storage tank 110, the output pump 120 and the waste to move to the space for performing the dust collecting operation, such as separation, compression, discharge of the liquid waste mixed with the dust and water stored therein Inlet pipe 125 is installed.

Furthermore, a separate underwater insertion-resistant pump (not shown) may be installed at one side of the waste storage tank 110. Here, the wear-resistant pump is a part designed in consideration of the fact that the dust in the liquid waste stored in the waste storage tank 110 has a sediment distribution at the bottom and that the dust is provided mostly with abrasive abrasives, the output described above The pump 120 may be implemented in one device, or in some cases, may be separated and implemented in each device.

Output pump 120 is a pump configuration for sending the liquid waste (WD) stored in the waste storage tank 110 into the cyclone 130 through the waste inlet pipe 125, installed on one side of the waste inlet pipe 125 do.

 Waste inlet pipe 125 is one side is in communication with the inlet of the first body portion 131 in the cyclone 130 to be described later, the other side is in communication with the waste storage tank 110, the output pump 120 is at one side The movement path is installed so that the waste (WD) mixed with the dust (D) and water (W) in the first body portion 131 from the waste storage tank 110 by the pressure of the output pump 120 can be introduced. To provide plumbing.

Cyclone 130 is a liquid waste (WD) mixed with dust (D) and water (W) is introduced and separated through centrifugal force by the swirl (Vortex), the water (W) in the waste is moved upwards ( IV) and the dust in the waste (D) is a centrifugal device to allow the dust (OV) to be lowered, there is no need for a separate movable part.

Thus, when the separation of the liquid waste (WD) mixed with dust (D) and water (W) by using a centrifugal separation through the cyclone 130, the liquid waste containing a large amount of water (WD) Various moving parts are involved in the separation and collection process, such as failure or damage to the moving parts caused by the accumulation of waste in the moving parts, the need for direct cleaning, and the operation of the dust collector itself for cleaning. Possible to resolve

To this end, the cyclone 130 as shown in Figures 2 and 3, the first body portion 131, the second body portion 132, the third body portion 133 and the fourth body portion 134 Include.

Here, the first body 131 is provided in a cylindrical shape having an internal space, the waste (WD) mixed with dust and water to form a swirl flow inlet is provided on one side of the inlet.

Waste introduced into the inner space of the first body 131 is introduced from the waste storage tank 110 by the pressure of the output pump 120 through the waste inlet pipe 125 described above, After being introduced, it forms a swirling flow and is centrifuged together with the inner space of the second body portion 132 which will be described below.

Next, the second body portion 132 is a body of the cyclone 130, which is formed in a hollow conical shape with a narrower diameter from the lower end of the first body portion as shown in FIG. The first body portion 131 is integrated with the centrifugal separation.

Specifically, as shown in FIG. 3, particles are separated from each other based on the centrifugal force for the particles constituting the waste by the rotation of the waste WD flowing into the inner space of the first body 131. 1 through the formation of the swirl flow from the upper side provided with the inlet of the body portion 131 to the lower side of the second body portion 132.

First, as shown in FIG. 3, the waste WD introduced into the internal space of the first body 131 is screwed and forms the outer swirl flow OV, and the upper side of the first body 131 is formed. In the downward movement to the lower side of the second body portion 132, in the process dust (D) in the waste is sedimented on the lower side of the second body portion 132 is made to collect.

Next, as shown in FIG. 3, the water W in the waste, which forms the outer swirl flow OV and moves downward to the lower side of the second body 132, finishes the downward screw movement and the inner swirl flow ( IV) is moved upward from the lower side of the second body portion 132 to the upper side of the first body portion 131 in the form.

In this way, the inner space of the first body portion 131 and the second body portion 132 is moved downward along the outer swirl flow (OV), and then moved upward along the inner swirl flow (IV) Water W is discharged to the outside after moving to the inner space of the third body portion to be described below.

