KR101168206B1 - Production facilities equipment of renewable energy materials - Google Patents

Abstract

The present invention relates to an apparatus for producing renewable energy raw materials, and more particularly, to a apparatus for producing renewable energy raw materials, in which waste is collected to produce renewable energy raw materials. A first crushing unit to be crushed; Separation unit for sorting the combustibles made of combustible plastic or rubber from the pulverized product discharged from the first crushing unit; A second crushing unit for discharging the combustible material by secondary crushing the combustible material for easy extrusion molding; And a renewable energy raw material production unit for producing renewable energy raw materials by extruding the combustible material.

According to the present invention, it is possible to provide an efficient production equipment apparatus capable of producing high calorie and high quality renewable raw materials from marine waste and the like.

Renewable energy raw materials, waste, combustible materials, ballistic sorter, magnetic separator

Description

Production facilities equipment of renewable energy materials

The present invention relates to an apparatus for producing renewable energy raw materials, and more particularly, to a facility for producing renewable energy raw materials by collecting marine wastes as well as materials to be used as renewable energy raw materials. It is about.

Although resources are limited today, energy resources are gradually being depleted due to population growth and accelerated consumption.

As a result, research on technologies that use non-polluting energy such as solar, geothermal, wind, and tidal power as alternative fuels is ongoing, but these technologies are subject to natural constraints, making it difficult to commercialize them, and the initial facility cost is enormous. There was this.

In this regard, the most attention is being paid to the energy recovery system, a technology for processing waste and using it as a recycle derived fuel (RDF).

The amount and type of domestic waste generated in daily life is enormous, and since most of the waste is mixed with various kinds of wastes, it is not only difficult to recycle it immediately, but also various production and consumption activities. Due to the large amount of waste discharged due to this situation is urgent treatment.

The remaining waste except food waste is divided into paper, wood, metal and nonmetals, glass bottles, plastics, clothing, styrofoam, etc. In the past, PET, PP, PS, PE, etc. among the plastics are selected and recycled. It was sent to beverage companies and recycled.

However, in the case of a large amount of foreign matter mixed or dissimilar materials among the plastics, it is difficult to recycle them as it is, in many cases incineration incinerators, in this case, due to the high calorific value of the plastic may reduce the life of the incinerator or cause failure. It was.

As a result, there are many efforts to commercialize the technology for producing recycled fuel from waste through many researches and developments, but the recycled fuel produced through the prior art has a form in which the crushed and dried waste is compressed as it is. It is difficult to ignite during combustion because it is heat-treated to maintain a constant shape only on the outside, the calorific value is less than half of the existing fossil fuel, there was a problem that generates a large amount of sludge and environmental pollutants.

The present invention has been made in order to solve the above-mentioned problems, and has a production equipment of renewable energy raw materials to produce a high-efficiency renewable energy raw material having a plurality of devices for collecting and efficiently separating and shredding general household waste The purpose is to provide.

Renewable energy raw material production equipment device of the present invention for achieving the above object in the renewable energy raw material production equipment device to collect the waste to produce a renewable energy raw material, so that it is easy to separate the sorted by receiving the collected waste A first crushing unit to first crush; Separation unit for sorting the combustibles made of combustible plastic or rubber from the pulverized product discharged from the first crushing unit; A second crushing unit for discharging the combustible material by secondary grinding of the combustible material to facilitate extrusion molding; And a renewable energy raw material producing unit for producing renewable energy raw materials by extruding the combustible material.

Here, the separation unit, the first separation unit for separating and carrying out the ferrous metal by using a magnetic force receives the pulverized product discharged from the first crushing unit, and the pulverized product separated and taken out of the ferrous metal by the first separation unit A second separation part for separating the heavy material and the light object using vibration, a third separation part for sorting combustible plastics from ferrous or non-ferrous metals among the light weight material separated by the second separation part, and the second separation part It is preferable to include a fourth separation unit for separating the rubber material from the ferrous or non-ferrous metal in the weight separated by.

