KR20230078562A - Oil extraction device for pyrolysis of combustible waste - Google Patents

Abstract

The present invention relates to a continuous treatment device for combustible waste using a molding device, and more particularly, to a continuous treatment system for continuously treating combustible waste such as waste plastic and vinyl, preventing the inflow of oxygen, and having excellent input efficiency of combustible waste. It relates to a thermal decomposition emulsifier.
Continuous treatment of combustible waste using a molding device according to the present invention heats and compresses combustible waste through a heating and discharging unit, supplies the combustible waste into the thermal decomposer in an oxygen-free atmosphere, and heats and stirs the combustible waste supplied to the thermal decomposer. The gas and by-products are separately discharged, and the pyrolysis gas and by-products are treated by the pyrolysis gas processing unit and the by-product processing unit, respectively, so that a series of emulsification processes can be continuously performed.
In addition, the continuous treatment device for combustible waste using the molding device according to the present invention makes it easy to control the input amount of waste, and presses and supplies it into the pyrolysis unit while blocking the inflow of oxygen, enabling smooth transfer and input without congestion of waste. Therefore, it has the advantage of improving the waste input efficiency.

Description

Continuous processing device for combustible waste using a molding device {Oil extraction device for pyrolysis of combustible waste}

The present invention relates to a continuous processing device for combustible waste using a molding device, and more particularly, to a molding device that continuously treats combustible waste such as waste plastic and vinyl, prevents the inflow of oxygen, and has excellent input efficiency of combustible waste. It relates to a continuous treatment device for combustible waste using

As interest in recycling resources increases, various methods for recycling wastes are being tried. As one of these attempts, a method of treating waste by pyrolyzing waste such as waste plastic or waste wire to extract liquid fuel has been attempted. The device used at this time is called a waste emulsification device.

This waste emulsification device includes a heating furnace for accommodating waste and a heating device for heating the heating furnace. After putting waste plastic into the heating furnace, when the inside of the heating furnace is heated to a certain temperature or higher through a heating device, the waste plastic melts and vaporizes. It is discharged to the outside by heating. Liquid fuel can be obtained by liquefying the gaseous fuel discharged in this way through a cooling device.

Such an emulsification device may be of a type that continuously processes a large amount of waste using a transfer device such as a conveyor, or may be of a type that uses a relatively small-capacity heating furnace.

A conventional emulsification device includes a heating furnace for thermally decomposing polymer waste at a high temperature to obtain gaseous oil components, a separator for separating gaseous oil components generated by thermal decomposition by the heating furnace by oil type, and separated oil vapor. It is roughly divided into a cooling device that cools and liquefies, and a gas storage that stores cooled gas and oil, and includes a gas supply that resupplies non-liquefied gas through heating.

Such a conventional emulsification device is a so-called batch type, and due to the morphological characteristics of the inlet of the heating furnace, which is limited in size, a pretreatment process of crushing the waste first is required, and the process in which the molten waste is discharged from the heating furnace There is a problem in that the outlet is clogged by sticking to the surface of the outlet of the heating furnace.

In addition, since foreign substances and additives partially mixed in the heating furnace remain on the bottom of the heating furnace as undecomposed residues, it is inconvenient and inconvenient for the operator to scrape the residues one by one while the operation of the equipment is stopped for a certain period of time. Accordingly, there is a problem in that workability, productivity, and yield are lowered because it cannot be treated in a continuous process.

Korean Registered Patent No. 10-1804805 Korean Registered Patent No. 10-1914366 Korean Registered Patent No. 10-1779777

The present invention is to solve the above conventional problems, and it is easy to control the input amount of waste in a continuous manner, and the waste is stagnant by pressing and transferring the waste into the pyrolysis device and supplying the waste while blocking the supply and oxygen inflow. It is an object of the present invention to provide a continuous processing device for combustible waste using a molding device that can be smoothly transported and introduced without increasing waste input efficiency, increases productivity, yield, and economy, and is easy to maintain and repair.

To achieve the above object, a continuous processing device for combustible waste using a molding device according to the present invention includes a collection unit for collecting coastal waste; a cutting unit for cutting the collected waste; a sorting unit for sorting the cut waste into combustible waste and incombustible waste; a heating and discharging unit for heating and discharging the sorted combustible waste; a thermal decomposition unit receiving the flammable waste discharged from the heating and discharging unit, thermally decomposing the flammable waste in an oxygen-free atmosphere, and discharging the pyrolysis gas and by-products; a thermal decomposition gas processing unit for liquefying and storing the thermal decomposition gas discharged from the thermal decomposition unit; and a by-product processing unit for transporting and storing by-products discharged from the pyrolysis unit.