In this regard, the third body portion 133 is provided in the form of a tube having a smaller diameter than the diameter of the first body portion 131 and the inner space of the first body portion 131 in the upper central portion of the first body portion 131. Corresponding to the swirl flow finder (Vortex Finder) of the cyclone 130 is installed in communication.

Here, the water (W) in the waste moved upward along the inner swirl flow (IV) described above is introduced into the pipe of the third body portion 133.

And one side of the third body portion 133 is separated by centrifugal force due to the swirl flow generated in the inner space of the first body portion 131 and the second body portion 132 is moved upward and flows into the tube An outlet for water W in the waste is provided.

 Accordingly, the outlet of the water (W) in the waste provided on one side of the third body portion 133 is connected to the water storage tank 170 through the water discharge pipe 160.

 Specifically, the water discharge pipe 160 is one side is in communication with the outlet of the third body portion 133, the other side is in communication with the water storage tank 170 to move for the discharge of the water (W) in the centrifuged waste It is the configuration of piping to provide a path.

 2 and 3, the water discharge pipe 160 is provided on the side of the third body portion 133, and most preferably, the first body portion 131 feel of the third body portion 133 It is installed on the side of the outer region exposed to the outside of the upper side of the first body portion 131 of the inner region and the outer region.

 Finally, as shown in FIGS. 2 and 3, the fourth body part 134 extends into a hollow cylindrical shape in which an inner space is formed from the lower end of the second body part 132, and the first body part 131. And a dust discharge port for separating dust (D) in the waste collected by moving through the centrifugal force due to the swirl flow (OV) generated in the inner space of the second body 132 to be discharged through the inner space. Perform the inverse of.

Specifically, the waste WD introduced into the inner space of the first body portion 131 is screwed and forms the outer swirl flow OV, and the second body portion 131 is formed on the upper side of the first body portion 131. After the dust (D) in the waste is sedimented to the lower side of the second body portion 132 through the process of moving downward to the lower side of the 132 is collected and the cylinder 140 and the compression device 150 to be described later By being automatically discharged to the external or separate dust storage tank, the dust (D) collected in the lower side of the second body portion 132 in the process is discharged through the fourth body portion 134.

The cylinder 140 is installed on the upper central portion of the cyclone 130 to provide vertical reciprocating force of the inner piston. Specifically, the cylinder 140 is installed on the upper side of the third body portion 133 to provide a tube of the third body portion 133. The compression rod 151 interlocked with the cylinder 140 can be lifted therein.

Here, in the cylinder 140, the lifting movement of the up and down reciprocating movement is made by the piston, and thus a separate device connected to the cylinder 140 is linked to the lifting movement of the piston to perform the up and down reciprocating movement.

Compressor 150 is installed along the inner vertical direction of the cyclone 130, and is connected to the cylinder 140, in conjunction with the lifting movement of the piston in the cylinder 140, dust collected below the cyclone 130 ( Perform compression and ejection of D).

To this end, the compression device 150 includes a compression rod 151, an upper plate 152, a lower plate 153, a plate connecting portion 154 and the dust discharge unit 155.

First, the compression rod 151 is located in the cyclone 130 from the upper side to the lower side, the upper end is a rod-shaped rod connected to the cylinder 140, the upper portion of the compression rod 151 is the third body portion It is accommodated in a state connected to the cylinder 140 inside the tube of 133.

Therefore, the compression rod unit 151 also moves up and down in conjunction with the lifting movement of the piston in the cylinder 140, and is installed to be located in the inner space of the cyclone 130 as shown in Figure 2 and 3 as a whole. .

Next, the upper plate portion 152 is provided in the form of a plate is connected to the lower end of the compression rod portion 151, and at least two or more water outlets 152H open up and down is provided.

Next, the lower plate part 153 is provided in a plate shape corresponding to the upper plate part 152 and is spaced apart from the upper plate part 152 by a predetermined interval.