In addition, the first separation unit, the first conveyor belt for receiving and transporting the pulverized product discharged from the first crushing unit, and is provided on the upper side of the first conveyor belt in a direction perpendicular to the moving direction of the first conveyor belt. It is preferable that the first separation belt is driven, and the separation magnet is mounted inside the first separation belt and the separation magnet for separating out the ferrous metal using magnetic force from the pulverized product transported along the first conveyor belt.

The second separator may include a second hopper through which the pulverized material having passed through the first separator is introduced, a crank shaft rotated by a driving motor, and a plurality of the crank shafts connected to each other, and one end of which is connected upwardly. It is inclined so as to face the sorting plate for separating and transporting the pulverized object to one end and the other end according to the weight by reciprocating mutually shifted up and down by the rotation of the crank shaft, and separated by the driving of the sorting plate A first accommodating part for accommodating the light object transferred to one end and a second accommodating part for accommodating the heavy material separated by the driving of the sorting plate and transferred to the other end of the sorting plate are provided. It is preferable that it is a ballistic sorter in which two screen holes are formed and the residues contained in the pulverized product are carried out through the screen holes.

The third separator may further include: a second conveyor belt for receiving and transporting a light object from the second separator, an electromagnet wheel for driving the second conveyor belt by being attached to one end of the second conveyor belt and rotating; The ferrous metal discharge portion for receiving the ferrous metal is transported to the lower side in the state attached to the second conveyor belt by the magnetic force of the electromagnet wheel and the non-ferrous spring bounced along the transfer direction by the repulsive force of the electromagnet wheel A non-ferrous metal carrying portion provided at a position spaced apart from one end of the second conveyor belt to accommodate the metal, and provided on the lower side of the electromagnet wheel to accommodate the plastic falling from one end of the second conveyor belt It is preferable that a plastic container is provided.

The second crusher may include a plastic crusher that receives the plastic sorted from the third separator and crushes the combustible material, and a rubber crusher crushes the rubber material selected by the fourth separator into the combustible material. desirable.

Here, the plastic crusher, the third hopper receiving the plastic selected by the third separation unit, the plurality of rotary blades and the rotary blades are rotated by 20 to 50mm spaced apart from the rotary blades by receiving the driving force by the motor A cutter equipped with a fixed blade for pulverizing the plastic between the rotary blade and the fixed blade to discharge the combustible material used for extrusion molding, and provided at the lower side of the cutter to separate the combustible material and filter foreign substances. It is preferred to have a screen net.

In addition, the rubber crusher is provided with a fourth hopper receiving the rubber material selected in the third separation unit, and a pair of tooth blades rotated in engagement with the interval of 20 ~ 50mm is provided between the pair of tooth blades. It is preferable that a pulverization part for discharging the combustible material used for extrusion molding is provided by pulverizing the rubber material.

In addition, the renewable energy raw material production unit, a fixed amount feeder for adjusting the supply amount of the combustible material, an extruder for extruding the combustible material supplied from the fixed amount feeder, and a cooling fan for cooling the combustible material extruded by the extruder It is preferable to include.

Here, it is preferable that the extruder is provided with a hopper to which the combustible material is supplied, and a pair of screws which are connected to a rotating shaft driven by a driving motor to be extruded while transferring the combustible material to one end.

As described above, the apparatus for producing renewable energy raw materials of the present invention,

First, there is an advantage to provide a device for producing renewable fuels environmentally friendly by collecting the general household waste and use it in the production of renewable energy raw materials.

Second, since the sorting and crushing steps are performed by a plurality of separating and crushing parts, only the combustible material of size and type suitable for the production of renewable energy raw materials by extrusion molding is produced, so that high calorific value and high quality renewable fuel can be produced. There is this.

Third, there is an advantage that the appropriate separation and shredding unit is disposed according to the material and weight of each material to improve the efficiency of renewable energy raw material production.

