KR102026174B1 - Manufacturing Method for Apparatus Assorting Gravels and Sand - Google Patents

Abstract

The present invention relates to a method for manufacturing an aggregate sorting apparatus, which is applied with a technique capable of improving the quality and lifespan of equipment. The method of the present invention comprises: a first step of allowing a supply conveyor (10) to have a frame (1); a step of providing a filtering frame body (20); and a step of providing a discharge conveyor (41) at a lower portion of the filtering frame body (20).

Description

Manufacturing Method for Apparatus Assorting Gravels and Sand}

The present invention relates to a method for producing an aggregate screening apparatus, and more particularly, to efficiently and stably maintain equipment for aggregate sorting in the process of collecting aggregates, thereby preventing deterioration in quality management of equipment before actual installation. When operating equipment for screening aggregates, it relates to a method for manufacturing aggregate screening devices using technology that can improve the quality and life of the equipment itself by minimizing damage (eg, scratches) and contamination of the equipment itself due to the aggregate. .

As an exemplary method of producing aggregates, raw stones are first crushed with jaw crushers, the mandibular stones or gabions are separated by an aggregate sorter, followed by a second crushing process with a cone crusher, and a third crushing process with a fine aggregate crusher. After that, it is possible by finally separating the aggregate through the product sorting screen. In this way, aggregate is generally supplied to the upper screen, falls to the lower screen below the aggregate such as mixed manta stone, gabion, rubble, and is discharged to the conveyor. Existing technical research has focused on the technology to solve the problem that the upper screen 13 is a net screen to prevent damage, such as large holes or wear, without impact force when the aggregate falls from the top . In other words, it does not just solve the problem that occurs afterwards. Therefore, there is a problem that it is difficult to prevent the deterioration of the quality of the sorting equipment in the waiting time generated before the manufacture and installation of the equipment for sorting. In addition, there is a problem that it is difficult to effectively prevent the damage pollution, such as by the aggregate or other external environmental factors in the operation process through the sorting equipment.

Therefore, there is a disadvantage that the maintenance management of the aggregate screening equipment is not easy in the aggregate collection process.

Korea Utility Model Registration No. 20-0137856

The present invention can effectively and stably maintain the equipment for the selection of aggregates in the process of collecting the aggregates in advance to prevent the deterioration in quality management of the equipment before the actual installation, the equipment due to the aggregates during the operation of the equipment for the selection of aggregates It is an object of the present invention to provide a method for fabricating an aggregate screening device with a technology that can minimize the damage (eg scratches) and contamination of the equipment to improve the quality and life of the equipment itself.

The present invention provides a method for producing an aggregate screening apparatus, comprising: a first step of supplying a frame to a supply conveyor having a drive motor and a hopper; A lower frame provided with a vibration motor and a filter net under the hopper, and a lower frame linked with the driving motor is connected with the upper frame so that the filter frame is provided; And discharging a conveyor having a driving motor in a lower portion of the filtering body, wherein at least the hopper, the supply conveyor, the lower frame and the upper frame of the aggregate sorting device are coated with a film treatment device. The processing apparatus, wherein the coating treatment apparatus, an aggregate comprising a direct liquid spraying device for spraying the coating liquid, and a driving auxiliary module provided under the direct liquid spraying device to assist the drive of the direct liquid spraying device. It provides a method of manufacturing the sorting device.

According to the present invention can effectively and reliably maintain the equipment for the selection of aggregates in the process of collecting the aggregates in advance to prevent the deterioration in quality management of the equipment before the actual installation, when operating the equipment for the selection of aggregates due to the aggregates There is an effect that it can provide a method for producing an aggregate screening device for collecting the aggregate applied technology that can minimize the damage (eg scratches) and contamination of the equipment itself to improve the quality and life of the equipment itself.

1 is a view showing the aggregate sorting apparatus according to an embodiment of the present invention.
2 to 4 show the components according to FIG. 1.
5 is a flowchart sequentially showing an aggregate selection method according to an embodiment of the present invention.
6 is a flowchart sequentially illustrating a method for manufacturing an aggregate sorting apparatus according to an embodiment of the present invention.
7 is a block diagram showing the configuration of the aggregate screening system according to an embodiment of the present invention.
FIG. 8 is a view showing a film processing apparatus applied to FIGS. 1 to 5.
9 to 10 are views showing another embodiment of the film processing apparatus according to FIG.

