KR20220022529A - A solid fuel recycling resource system for increases recovery of combustible waste among construction wasters - Google Patents

Abstract

The present invention relates to a solid fuel recycling resource system capable of increasing recovery of combustible waste among construction waste. The solid fuel recycling system includes: a vibration particle size sorter for separating construction mixed waste into a preset size and dividing and discharging first mixed construction waste and second mixed construction waste; a first mixed construction waste treatment unit in which magnetic sorting, particle size sorting, and water sorting treatment processes are performed on the separated first mixed construction waste; a second mixed construction waste treatment unit in which water sorting treatment and primary crushing treatment processes are performed on the separated second mixed construction waste; a confluence transfer facility in which the treated remaining pre-treated construction waste is input and transferred; a combustible waste recovery processing unit for recovering combustible waste through magnetic sorting and specific gravity sorting processes on the pre-treated construction mixed waste; and a waste recycling treatment unit which returns remaining final construction mixed waste to the confluence transfer facility to be recycled after sorting through processing processes of vertical crushing, vibrating feeder, and magnetic sorting.

Description

{A SOLID FUEL RECYCLING RESOURCE SYSTEM FOR INCREASES RECOVERY OF COMBUSTIBLE WASTE AMONG CONSTRUCTION WASTERS}

The present invention relates to a solid fuel recycling resource-making system, and more specifically, reducing construction mixed waste generated at a construction site and recycling it as a resource. It relates to a solid fuel recycling resource system that has increased the recovery rate of combustible waste among construction mixed wastes.

In general, a large number of household wastes or mixed wastes in a state in which combustibles, waste earth, incombustibles, etc. are entangled or combined are discharged from construction sites or workplaces. However, in the case of currently discharged mixed wastes, their properties are combined or tangled to such a degree that it is difficult to separate and sort them, and most of them are simply landfilled or incinerated. When looking at waste by properties, in the case of combustible waste, finely divided soil and incombustible materials are mixed, so a large amount of ash or ash is generated during incineration, increasing the treatment cost due to secondary landfilling, and various hazardous substances due to combustion anxiety. Due to this occurrence, the situation in which it is impossible to bring in the incineration facility is continuously occurring. In addition, in the case of non-combustible materials such as waste earth and iron, it is impossible to bring it to the landfill because it contains finely divided combustible materials and foreign substances. Due to this, the generation of neglected waste, which has been considered a problem in recent years, is continuously increasing, and efforts are needed to fundamentally solve this problem.

Accordingly, as a problem with the previous treatment method, the imported mixed wastes must be separated and treated according to the final treatment standards for each property. Selection is difficult.

1 is a view showing the configuration of a simple sorting of construction mixed waste generated at a conventional construction site. As shown in Figure 1, in the case of construction site waste generated at the construction site, various types of properties are very complexly mixed and entangled, so there is a limit to simple backhoe or manpower sorting. , Since waste cans and coarse combustible wastes are mixed and entangled, it is difficult to separate and sort, and in the case of non-ferrous metals, it is difficult to separate them by simple magnetic sorting, so there is a limit to processing the mixed wastes.

In addition, in the case of cloth and hemp waste, a large amount of soil dust and foreign substances are contained in the composition, so it is difficult to separate it with a simple specific gravity separation method. , a large amount of ash (incineration ash) is generated during incineration, which continues to be a problem.

The present invention has been proposed to solve the above problems of the previously proposed methods, and a vibratory particle size separator that separates construction mixed waste into a preset size and separates it into a first mixed construction waste and a second mixed construction waste and discharges it and a first mixed construction waste treatment unit in which magnetic sorting, particle size sorting, and treatment by repair are performed on the first mixed construction waste, and a second process in which the second construction waste is treated by repair and primary crushing process 2 A construction mixed waste treatment unit, a combined transport facility where pre-treated construction mixed wastes are input and transported, a combustible waste recovery unit that collects combustible wastes through self-sorting and specific gravity sorting processes for pre-treated construction mixed wastes, and combustible waste By including a waste recycling processing unit that is returned to the confluence transfer facility and recycled after sorting through the processing process of vertical crushing, vibration feeder, and magnetic sorting for the remaining final construction mixed waste, each of the construction mixed waste By separating and sorting construction wastes by their properties, it is possible to reduce the amount of construction wastes and turn them into resources through recycling for each property, as well as increase the recovery rate of combustible wastes to enable them to be used as solid fuels. An object of the present invention is to provide a solid fuel recycling system.