Hereinafter, preferred embodiments of the present invention will be described in detail with reference to the accompanying drawings. Prior to this, terms or words used in the specification and claims should not be construed as having a conventional or dictionary meaning, and the inventors should properly explain the concept of terms in order to best explain their own invention. Based on the principle that can be defined, it should be interpreted as meaning and concept corresponding to the technical idea of the present invention.

Therefore, the embodiments described in the specification and the drawings shown in the drawings are only the most preferred embodiments of the present invention and do not represent all of the technical idea of the present invention, various equivalents that may be substituted for them at the time of the present application It should be understood that there may be water and variations.

Hereinafter, referring to FIGS. 1 to 9b, a production facility apparatus for renewable energy raw materials according to an exemplary embodiment of the present invention will be described.

1 is a process flow diagram showing a schematic process flow of the production equipment of the renewable energy raw material according to an embodiment of the present invention.

Referring to FIG. 1, the apparatus 100 for producing renewable energy raw material according to an embodiment of the present invention may include a first shredding unit 110, a first separating unit 120, a second separating unit 130, and a second separating unit 130. The third separator 140, the fourth separator 150, the second crushing unit and the renewable energy raw material production unit 180 is provided.

In addition, the production facility apparatus 100 for renewable energy raw materials produces renewable energy raw materials through each of the components arranged sequentially when the general household waste is collected and supplied. At this time, a plurality of conveyor belts are provided between each of the components is provided to transfer the material passing through each component to the next component provided through the conveyor belt.

When a large amount of waste obtained in daily life is collected and supplied to the first crushing unit 110, the first crushing unit 110 is crushed to an appropriate size to facilitate the separation and sorting of the various sizes of the supplied waste. do.

2A and 2B, the first crushing unit 110 includes a first hopper 111, a roller 113, a grinding blade 115, and a fixed blade 117. 2A is a plan view of the first shredding portion, and FIG. 2B shows a side view of the first shredding portion.

When a large amount of waste collected through the first hopper 111 is supplied, a roller 113 rotating by a motor drive, two rows of grinding blades protruding spirally in a direction inclined from the roller 113 ( 115) and the waste supplied by the driving of the fixed blade 117 provided in a form corresponding to each other at a predetermined interval so that the waste is crushed between the grinding blade 115 and Are compressed to a size advantageous for separation screening and milled.

At this time, the interval between the grinding blade 115 and the fixed blade 117 is preferably 100 ~ 200mm. Wastes of various sizes can be separated and sorted more easily in the separation sorting step by the separating part by first crushing to have a weight and size that are easy to separate and sort in the first shredding part 110.

The pulverized product discharged by the first crushing unit 110 is transferred to the first separating unit 120 by a conveyor belt.

Referring to FIG. 3, the first separator 120 includes a first conveyor belt 121, a first separator belt 123, and a separator magnet 125.

The combustibles conveyed to the first separation unit 120 are moved through the first conveyor belt 121, and the first separation belt 123 is provided on the upper side of the first conveyor belt 121. 1 is driven in the direction perpendicular to the moving direction of the conveyor belt 121, the separating magnet 125 made of a magnet selected from a permanent magnet or an electromagnet is mounted inside.

Therefore, the first separation belt 123 driving in the direction perpendicular to the driving direction of the first conveyor belt 121 is crushed to move up the first conveyor belt 121 by using the magnetic force of the separation magnet (125). Remove and attach only ferrous metals in water. The ferrous metal is transported in a state in which it is attached to the first separation belt 123 and reaches a portion where the magnetic force of the separator magnet 125 does not reach. The ferrous metal is separated and dropped from the first separation belt 123 to separate the storage tank. Is exported.

After the ferrous metal is separated from the pulverized product by the first separator 120, the pulverized product from which the ferrous metal is separated is transferred to the second separator 130.