Here, the shape and size of the upper plate portion 152 and the lower plate portion 153 is preferably provided to correspond to the shape and opening diameter of the inner space of the fourth body portion 134, in particular the lower plate portion 153 The shape and size of the should be able to prevent the leak without a gap when moving to the inner space of the body portion 134 in consideration of the installation of the second packing member 153S to be described later.

Next, the plate connecting portion 154 is fixedly coupled to the upper end of the upper plate portion 152, the lower end is coupled to the flowable form to the lower plate portion 153, the upper plate portion 152 and the lower plate portion 153 Connect it.

Accordingly, when a force is applied from the lower portion, the upper plate portion 152 and the plate connecting portion 154 may move to the upper portion of the lower plate portion 153 along the plate connecting portion 154 while the phase is fixed. Become.

Specifically, the lower plate portion 153 is lower in the cyclone 130 (the lower side of the second body portion 132) as the compression rod portion 15 moves downward in association with the downward movement of the piston in the cylinder 140. In contact with the dust collected in the upper plate portion 154 is moved upward to the upper plate portion 152 side.

As a result, the dust D collected between the upper plate 152 and the lower plate 153 is narrowed between the upper plate 152 and the lower plate 153 during the downward movement of the cylinder 140. As the load is applied, the first body part is compressed from the lower side of the second body part 132 along the inner swirl flow IV through the water outlet 152H by squeezing out moisture contained in the collected dust D. At the same time as to join the flow of the upward movement to the upper side of the 131, the dust is reduced further through the compression to be pushed down through the side between the upper plate portion 152 and the lower plate portion 153.

This is the first body from the lower side of the second body portion 132 in the form of forming the inner swirl flow (IV) after completing the downward screw movement in the dust collected to the lower end of the second body portion 152 in the cyclone (130) It is a configuration for minimizing the remaining water contained in the stay without moving upward to the upper portion (131).

In addition, a second packing member 153S may be installed on the side outer circumferential surface of the lower plate 153 to prevent leakage through a coupling gap with the inner space of the fourth body 134 as illustrated in FIG. 5. .

As the second packing member 153S is interlocked with the vertical movement of the piston in the cylinder 140, as the compression rod part 151 is lifted, the lower plate part 153 is lifted in the inner space of the fourth body part 134. When it is elastically deformed is a leakage preventing means for continuously maintaining the watertight state between the side outer peripheral surface of the lower plate portion 153 and the inner space of the fourth body portion 134.

Finally, the dust discharge unit 155 is connected to the lower central portion of the lower plate 153, and has a structure that forms a slope and the diameter is wider toward the lower side over a predetermined area of the vertical direction.

Specifically, as shown in FIG. 2, the dust discharge part 155 is wider in diameter toward the lower side, and the dust discharge part 155a and the lower plate 153 having a truncated conical structure inclined to taper. It includes a connecting portion 155b for fixing the lower side and the upper side of the dust discharge portion 155a mutually.

Here, the structure of the lowermost part of the dust discharge portion 155a is provided in a form capable of moving up and down within the inner space of the fourth body portion 154.

In addition, when the dust discharge part 155 moves upward as the compression rod part 151 moves upward in conjunction with the upward movement of the piston in the cylinder 140, the lowermost end of the dust discharge part 155a is the fourth body. It is designed to be located at the top of the inner space of the portion 134.

In particular, the truncated conical shape of the dust discharge portion 155a is dust collected between the lower plate 153 and the dust discharge portion 155 through the inclined area, the dust (D) is discharged through the fourth body 134 When it is natural to slide down as shown in Figure 6.

In addition, the first packing member 155S may be installed on the side outer peripheral surface of the dust discharge part 155a at the lowermost end to prevent leakage through a coupling gap with the inner space of the fourth body part 134 as shown in FIG. 3. have.