The heating and discharge unit of the continuous processing device for combustible waste using the molding device according to the present invention includes a hopper into which combustible waste is put, a first chamber into which combustible waste discharged from the hopper is put into one side, and heating the first chamber A first heater installed inside the first chamber to transfer the combustible waste in the first chamber from one side to the other side of the first chamber, and a first transfer screw to rotate the first transfer screw. It includes a driving unit and a nozzle unit installed at the other end of the first chamber to discharge the combustible waste transported by the first transfer screw to the outside of the first chamber.

The thermal decomposition unit of the continuous processing device for combustible waste using the molding device according to the present invention includes a second chamber into which combustible waste discharged from the heating and discharge unit is put, a second heater for heating the second chamber, and the second chamber and at least one second transfer screw installed therein to transfer the combustible waste in the second chamber from one side to the other side of the second chamber while agitating it, and a second driving unit for rotating the second transfer screw.

The second transfer screw of the continuous processing device for combustible waste using the molding device according to the present invention includes a pair of second rotational shafts disposed side by side and adjacent to each other inside the second chamber, and the length of the second rotational shaft It includes a plurality of transfer agitation units disposed at regular intervals along the direction, wherein the transfer agitation unit includes a plurality of transfer agitation vanes disposed at a predetermined interval apart along the circumferential direction of the second rotation shaft, wherein the transfer agitation vanes A rim portion formed to surround a portion of the second rotational shaft in the circumferential direction, a plurality of first vertical wings extending in different directions from the rim portion, and the first vertical wing from an end of the first vertical wing. Horizontal wings that intersect with the vertical wings and extend a certain length on both sides in parallel with the second rotational axis, and second vertical wings that extend a certain length from both ends of the first horizontal wing toward the second rotational axis, respectively In the transfer agitation blade, the first vertical blade of the second transfer screw on one side enters between the first vertical blades on both sides adjacent to each other of the second transfer screw on the other side, and the second transfer screw on one side The horizontal blade enters between the horizontal blades on both sides adjacent to each other and the second rotation axis of the second transfer screw on the other side, and the second vertical wing of the second transfer screw on one side moves to the first side of the second transfer screw on the other side. It is formed to be able to enter between the vertical blade and the second vertical blade, and on one side of the first vertical blade, the horizontal blade, and the second vertical blade of each transfer stirring blade corresponding to the rotational direction of the second pivot shaft A transfer contact surface for transporting the flammable waste in contact with the flammable waste is formed, the transfer contact surface of each of the transfer agitation blades is inclined in a direction crossing the second rotation axis, and each transfer of the transfer agitation blades The contact surfaces form discontinuous helical planes along the longitudinal direction of the second pivot shaft.

While the second transfer screw on one side of the continuous processing device for combustible waste using the molding device according to the present invention is being rotated, the second transfer screw interferes with the second rotation shaft of the other side while the second transfer screw rotates. A scraper unit for separating attached combustible waste is further provided, and an installation groove is formed on the horizontal wing of the transfer agitating wing to detachably install the scraper unit, and the scraper unit is inserted into the installation groove A mounting bracket equipped with a mounting groove on one side, one side inserted into and fixed to the mounting groove, and the other side extended away from the mounting bracket so as to come into contact with the outer circumferential surface of the second pivot shaft and formed to be flexible and bendable. It includes a scraper member.

Continuous treatment of combustible waste using a molding device according to the present invention heats and compresses combustible waste through a heating and discharging unit, supplies the combustible waste into the thermal decomposer in an oxygen-free atmosphere, and heats and stirs the combustible waste supplied to the thermal decomposer. The gas and by-products are separately discharged, and the pyrolysis gas and by-products are treated by the pyrolysis gas processing unit and the by-product processing unit, respectively, so that a series of emulsification processes can be continuously performed.

In addition, the continuous treatment device for combustible waste using the molding device according to the present invention makes it easy to control the input amount of waste, and presses and supplies it into the pyrolysis unit while blocking the inflow of oxygen, enabling smooth transfer and input without congestion of waste. Therefore, it has the advantage of improving the waste input efficiency.