4A to 4C, the second separator 130 is a ballistic sorter, and includes a second hopper 131, a crank shaft 132, a sorting plate 133, a first accommodating part 135, and The second accommodating part 136 is provided. 4A illustrates a schematic view of the second separator 130, FIG. 4B illustrates a front cross-sectional view of the second separator 130, and FIG. 4C illustrates a side of the second separator 130. The cross section is shown.

After the ferrous metal is separated from the pulverized product by the first separating part 120, the remaining pulverized material is transferred to the second separating part 130 and supplied through the second hopper 131.

When the pulverized product is supplied above the sorting plate 133 through the second hopper 131, as shown in FIG. 4, the plurality of sorting plates 133 vertically connected to the crankshaft 132 are connected to a motor. As the crankshaft 132 rotates, the plurality of sorting plates 133 are separated and vibrate in the vertical direction.

Here, the sorting plate 133 is formed to be inclined so that one end is directed upward, and as described above, when the vibrating in the vertical direction according to the rotation of the crankshaft 132 was randomly mixed on the sorting plate 133. The crushed materials are separated according to the weight so that the relatively lighter weights are transported and separated to one end inclined upward by the climbing motion, and the relatively heavy weights are transported to the other end inclined to the lower side.

As described above, the heavy material and the light weight are separated by the vertical vibration of the sorting plate 133, and the light weight material transferred to one end of the sorting plate 133 is supplied to the first accommodating part 135 to be described below. The heavy material transferred to the other end of the sorting plate 133 is supplied to the second accommodating part 136 and transferred to the fourth separating part 150 to be described later.

The light weight material may include various materials, but may include relatively lightweight combustible plastics, ferrous metals and non-ferrous metals mixed with other foreign materials and not separated by the first separating part 120. Relatively heavy rubber materials and nonferrous metals may be included.

In addition, a plurality of screen holes 133a are formed at the central portion of the sorting plate 133, and when the sorting plate 133 is driven and vibrated by a motor, the screen holes 133a are included in the pulverized product. The residue is separated and discharged.

The lightweight material supplied to the first accommodating part 135 is transferred to the third separating part 140, wherein the third separating part 140 is the second conveyor belt 141, the electromagnet wheel 143, and the ferrous metal. The carrying out part 145, the plastic accommodating part 149, and the nonferrous metal carrying out part 147 are provided.

As shown in FIG. 5, the second conveyor belt 141 receives light weight from the second separating unit 130 and transfers the light weight in one direction. One end of the second conveyor belt 141 is equipped with an electromagnetic wheel 143 is rotated by a motor drive to drive the second conveyor belt 141.

A constant magnetic force flows through the electromagnet wheel 143. Among the light objects transported along the second conveyor belt 141 by the magnetic force of the electromagnet wheel 143, the ferrous metal affected by the magnetic force is the second conveyor belt. The ferrous metal carrying out portion is transported downward while being attached to the second conveyor belt 141 without falling or jumping out of one end of the unit 141, and falling to reach a portion which does not affect the magnetic force. 145) and discharged separately.

Among the lightweight materials, the ferrous metal is mixed with other materials and thus cannot be separated by the first separation unit 120. The ferrous metal is not suitable for use as a combustible material and is separated and discharged as described above.

In addition, the non-ferrous metal carrying part 147 is spaced apart from one end of the second conveyor belt 141 by a predetermined distance so as to accommodate the non-ferrous metal bounced along the conveying direction by the repulsive force with the electromagnet wheel 143. Prepared.

The non-ferrous metal of the light weight is not attracted by the electromagnet wheel 143 and the force is repulsed by a predetermined distance by the repulsive force with the electromagnet wheel 143 that rotates at high speed, such a non-ferrous metal is also used as a combustible material As it is not suitable, separate and discharge as above.

The plastic accommodating part 149 is provided below the electromagnet wheel 143 mounted on one end of the second conveyor belt 141 to accommodate the plastic falling from one end of the second conveyor belt 141. do.

As described above, the plastic shredder of the second shredding unit to be described later by receiving the remaining plastic by separating and exporting the materials unsuitable for use as a combustible material by the ferrous metal carrying out portion 145 and the non-ferrous metal carrying out portion 147 of the light weight material. Transfer to 160.