In addition, the present invention is configured to enable separation and sorting of each type of mixed construction waste in a state of being entangled or combined with a plurality of characteristics, so that secondary waste generated by incineration or landfill by precise sorting of construction mixed waste. Another object of the present invention is to provide a solid fuel recycling resource-recycling system with an increased recovery rate of combustible waste among construction mixed wastes, which minimizes generation and prevents environmental pollution from occurring.

In addition, the present invention, by automating the process of separation and screening for each property of the construction mixed waste, to increase the processing efficiency of the construction mixed waste, and to enable the other daily processing capacity to be greatly increased, among the construction mixed waste Another object of the present invention is to provide a solid fuel recycling resource conversion system with an increased recovery rate of combustible waste.

A solid fuel recycling resource recycling system with an increased recovery rate of combustible waste among construction mixed wastes according to a feature of the present invention for achieving the above object,

As a solid fuel recycling resource system that increases the recovery rate of combustible waste among construction mixed wastes,

A vibratory particle size separator for separating the mixed construction waste into a predetermined size and discharging the first mixed construction waste and the second mixed construction waste by separating the construction mixed waste inputted to the input facility into which the construction mixed waste discharged from the construction site is input;

a first mixed construction waste treatment unit that performs magnetic sorting, particle size sorting, and repair process for the first mixed construction waste separated through the vibrating particle size sorter;

a second mixed construction waste treatment unit in which water sorting and primary crushing processes are performed on the second mixed construction waste separated through the vibrating particle size sorter;

a merging transfer facility for inputting and transferring the remaining pre-treated construction waste after being respectively processed through the first and second mixed construction waste processing units;

a combustible waste recovery processing unit for recovering combustible wastes through self-selection and specific gravity separation processes for pre-processed construction mixed wastes input and transported to the merging transport facility; and

After sorting through the processing processes of vertical crushing, vibrating feeder, and magnetic sorting for the remaining final construction mixed waste, except for combustible waste classified through the self-selection and specific gravity screening process of the combustible waste recovery processing unit, return to the merging transfer facility It is characterized in its configuration to include a waste recycling treatment unit to be recycled.

Preferably, the vibration particle size sorter,

It may be configured to include a vibrating screen in which a plurality of sorting holes are formed for separating the mixed construction waste into a preset size and discharging the first mixed construction waste and the second mixed construction waste.

More preferably, the vibration particle size sorter,

It consists of a vibrating screen in which a plurality of sorting holes are formed, and the plurality of sorting holes may be configured in a circular shape having a diameter of 200 mm or a square shape having a width of 200 mm.

Preferably, the first construction mixed waste treatment unit,

a first magnetic mixed construction waste sorter for magnetically sorting iron materials contained in the first mixed construction waste of 200 mm or less selected and separated through the vibrating particle size sorter;

a cylindrical trommel particle size sorter for separating and sorting the earth and sand of the first mixed construction waste from which iron materials are separated through the first construction mixed waste magnetic separator; and

Including a first construction mixed waste repair and sorting unit in which non-combustible materials including aluminum cans without magnetism or wood included in the first construction mixed waste from which earth and sand are separated and sorted through the cylindrical trommel particle size separator are separated can

Preferably, the second construction mixed waste treatment unit,

a second construction mixed waste repair sorting unit that separates and sorts non-combustible materials including wood and concrete that are not easily crushed with respect to the second mixed construction waste of 200 mm or more separated through the vibrating particle size separator; and

A second of primary crushing treatment so that the second mixed construction waste except for non-combustible materials including wood and concrete, which are separated and sorted through the second construction mixed waste repairing unit, can be sorted and separated in a subsequent treatment process It can be configured to include a construction mixed waste shredding processing unit.

Preferably, the combustible waste recovery processing unit,

a magnetic sorter for recovering combustible waste that magnetically separates iron materials contained in the pre-processed construction mixed waste that is input and transferred from the combined transfer facility; and

Including a specific gravity separator that generates a wind force for specific gravity separation of the pre-processed construction mixed waste from which iron is separated through the magnetic separator for combustible waste recovery and supplies a flowing fluid so that lightweight combustible waste is separated along the flowing fluid. can do.

