KR102018047B1 - Solidification System Of Fine Particle - Google Patents

Abstract

The present invention is a dust collecting device for collecting fine particles (10); Fine particle transfer device 20 for transferring the collected fine particles; A buffer storage device 30 for temporarily storing the transferred fine particles; A discharge transfer device (60) for discharging and transferring the solidified pellets; And a pellet temporary storage system 70 for temporarily storing the discharged and transported pellets, wherein the buffer storage device is disposed between the buffer storage device 30 and the discharge transfer device 60. It relates to a solidification system, characterized in that it comprises a continuous compression device (50) for continuously compressing the fine particles taken out in 30) and solidified into pellets to supply to the discharge transfer device (60).

Description

Solid Particle Solidification System

The present invention is a dust collecting device for collecting fine particles (10); Fine particle transfer device 20 for transferring the collected fine particles; A buffer storage device 30 for temporarily storing the transferred fine particles; A discharge transfer device (60) for discharging and transferring the solidified pellets; And a pellet temporary storage system 70 for temporarily storing the discharged and transported pellets, wherein the buffer storage device is disposed between the buffer storage device 30 and the discharge transfer device 60. It relates to a fine particle solidification system, characterized in that it comprises a continuous compression device (50) for continuously compressing the fine particles taken out in 30) and solidified into pellets to supply to the discharge transfer device (60).

The present invention provides fine particles that solidify fine particles such as food waste, plastics such as PET bottles, metals such as ceramics, glass, vinyl, paper, aluminum, or finely crushed objects or goods. A particle solidification system.

The fine particles, for example, particulate matter (PM) are air pollutants containing numerous air pollutants together with sulfurous acid gas, nitrogen oxides, lead, ozone, carbon monoxide, etc., generated in automobiles and factories. Therefore, it is a fine dust having a particle diameter of 10㎛ or less floating in the air for a long time, and is called PM10, and when the particle is 2.5㎛ or less, it is written as PM 2.5 and is called 'ultrafine dust' or 'ultrafine dust'. Academia is called aerosol. Fine particles are also called suspended particles, particulate matters, etc. and have slightly different meanings according to their names. The particulate matter has an aerodynamic particle diameter (diameter) of about 10 nm to 100 μm. If the particle size is larger than that, the residence time in the atmosphere is very short due to the sedimentation effect caused by gravity.

Fine dust is a substance that greatly affects the human body. Air pollution, which killed 20 people in Donora, Pennsylvania, in 1948, and London Smog, which caused about 4,000 deaths in 1952, are examples of how fine dust affects the human body. Since then, various epidemiological investigations have been conducted on the effect of fine dust on the human body. Especially, the fine dust particles (PM10) of 10㎛ or less are highly likely to have harmful effects on the human body, such as increasing the incidence and mortality rate of vulnerable groups. It turned out. After these findings, governments began to prepare air pollution measures, and air pollution standards were also set up to reduce the harmful effects of fine dust on the human body and the environment.

The state in which particulate matter (solid or liquid state) is suspended in the air is generally called aerosol. It is commonly referred to as dust.

Although the particle size range of dust is 0.001 ~ 1000㎛, dust of 70㎛ or more is settled immediately when it occurs, so dust below 70㎛ is generally called Total Suspended Particle (TSP).

The particle size of dust below 0.1㎛ is called ultra range, and most of dust is distributed between 0.1 ~ 10㎛. Particles in the range of 0.1 to 1 ㎛ have a long residence time in the air and are most easily infiltrated into the alveoli because they are not easily settled or aggregated due to the nature of the particle size distribution. The particles having a size of 0.5 μm have the largest scattering effect of light, which may cause a decrease in visibility.

The sources of fine dust are classified into artificial and natural occurrences. And dust from dill ashes and forest fires. Sea salt particles also have a lot of influence where they are located near the sea.

About 50% of these fine dusts are caused in Korea, and at this point, it is necessary to collect and process fine particles such as fine dusts, and in the future, fine dust regulation is expected to be intensified. In addition to fine dust, the demand for fine particle processing technology for finely crushing objects or goods is expected to increase.

In relation to the conventional fine particle treatment technology, Figure 6 is a photograph showing the fine dust, that is, the existing dust treatment process of one of the existing fine particles.

