KR20120063418A - Separating apparatus for kernel of pine cone - Google Patents

Abstract

PURPOSE: A pine nut separating device is provided to automate processes of crushing pine cones and transferring obtained pine nuts and pine cone by products to a net body. CONSTITUTION: A pine nut separating device comprises the following: a crushing unit(100) crushing pine cones using the torque transferred from a driver(300), and separating pine nuts from the pine cones; a conveying unit(200) transferring pine cone by-products and the pine nuts discharged from the crushing unit to the lower side of the device; a separation unit(500) separating the pine cone by-products and the pine nuts by rotating; crushing tabs(130) having a sharp shape; a fixing container(110) including a discharging net in a net body form, fixed to a frame(700); a hollow external container(510) rotatably supported to the lower side of the crushing unit; an internal container(520) rotating with the external container; an upper bracket installed on the tip-end of the external and internal containers; a lower bracket(540) formed on the rear-end of the external and internal containers; and a separation preventing unit(550) installed on an upper outside supporter.

Description

Separating Apparatus for kernel of pine cone}

The present invention relates to a pineapple separating device, and more particularly, to a pineapple separating device for crushing pine nuts and automatically separating the pine nuts from pine nuts.

In general, pine nuts are crushed with ripe pine nuts to collect the pine nuts covered with a hard shell, and the process of removing the outer shell of the pine nuts is stored in the white pine is used in cooking or is sold as a snack or snack food.

Hereinafter, pine nuts that are crushed and separated from pine nuts are referred to as 'pine pine by-products'.

Conventionally, pine nuts can be obtained from pine nuts by crushing pine nuts using a tool such as a bat after harvesting pine nuts in order to obtain pine nuts from pine nuts.

By the way, when the pine nuts are crushed to obtain pine nuts through manual labor, the work itself is all done by manual labor. Therefore, in order to improve production efficiency, it is necessary to increase the number of workers in proportion to this, which increases labor costs. .

The present invention has been made to solve the above-described problems, by constructing the operation of transporting pine pine by-products and pine nuts into a crushed pine nut rotating and rotating the pine nuts to the mesh and the pine pine by-products left in the mesh By making a large amount of pine nuts can be obtained, according to the production efficiency can be improved, and even pine nuts having a variety of thicknesses to provide a one-pipe separation device to be broken through a single device.

The pineapple separating device of the present invention for achieving the above object, and is fixed to the frame and receiving the rotational force of the drive unit crushed pine pine crushed to put the pine nut from the pine crushed; A conveying unit provided at a lower portion of the crushing unit and receiving a rotational force of the driving unit to transfer pine nut by-products and pine nuts downstream from the crushing unit; It is rotatably supported downstream of the crushing portion and the pine nut by-products and pine nuts are transported from the conveying portion while separating and separating the pine pine by-products and the pine nuts from each other; do.

The shredding tab may be disposed in a plurality in a sharp shape toward the radially outer side and inclined in the longitudinal direction.

The crushing unit is provided with a discharge net of the net body is made of a hollow fixing cylinder fixed to the frame, and a rotating cylinder rotatably provided in the interior of the fixing cylinder and protruding a plurality of crushing tabs to the outside; The separating portion is rotatably supported downstream of the crushing portion and is provided with a hollow outer cylinder provided to decrease the diameter toward the rear in the longitudinal direction, and is located inside the outer cylinder to rotate integrally with the outer cylinder and to the rear in the longitudinal direction. A hollow and mesh inner cylinder provided to increase in diameter; The conveying unit may include a conveying means provided at a lower portion of the discharge network of the crushing unit, and a rear side thereof may communicate with an inner cylinder of the separating unit.

The outer cylinder and the inner cylinder is a conical shape of the front end and the rear end is open, the front end of the inner cylinder is spaced radially inward from the front end of the outer cylinder, the front of the outer cylinder is spaced along the circumferential direction To be discharged in the radial direction.

Upstream brackets are installed at the front ends of the outer cylinder and the inner cylinder, downstream brackets are installed at the rear ends of the outer cylinder and the inner cylinder, and the rotating shaft connected to the transfer part is provided at the upstream bracket. The downstream bracket may be provided with a rotary shaft rotatably connected to the frame to protrude rearward.