1 is a perspective view of a continuous processing device for combustible waste using a molding device according to the present invention.
2 is a perspective view showing a second transfer screw according to a first embodiment of a continuous processing device for combustible waste using a molding device according to the present invention.
3 is a plan view showing a second transfer screw according to a first embodiment of a continuous processing device for combustible waste using a molding device according to the present invention.
4 is a perspective view showing a second transfer screw according to a second embodiment of a continuous processing device for combustible waste using a molding device according to the present invention.
5 is a plan view showing a second transfer screw according to a second embodiment of a continuous processing device for combustible waste using a molding device according to the present invention.
6 is a side view showing a second transfer screw according to a second embodiment of a continuous processing device for combustible waste using a molding device according to the present invention.
7 is a perspective view showing a scraper unit of a continuous processing device for combustible waste using a molding device according to another embodiment of the present invention.
Figure 8 is an exploded perspective view showing the scraper unit of Figure 7;
9 is a cross-sectional view showing an operating state of the second transfer screw equipped with the scraper unit of FIG. 7;

Hereinafter, an apparatus for continuously processing flammable waste using a molding apparatus according to a preferred embodiment of the present invention will be described in detail with reference to the accompanying drawings.

1 to 9 show an apparatus 1 for continuous processing of combustible waste using a molding apparatus according to the present invention. 1 to 9, the continuous processing device 1 for combustible waste using the molding device according to the present invention includes a collection unit, a cutting unit, a sorting unit, a heating and discharging unit 10, and a thermal decomposition unit 20 ), a pyrolysis gas processing unit 30, and a by-product processing unit 40.

The collection unit collects waste generated in the sea and the coast and can be composed of a crane. The collection unit collects marine and coastal wastes (vinyl, nets, buoys and buoys, ropes, fishing gear, etc.), is fixed to the vehicle, can rotate left and right, and has tongs that can grip coastal wastes at the end. are provided

The cutting unit cuts the wastes collected by the collection unit, and includes an input hopper into which coastal wastes are input, and a cutting roller unit rotatably installed in the input hopper and rotatingly cutting the coastal wastes input through the input hopper.

The sorting unit sorts the waste cut at the cutting unit into combustible waste and incombustible waste, and the housing into which the cut coastal waste is input and the coastal waste input into the housing are separated by their own weight using wind. It includes an air injection unit for injecting high-pressure air.

A discharge port for discharging incombustible waste and a discharge port for discharging combustible waste are respectively formed in a lower portion of one side of the housing where the air blowing unit is installed and a lower portion of the other side opposite thereto.

The marine waste cut by the cutter is put into the interior through the inlet of the housing of the sorter, and when the marine waste is put into the interior, the marine waste with a relatively high specific gravity falls in a short distance by the wind discharged at high pressure by the air blowing unit. Discharged through the outlet on one side, marine wastes of relatively low specific gravity fall far and are discharged through the outlet on the other side.

The heating and discharging unit 10 heats the sorted combustible waste and discharges it to the thermal decomposition unit 20 while maintaining an anoxic atmosphere, and includes a hopper into which the combustible waste is put, and the combustible waste discharged from the hopper into one side. a first chamber, a first heater for heating the first chamber, and a first transfer screw installed inside the first chamber to transfer the combustible waste in the first chamber from one side of the first chamber to the other side. And, a first drive unit for rotating the first transfer screw, and a nozzle unit installed at the other end of the first chamber and discharging the flammable waste transported by the first transfer screw to the outside of the first chamber. It consists of

The thermal decomposition unit 20 receives the flammable waste discharged from the heating and discharging unit 10, thermally decomposes the flammable waste in an oxygen-free atmosphere, and discharges the pyrolysis gas and by-products, respectively. In more detail, the pyrolysis unit 20 has one side formed to surround and seal the nozzle unit so that flammable waste discharged from the nozzle unit can be blocked from being exposed to the air, and the other side has a pyrolysis gas discharge port for discharging pyrolysis gas A second chamber 21 provided with a by-product discharge port for discharging and by-products, a second heater for heating the second chamber 21, and a second heater installed inside the second chamber 21 to heat the second chamber 21 ) At least one second transfer screw 100 for transferring the flammable waste in the second chamber 21 from one side to the other side while stirring, and a second driving unit 200 for rotating the second transfer screw 100 ) is composed of.

2 and 3 show a second conveying screw according to a first embodiment of an apparatus for continuous processing of combustible waste using a molding apparatus according to the present invention. 2 and 3, the second transfer screw 100 includes a pair of second rotational shafts 110 disposed side by side and adjacent to each other inside the second chamber 21, and a second rotational shaft ( 110) It is configured to include a plurality of transfer and agitation units 120 disposed spaced apart at regular intervals along each longitudinal direction.