Referring to FIG. 6, after collecting the fine particles in the dust treatment apparatus and storing the collected fine particles and putting them back in the tone bags, the tone bags are transported to a waste site and finally, the fine particles are disposed and landfilled in the waste site. In the above process, there was a problem that a large amount of scattering dust is generated during storage, toneback treatment, and dump site transportation.

Republic of Korea Patent Publication No. 10-0667711 (2007.01.05.).

The present invention aims to solve the problems of the prior art as described above.

In particular, it is an object of the present invention to provide a fine particle solidification system that allows for the collection and processing of fine particles.

Another object of the present invention is to recycle useful resources contained in the fine particles.

Another object of the present invention is to reduce the transport cost through the compression of the fine particles.

Technical problems to be achieved by the present invention are not limited to the above-mentioned problems, and other technical problems not mentioned above may be clearly understood by those skilled in the art from the following description. There will be.

The fine particle solidification system according to the present invention for achieving this object is a dust collecting device for collecting fine particles (10); Fine particle transfer device 20 for transferring the collected fine particles; A buffer storage device 30 for temporarily storing the transferred fine particles; A discharge transfer device (60) for discharging and transferring the pellets solidified from the fine particles; And a pellet temporary storage system 70 for temporarily storing the discharged and transported pellets, wherein the buffer storage device is disposed between the buffer storage device 30 and the discharge transfer device 60. It characterized in that it comprises a continuous compression device (50) for continuously compressing the fine particles taken out and supplied in 30) to solidify the pellets to supply to the discharge transfer device (60).

It is coupled to the continuous compression device 50, and further comprises a binder mixing device 40 for mixing by mixing the fine particles supplied from the buffer storage device 30 with a binder.

The continuous compression device 50 includes a first low pressure piston 52P1 capable of reciprocating inside the outer low pressure cylinder housing 51 by an outer low pressure cylinder housing 51, an inner low pressure cylinder housing 53, and hydraulic pressure. ), A second low pressure piston 52P2 capable of reciprocating in the inner low pressure cylinder housing 53 in association with the reciprocating motion of the first low pressure piston 52P1, and the first low pressure piston 52P1 and the first low pressure piston 52P1. A low pressure press section 54 including a rod 52 connecting between two low pressure pistons 52P2; The first high pressure piston 56P1 and the first high pressure piston 56P1 that can reciprocate in the inside of the outer high pressure cylinder housing 55 by the outer high pressure cylinder housing 55, the inner high pressure cylinder housing 57, and hydraulic pressure. The second high pressure piston 56P2 and the first high pressure piston 56P1 and the second high pressure piston 56P2 which may reciprocate in the inner high pressure cylinder housing 57 in association with the reciprocation of And a high pressure press unit 58 including a rod 56 for connecting, wherein the low pressure press unit 54 and the high pressure press unit 58 are arranged at a vertical angle.

The binder mixing device 40 includes: a rotation shaft 42 rotatably installed at the center of the housing 41 in the longitudinal direction of the housing 41; A plurality of first rods 43 disposed perpendicularly to the rotation shaft 42 at intervals along the longitudinal direction of the rotation shaft 42 and composed of a plurality of pairs of rods including a pair of adjacent rods; A plurality of second rods 44 installed perpendicular to the rotation shaft 42 and disposed between the first rods 43 and shorter than the first rods 43; A first ribbon 45 connecting diagonal ends of the rods of each pair of rods of the plurality of pairs of rods of the plurality of first rods 43; A plurality of second ribbons (46) connecting an end portion of one rod of each pair of rods of the plurality of first rods (43) and an adjacent portion adjacent to a center of the other rod; And at least one third ribbon 47 connecting the diagonal ends of each pair of rods of the plurality of pairs of rods including a pair of adjacent rods among the plurality of second rods 44.

As described above, the present invention provides a fine particle solidification system, which makes it possible to enhance the collection and processing of fine particles, to recycle useful resources contained in the fine particles, and to reduce transportation costs through the compression of the fine particles. It is effective to provide.

The technical effects of the present invention are not limited to the technical effects mentioned above, and other technical effects not mentioned above may be clearly understood by those skilled in the art from the description of the claims. There will be.