The upstream bracket includes a ring-shaped upstream outer support portion, a disk-shaped upstream inner support portion positioned radially inward of the upstream outer support portion, and an upstream connection portion connected to the upstream outer support portion and the upstream inner support portion. The upstream outer support is located between the front end of the outer cylinder and the front end of the inner cylinder; The downstream bracket is composed of a ring-shaped downstream outer support portion, a disk-shaped downstream inner support portion located radially inward of the downstream outer support portion, and a downstream connection portion connected in plurality between the downstream outer support portion and the downstream inner support portion. The downstream outer support is located radially outward at the rear end of the outer cylinder and the rear end of the inner cylinder; A rotary shaft connected to the transfer part may be provided at the upstream inner support part, and a rotary shaft rotatably connected to the frame may be provided at the downstream internal support part.

The upstream outer support part located at the front end of the inner cylinder may be provided with a departure prevention part extended to reduce the diameter toward the front.

The conveying portion is formed of a guide portion provided in the longitudinal direction in the lower portion of the discharge network, the conveying means is provided inside the guide portion is connected to the drive portion and the rear end is connected to the upstream inner support portion; The upper portion of the guide portion is open, the cross-sectional shape in the radial direction may be a shape that narrows toward the bottom.

A chute is provided at the rear of the guide part to be inclined downward toward the inner cylinder, and an end portion of the chute may be located between the front end portion of the inner cylinder and the separation preventing portion.

According to the pineapple separation device of the present invention as described above, the pine nuts are passed through the mesh and pine nut by-products are left in the mesh by constructing the operation of conveying pine pine by-products and pine nuts into a rotating mesh to crush pine nuts and rotate them. By making a large amount of pine nuts can be obtained, and thus the production efficiency can be improved, there is an effect that even pine nuts having various thicknesses can be broken through a single device.

1 and 2 are a perspective view showing a pineapple separating apparatus according to an embodiment of the present invention,
3 is a perspective view illustrating a state in which a cover is removed from a crushing part forming a pineapple separating device according to an embodiment of the present invention;
Figure 4 is a cross-sectional view showing a crushing portion forming a pineapple separating apparatus according to an embodiment of the present invention,
5 is a perspective view showing a state in which a part of the outer cylinder is removed from the separating part constituting the pineapple separating apparatus according to an embodiment of the present invention,
Figure 6 is a cross-sectional view showing a separation portion forming a pineapple separating apparatus according to an embodiment of the present invention,
7 is a perspective view illustrating a connection relationship between a separating part and a conveying part forming a pineapple separating device according to an embodiment of the present invention;
8 is a cross-sectional view taken along line A-A 'of FIG. 1 to explain an operating state of a pineapple separating device according to an embodiment of the present invention.

DETAILED DESCRIPTION Hereinafter, exemplary embodiments of the present invention will be described in detail with reference to the accompanying drawings so that those skilled in the art may easily implement the present invention.

In the following description, the horizontal direction in FIG. 8 is referred to as the “length direction” and the vertical direction as the “radial direction”, and the direction toward the crushing unit 100 in the longitudinal direction is 'forward' and the direction toward the separating unit 500. This is referred to as the 'rear', the radial direction in the direction toward the conveying unit 200 'radial inner', the direction away from the conveying unit 200 is referred to as 'radial outer'.

1 and 2 are a perspective view showing a pineapple separating apparatus according to an embodiment of the present invention, Figure 3 is a perspective view showing a state in which the cover removed from the crushed portion forming a pineapple separating apparatus according to an embodiment of the present invention 4 is a cross-sectional view showing a crushing part forming a pineapple separating apparatus according to an embodiment of the present invention.

1 and 2 according to an embodiment of the present invention, the pine nut separating apparatus is fixed to the frame 700 and receives the rotational force of the driving unit 300 to crush the pine pine which is put in from pine nuts The crushed part 100 and the lower part of the crushed part 100 are separated from the crushed part 100 and the pine nut by-products and pine nuts discharged from the crushed part 100 are received downstream of the crushed part 100. The conveyer 200 for transporting and the pine nut by-product and the pine nuts are rotatably supported by the frame 700 so as to be rotatable downstream of the crushing part 100 and receive and feed pine nut by-products and pine nuts transferred from the conveyer 200. It comprises a separation unit 500 to separate from each other.