In addition, the fourth separation unit 150 receives the heavy material supplied to the second receiving unit 136 of the second separation unit 130 and selects a rubber material from the heavy material. The heavy rubber material and the heavy weight non-ferrous metal are mixed in part, and the rubber crusher 170 of the second crushing part to be described later is selected by selecting only the rubber material suitable for use as a combustible material while transferring the heavy material through the conveyor belt. The material, except for the rubber material, is transferred to the third separation unit 140 to sort the plastic according to the process as described above.

Here, the second crusher includes a plastic crusher 160 and a rubber crusher 170, first, the plastic contained in the plastic receiving portion 149 is transferred to the plastic crusher 160 is of a size suitable for extrusion molding Secondary grinding with combustible materials.

6, the plastic crusher 160 includes a third hopper 161, a cutter 163, and a screen net 165.

When the plastic selected by the third separating unit 140 is supplied through the third hopper 161, a plurality of rotating blades 163a and the rotating blades 163a and 20 rotated by a driving force transmitted by a motor. Cutter 163 having a fixed blade 163b spaced apart at intervals of ˜50 mm is combustible material used for extrusion molding by pulverizing the plastic between the rotary blade 163a and the fixed blade 163b. Discharge and the screen net 165 is provided on the lower side of the cutter 163 to separate the combustible material and to filter foreign matter.

That is, the plastic crusher 160 may supply the combustible material to the renewable energy raw material production unit 170 to be described later by pulverizing the plastic into a combustible material.

In this case, when the distance between the rotary blade 163a and the fixed blade 163b exceeds 50mm, the size of the combustible material is so large that the heat transfer is not made to the inside of the combustible material during extrusion, so that extrusion is difficult. When the distance between the rotary blade 163a and the fixed blade 163b is less than 20mm, the amount of combustible material discharged and separated is very small, resulting in low yield of renewable energy raw materials obtained per fixed amount of waste. There is this.

Therefore, the interval between the rotary blade (163a) and the fixed blade (163b) is preferably 20 ~ 50mm.

7A and 7B, the rubber crusher 170 includes a fourth hopper 171 and a pulverizer 173.

The rubber material separated from the fourth separation unit 150 is supplied to the rubber crusher 170 through the fourth hopper 171, in which the pulverization unit 173 is rotated by engaging each other at an interval of 20 to 50 mm. A pair of tooth blades 173a is provided to pulverize the rubber material between the pair of tooth blades 173a to discharge the combustible material used for extrusion molding.

The pair of combustible materials discharged by the rubber crusher 170 is also heat-transmitted to the inside in the extrusion molding process to be described later, similarly to the combustible materials discharged by the plastic crusher 160, so that the yield can be efficiently obtained. It is preferable that the space | interval between the tooth blades 173a of is 20-50 mm.

The combustible material discharged through the plastic crusher 160 and the rubber crusher 170 of the second crusher is transferred to the renewable energy source production unit 180 and used to produce the renewable energy source. Here, the renewable energy raw material production unit 180 is provided with a metering feeder 181, an extruder 183 and a cooling fan 185.

The metering feeder 181 detects the processing speed of the extruder 183 with a sensor and performs a buffer function for controlling the fine supply of the combustible material so that an excessive amount of combustible material is not supplied to the extruder 183.

8A and 8B, the extruder 183 includes a hopper 183a, a rotating shaft 183b, and a screw 183c.

When an appropriate amount of combustible material is supplied to the hopper 183a according to extrusion from the metering feeder 181, the rotating shaft 183b is driven by a driving motor to rotate, and a screw 183c connected to the rotating shaft 183b. ) Transfers the combustible material supplied by rotating together with the rotation shaft 183b to one end. That is, the combustible material is extruded by being pressurized and melted while being transferred to one end through the screw 183c.