1 is a view showing an apparatus and process for the treatment of fine particles in a fine particle solidification system according to an embodiment of the present invention.
FIG. 2 is a diagram illustrating a configuration of a continuous compression device among the devices of FIG. 1.
FIG. 3 is a diagram sequentially illustrating a continuous compression operation of the continuous compression device of FIG. 2.
4 is a view showing an embodiment of a binder mixing device of the devices of FIG.
5 is a view showing another embodiment of the binder mixing device of the devices of FIG.
6 is a photograph showing a process of treating existing fine particles.

Hereinafter, exemplary embodiments of the present invention will be described in detail with reference to the accompanying drawings. For reference, the size of the components, the thickness of the line, and the like shown in the drawings referred to for describing the present invention may be somewhat exaggerated for ease of understanding. In addition, terms used in the description of the present invention are defined in consideration of the functions in the present invention and may vary according to a user, an operator's intention, customs, and the like. Therefore, the definition of this term should be based on the contents throughout the specification.

In addition, although the preferred embodiments of the present invention will be described in detail with reference to the accompanying drawings, which can be specifically realized the object of the present invention, which is intended for easier understanding of the present invention, the scope of the present invention is limited thereto It is not. In addition, in describing the embodiment of the present invention, the same name and the same reference numerals are used for the same configuration and additional description thereof will be omitted.

Prior to the detailed description of each construction step of the present invention, the terms or words used in the present specification and claims should not be construed as limiting their ordinary or dictionary meanings, and the inventors should consider their own invention in the best way. For the purpose of explanation, the terms should be interpreted as meanings and concepts corresponding to the technical spirit of the present invention based on the principle that the concept of terms may be properly defined. Therefore, the embodiments described in the specification and the drawings shown in the drawings are only the most preferred embodiment of the present invention and do not represent all of the technical spirit of the present invention, various modifications that can be replaced at the time of the present application It should be understood that there may be equivalents and variations.

1 is a view showing an apparatus and process for processing fine particles in a solidification system according to an embodiment of the present invention.

Referring to Figure 1, the fine particle solidification system according to an embodiment of the present invention, the dust collector 10, fine particle transfer device 20, Buffer storage device 30, continuous compression device 50, discharge transport Apparatus 60, and pellet temporary storage system 70.

The dust collector 10 is for collecting fine particles, the fine particle transport device 20 is for transporting the collected fine particles, the buffer storage device 30 to temporarily store the transported fine particles It is for.

FIG. 2 is a view showing the configuration of a continuous compression device among the devices of FIG. 1, and FIG. 3 is a view showing a continuous compression operation of the continuous compression device of FIG.

Referring to FIGS. 2 and 3, the continuous compression device 50 includes fine particles drawn out from the buffer storage device 30 and supplied between the buffer storage device 30 and the discharge transfer device 60. Is a device for continuously compressing and solidifying the pellets into pellets and supplying them to the discharge transfer device 60. Specifically, the outer low pressure cylinder housing 51, the inner low pressure cylinder housing 53, and the external low pressure cylinder housing by hydraulic pressure ( The first low pressure piston 52P1 capable of reciprocating in the inside of 51, and the second low pressure reciprocating inside the inner low pressure cylinder housing 53 in association with the reciprocating motion of the first low pressure piston 52P1. A low pressure press part (54) comprising a piston (52P2) and a rod (52) connecting between the first low pressure piston (52P1) and the second low pressure piston (52P2); The first high pressure piston 56P1 and the first high pressure piston 56P1 that can reciprocate in the inside of the outer high pressure cylinder housing 55 by the outer high pressure cylinder housing 55, the inner high pressure cylinder housing 57, and hydraulic pressure. The second high pressure piston 56P2 and the first high pressure piston 56P1 and the second high pressure piston 56P2 which may reciprocate in the inner high pressure cylinder housing 57 in association with the reciprocation of And a high pressure press unit 58 including a rod 56 for connecting. The low pressure press unit 54 and the high pressure press unit 58 are disposed at a vertical angle.

According to this configuration, the microparticles that can be solidified by compression, for example, bioparticles, continuous chips are entangled with each other by compression without a binder, such as a binder, such as a biomass, a continuous chip, and the microparticles capable of compression can be continuously compressed. Compression and solidification are possible only by the continuous compression force of the low pressure press unit 54 and the high pressure press unit 58 without a separate binder.