In this embodiment, two second transfer screws 100 are applied, and the second transfer screw 100 on one side is crossed with the second transfer screw 100 on the other side and the transfer stirring blades 130 A structure is applied so that the second pivot shaft 110 intersects each other during rotation.

The transfer and agitation unit 120 includes a plurality of transfer and agitation blades 130 disposed spaced apart at regular intervals along the circumferential direction of the second rotation shaft 110 .

The transfer agitation blades 130 extend from the first vertical blade 140 protruding from the second pivot shaft 110 and from the end of the first vertical blade 140 to both sides parallel to the second pivot shaft 110. Each consists of a horizontal wing 150 extending a certain length and a second vertical wing 160 extending a certain length from the end of the first horizontal wing 150 toward the second rotation shaft 110.

The horizontal wing may be configured to come into contact with the inner surface of the second chamber to scrape off melted waste or other foreign substances attached to the inner surface of the second chamber.

In addition, the transfer and agitation unit 120 may be arranged so that the horizontal blades 150 form a spiral structure so that the waste can be sufficiently heated and stirred inside the second chamber 21 .

In addition, the transfer stirring blades 130 are the first vertical blades 140 on both sides of which the first vertical blades 140 of the second transfer screw 100 on one side are adjacent to each other of the second transfer screw 100 on the other side. Arranged and formed to enter and be located between them.

In addition, in the transfer stirring blades 130, the horizontal blades 150 of the second transfer screw 100 on one side are adjacent to each other of the second transfer screw 100 on the other side, and the second transfer screw 100 is adjacent to each other. It is formed to enter between the pivot shafts 110.

In addition, in the transfer agitation blades 130, the second vertical blades 160 of the second transfer screw 100 on one side are adjacent to the first vertical blades 140 of the second transfer screw 100 on the other side and It is formed to be able to enter between the second vertical wings (160).

Meanwhile, FIGS. 4 to 6 show a second conveying screw according to a second embodiment of an apparatus for continuous processing of combustible waste using the molding apparatus according to the present invention. Referring to FIGS. 4 to 6 , the second transfer screw 100 may include a second rotation shaft 110 and a plurality of transfer/stirring units 120 .

The second pivot shafts 110 are configured as a pair and are disposed side by side and adjacent to each other inside the second chamber 21 .

The transfer and agitation units 120 are spaced apart at regular intervals along the longitudinal direction of the second rotation shaft 110 .

The transfer and agitation unit 120 includes a plurality of transfer and agitation blades 130 disposed spaced apart at regular intervals along the circumferential direction of the second rotation shaft 110 .

The transfer agitation blade 130 may be composed of an edge portion 170, a first vertical blade 140, a horizontal blade 150, and a second vertical blade 160.

A different number of conveying agitation vanes may be applied to the pair of second conveying screws. In this embodiment, a transfer stirring blade composed of five first vertical blades, horizontal blades, and second vertical blades is applied to the second transfer screw on one side, and four first vertical blades are applied to the second transfer screw on the other side. A transfer agitation blade consisting of a horizontal blade and a second vertical blade was applied. Alternatively, the same number may be applied.

The rim portion 170 is formed in an annular shape so as to surround a portion of the second rotation shaft 110 along the circumferential direction.

The first vertical wings 140 extend in different directions from the rim portion 170, and a plurality of them are spaced apart at regular intervals along the rim portion 170. In this embodiment, the first vertical wing 140 was applied with four.

Then, the horizontal blade 150 intersects the first vertical blade 140 from the end of the first vertical blade 140, and extends to both sides in parallel with the second rotational shaft 110, respectively, a predetermined length. The horizontal blades 150 are separated from the horizontal blades 150 of the adjacent transfer stirring blades 130 so that the first vertical blade 140 of the second transfer screw 100 on the other side can pass through. do.

The second vertical wing 160 extends a certain length from both ends of the first horizontal wing 150 toward the second rotation shaft 110, respectively.

The transfer agitation blade 130 is formed between the first vertical blades 140 of the second transfer screw 100 on one side and the first vertical blades 140 on both sides adjacent to each other of the second transfer screw 100 on the other side. Arranged and formed to enter and be located between.