More preferably, the combustible waste,

The combustible waste recovery treatment unit is classified and recovered through a magnetic separator for recovery of combustible waste and a specific gravity separator, but it can be recycled as solid waste fuel with a foreign matter ratio of less than 5% by weight.

Even more preferably, the waste recycling processing unit,

a vertical shredder for secondary crushing of the final mixed construction waste except for the combustible waste that is classified and recovered through a magnetic separator for recovery of combustible waste of the combustible waste recovery treatment unit and a specific gravity separator;

a vibratory feeder having a vibrating screen so that non-ferrous materials including rubber materials can be separated and sorted from the final mixed construction waste that has been vertically secondarily crushed through the vertical crusher; and

Including a magnetic separator for recycling that magnetically separates iron materials contained in the final mixed construction waste that has passed through the vibrating feeder,

The waste recycling treatment unit,

Recirculation to the merging transfer facility may be repeatedly performed at a preset cycle.

According to the solid fuel recycling resourceization system that has increased the recovery rate of combustible waste among the construction mixed wastes proposed in the present invention, the mixed construction waste is separated into a preset size, and the first construction mixed waste and the second construction mixed waste are separated and discharged. A vibrating particle size sorter, a first mixed construction waste treatment unit that performs magnetic sorting, particle size sorting, and treatment by repair for the first mixed construction waste, and a process for treating and first crushing the second mixed construction waste A second construction mixed waste treatment unit comprising this, a combined transport facility for input and transport of pre-treated construction waste, and a combustible waste recovery processing unit for recovering combustible waste through self-selection and specific gravity sorting processes for the pre-treated construction mixed waste; , After sorting through the processing process of vertical crushing, vibration feeder, and magnetic sorting for the remaining final construction mixed waste except combustible waste, it is returned to the confluence transfer facility and includes a waste recycling treatment unit for recycling treatment. By separating and sorting wastes by each property, it is possible to reduce the amount of construction mixed waste and to turn it into a resource through recycling by each property, as well as increase the recovery rate of combustible waste to make it possible to use it as a solid fuel.

In addition, according to the solid fuel recycling resourceization system that has increased the recovery rate of combustible wastes among construction wastes of the present invention, by configuring to enable separation and sorting of construction mixed wastes in a state of being entangled or combined in a plurality of properties, it is possible to separate and sort them, By precisely sorting construction waste, it is possible to minimize the generation of secondary waste generated by incineration or landfill, and to prevent environmental pollution as a result.

In addition, according to the solid fuel recycling resourceization system that has increased the recovery rate of combustible waste among construction mixed wastes of the present invention, by automating the process of separation and sorting for each property of mixed construction waste, the processing efficiency of mixed construction waste is increased, In addition, other daily processing capacity can be significantly increased.

1 is a view showing the configuration of a simple sorting of mixed construction waste generated at a conventional construction site.
FIG. 2 is a functional block diagram illustrating the configuration of a solid fuel recycling system for increasing the recovery rate of combustible waste among construction mixed wastes according to an embodiment of the present invention; FIG.
3 is a view showing the configuration of a first construction mixed waste treatment unit of the solid fuel recycling resource conversion system with an increased recovery rate of combustible waste among construction mixed wastes according to an embodiment of the present invention as a functional block.
4 is a functional block diagram illustrating the configuration of a second construction mixed waste treatment unit of the solid fuel recycling resource conversion system with an increased recovery rate of combustible waste among construction mixed wastes according to an embodiment of the present invention;
FIG. 5 is a functional block diagram illustrating the configuration of a combustible waste recovery processing unit of a solid fuel recycling resource conversion system with an increased recovery rate of combustible waste among construction mixed wastes according to an embodiment of the present invention; FIG.
FIG. 6 is a functional block diagram illustrating the configuration of a waste recirculation processing unit of a solid fuel recycling resource conversion system with an increased recovery rate of combustible waste among construction mixed wastes according to an embodiment of the present invention; FIG.
7 is a view showing a schematic configuration of a solid fuel recycling system for increasing the recovery rate of combustible waste among construction mixed wastes according to an embodiment of the present invention.