Here, the first packing member 155S is linked to the vertical movement of the piston in the cylinder 140, so that the dust discharge portion 155 ascend in the inner space of the fourth body portion 134 as the compression rod 151 is elevated. When it is elastically deformed is a leakage preventing means for continuously maintaining a watertight state between the outer peripheral surface of the lowermost side of the dust discharge portion (155a) and the inner space of the fourth body portion 134.

The exhaust nozzle 180 is installed on the upper side of the water storage tank 170 to filter the air (A) above the water (W) separated from the waste stored in the interior of the water storage tank 170 by centrifugation and exhaust body. It is a configuration for going out through the 190.

Specifically, the exhaust nozzle 180 may also discharge the water (W) separated through centrifugal separation from the waste stored therein in the process of filtering and discharging the air layer existing in the water storage tank 170. It includes a filtration duct 181 and a sub duct 182 to prevent this and fall back into the water storage tank 170.

Here, the filtration duct 181 is made up of the upper and lower through cylindrical shape of the upper and lower narrow (上 廣 下 狹), the upper end is coupled to the communication hole and the lower end of the frame spaced apart from the water surface of the water storage tank 170, It is disposed on the inner center of the frame, consisting of a plate made of a plate shape, and the inclined skirt formed to be inclined downward along the circumference of the plate, it is made of a blocking plate spaced apart from the inner peripheral surface of the frame by a bracket.

The filtration duct 181 of this structure induces air and water to come into contact with each other by the principle of an orifice. The water duct 181 hits the blocking plate and falls without further rising.

In addition, the sub duct 182 is configured to be spaced apart from the communication hole so as to block the water introduced into the exhaust space 190T of the exhaust body 190 secondary, the water storage tank in which the communication hole is located ( 170 is a sub-blocking plate consisting of two or more subframes installed vertically at the top, a plate-shaped subplate coupled to an upper end of the subframe, and a sub-inclined skirt inclined downward along the periphery of the subplate 521. Is done.

The exhaust body 190 is a body through which the air layer A, which has passed through the exhaust nozzle 180, enters the internal exhaust space 190T and is discharged to the outside. The exhaust body 190 includes an exhaust pipe 193 and a suction fan 195. do.

After filtration from the inside of the water storage tank 170 via the exhaust nozzle 180, the water (W) falls again, and the air (A) layer introduced into the exhaust space 190T passes through the exhaust pipe 193 through the suction fan ( 195 may be pressurized and discharged to the outside.

2. Description of the usage of wet dust collector

Referring to Figures 3 to 6 in detail the form of dust collection, compression, movement, discharge of the wet dust collector 100 of the present invention, the wet dust collector 100 of the present invention is centrifuged inside the cyclone 130 The dust (D) separated and separated from the water through the method is automatically discharged to the outside of the cyclone 130 through the cylinder 140 and the compression device 150.

Through this, unlike the prior art, when using the wet dust collector 100 of the present invention for the removal of the dust collected in the dust collector 100 to solve the inconvenience of having to enter the dust collector 100 directly to perform the cleaning, as well as Ultimately, the problem of stopping operation for dust removal work inside the dust collector 100 may be solved at the same time, thereby providing an effect of increasing work efficiency.

Furthermore, the process of separating the dust (D) in the waste (WD) from the water (W) is effectively carried out, and further removal of residual water through a separate compression device to minimize the moisture content of the collected dust (D) This can also provide the effect of minimizing the release of contaminated water, which can act as a water pollution source.

First, as shown in FIG. 3, the phases of the cylinder 140 and the compression device 150 are positioned at the top of the dust collection process. In this case, the configuration of the cylinder 140 and the compression device 150 is located at the bottom of the compression device 150. The lowermost end of the dust discharge part 155 is located at the uppermost end of the fourth body part 134 of the cyclone 130, and the dust is continuously kept in such a state that the dust collected does not fall into the fourth body part 134 before compression. Dust collection is in progress.