As shown in FIGS. 3 and 4, the crushing unit 100 is hollow and cylindrical fixing cylinder 110 fixedly supported by the frame 700 and rotatably supported inside the fixing cylinder 110. It consists of a cylindrical rotating cylinder 120 provided.

The fixing cylinder 110 is provided with a discharge net 115 of the net body on the outer surface on the downstream side, the discharge net 115 may be formed with a plurality of through holes having a horizontal length and a vertical length of 25mm to 35mm, respectively, Preferably, the horizontal length and the vertical length may be formed to each 30mm.

If the horizontal length and vertical length of the through hole formed in the discharge network 115 is greater than 35 mm, pine pine by-products in which the pine nuts are not completely separated may be introduced into the through holes. Accordingly, by reducing the horizontal length and the vertical length of the through hole formed in the discharge network 115 to less than 35 mm, only pine nut by-products finely crushed and all the pine nuts are removed may be introduced into the through hole formed in the discharge network 115. .

In addition, an inlet 119 is formed on an outer surface of the fixing barrel 110 to inject pine nuts into the fixing cylinder 110, and the lid 117 may be provided in the inlet 119 to open and close. have.

A plurality of shredding tabs 130 protrude from the outer surface of the rotating cylinder 120. The shredding tab 130 may protrude in a sharp shape from the outer surface of the rotary cylinder 120 toward the radially outer side, and a diagonal line between the longitudinal direction and the radial extension line on the outer surface of the rotary cylinder 120. It may be arranged in a plurality so as to incline in the direction.

A gap t between 13 mm and 17 mm may be formed between an inner surface of the fixing tube 110 and an upper end of the crushing tab 130, and may be preferably 15 mm.

The pine nuts introduced into the fixing tube 110 are crushed while being sandwiched between the crushing tab 130 and the inner surface of the fixing cylinder, and the crushed tab is spaced between the crushing tab 130 and the inner surface of the fixing cylinder 110 by about 15 mm. Even if pine nuts of different sizes are put into the fixed container 110, the pine pine by-products can be sized enough to pass through the discharge network 115 while being crushed and crushed repeatedly.

Therefore, in the shredding part 100, even if the pine nuts are separated from the pine nuts by crushing the pine nuts, the process of repeatedly crushing until the pine pine by-products are large enough to pass through the discharge network 115. This is done.

The front end and the rear end of the rotary cylinder 120 is provided with a rotary shaft 140 protrudes, respectively, the rotary cylinder 120 is rotatably supported inside the fixed cylinder 110 by the rotary shaft 140. Can be.

The rotating shaft 140 provided at the front end of the rotating cylinder 120 may protrude outwards through the fixing cylinder 110 to be coupled to the first pulley 150.

Therefore, the first pulley 150 is connected to the drive shaft 310 of the drive unit 300 to be described later, the rotary cylinder 120 can be rotated by receiving a rotational force.

As illustrated in FIGS. 1 and 2, the transfer part 200 includes a guide part 210 provided in the longitudinal direction under the discharge network 115 and a transfer part provided in the guide part 210. Means 230.

The guide portion 210 is open at the top, the cross-sectional shape in the radial direction may be formed in a shape that becomes narrower from the open inlet of the top toward the bottom.

The guide part 210 may be in close contact with the lower end of the fixing tube 110 so that the open inlet is located below the discharge network 115.

A conveying hole 215 is formed at the rear of the guide part 210, and a chute 250 is inclined downward toward the separating part 500 under the conveying hole 215. The chute 250 may be provided by cutting a portion of the rear lower surface of the guide part 210 and then bending it downwardly.

The conveying means 230 may use a screw conveyor consisting of a rotating shaft and a spiral feed blade provided on the outer surface of the rotating shaft.

Therefore, when the pine pine by-products and the pine nuts crushed by the crushing unit 100 fall into the lower conveying unit 200 through the discharge network 115, the pine cone by-products through the conveying means 230 in the conveying unit 200 And the pine nuts are transferred downstream.

Pine pine by-products and pine nuts that were transferred through the transfer means 230 may be introduced into the transfer hole 215 and transferred to the separation unit 500 through the chute 250.

A second pulley 290 is installed at the front end of the transfer means 230, the rear end is connected to the separation unit 500.