Hereinafter, exemplary embodiments of the present invention will be described in detail with reference to the accompanying drawings.

Aggregate sorting device

1 is a view showing the aggregate sorting apparatus according to an embodiment of the present invention. 2 to 4 show the components according to FIG. 1. 1 to 4, a hopper 11 for supplying aggregate to the supply conveyor 10 is formed at one side of the supply conveyor 10, and a supply conveyor 10 is provided at the other side of the supply conveyor 10. The drive motor 12 which drives and the hopper 13 which supplies an aggregate to the sieve 20 are formed. The filter body 20 is formed at the lower part of the supply conveyor 10, and as shown in FIG. 2, the upper frame 21 and the lower frame 22 are connected by a spring 24.

The upper frame 21 is a vibration motor 26 is fixed to the upper frame 21 through the support 25 on the upper portion, the locking jaw 36 is formed on the inner side of the upper frame 21 is a mesh net 23 ) Can be easily detached to the upper frame 21, the discharge port 27 is formed on one side of the upper frame 21 to discharge the large aggregate after filtering the aggregate below a certain size by the strainer 34. . The wheel 30 formed on the lower frame 22 is configured to move along the rail 29 provided in the frame 1 of the aggregate sorter, and in particular, the wheel 30 behind the lower frame 22 is height-adjusted. Since it is fixed to the lower frame 22 through the base 28, it is possible to adjust the inclination of the frame 20 by using the fixing bolt 33. One side of the lower frame 22 is the drive motor 31 and the link As the driving motor 31 is rotated by connecting the 32, the frame 20 is configured to move left and right reciprocating along the rail 29.

Discharge conveyor 41 is formed in the lower portion of the filter body 20, the drive motor 42 for driving the discharge conveyor 41 is configured on one side of the discharge conveyor 41 is selected by the filter body 20 The aggregate is moved to the storage tank (3). Referring to the operation of the present invention configured as follows. When supplying aggregates mixed with gravel and sand of various sizes to the supply conveyor 10 through the hopper 11 on one side of the supply conveyor 10, the aggregate is supplied along the supply conveyor 10 driven by the driving motor 12. The hopper 13 is formed on the other side of the conveyor 10 and is supplied to the strainer body 20.

The vibration motor 26 provided on the upper part of the sieve frame 20 vibrates the upper frame 21 of the sieve body 20, and one side of the lower frame 22 of the sieve body 20 has a driving motor 31. Connected to the link 32 so that the sieve body 20 vibrates along the rails 29 of the frame 1 and moves reciprocally, so that the aggregate supplied to the sieve body 20 vibrates and moves reciprocatingly. Aggregate of a predetermined size or less through the strainer 34 of the 23 passes through the strainer 34 and falls to the discharge conveyor 41 through the hopper 35 provided in the lower portion of the strainer 20, strainer ( Aggregate of a predetermined size or more that does not pass through 34 is discharged to the storage tank (2) through the outlet (27).

At this time, even if the upper frame 21 of the strainer body 20 vibrates by the vibration motor 26 and moves left and right along the rail 29, the upper frame 21 and the lower frame 22 move to the spring 24. Is connected so that the wheel 30 of the lower frame 22 does not leave the rail (29). Aggregate of a predetermined size or less that passes through the strainer 34 and falls into the hopper 35 is moved in the discharge conveyor 41 driven by the drive motor 42 and stored in the storage tank 3. Figure 3 is a state of use of the aggregate sorter according to the present invention, Figure 4 is a partial perspective view of the supply conveyor according to the present invention. As shown in FIG. 1, the aggregate 44 is not supplied to the supply conveyor 10 through the hopper 11, and as shown in FIG. 3, the ground of the aggregate harvesting site or the construction site is dug to make a pit, where gravel and sand are mixed. By storing the aggregate so that the supply conveyor 10 can directly supply the aggregate 44 to the aggregate sorter, a large amount of aggregate 44 is supplied to the supply conveyor 10 without having to supply the aggregate 44 to the supply conveyor 10. ) Can be supplied to the aggregate sorter.