Hereinafter, preferred embodiments will be described in detail so that those of ordinary skill in the art can easily practice the present invention with reference to the accompanying drawings. However, in describing the preferred embodiment of the present invention in detail, if it is determined that a detailed description of a related known function or configuration may unnecessarily obscure the gist of the present invention, the detailed description thereof will be omitted. In addition, the same reference numerals are used throughout the drawings for parts having similar functions and functions.

In addition, throughout the specification, when a part is 'connected' with another part, it is not only 'directly connected' but also 'indirectly connected' with another element interposed therebetween. include In addition, "including" a certain component means that other components may be further included, rather than excluding other components, unless otherwise stated.

FIG. 2 is a functional block diagram illustrating the configuration of a solid fuel recycling resource conversion system with an increased recovery rate of combustible waste among construction mixed wastes according to an embodiment of the present invention, and FIG. 3 is a construction mixture according to an embodiment of the present invention. It is a functional block diagram showing the configuration of the first construction mixed waste treatment unit of the solid fuel recycling resource conversion system that has increased the recovery rate of combustible waste among wastes, and FIG. 4 is a recovery rate of combustible waste among construction mixed wastes according to an embodiment of the present invention It is a block diagram showing the configuration of the second construction mixed waste treatment unit of the solid fuel recycling resource conversion system that has increased It is a diagram showing the configuration of the combustible waste recovery processing unit of the system as a functional block, and FIG. 6 is a configuration of the waste recycling processing unit of the solid fuel recycling resource conversion system that has increased the recovery rate of combustible waste among construction mixed wastes according to an embodiment of the present invention. It is a diagram showing functional blocks. As shown in FIGS. 2 to 6 , the solid fuel recycling resource conversion system 100 that has increased the recovery rate of combustible waste among construction mixed wastes according to an embodiment of the present invention is a vibration particle size separator 110 , the first construction It may be configured to include a mixed waste treatment unit 120, a second construction mixed waste treatment unit 130, a combined transfer facility 140, a combustible waste recovery treatment unit 150, and a waste recycling treatment unit 160, and a mist device unit It may be configured to further include 170 .

The vibrating particle size separator 110 separates the construction mixed waste inputted to the input facility into which the construction mixed waste discharged from the construction site is put into a preset size to classify and discharge the first mixed construction waste and the second mixed construction waste configuration for This vibrating particle size sorter 110 is configured to include a vibrating screen in which a plurality of sorting holes are formed for separating the construction mixed waste into a preset size and classifying it into a first mixed construction waste and a second mixed construction waste and discharging it. there is.

In addition, the vibrating particle size sorter 110 is configured as a vibrating screen in which a plurality of sorting holes are formed, and the plurality of sorting holes may be configured in a circular shape having a diameter of 200 mm or a square shape having a width of 200 mm. The first mixed construction waste of 200 mm or less and the second mixed construction waste of 200 mm or more of the construction mixed waste are separated through the plurality of sorting holes of the vibrating particle size sorter 110 .

The first mixed construction waste treatment unit 120 has a configuration in which magnetic sorting, particle size sorting, and repair sorting processes are performed on the first mixed construction waste separated through the vibrating particle size sorter 110 . As shown in FIG. 3 , the first mixed construction waste treatment unit 120 is a first construction that self-selects iron materials included in the first mixed construction waste of 200 mm or less selected and separated through the vibrating particle size separator 110 . Cylindrical trommel particle size separator 122 for separating and sorting the earth and sand of the first construction mixed waste from which iron materials are separated through the mixed waste magnetic separator 121 and the first construction mixed waste magnetic separator 121, and the cylindrical trommel particle size The first construction mixed waste repairing unit 123 in which non-combustible materials including aluminum cans or woods, including non-magnetic aluminum cans, contained in the first construction mixed waste separated and sorted through the sorter 122 are separated and sorted. can do.

In addition, the first construction mixed waste processing unit 120 first magnetically separates and separates iron materials through the first construction mixed waste magnetic separator 121, and the first mixed construction waste from which the iron materials are separated is a cylindrical trommel particle size separator ( 122), soils with a thickness or width of 50 mm or less in one direction are separated and sorted, and the segregated and sorted soils can be recycled as cover materials. In addition, the first mixed construction waste from which iron and soil are separated is non-combustible materials including non-magnetic aluminum (AL) cans or wood, etc. through the first construction mixed waste repair and sorting processing unit 123. It can be separated and selected. .