Here, the screw (183c) is interlocked with the rotating shaft (183b) body (183d) of the cross shape, and wings (183e) protruding in a spiral shape on the outer peripheral surface of the body (183d), and It is provided with a plate-shaped blade (183f) formed in a cross shape at one end of the body (183d) to finally crush the material remaining unmelted in the combustible material transferred along the blade (183e) to extrude in a molten state.

Here, the blade 183f is installed to be separated and exchanged together with the end side of the center body 183d. That is, the blade 183f is to consider that the replacement is inevitable as the wear gradually progresses during the grinding of the combustible material, and furthermore, it is advantageous to increase the hardness by heat-treating the side end portion H in the rotational direction.

The combustible material extruded by the extruder 183 is air cooled by the cooling fan 185 and then discharged as a renewable energy raw material.

The discharged renewable energy raw material may be packaged and used in a ton bag having a predetermined size to facilitate transportation or storage.

As described above, the production facility apparatus 100 for renewable energy raw materials according to the characteristics of each material undergoes a separation operation and performs a process of crushing to increase the efficiency of the process as well as marine waste. It is possible to produce high calorific value and high quality renewable energy raw materials by providing a washing machine as a treatment method.

As mentioned above, although this invention was demonstrated by the limited embodiment and drawing, this invention is not limited by this, The person of ordinary skill in the art to which this invention belongs, Of course, various modifications and variations are possible within the scope of equivalent claims.

1 is a process flow diagram showing a schematic process flow of a renewable energy raw material production facility apparatus according to an embodiment of the present invention,

2a and 2b is a schematic diagram showing the structure of the first shredding unit in the renewable energy raw material production equipment shown in FIG.

Figure 3 is a schematic diagram showing the structure of the first separation unit in the renewable energy raw material production equipment shown in Figure 1,

Figures 4a to 4c is a schematic view, front cross-sectional view and side cross-sectional view of the second separation unit in the renewable energy raw material production equipment shown in FIG.

5 is a schematic view showing the structure of a third separation unit in the renewable energy raw material production equipment shown in FIG.

6 is a schematic view showing the structure of a plastic crusher in the renewable energy raw material production equipment shown in FIG.

7a and 7b is a schematic diagram showing the structure of a rubber crusher in the renewable energy raw material production equipment shown in Figure 1,

FIG. 8A is a schematic view showing the structure of an extruder in the renewable energy raw material production equipment device shown in FIG. 1, and FIG. 8B is a schematic view showing a screw in the extruder shown in FIG. 8A.

<Description of the symbols for the main parts of the drawings>

100: renewable energy raw material production equipment

110: first shredding portion 111: the first hopper

113: roller 115: grinding blade

117: fixed blade 120: first separation unit

121: first conveyor belt 123: first separation belt

125: separation magnet 130: second separation unit

131: the second hopper 132: crankshaft

133: sorting plate 133a: screen hole

135: first accommodating part 136: second accommodating part

140: third separator 141: second conveyor belt

143: electromagnet wheel 145: iron metal carrying out portion

147: non-ferrous metal carrying portion 149: plastic receiving portion

150: fourth separator 160: plastic shredder

161: the third hopper 163: cutter

163a: rotating blade 163b: fixed blade

165 screen mesh 170 rubber crusher

171: the fourth hopper 173: grinding unit

173a: Tooth blade 180: Renewable energy raw material production department

181: metering feeder 183: extruder

183a: Hopper 183b: rotating shaft

183c: screw 183d: body

183e: Wings 183f: Blade

185: cooling fan

Claims (10)