In order to prevent the water of the ground from seeping into the aggregate or the soil around the pit collapsing and mixing with the aggregate when digging the ground of the aggregate harvesting site or construction site, as shown in FIG. 4, the fixing ring 45 of the sheet 43 is removed. The hooks 46 formed on both sides of the supply conveyor 10 are fixed to the hooks, and the waterproof sheet 43 is laid in the pit to store the aggregate thereon so that water does not penetrate the aggregate. It can be prevented from mixing with the aggregate (44). Also included in the present invention is a configuration in which the zipper is formed on both sides of the supply conveyor 10 to be combined with the sheet 43. As a result, the technical idea of the present invention is a supply conveyor 10 having a drive motor 12 and a hopper 13 on one side is formed on the upper side of the frame 1, the vibration motor 26 in the lower portion of the hopper 13 ) And a height adjuster 28 is provided on the wheel 30 rolling on the rail 29 of the frame 1 and the upper frame 21 having the mesh net 23 and the driving motor 31 and the link ( The lower frame 22 connected by the 32 is connected to the upper frame 21 by the spring 24 to form the filtering frame 20, and the lower portion of the filtering frame 20 is provided with a driving motor 42. Aggregate sorter, characterized in that the conveyor 41 is configured, the supply conveyor 10 is formed with a hook 46 that can be fixed by connecting the fixing ring 45 of the sheet 43 on both sides thereof.

On the other hand, at least the hopper 13, the supply conveyor 10, the lower mold 22, and the upper mold 21 of the aggregate sorting apparatus are processed by the film processing apparatus 200.

Aggregate Screening Method

5 is a flowchart sequentially showing an aggregate selection method according to an embodiment of the present invention. Referring to Figure 5, in the aggregate screening method for collecting the aggregate, aggregate input step receiving the aggregate 44; Aggregate selection step of selecting the aggregate 44 with the aggregate sorting device according to the preset conditions; And an aggregate discharge step of discharging the aggregate 44 selected according to preset conditions to the outside. In the aggregate selection step, the aggregate sorting device includes a supply conveyor having a driving motor 12 and a hopper 13. 10 is formed on the upper side of the frame 1, the upper frame 21 and the rail 29 of the frame 1 is provided with a vibrating motor 26 and the mesh netting 23 in the lower portion of the hopper 13 The height adjuster 28 is provided on the wheel 30 that rolls up, and the lower frame 22 connected to the drive motor 31 and the link 32 is connected to the upper frame 21 by the spring 24 to be walked. The frame 20 is configured, and the discharge conveyor 41 is provided in the lower portion of the frame 20. At least the hopper 13, the supply conveyor 10, the lower mold 22, and the upper mold 21 of the aggregate sorting apparatus are subjected to an encapsulation process through the encapsulation apparatus 200, and the encapsulation apparatus 200 is encapsulated. Direct fluid injection device 250 for injecting a liquid, and is provided in the lower portion of the direct fluid injection device 250 includes a drive auxiliary module 270 for assisting the drive of the direct fluid injection device (250).

<Method of manufacturing aggregate sorting device>

6 is a flowchart sequentially illustrating a method for manufacturing an aggregate sorting apparatus according to an embodiment of the present invention. Referring to FIG. 6, in the method of manufacturing an aggregate screening apparatus, a first step of supplying a frame 1 to a supply conveyor 10 provided with a drive motor 12 and a hopper 13; An upper frame 21 having a vibration motor 26 and a mesh net 23 is provided at a lower portion of the hopper 13, and a lower frame 22 interlocked with the driving motor 31 is connected to the upper frame 21. To be provided with a strainer body 20; And a discharge conveyor 41 having a drive motor 42 provided below the strainer body 20.