Therefore, the second pulley 290 is connected to the drive shaft 310 of the drive unit 300, which will be described later to receive the rotational force so that the transfer means 230 can rotate.

In addition, since the rear end of the transfer means 230 is connected to the separation unit 500, the separation unit 500 also rotates as the transfer means 230 rotates.

As shown in FIGS. 1 and 2, the driving unit 300 may be fixedly installed in the frame 700 under the transfer unit 200. The drive unit 300 may include a motor 350 and a drive shaft 310 connected to the motor 350 in the longitudinal direction.

A first drive belt 330 is connected between the drive shaft 310 and the first pulley 150 connected to the rotary cylinder 120, and a second pulley connected to the drive shaft 310 and the transfer means 230. The second driving belt 320 is connected between the (290). Therefore, the rotary cylinder 120 and the transfer means 230 is able to rotate by receiving the rotational force of the drive shaft 310.

5 is a perspective view showing a state in which a part of the outer cylinder is removed from the separating part constituting the pineapple separating apparatus according to an embodiment of the present invention, Figure 6 is a separating portion forming a pineapple separating apparatus according to an embodiment of the present invention Figure 7 is a cross-sectional view, Figure 7 is a perspective view for explaining the connection between the separating portion and the transfer portion forming the pineapple separating apparatus according to an embodiment of the present invention.

As shown in FIGS. 5 and 6, the separating part 500 includes a hollow outer cylinder 510 provided to decrease in diameter from the front end to the rear end of the longitudinal direction, and inside the outer cylinder 510. It is fixed to the hollow and provided to increase the diameter from the front end to the rear end of the longitudinal direction is made of an inner cylinder 520 of the mesh.

The inner cylinder 520 may be formed with a plurality of through-holes having a horizontal length and a vertical length of 7mm to 13mm, respectively, preferably may be formed so that the horizontal length and vertical length are 10mm respectively.

The outer cylinder 510 and the inner cylinder 520 is a conical shape of the front end and the rear end is open, the front end of the inner cylinder 520 is located radially inwardly spaced from the front end of the outer cylinder 510 The rear end of the inner cylinder 520 is in contact with the rear end of the outer cylinder 510.

Therefore, the diameter of the front end of the outer cylinder 510 is larger than the diameter of the rear end, the diameter of the front end of the inner cylinder 520 is smaller than the diameter of the rear end. The diameter of the front end of the outer cylinder 510 is larger than the diameter of the front end of the inner cylinder 520, and the diameter of the rear end of the outer cylinder 51 and the diameter of the rear end of the inner cylinder 520 are the same. do.

Since the diameter of the front end portion of the outer cylinder 510 is larger than the diameter of the rear end portion, the lower portion in the longitudinal direction of the outer cylinder 510 is inclined downward from the rear end portion to the front end portion.

On the other hand, since the diameter of the front end of the inner cylinder 520 is smaller than the diameter of the rear end, the lower portion in the cross section in the longitudinal direction of the inner cylinder 520 is inclined downward from the front end to the rear end.

The front of the outer cylinder 510 is spaced along the circumferential direction is formed with a plurality of discharge holes 513 in the radial direction.

5 and 6, the upstream bracket 530 is installed at the front end of the outer cylinder 510 and the inner cylinder 520, and after the outer cylinder 510 and the inner cylinder 520 The downstream bracket 540 is installed at the end.

The upstream bracket 530 has a ring-shaped upstream outer support 531, a disk-shaped upstream inner support 535 located radially inward of the upstream outer support 531, and the upstream outer support 531. And an upstream connection portion 537 connected between the upstream inner support portion 535 and the upstream outer support portion 531 between the front end portion of the outer cylinder 510 and the front end portion of the inner cylinder 520. It is installed to be located.

The downstream bracket 540 is symmetrical with the upstream bracket 530, and has a ring-shaped downstream outer support portion 541 and a disk-shaped downstream inner support portion located radially inward of the downstream outer support portion 541. 545, and a downstream connection portion 547 connected to the downstream outer support portion 541 and the downstream inner support portion 545. The rear end portion of the outer cylinder 510 and the inner cylinder 520 are respectively formed. The downstream outer support portion 541 is installed on the radially outer side at the rear end.

Therefore, a space portion is formed between the inner surface of the outer cylinder 510, the outer surface of the inner cylinder 520, and the upstream outer support 531.