In this embodiment, the continuous compression device 50 includes a low pressure press section 54 and a high pressure press section 58, and the low pressure press section 54 and the high pressure press section 58 are disposed at a vertical angle. Although the present invention is illustrated and described, the present invention is not limited thereto. In another embodiment, the present invention further includes two or more intermediate pressure press parts having one or different pressures in addition to the low pressure press part 54 and the high pressure press part 58. The low pressure press unit 54, the high pressure press unit 58, and one or more intermediate pressure press units may be arranged at a predetermined angle.

The continuous compression device 50 is shown and described as a continuous compression of the fine particles 80, where the fine particles 80, such as food waste, plastics such as PET bottles, ceramics, glass, vinyl, paper, aluminum An object or a product containing metal is finely crushed or fine dust, which refers to a finely crushed or fine dust of an object, object or product.

The discharge transfer device 60 is a device for discharging and conveying solidified pellets, and the pellet temporary storage system 70 is a space for temporarily storing the discharged pellets.

In the present embodiment, in the case of fine particles that cannot be solidified only by compression, for example, ultra-fine particles, metal rust, ceramics, dust, etc., when compression is not possible due to the fine particle characteristics, the solidification system of the present invention is It is also coupled to the continuous compression device 50, it is also possible to further comprise a binder mixing device 40 for mixing the agitated fine particles supplied from the buffer storage device 30 with the binder.

In this regard, FIG. 4 is a view showing an embodiment of a binder mixing device among the devices of FIG. 1.

Referring to FIG. 4, in the above embodiment, the binder mixing device 40 may include: a rotation shaft 42 installed at a center of the housing 41 in the longitudinal direction of the housing 41 to rotate; A plurality of first rods 43 disposed perpendicularly to the rotation shaft 42 at intervals along the longitudinal direction of the rotation shaft 42 and composed of a plurality of pairs of rods including a pair of adjacent rods; A plurality of second rods 44 installed perpendicular to the rotation shaft 42 and disposed between the first rods 43 and shorter than the first rods 43; A first ribbon 45 connecting diagonal ends of the rods of each pair of rods of the plurality of pairs of rods of the plurality of first rods 43; A plurality of second ribbons (46) connecting an end portion of one rod of each pair of rods of the plurality of first rods (43) and an adjacent portion adjacent to a center of the other rod; And one or more third ribbons 47 connecting the diagonal ends of each pair of rods of the plurality of pairs of rods including a pair of rods adjacent to one another of the plurality of second rods 44.

According to such a structure, since the rotating shaft 42 can rotate, the 1st rod 43 and the 2nd rod 44 provided in the rotating shaft 42, and the 1st ribbon 45 and 2nd connected to these rods, The ribbon 46 and the third ribbon 47 can rotate so that the fine particles in the housing 41 and the binder, which is a binder, can be mixed with proper stirring throughout the housing 41. This makes it possible to prevent the fine particles from scattering during the processing, storage and transport of the fine particles.

In this embodiment, the binder mixing device 40 includes a plurality of first rods 43, a plurality of second rods 44, a first ribbon 45, a plurality of second ribbons 46, and one or more. Although shown and described as being comprised of a third ribbon 47, the invention is not so limited, and in other embodiments is more than the second rod 44 between the first rod 43 and the second rod 44. It is of course also possible to further include a fourth ribbon comprising a third rod of short length and connecting the diagonal ends of two adjacent third rods.

5 is a view showing another embodiment of the binder mixing device of the devices of FIG.

Referring to FIG. 5, the binder mixing device 40 according to another embodiment of the present invention includes a rotating shaft 42 installed and rotated in the center of the housing 41 in the longitudinal direction of the housing 41; Rotation mixing part having three rods 43-1 installed on the rotation shaft at predetermined intervals through the rotation shaft 42 and paddles 43-2 provided at both free ends of the rod 43-1. (43); And a blade 44 disposed between the rods 43-1 and vertically installed on the rotational shaft 42 on both sides of the rotation shaft 42, and the blade 44 may rotate.