 At least the hopper 13, the supply conveyor 10, the lower mold 22 and the upper mold 21 of the aggregate sorting apparatus are subjected to an encapsulation process through the encapsulation apparatus 200, but the encapsulation apparatus 200 is coated with Direct fluid injection device 250 for injecting the processing liquid, and a drive auxiliary module 270 provided in the lower portion of the direct fluid injection device 250 to assist the drive of the direct fluid injection device 250.

Aggregate sorting system

7 is a block diagram showing the configuration of the aggregate screening system according to an embodiment of the present invention. Referring to Figure 7, in the aggregate sorting system, the aggregate input unit 110 receives the aggregate; Aggregate sorting unit 120 for selecting the aggregate with the aggregate screening device according to the preset conditions; And it includes an aggregate discharge unit 130 for discharging the aggregate selected in accordance with the preset conditions to the outside. In the aggregate sorting device, a supply conveyor 10 provided with a drive motor 12 and a hopper 13 is formed on the upper side of the frame 1, and a vibration motor 26 and a mantle ( 23 is provided with a height adjuster 28 on the upper frame 21 and the wheel 30 rolling on the rail 29 of the frame 1, the lower portion connected to the drive motor 31 and the link 32 The frame 22 is connected to the upper frame 21 by a spring 24 to form a filter frame 20, and a discharge conveyor 41 is provided at the lower portion of the filter frame 20, and has an aggregate selection device. At least the hopper 13, the supply conveyor 10, the lower mold 22, and the upper mold 21 are processed by the film processing apparatus 200, and the film processing apparatus 200 sprays the film processing liquid. Direct fluid spraying device 250 and a drive auxiliary module 270 provided to the lower portion of the direct fluid spraying device 250 to assist the drive of the direct fluid spraying device 250.

<Film processing apparatus 1>
FIG. 8 is a view showing a film processing apparatus applied to FIGS. 1 to 5. Referring to FIG. 8, the film processing apparatus 200 includes a direct fluid spraying device. The direct fluid injector includes a gas-liquid mixing unit 210 which forms a gas-liquid mixing fluid by mixing a liquid reaction source diluted with a solvent and a carrier gas; A cooling unit 220 installed at the side of the gas-liquid mixing unit 210 to cool the third flow path 223 through which the gas-liquid mixing fluid flows so that the solvent contained in the gas-liquid mixing fluid is not vaporized; And a vaporization unit 230 for vaporizing the gas-liquid mixed fluid via the transfer line L connected to the third passage 223.
The gas-liquid mixing unit 210 includes a first inlet 211a through which a metal organic compound, such as SrTiO3 and BaTiO3, is introduced, and a second inlet 212a through which a carrier gas is introduced. It is. In the gas-liquid mixing unit 210, a first flow passage 211 communicating with the first inlet 211a, a second flow passage 212 communicating with the second inlet 212a, and a first flow passage 211 are provided. A mixing chamber 213 is formed in communication with the second flow path 212 and connected to the third flow path 223. In addition, the gas-liquid mixing unit 210 controls the valve 214 to open and close the first flow passage 211 in order to control the amount of the liquid reaction source flowing into the first flow passage 211 in communication with the mixing chamber 213. The control valve 214 may be a known piezo valve or an air valve.
The cooling unit 220 is to prevent the vaporization of the solvent in the gas-liquid mixing unit 210, the vaporization temperature is relatively very low compared to the liquid phase reaction source. Solvent is a dilution of the liquid phase source, so if the solvent is vaporized, the dilution will not work properly. Therefore, the solvent should not be vaporized in the gas-liquid mixing unit 210, for this purpose is to install the cooling unit 220 on the side of the gas-liquid mixing unit 210. The cooling unit 220 may be implemented in various forms. In the present embodiment, a cooling fluid inlet 221 through which a cooling fluid, for example, air or cooling water, flows around the outer circumference of the third flow path 223, and a third A cooling outlet 222 through which a cooling fluid is discharged through the outer circumference of the flow path 223 is formed, and a plurality of cooling fins 223a are formed at the outer circumference of the third flow path 223. However, the cooling unit 220 is installed around the outer circumference of the third flow path 223 and may be implemented by mounting a Peltier element that cools when electric power is applied.