The upstream internal support 535 is provided with a rotation shaft 590 connected to the conveying means 230 of the conveying part 200 to protrude forward, and the downstream internal support 545 is rotatable to the frame 700. The rotating shaft 590 is projected to the rear.

 Therefore, the separating part 500 may rotate by receiving the rotational force of the transfer means 230.

Since the inner cylinder 520 is coupled to the outer cylinder 510, the outer cylinder 510 and the inner cylinder 520 rotate simultaneously.

The upstream outer support part 531 located at the front end of the inner cylinder 520 is provided with a departure prevention part 550 extending to reduce the diameter toward the front.

On the other hand, the end of the chute 250 is located in the space portion between the front end portion and the separation prevention portion 550 of the inner cylinder 520, as shown in FIG. Therefore, the chute 250 may not interfere with the rotation of the separator 500 even if the separator 500 is rotated.

8 is a cross-sectional view taken along line A-A 'of FIG. 1 to explain an operating state of a pineapple separating device according to an embodiment of the present invention.

When the separation device is made as described above, first, after removing the cover 117 provided in the fixing tube 110, the pine nut is put into the inlet 119 and the cover 117 is coupled.

Subsequently, when the driving unit 300 is driven, the rotary cylinder 120 connected to the driving unit 300 and the transfer unit 230 rotate, and the separation unit 500 connected to the transfer unit 230 also rotates. .

Since the rotatable cylinder 120 rotates, the pine nuts inserted into the fixing cylinder 110 are moved inside the fixing cylinder 110 as the crushing tab 130 rotates, and the inner surface of the fixing cylinder 110 is rotated. Compressed and crushed between the crushed tab 130, the pine nut is separated from the pine nut.

Subsequently, while the rotary cylinder 120 continues to rotate, the pine pine by-products are repeatedly compressed between the inner surface of the fixed cylinder 110 and the crushing tab 130 to be finely crushed.

In this way, when pine pine by-products are crushed smaller than the size of the discharge network 115, pine pine by-products and pine nuts are dropped into the transfer means 230 of the transfer unit 200 through the discharge network (115).

Pine pine by-products and pine nuts falling into the conveying part 200 may be directed toward the conveying means 230 without leaving the outside by the guide portion 210.

Since the conveying means 230 is connected to the driving unit 300 and rotates, pine pine by-products and pine nuts dropped to the conveying means 230 move downstream, and the inside of the separating part 500 through the chute 250. Will be transferred to the barrel (520).

The separating part 500 is connected to the conveying means 230, but the state is rotated, the end of the chute 250 is located in the space between the front end of the inner cylinder 520 and the separation prevention portion 550 Therefore, even if the separator 500 is rotated, the chute 250 may not interfere with the rotation of the separator 500.

In addition, since the end of the chute 250 is located in the departure prevention part 550, pine pine by-products and pine nuts transferred through the chute 250 are not separated to the outside, to the inner cylinder 520 Can be transported.

Since the lower portion of the cross section in the longitudinal direction of the chute 250 is inclined downward from the front end portion to the rear end portion, even if pine pine by-products or pine nuts fall to the departure preventing portion 550 without being directly transferred to the inner cylinder 520. It may be transferred to the inner cylinder 520 by the inclined surface.

The pine pine by-products and the pine nuts transferred to the inner side of the inner cylinder 520 are moved by rearward gravity due to the centrifugal force generated as the inner cylinder 520 rotates and the downward slope from the front end to the lower end in cross section. do.

At this time, the pipe smaller than the through-hole formed in the inner cylinder 520 is introduced into the through hole and falls into the space between the inner surface of the outer cylinder 510 and the outer surface of the inner cylinder 520 and the upstream outer support 531, pine pine by-products Is continuously transported backwards and is discharged outside the downstream bracket 540.

The pipes dropped into the space are transferred to the front by gravity acting by the centrifugal force generated as the outer cylinder 510 rotates and a downward inclined surface is formed from the rear end to the front end in the cross section, and the discharge hole formed in the outer cylinder 510. It is discharged to the outside through 513.

On the other hand, as the through-holes formed in the inner tube 520, not only pine nuts but also finely crushed pine pine by-products may fall together, and the pine nuts and pine pine by-products may be discharged together through the discharge hole 513.