According to such a structure, since the rotating shaft 42 and the blade 44 can rotate, respectively, the fine particle in the housing 41 and the binder which are binders are mixed, stirring suitably over the whole in the housing 41, and mixing. This makes it possible to prevent the fine particles from scattering during the processing, storage and transport of the fine particles.

Although described above with reference to the drawings according to an embodiment of the present invention, those skilled in the art to which the present invention pertains to various applications, modifications and modifications can be made within the scope of the present invention based on the above contents. will be. Accordingly, the true scope of protection of the invention should be defined only by the appended claims.

10: dust collector
20: fine particle transfer device
30: Buffer storage device
40: binder mixing device
41: housing
42: rotation axis
43: first rod
44: second rod
45: first ribbon
46: second ribbon
47: third ribbon
50: continuous compression device
51: outer low pressure cylinder housing
52, 56: load
52P1: first low pressure piston
52P2: second low pressure piston
53: inner low pressure cylinder housing
54: low pressure press section
55: outer high pressure cylinder housing
56P1: first high pressure piston
56P2: second high pressure piston
57: inner high pressure cylinder housing
58: high pressure press
60: discharge feeder
70: Pellet Temporary Storage System

Claims (4)

A dust collecting device 10 for collecting fine particles;
Fine particle transfer device 20 for transferring the collected fine particles;
A buffer storage device 30 for temporarily storing the transferred fine particles;
A discharge transfer device (60) for discharging and transporting pellets solidified from the fine particles; And
In the solidification system comprising a temporary storage system 70 for temporarily storing the discharged and conveyed pellets,
Between the buffer storage device 30 and the discharge transport device 60, the fine particles drawn out from the buffer storage device 30 are continuously compressed and solidified into pellets to the discharge transport device 60. It includes a continuous compressor 50 for supplying,
The continuous compression device 50 includes a first low pressure piston 52P1 capable of reciprocating inside the outer low pressure cylinder housing 51 by an outer low pressure cylinder housing 51, an inner low pressure cylinder housing 53, and hydraulic pressure. A second low pressure piston 52P2 capable of reciprocating in the inner low pressure cylinder housing 53 in association with the reciprocating motion of the first low pressure piston 52P1, and the first low pressure piston 52P1 and the second; A low pressure press section 54 including a rod 52 connecting between the low pressure pistons 52P2; The first high pressure piston 56P1 and the first high pressure piston 56P1 which can reciprocate in the inside of the outer high pressure cylinder housing 55 by the outer high pressure cylinder housing 55, the inner high pressure cylinder housing 57, and hydraulic pressure. The second high pressure piston 56P2 and the first high pressure piston 56P1 and the second high pressure piston 56P2 which may reciprocate in the inner high pressure cylinder housing 57 in association with the reciprocation of And a high pressure press unit 58 including a rod 56 for connecting, wherein the low pressure press unit 54 and the high pressure press unit 58 are disposed at a vertical angle.
It comprises two or more intermediate pressure presses of one or different pressures, the low pressure press 54 and the high pressure press 58 and one or more intermediate pressure presses are arranged at an angle,
It is coupled to the continuous compression device 50, and comprises a binder mixing device 40 for mixing by mixing the fine particles supplied from the buffer storage device 30 with a binder,
The binder mixing device 40 includes a rotating shaft 42 which is installed at the center of the housing 41 in the longitudinal direction of the housing 41 and rotates; A plurality of first rods 43 disposed perpendicularly to the rotation shaft 42 at intervals along the longitudinal direction of the rotation shaft 42 and composed of a plurality of pairs of rods including a pair of adjacent rods; A plurality of second rods 44 installed perpendicular to the rotation shaft 42 and disposed between the first rods 43 and shorter than the first rods 43; A third rod having a shorter length than the second rod 44 between the first rod 43 and the second rod 44; A first ribbon 45 connecting diagonal ends of the rods of each pair of rods of the plurality of pairs of rods of the plurality of first rods 43; A plurality of second ribbons (46) connecting an end portion of one rod of each pair of rods of the plurality of first rods (43) and an adjacent portion adjacent to a center of the other rod; One or more third ribbons (47) connecting the diagonal ends of each pair of rods of the plurality of pairs of rods including a pair of adjacent ones of the plurality of second rods (44); And a fourth ribbon connecting the diagonal ends of two adjacent third rods. delete delete delete

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