The vaporizer 230 may include a nozzle 231 to which the gas-liquid mixed fluid conveyed by the transfer line L is sprayed, and a heater that applies heat to vaporize fine droplets of the gas-liquid mixed fluid sprayed from the nozzle 231 ( 233 to which the vaporization chamber 232 is mounted. That is, the nozzle 231 has a venturi tube structure in which the diameter thereof becomes smaller, so that the gas-liquid mixed fluid conveyed by the transfer line L is quickly discharged and sprayed into the droplets. The vaporization chamber 232 is formed in front of the nozzle 231 is connected to the chamber (not shown) and the reaction source supply line (not shown) that the thin film deposition proceeds. The heater 233 vaporizes the sprayed microdroplets by applying heat to the vaporization chamber 232. The heater 233 should apply a temperature higher than the vaporization temperature of the liquid phase reaction source so that the droplets can be vaporized, for this purpose, at least 200 degrees or more, in the present embodiment is applied at least 300 degrees. Next, the operation of the direct fluid injector having the structure as follows will be described. The liquid reaction source diluted with solvent and the carrier gas are introduced into the mixing chamber 213 through the first flow passage 211 and the second flow passage 212, respectively, and are mixed to form a gas-liquid mixture fluid, and then the gas-liquid mixture fluid is It is introduced into the vaporization unit 230 through the third passage 223 and the transfer line (L). At this time, the cooling unit 220 lowers the temperature of the gas-liquid mixture fluid passing through the third passage 223 to prevent the solvent from vaporizing. Then, the gas-liquid mixed fluid transferred to the vaporization unit 230 is sprayed by the nozzle 231 and then vaporized into gas in the vaporization chamber 232 and then introduced into the chamber through the reaction source supply line.

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<Film processing apparatus 2>

9 to 10 are views showing another embodiment of the film processing apparatus according to FIG. In the following description, the overlapping contents are omitted as necessary, and the description will be given based on technical differences. 9 to 10, the film processing apparatus 300 includes a direct fluid spraying device 350 for spraying the coating liquid and a lower portion of the direct fluid spraying device 350 to directly spray the liquid spraying device. It includes a drive auxiliary module 370 to assist the driving of the 350.

 The driving auxiliary module 370 is a frustum-shaped structure having a triangular longitudinal section, and the driving auxiliary module 370 is located on both sides of the rotating body 372 and the rotating body 372 rotatably provided, and the outer side thereof is inclined. A first region module 371 and an upper end including a forward and backward fixed body 392 which is formed to extend, and fixes the rotary body 372 to the inner side based on the forward and backward flow in the horizontal direction, and the fixed body 392. The second region module 394 and the first region module 371 and the second region module 394 of the lower portion which is located at the lower portion of the lower portion and formed to have an inclined portion of the outer portion corresponding to the fixing body 392. A fluid 373 reciprocating on the inclined outer portion is provided.

 The driving auxiliary module 370 is provided with a contact plate 393 which is coupled with the direct fluid spraying device 350, and a mounting part 274 on which the contact plate 393 is mounted is provided on the upper portion of the rotating body 372. When the fluid 373 is positioned in the first area module 371, the contact plate 393 is mounted on the circumference of the mounting part 274.

 The fluid 373 may flow between the first area module 371 and the second area module 394 in a state where the fixed body 392 flows toward the rotor 372 to fix the rotor 372. Fluid injection device 350 is capable of reciprocating flow from the driving auxiliary module 370 via the contact plate 393.

 The driving auxiliary module 370 may further include a predetermined distance adjusting module. The bottom portion of the second area module 394 is provided with a plurality of support parts that can flow in the longitudinal direction with elastic restoring force, and the support parts include a first support part 375, a second support part 376, and a third support part 377. The fourth support part 378 is provided. The separation distance adjusting module presses the first support part 375 to the fourth support part 378 so that the first support part 375 to the fourth support part 378 are based on the direct fluid injection device 350 and the driving auxiliary module 370. Reduce vibration generated in