The second mixed construction waste treatment unit 130 is configured to perform a water sorting process and a primary crushing process for the second mixed construction waste separated through the vibrating particle size sorter 110 . As shown in FIG. 4, the second mixed construction waste treatment unit 130 includes wood and concrete that are not easily crushed for the second mixed construction waste of 200 mm or more separated through the vibrating particle size separator 110. Non-combustible materials including wood and concrete, which are separated and sorted through the second construction mixed waste repair processing unit 131 in which non-combustible materials are separated and sorted, and the second construction mixed waste repair processing unit 131 2 It may be configured to include a second construction mixed waste crushing unit 132 for primary crushing so that the construction mixed waste can be sorted and separated in a subsequent treatment process.

In addition, in the second construction mixed waste treatment unit 131 of the second construction mixed waste treatment unit 130, non-combustible materials such as wood and concrete that are not easily crushed are separated and sorted, and the separated concrete is used as aggregate. Can be recycled.

The merging transfer facility 140 is configured to input and transfer the remaining pre-treated construction waste after being processed through the first and second mixed construction waste processing units 120 and 130 , respectively. The confluence transfer facility 140 may transfer the pre-processed construction mixed waste remaining after being processed by the first and second mixed construction waste processing units 120 and 130 for processing in the combustible waste recovery processing unit 150 . Here, the confluence transfer facility 140 may have a size of 200 mm, and industrial waste may be input.

The combustible waste recovery processing unit 150 has a configuration in which combustible waste is recovered through self-selection and specific gravity screening processes for the pre-processed construction mixed waste input and transported to the combined transport facility 140 . As shown in FIG. 5, the combustible waste recovery processing unit 150 includes a magnetic separator 151 for recovering combustible waste that self-selects iron materials contained in the pre-processed construction mixed waste that is input and transported from the combined transport facility 140 and , a specific gravity separator ( 152) can be included.

Here, the combustible waste is classified and recovered through the magnetic separator 151 and the specific gravity separator 152 for combustible waste recovery of the combustible waste recovery processing unit 150, but the ratio of foreign substances to weight is less than 5%. It can be recycled as fuel). These combustible wastes are combustible wastes separated through precise screening of construction mixed wastes. It is difficult to recycle because the average of less than 3000 kcal and chlorine components are detected above the standard. By mixing general waste synthetic resin, it can be recycled as a solid fuel with a lower level of chlorine, etc. and 3500 kcal or higher, the standard for solid fuel. Here, the combustible waste may include not only vinyl, but also cloth or linen discharged from a construction site.

In addition, the combustible waste recovery processing unit 150 may separate iron materials having magnetism through the magnetic separator 151 for recovering combustible waste, and non-ferrous materials having a weight greater than or equal to a preset weight through the specific gravity separator 152 . allow it to be separated. Here, foreign substances combined with bolts or iron materials may be separated through magnetic separation, and non-ferrous materials having a weight greater than a preset weight may include electric wires, aluminum cans, and the like.

Waste recycling processing unit 160, vertical crushing, vibrating feeder, and magnetic sorting process for the remaining final construction mixed waste excluding combustible waste classified through the magnetic screening and specific gravity screening process of the combustible waste recovery processing unit 150 After sorting through, it is returned to the merging transfer facility 140 to be recirculated. As shown in FIG. 6 , the waste recirculation processing unit 160 is classified through the magnetic separator 151 and the specific gravity separator 152 for the recovery of combustible waste of the combustible waste recovery processing unit 150 , except for the recovered combustible waste. The vertical crusher 161 for secondary crushing of the construction waste, and the final mixed construction waste vertically secondarily crushed through the vertical crusher 161 so that non-ferrous materials including rubber materials can be separated and sorted It can be configured to include a vibrating feeder 162 having a vibrating screen, and a recirculating magnetic separator 163 for self-selecting iron materials contained in the final construction mixed waste that has passed through the vibrating feeder 162 . Here, the waste recirculation processing unit 160 may repeatedly perform recirculation to the confluence transfer facility 140 at a preset cycle.

In addition, the vertical shredder 161 of the waste recirculation processing unit 160 is provided with a hammer (Hammer) driven up and down, and iron materials in a state of being entangled or combined through vertical blow crushing by the hammer and the remaining foreign substances (mainly non-ferrous) can be separated from each other. Here, the iron materials included in the waste may be agglomerated as the hammer strikes vertically, and the remaining foreign substances except for the iron materials are torn or split as the hammer strikes vertically.