Next, after dust collection is completed, as shown in FIG. 4, the piston of the cylinder 140 starts the downward motion so that the phase of the compression device 150 is also moved downward, and the phase of the compression device 150 is generally changed. The lower plate portion 153 moves along the plate connecting portion 154 toward the upper plate portion 152 toward the upper plate portion 152 and immediately before or downwardly, and is collected between the upper plate portion 152 and the lower plate portion 153. The collected dust (D) is compressed to the side and collected again down, the residual moisture contained in the dust is discharged through the water outlet (153S) of the upper plate portion 152 and rises along the inner swirl flow (IV) After flowing into the third body 133, the water storage pipe 170 moves through the water discharge pipe 160.

Next, after the compression of the dust and the removal of the residual water is completed, as shown in FIG. 5, the piston of the linder 140 continues downward movement so that the phase of the compression device 150 is further moved downward so that the lower plate portion 153 ) And dust discharged between the dust discharge unit 155 can be moved into the fourth body portion 134 of the cyclone (130).

The first packing member 155S and the second packing member 153S as leakage preventing means installed on the outer surface of the lower plate portion 153 and the lower outer surface of the dust discharge portion 155a of the dust discharge portion 155 in the process. ) Keeps the leak protection on the go.

Finally, as the dust continues to move inside the fourth body 134 of the cyclone 130, as shown in FIG. 6, the bottom end of the dust discharge part 155a of the dust discharge part 155 is the fourth body part 134. When passing through the bottom end of the), the dust compressed between the lower plate portion 153 and the dust discharge portion 155 is discharged by sliding down along the inclined surface formed by the dust discharge portion (155a).

Therefore, when passing through the lower end of the fourth body portion 134 to the lower plate portion 153, all the moving dust (D) is discharged to the outside and collected separately in a separate storage tank, the piston of the cylinder 140 Again, the upward motion is started so that the phase of the compression device 150 is also moved upward to restore the state as shown in FIG.

Accordingly, the wet dust collector 100 in which the phase recovery of the compression device 150 is completed is waste (W) mixed with dust (D) and water (W) again through an inlet of the first body part 131 of the cyclone 130. WD) is introduced to perform the separation and dust collection by centrifugation in the cyclone (130) inside, repeating the above process continuously.

The embodiments disclosed in the present invention are not intended to limit the technical idea of the present invention but to describe the present invention, and the scope of the technical idea of the present invention is not limited by these embodiments. The scope of protection should be interpreted by the following claims, and all technical ideas within the scope equivalent thereto shall be construed as being included in the scope of the present invention.

100: wet dust collector
110: waste storage tank
120: output pump
125: waste inlet pipe
130: cyclone
131: first body portion 132: second body portion
133: third body portion 134: fourth body portion
140: cylinder
150: compression device
151: compression rod portion 152: upper plate portion
152H: water outlet 153: lower plate part
153S: second packing member 154: plate connection
155: dust discharge part 155S: first packing member
160: water discharge pipe
170: water storage tank
180: exhaust nozzle
181: filtration duct 182: sub duct
190: exhaust body
190T: Exhaust Space 193: Exhaust Pipe
195: suction fan
WD: Waste
W: water
D: Dust
A: air

Claims (9)