In addition, in the transfer stirring blades 130, the horizontal blades 150 of the second transfer screw 100 on one side are adjacent to each other of the second transfer screw 100 on the other side, and the second transfer screw 100 is adjacent to each other. It is formed to enter between the pivot shafts 110.

In addition, in the transfer agitation blades 130, the second vertical blades 160 of the second transfer screw 100 on one side are adjacent to the first vertical blades 140 of the second transfer screw 100 on the other side and It is formed to be able to enter between the second vertical wings (160).

The second transfer screw 100 is composed of a pair, and the first vertical blades 140, horizontal blades 150, and second vertical blades 160 of the second transfer screws 100 on one side are rotated on the other side. Since the first vertical blade 140, the horizontal blade 150, and the second vertical blade 160 of the second transfer screw 100 cross each other, the combustible waste inside the second chamber 21 is effectively stirred. In addition, as the transfer agitating blades 130 cross each other, flammable wastes having relatively large particles are pulverized or crushed so that they can be melted more easily.

On the other hand, on one side of the first vertical blade 140, the horizontal blade 150, and the second vertical blade 160 of each transfer agitation blade 130 corresponding to the rotation direction of the second pivot shaft 110, a second chamber A transfer contact surface 135 is formed in contact with the flammable waste in (21) to transfer the flammable waste.

The transfer contact surfaces 135 of each of the transfer agitation blades 130 are inclined in a direction crossing the second pivot shaft 110 . In addition, the transfer contact surfaces 135 of each of the transfer agitation blades 130 form a discontinuous spiral plane along the longitudinal direction of the second pivot shaft 110 . The transfer contact surfaces 135 formed on the transfer agitation blades 130 are discontinuously formed so that the transfer speed of combustible waste can be slowed down compared to a general screw having a continuous spiral plane, and by effectively stirring the combustible waste, the second chamber (21) so that combustible waste can be easily melted.

On the other hand, the continuous processing device for combustible waste using the molding device according to the present invention may further include a scraper unit 180.

7 to 9, the scraper unit 180 is provided in the transfer stirring unit 120, and while the second transfer screw 100 on one side rotates, the second transfer screw 100 on the other side Combustible waste attached to the second pivot shaft 110 is separated while interfering with the second pivot shaft 110 .

In order to install the scraper unit 180 in the transfer agitation unit 120, the horizontal blade 150 of the transfer agitation blade 130 is formed with a retracted installation groove 131 for detachably installing the scraper unit 180. do.

The installation groove 131 is drawn inward from the outer circumferential surface of the end side of the horizontal blade 150 and extends in a direction parallel to the longitudinal direction of the horizontal blade 150 so that the mounting bracket 181 can be inserted and installed in a sliding manner. The installation groove 131 has a wide terminal portion corresponding to the inside of the horizontal blade 150 and a narrow inlet portion corresponding to the outside of the horizontal blade 150, so that when the second rotational shaft 110 is rotated, the mounting bracket 181 This separation is prevented.

The scraper unit 180 may include a mounting bracket 181 and a scraper member 185.

The mounting bracket 181 is inserted into the installation groove 131 formed on the horizontal blade 150, and has a mounting groove 182 on one side for inserting and holding and fixing one side of the scraper member 185.

One side of the scraper member 185 is inserted and fixed into the mounting groove 182, and the other side extends a certain length away from the mounting bracket 181 so as to come into contact with the outer circumferential surface of the second pivot shaft 110. The scraper member 185 has elasticity so that it can be bent when in contact with the outer circumferential surface of the second pivot shaft 110 .

The pyrolysis gas treatment unit 30 liquefies and stores the pyrolysis gas discharged from the pyrolysis unit 20, and condenses and liquefies the pyrolysis gas transported through the pyrolysis gas transport pipe discharged from the pyrolysis unit 20 and the pyrolysis gas transport pipe. It is configured to include a condenser, a filter for filtering liquefied oil in the condenser, and an oil storage tank for storing the filtered oil.

The by-product processing unit 40 transports and stores the by-products discharged from the pyrolysis unit 20, and is composed of a transfer unit for transporting the by-products and a by-product storage tank for storing the by-products transported by the transfer unit.

As described above, the continuous processing device for combustible waste using the molding device according to the present invention heats and presses the combustible waste selected by the sorting unit through the heating and discharging unit 10, and supplies it to the inside of the pyrolysis machine in an oxygen-free atmosphere, The pyrolysis gas and by-products generated while the combustible waste supplied to the pyrolysis machine is heated and stirred are separated and discharged, respectively, and the pyrolysis gas and by-products are treated by the pyrolysis gas processing unit 30 and the by-product processing unit 40, respectively, thereby performing a series of emulsification processes. can proceed continuously.