Mist device unit 170 is installed in each facility that performs the processing of precise sorting of mixed construction waste, and serves to suppress the generation of scattering dust to prevent the occurrence of civil complaints in advance. The mist device unit 170 is a vibration particle size separator 110, the first construction mixed waste processing unit 120, the second construction mixed waste processing unit 130, which generates dust in the process of sorting and processing the construction mixed waste. At least one may be installed in each of 140 , the combustible waste recovery processing unit 150 , and the waste recycling processing unit 160 .

7 shows a schematic installation configuration of a solid fuel recycling resource-saving system with an increased recovery rate of combustible waste among construction mixed wastes according to an embodiment of the present invention. That is, the solid fuel recycling system 100 according to the present invention may be installed and configured for precise selection of construction mixed waste, as shown in FIG. 7 .

As described above, the solid fuel recycling resource conversion system with an increased recovery rate of combustible waste among construction mixed wastes according to an embodiment of the present invention separates the construction mixed wastes into a preset size and mixes the first and second construction wastes. A vibrating particle size sorter that separates and discharges waste, a first mixed construction waste treatment unit that performs magnetic sorting, particle size sorting, and treatment by repair for the first mixed construction waste, and a second process for mixed construction waste by repair , a second construction mixed waste treatment unit where the primary crushing process is performed, a combined transport facility where pre-treated construction mixed waste is input and transported, and combustible waste is recovered through self-selection and specific gravity sorting processes for pre-treated construction waste Combustible waste recovery processing unit, and the final mixed construction waste other than combustible waste is sorted through the processing process of vertical crushing, vibrating feeder, and magnetic sorting, and returned to the merging transfer facility, including a waste recycling processing unit for recycling By constructing this, it is possible to separate and sort the construction mixed waste by each property to reduce the construction waste and to turn it into a resource through recycling by each property, as well as to increase the recovery rate of combustible waste so that it can be used as a solid fuel. , in particular, to minimize the generation of secondary wastes generated by incineration or landfill through precise sorting of construction mixed wastes by configuring it to be possible to separate and sort the construction mixed wastes in a state of being entangled or combined with multiple properties. And it is possible to prevent the occurrence of environmental pollution resulting therefrom. In addition, by automating the process of separation and screening for each property of the mixed construction waste, it is possible to increase the processing efficiency of the mixed construction waste, and to increase the other daily processing capacity significantly.

Various modifications and applications of the present invention described above are possible by those skilled in the art to which the present invention pertains, and the scope of the technical idea according to the present invention should be defined by the following claims.

100: Solid fuel recycling system according to an embodiment of the present invention
110: vibration particle size separator
120: first construction mixed waste treatment unit
121: first construction mixed waste magnetic separator
122: cylindrical trommel particle size separator
123: 1st construction mixed waste water treatment unit
130: second construction mixed waste treatment unit
131: 2nd construction mixed waste water treatment unit
132: second construction mixed waste shredding unit
140: merging transfer facility
150: combustible waste recovery processing unit
151: magnetic sorter for recovery of combustible waste
152: specific gravity separator
160: waste recycling processing unit
161: vertical crusher
162: vibrating feeder
163: magnetic separator for recirculation
170: mist device unit

Claims (8)