A cyclone (Cyclone) in which waste mixed with dust and water flows in and is separated by centrifugal force by a vortex (Vortex), so that water in the waste is moved upwards and dust in the waste is collected downward;
A cylinder installed at an upper center portion of the cyclone to provide a vertical reciprocating force of the inner piston; And
And a compression device installed along the inner vertical direction of the cyclone and connected to the cylinder to interlock with the lifting motion of the piston in the cylinder to perform compression and discharge of dust collected on the lower side of the cyclone.
The compression device,
A compression rod part positioned from an upper side to a lower side in the cyclone, and having an upper end connected to the cylinder;
An upper plate portion provided in a plate shape and connected to a lower end of the compression rod portion and having at least two water outlets open up and down;
A lower plate portion provided in a plate shape corresponding to the upper plate portion and spaced apart from the upper plate portion by a predetermined interval;
A plate connection part having an upper end fixedly coupled to the upper plate part and a lower end coupled to the lower plate part in a flowable manner; And
It is connected to the lower central portion of the lower plate, the dust discharge portion having a structure that forms a slope wider toward the lower side over a predetermined area on the basis of the vertical direction;
The dust discharge unit,
A dust discharge portion having a truncated conical structure, the diameter of which is wider toward the lower side and tapered to taper; And
And a connecting portion configured to mutually fix the lower side of the lower plate and the upper side of the dust discharge portion.
Wet dust collector.
delete The method of claim 1,
The lower plate portion is moved upward toward the upper plate portion along the plate connection portion in contact with the dust collected on the lower side in the cyclone as the compression rod portion moves downward in conjunction with the downward movement of the piston in the cylinder. doing
Wet dust collector.
delete The method of claim 3,
The cyclone is,
A first body part having a cylindrical shape having an inner space, the waste in which dust and water are mixed to form a swirl flow, and having an inlet of the waste introduced into one side;
A second body part which is narrowed in diameter from a lower end of the first body part and extends in a hollow conical shape having an inner space;
It is provided in the form of a tube having a diameter smaller than the diameter of the first body portion is installed in the form communicating with the internal space of the first body portion in the upper central portion of the first body portion, the internal space of the first body portion and the second body portion A third body part having a discharge port of water in the waste introduced into the pipe by separating through centrifugal force due to the swirl flow generated in the pipe and flowing into the pipe; And
Waste formed by extending from the lower end of the second body portion to a hollow cylindrical shape having an inner space, separated by centrifugal force due to the swirl flow generated in the inner space of the first body portion and the second body portion and collected and moved downward And a fourth body part in which dust is discharged through the inner space.
The cylinder is installed on the upper side of the third body portion, and the upper portion of the compression rod portion connected to the cylinder is accommodated in the tube of the third body portion, characterized in that
Wet dust collector.
The method of claim 5,
The lowermost structure of the dust discharge portion in the dust discharge portion is provided in a form capable of moving up and down in the inner space of the fourth body portion,
When the dust discharge portion moves upward as the compression rod portion moves upward in association with the upward movement of the piston in the cylinder, the lowermost end of the dust discharge portion in the dust discharge portion is located at the top of the inner space of the fourth body portion. Characterized by
Wet dust collector.
The method of claim 6,
A first packing member is installed on the side outer peripheral surface of the lowermost part of the dust discharge part in the dust discharge part to prevent leakage through a coupling gap with the inner space of the fourth body part.
The first packing member is elastically deformed when the dust discharge part is elevated in the inner space of the fourth body part as the compression rod part is lifted in conjunction with the vertical movement of the piston in the cylinder, thereby lowering the dust discharge part in the dust discharge part. Characterized in that the watertight state between the outer peripheral surface of the side and the inner space of the fourth body portion is continuously maintained.
Wet dust collector.
The method of claim 7, wherein
On the side outer peripheral surface of the lower plate portion is provided a second packing member for preventing leakage through the coupling gap with the inner space of the fourth body portion,
The second packing member is elastically deformed when the lower plate part is lifted from the inner space of the fourth body part as the compression rod part is lifted in conjunction with the vertical movement of the piston in the cylinder. 4, characterized in that to maintain the watertight state between the inner space of the body portion continuously
Wet dust collector.
The method of claim 5,
The wet dust collector,
One side is in communication with the inlet of the first body portion, the other side is in communication with the waste storage tank, the output pump is installed on one side dust and water in the first body portion from the waste storage tank by the pressure of the output pump A waste inlet pipe providing a movement path through which the mixed waste can be introduced; And
One side is in communication with the outlet of the third body portion, the other side is in communication with the water reservoir and the water discharge pipe for providing a movement path for the discharge of water in the centrifuged waste; further comprising a
Wet dust collector.

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