In the renewable energy raw material production equipment device for collecting the waste to produce renewable energy raw materials, A first crushing unit for first crushing to receive the collected wastes and to easily separate and sort the wastes; Separation unit for sorting the combustibles made of combustible plastic or rubber from the pulverized product discharged from the first crushing unit; A second crushing unit for discharging the combustible material by secondary grinding of the combustible material to facilitate extrusion molding; And It is provided with a renewable energy raw material production unit for producing a renewable energy raw material by extruding the combustible material, The separation unit, A first separation unit for separating and carrying out ferrous metal by using magnetic force while receiving and transporting the pulverized product discharged from the first crushing unit; A second separation unit for separating the pulverized product passing through the first separation unit into a heavy product, a light product and a residue by using an inclination and a ballistic, A third separation part for separating out the ferrous metal and the nonferrous metal remaining in the lightweight material and selecting the plastic; A fourth separator for separating the rubber material from the weight, The second crushing unit, A plastic crusher which receives the plastic sorted from the third separator and grinds it into a combustible material; Equipment for production of renewable energy raw material, characterized in that consisting of a rubber crusher for grinding the rubber material selected in the fourth separation unit into a combustible material. delete The method of claim 1, wherein the first separation unit, A first conveyor belt for receiving and conveying the pulverized product discharged from the first crushing unit; A first separation belt provided on an upper side of the first conveyor belt and driven in a direction perpendicular to a moving direction of the first conveyor belt; And a separating magnet mounted inside the first separating belt and separating and carrying out ferrous metal from magnetic powder from the pulverized product transported along the first conveyor belt. The method of claim 1, wherein the second separation unit, A second hopper into which the pulverized product having passed through the first separator is introduced; A crankshaft rotated by a drive motor, A plurality of sorting plates connected to the crankshaft, one end of which is inclined upwardly, and reciprocally shifted upwards and downwards by rotation of the crankshaft to separate and convey the pulverized product into one end and the other end according to the weight; , A first accommodating part which is separated by the driving of the sorting plate and accommodates the light material transferred to one end of the sorting plate; A second accommodating part for receiving a heavy object separated by the driving of the sorting plate and transferred to the other end of the sorting plate, A plurality of screen holes are formed in the central portion of the sorting plate is a production equipment device for renewable energy raw material, characterized in that the ballistic sorting machine to carry out the residue contained in the pulverized through the screen hole. The method of claim 1, wherein the third separator, A second conveyor belt for receiving and transporting a light article from the second separator; An electromagnet wheel which is mounted on one end of the second conveyor belt and rotates to drive the second conveyor belt; An iron metal carrying part for receiving the ferrous metal that is transported to the lower side while being attached to the second conveyor belt by the magnetic force of the electromagnet wheel and is dropped; A non-ferrous metal carrying part provided at a position spaced apart from one end of the second conveyor belt to accommodate the non-ferrous metal bounced along the conveying direction by the repulsive force with the electromagnet wheel; Recycling energy raw material production equipment characterized in that the plastic receiving portion provided on the lower side of the electromagnet wheel to accommodate the plastic falling from one end of the second conveyor belt. delete The method of claim 1, wherein the plastic shredder, A third hopper receiving the plastic sorted from the third separator; A plurality of rotary blades are rotated by receiving a driving force by a motor, and fixed blades spaced apart from the rotary blades at intervals of 20 to 50 mm are provided to crush the plastic between the rotary blades and the fixed blades. A cutter for discharging the used combustible material, It is provided on the lower side of the cutter equipment for the production of renewable energy raw material, characterized in that the screen net for separating the combustible material and filter the foreign matter. The rubber crusher of claim 1, A fourth hopper receiving the rubber material selected by the third separator; Regeneration is characterized in that a pair of tooth blades that are engaged to rotate at intervals of 20 ~ 50mm is provided to crush the rubber material between the pair of tooth blades to discharge the combustible material used for extrusion molding Equipment for the production of energy raw materials. The method of claim 1, wherein the renewable energy raw material production unit, A fixed-quantity feeder for controlling the supply amount of the combustible material, An extruder for extruding the combustible material supplied from the metering feeder, And a cooling fan for cooling the combustible material extruded by the extruder. 10. The method of claim 9, The extruder, Hopper supplied with combustible materials, And a pair of screws which are connected to a rotating shaft driven by a driving motor to be extruded while transferring the combustible material to one end.

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