 The first friction contact part MT1 is provided on the side of the first support part 375, and the second friction contact part MT2 is provided on the side of the second support part 376 to correspond to the first friction contact part MT1. The contact portion MT1 is a rectangular triangular structure having an inclined surface, and the first friction protrusion T1 is provided on the inclined surface, and the second friction contact portion MT2 is a rectangular triangular structure corresponding to the first frictional contact portion MT1. 2 friction projection (T2) is provided. The separation distance adjusting module includes a first separation distance adjustment part 379 to which the first support part 375 is fixed, a second separation distance adjustment part 380 to which the second support part 376 is fixed, and a third support part ( And a third separation distance adjustment part 381 to which 377 is fixed, and a fourth separation distance adjustment part 382 to which the fourth support part 378 is fixed. The first separation distance control unit 379 flows to be accommodated in the second separation distance control unit 380, and the fourth separation distance adjustment unit 382 flows to be accommodated in the third separation distance adjustment unit 381. do.

 The driving auxiliary module 370 further includes a fixing module that pressurizes the separation distance adjusting module, and the second separation distance adjusting part 380 and the third separation distance adjusting part 381 are one of the other inside each other. Is accepted. The fixed module includes a first fixture 383 to accommodate and fix the first distance controller 379 and a second distance controller 380 to a third distance controller 381. The third fixture 384, the third fixture 385 is accommodated and fixed to the third separation distance 381, and the fourth fixture 386 is received and fixed to the fourth separation distance control portion 382 It includes. The first fastener 383 flows into the second fastener 384, and the fourth fastener 386 flows into the third fastener 385.

 One fixture of the second fixture 384 and the third fixture 385 flows into the other fixture, and the first friction protrusion T1 and the second friction protrusion T2 are separated from each other. Based on the pressurized flow to the support of the will be interlocked. The direct fluid spraying device 350 includes a central body portion 351, a front end portion 352 provided at the front end of the central body portion 351, and a rear end body portion provided at the rear end portion of the central body portion 351. 353 is provided. The rear end body portion 353 includes a first body 353a that is coupled to a portion of the first central body portion 351, a second body 353b that extends outward from the first body 353a, and a second body. A third body 353c rotatably provided from 353b is provided. The third body 353c is provided to have elastic restoring force through the second body 353b and the elastic device CM, and is provided to be seated in contact with the user's shoulder through the protrusion area 353T formed at the bottom. The front end part 352 is provided with an identification part CM for photographing and identifying an object to be processed, and an opening and closing hole OC for allowing or blocking the injection of the coating liquid.

 The opening and closing port OC is opened when the elastic device CM is in a pressurized state, and is controlled to be closed in a state where the pressurization is released. The third body 353c is rotatably provided from the second body 353b, and the lower protrusion 353T includes a precision display unit HDP for precisely identifying the object. When the protrusion area 353T is positioned upward by the rotation of the third body 353c, the precision display unit HDP is flowed to be exposed to the outside. When the precision display unit HDP is externally exposed, the identification unit CM of the front end unit 352 is controlled to expose the precision identification unit CM for precisely identifying the object forward. The central body portion 351 is provided with a general display unit DP for identifying an object to be processed through the identification unit CM in an initial state other than the rotation state of the third body 353c.

Although the present invention has been described with reference to the embodiments shown in the drawings, this is merely exemplary, and it will be understood by those skilled in the art that various modifications and equivalent other embodiments are possible. Therefore, the true technical protection scope of the present invention will be defined by the technical spirit of the appended claims.

1: frame
2,3: storage tank
10: Supply Conveyor
11,13,35: Hopper
12,31,42: Drive motor
20: sieve
21: upper frame
22: lower frame

Claims (7)