In addition, the continuous processing device for combustible waste using the molding device according to the present invention as described above makes it easy to control the input amount of waste, and presses and supplies it into the pyrolysis unit 20 while blocking the inflow of oxygen, so that the stagnation of waste Since it is possible to transfer and input smoothly without the need, it has the advantage of improving the efficiency of waste input.

The continuous processing device for combustible waste using the molding device according to the present invention described above has been described with reference to the accompanying drawings, but this is only exemplary, and those skilled in the art can make various modifications and equivalents therefrom. It will be appreciated that other embodiments are possible.

Therefore, the scope of true technical protection of the present invention should be determined only by the technical spirit of the appended claims.

10: heating discharge unit
20: pyrolysis unit
30: pyrolysis gas treatment unit
40: by-product processing unit
100: 2nd transfer screw
110: 2nd rotation axis
120: transfer agitation unit

Claims (1)

a collection unit that collects coastal waste;
a cutting unit for cutting the collected waste;
a sorting unit for sorting the cut waste into combustible waste and incombustible waste;
a heating and discharging unit for heating and discharging the sorted combustible waste;
a thermal decomposition unit receiving the flammable waste discharged from the heating and discharging unit, thermally decomposing the flammable waste in an oxygen-free atmosphere, and discharging the pyrolysis gas and by-products;
a thermal decomposition gas processing unit for liquefying and storing the thermal decomposition gas discharged from the thermal decomposition unit;
A by-product processing unit for transporting and storing by-products discharged from the pyrolysis unit;
The thermal decomposition unit includes a second chamber into which combustible waste discharged from the heating and discharge unit is put, a second heater for heating the second chamber, and a second heater installed inside the second chamber to stir the combustible waste in the second chamber. At least one second transfer screw for transferring from one side of the second chamber to the other side, and a second driving unit for rotating the second transfer screw,
The second transfer screw includes a pair of second rotational shafts disposed side by side and adjacent to each other inside the second chamber, and a plurality of transfer and stirring units disposed spaced apart from each other by a predetermined interval along the longitudinal direction of the second rotational shaft. do,
The transfer and agitation unit includes a plurality of transfer and agitation blades disposed spaced apart at regular intervals along the circumferential direction of the second rotation axis,
The transfer stirring blades include an edge portion formed to surround a portion of the second rotation shaft in a circumferential direction, a plurality of first vertical blades extending in different directions from the edge portion, and an end portion of the first vertical blade. A horizontal wing extending a predetermined length on both sides of the first horizontal wing and parallel to the second rotational axis and intersecting the first vertical wing from the first horizontal wing, and a predetermined length extending from both ends of the first horizontal wing toward the second rotational axis, respectively. Including 2 vertical wings,
In the transfer stirring blade, the first vertical blade of the second transfer screw on one side enters between the first vertical blades on both sides adjacent to each other of the second transfer screw on the other side, and the horizontal blade of the second transfer screw on one side It enters between the horizontal blades of the second transfer screw on the other side and the second rotation shaft adjacent to each other, and the second vertical blade of the second transfer screw on one side is connected to the first vertical blade of the second transfer screw on the other side. It is formed to be able to enter between the second vertical wings,
A transfer contact surface is formed on one side of the first vertical blade, the horizontal blade, and the second vertical blade of each transfer agitation blade corresponding to the rotational direction of the second rotation shaft to contact flammable waste and transfer the flammable waste The transfer contact surfaces of each of the transfer agitation blades are inclined in a direction crossing the second rotation axis, and the transfer contact surfaces of each transfer agitation blades are discontinuous spiral along the longitudinal direction of the second rotation axis. form a plane,
The transfer stirring unit further includes a scraper unit that separates combustible wastes attached to the second rotational shaft while interfering with the second rotational shaft of the second transfer screw on the other side while the second transfer screw on one side rotates,
An installation groove is formed on the horizontal blade of the transfer stirring blade to detachably install the scraper unit,
The scraper unit includes a mounting bracket inserted into the installation groove and provided with a mounting groove on one side, and one side inserted and fixed into the mounting groove and the other side extending away from the mounting bracket so as to come into contact with the outer circumferential surface of the second pivot shaft. And a continuous processing device for combustible waste using a molding device, characterized in that it comprises a scraper member formed to be flexible and bendable.

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