A solid fuel recycling system 100 with an increased recovery rate of combustible waste among construction mixed wastes, comprising:
A vibrating particle size separator 110 that separates the construction mixed waste inputted to the input facility into which the construction mixed waste discharged from the construction site is put into a preset size and separates it into a first mixed construction waste and a second mixed construction waste;
a first mixed construction waste treatment unit 120 in which magnetic sorting, particle size sorting, and water sorting processes are performed on the first mixed construction waste separated through the vibrating particle size sorter 110;
a second mixed construction waste treatment unit 130 in which water sorting and primary crushing processes are performed on the second mixed construction waste separated through the vibrating particle size sorter 110;
a merging transfer facility 140 for inputting and transferring the remaining pre-treated construction waste after being processed through the first and second mixed construction waste processing units 120 and 130, respectively;
a combustible waste recovery processing unit 150 for recovering combustible wastes through self-selection and specific gravity screening processes for pre-treated construction mixed wastes input and transported to the combined transport facility 140; and
The final construction mixed waste except for the combustible waste classified through the magnetic separation and specific gravity screening process of the combustible waste recovery processing unit 150 is classified through the processing process of vertical crushing, vibrating feeder, and magnetic sorting, and then transferred to the merging A solid fuel recycling resource recycling system with an increased recovery rate of combustible waste among construction mixed wastes, characterized in that it includes a waste recycling treatment unit 160 that is returned to the facility 140 and undergoes recycling treatment.
According to claim 1, wherein the vibration particle size separator 110,
Among the construction mixed waste, characterized in that it comprises a vibrating screen in which a plurality of sorting holes are formed for separating the construction mixed waste into a preset size and discharging it into a first mixed construction waste and a second mixed construction waste. A solid fuel recycling resource system that increases the recovery rate of combustible waste.
The method of claim 2, wherein the vibration particle size separator 110,
It consists of a vibrating screen in which a plurality of sorting holes are formed, wherein the plurality of sorting holes are configured in a circular shape having a diameter of 200 mm or a square shape having a width of 200 mm. Advanced solid fuel recycling system.
According to claim 1, wherein the first construction mixed waste treatment unit 120,
a first magnetic mixed waste sorter 121 for magnetically sorting iron materials included in the first mixed construction waste of 200 mm or less selected and separated through the vibrating particle size sorter 110;
a cylindrical trommel particle size separator 122 for separating and sorting the earth and sand of the first mixed construction waste from which iron materials are separated through the first construction mixed waste magnetic separator 121; and
The first construction mixed waste repairing unit 123 in which non-combustible materials including aluminum cans without magnetism or wood included in the first construction mixed waste separated and sorted through the cylindrical trommel particle size separator 122 are separated and sorted ), characterized in that it comprises a solid fuel recycling resource system with an increased recovery rate of combustible waste among construction mixed wastes.
According to claim 1, wherein the second construction mixed waste treatment unit 130,
The second construction mixed waste repairing unit 131 in which non-combustible materials including wood and concrete, which are not easily crushed, are separated and sorted for the second mixed construction waste of 200 mm or more separated through the vibrating particle size sorter 110 . ); and
Primary crushing treatment so that the second mixed construction waste, excluding non-combustible materials including wood and concrete, separated and sorted through the second construction mixed waste repair processing unit 131 can be sorted and separated in a subsequent treatment process A solid fuel recycling resource system with an increased recovery rate of combustible waste among construction mixed wastes, characterized in that it comprises a second construction mixed waste crushing processing unit 132.
According to any one of claims 1 to 5, wherein the combustible waste recovery processing unit 150,
a magnetic sorter 151 for recovering combustible waste that magnetically separates iron materials contained in the pre-processed construction mixed waste that is input and transferred from the merging transfer facility 140; and
A specific gravity separator ( 152), characterized in that it comprises a solid fuel recycling resource recycling system with an increased recovery rate of combustible waste among construction mixed wastes.
According to claim 6, The combustible waste,
The combustible waste recovery processing unit 150 is classified and recovered through the magnetic separator 151 and the specific gravity separator 152 for the recovery of combustible waste, but the ratio of foreign substances to weight is less than 5% and is recycled as solid waste fuel. A solid fuel recycling resource system with an increased recovery rate of combustible waste among construction mixed wastes, characterized in that it is
According to claim 7, The waste recycling processing unit 160,
A vertical shredder 161 for secondary crushing of the final construction mixed waste excluding the combustible waste classified and recovered through the magnetic separator 151 and the specific gravity separator 152 for the recovery of combustible waste of the combustible waste recovery processing unit 150 ;
a vibrating feeder 162 having a vibrating screen so that non-ferrous materials including rubber materials can be separated and sorted from the final mixed construction waste vertically secondarily crushed through the vertical crusher 161; and
and a magnetic separator 163 for recirculation that magnetically separates iron materials contained in the final mixed construction waste that has passed through the vibrating feeder 162,
The waste recycling processing unit 160,
A solid fuel recycling resource recycling system with an increased recovery rate of combustible waste among construction mixed wastes, characterized in that recirculation to the confluence transfer facility 140 is repeatedly performed at a preset cycle.

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