In the aggregate sorting device manufacturing method,
A first step in which the supply conveyor 10 having the drive motor 12 and the hopper 13 is provided with the frame 1; The upper frame 21 is provided with a vibration motor 26 and the filter net 23 in the lower portion of the hopper 13 and the lower frame 22 is connected to the upper frame 21, the filter frame 20 is To be provided; And a discharge conveyor 41 having a drive motor 42 provided below the strainer body 20.
At least the hopper 13, the supply conveyor 10, the lower mold 22 and the upper mold 21 of the aggregate sorting device is subjected to an encapsulation process through the film treatment apparatus 300,
The film treatment apparatus 300,
The direct fluid spraying device 350 for spraying the coating liquid and the drive auxiliary module 370 provided at the lower portion of the direct fluid spraying device 350 to assist the drive of the direct fluid spraying device 350. Including,
The driving auxiliary module 370 is a frustum-shaped structure having a longitudinal cross section,
The driving auxiliary module 370,
Rotating body 372 rotatably provided, and located on both sides of the rotating body 372, the outer side is formed to be inclined, to fix the rotating body 372 to the inner side based on the retreat flow in the horizontal direction A first area module 371 at the top including an advancing fixture 392,
A second region module 394 disposed at a lower portion of the fixture 392 and formed to have an inclined portion of which an outer portion thereof extends in correspondence with the fixture 392;
And a fluid body 373 reciprocating on the inclined outer portion of the first region module 371 and the second region module 394. delete The method according to claim 1,
The driving auxiliary module 370,
The contact plate 393 which is coupled to the direct fluid injection device 350 is provided,
Aggregate sorting device manufacturing method is provided on the top of the rotating body 372 is provided with a mounting portion 274 is mounted on the contact plate (393). The method according to claim 3,
When the fluid 373 is located in the first area module 371, the contact plate 393 is mounted on the circumference of the mounting part 274,
The fluid 373 includes the first area module 371 and the second area module 394 in a state where the fixed body 392 flows toward the rotating body 372 to fix the rotating body 372. Aggregate sorting device manufacturing method that can flow between. The method according to claim 4,
The direct fluid spraying device 350 is capable of reciprocating flow in the drive auxiliary module 370 via the contact plate (393). In the aggregate sorting device manufacturing method,
A first step in which the supply conveyor 10 having the drive motor 12 and the hopper 13 is provided with the frame 1; The upper frame 21 provided with the vibration motor 26 and the mesh net 23 is provided in the lower portion of the hopper 13 and the lower frame 22 is connected to the upper frame 21 to the strain frame body 20 To be provided; And a discharge conveyor 41 having a drive motor 42 provided below the strainer body 20.
At least the hopper 13, the supply conveyor 10, the lower mold 22 and the upper mold 21 of the aggregate sorting device is subjected to an encapsulation process through the film treatment apparatus 300,
The film treatment apparatus 300,
The direct fluid spraying device 350 for spraying the coating liquid and the drive auxiliary module 370 provided at the lower portion of the direct fluid spraying device 350 to assist the drive of the direct fluid spraying device 350. Including,
Further comprising a separation distance control module provided in the lower portion of the drive auxiliary module 370,
A bottom portion of the driving auxiliary module 370 is provided with a plurality of support parts that can be moved in the longitudinal direction with elastic restoring force, and the support parts include a first support part 375, a second support part 376, and a third support part 377. ), A fourth support 378 is provided,
The separation distance control module,
Pressing the first support part 375 to the fourth support part 378 to the first support part 375 to the fourth support part based on the direct fluid injection device 350 and the driving auxiliary module 370. 378) to reduce the vibration generated in the aggregate sorting device manufacturing method. The method according to claim 6,
The first friction contact part MT1 is provided at the side of the first support part 375.
A second friction contact part MT2 is provided on the second support part 376 side to correspond to the first friction contact part MT1.
The first friction contact part MT1 is a rectangular triangular structure having an inclined surface, and the first friction protrusion T1 is provided on the inclined surface.
The second friction contact part MT2 is a rectangular triangular structure corresponding to the first friction contact part MT1, and a second friction protrusion T2 is provided on an inclined surface.
The separation distance control module,
A first separation distance adjustment part 379 to which the first support part 375 is fixed, a second separation distance adjustment part 380 to which the second support part 376 is fixed, and a third support part 377 to which the third support part 377 is fixed; A third separation distance adjustment part 381 and a fourth separation distance adjustment part 382 to which the fourth support part 378 is fixed;
The first separation distance control unit 379 flows to be accommodated in the second separation distance control unit 380, and the fourth separation distance adjustment unit 382 flows to be accommodated in the third separation distance adjustment unit 381. Aggregate sorting device manufacturing method.

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