In order to solve this problem, only pine nuts can be obtained by blowing a pine pine by-product discharged to the discharge hole 513 with a separate blowing means.

The pine pipe discharged to the discharge hole 513 may be accumulated in a separate collecting device (not shown), and the accumulated pine pipe may be transferred to a separate shell removing device (not shown) for removing the hard shell.

In the above description, the present invention has been described with reference to preferred embodiments, but the present invention is not necessarily limited thereto, and a person having ordinary skill in the art to which the present invention pertains does not depart from the technical spirit of the present invention. It will be readily appreciated that various substitutions, modifications and variations can be made.

100: crushing unit 110: fixed cylinder
115: discharge network 120: rotary cylinder
130: shred tab 200: transfer unit
230: transfer means 500: separation unit
510: outer cylinder 520: inner cylinder

Claims (9)

A crushing part 100 fixedly installed at the frame 700 and crushing the pine pine nuts received by receiving the rotational force of the driving unit 300 so that the pine nuts are separated from the pine nuts; A transfer part 200 provided at a lower portion of the crushing part 100 to receive the rotational force of the driving part 300 to transfer pine by-products and pine nuts downstream from the crushing part 100; A separation unit 500 rotatably supported downstream of the crushing unit 100 and separating pine pine by-products and pine nuts while rotating by receiving pine pine by-products and pine nuts transported from the conveying unit 200; Pineapple separator, characterized in that configured to include. The pipe separating apparatus according to claim 1, wherein the shredding tabs (130) are arranged in a plurality in a sharp shape toward the radially outer side and inclined in the longitudinal direction. According to claim 1, wherein the shredding part 100 is provided with a discharge net 115 of the mesh A hollow fixing cylinder 110 fixedly supported by the frame 700 and a rotating cylinder 120 rotatably provided inside the fixing cylinder 110 and having a plurality of crushing tabs 130 protruding outward. Done; The separating part 500 is rotatably supported downstream of the crushing part 100 so that the hollow outer cylinder 510 is provided to decrease in diameter toward the rear in the longitudinal direction, and the outer cylinder 510 It is made of a hollow and mesh inner cylinder 520 which is located inside and rotates integrally with the outer cylinder 510 and increases in diameter toward the rear in the longitudinal direction; The transfer unit 200 includes a transfer unit 230 provided below the discharge network 115 of the crush unit 100, the rear portion is made to communicate with the inner cylinder 520 of the separation unit 500 Pipette Separator. According to claim 3, The outer cylinder 510 and the inner cylinder 520 is a conical shape of the front end and the rear end is open, the front end of the inner cylinder 520 is a radius from the front end of the outer cylinder 510 Located in the direction spaced apart, the front of the outer cylinder 510 is separated in the circumferential direction spaced apart in the radial direction discharge pipe 513, characterized in that formed pipe. According to claim 3, Upstream bracket 530 is installed at the front end of the outer cylinder 510 and the inner cylinder 520, downstream brackets (530) at the rear end of the outer cylinder (510) and inner cylinder (520) 540 is installed, the upstream bracket 530 is provided with a rotating shaft 590 connected to the transfer unit 200 protrudes forward, the downstream bracket 540 is a rotating shaft rotatably connected to the frame 700 Pine pipe separation device, characterized in that the 590 is protruded to the rear. The upstream bracket 530 is a ring-shaped upstream outer support 531, a disk-shaped upstream inner support 535 located radially inward of the upstream outer support 531, The upstream outer support portion 531 is composed of a plurality of upstream connecting portion 537 connected between the upstream inner support portion 531 and the upstream inner support portion 535 between the front end portion of the outer cylinder 510 and the front end portion of the inner cylinder 520. 531 is located; The downstream bracket 540 has a ring-shaped downstream outer support 541, a disk-shaped downstream inner support 545 located radially inward of the downstream outer support 541, and the downstream outer support 541. And a downstream connection part 547 connected between the downstream inner support part 545 and the downstream outer support part 541 on the rear end of the outer cylinder 510 and the rear end of the inner cylinder 520 in the radially outer side. Is located; A rotary shaft 590 connected to the transfer part 200 is provided at the upstream internal support part 535, and a rotary shaft 590 rotatably connected to the frame 700 at the downstream internal support part 545 protrudes. Pineapple separator, characterized in that provided. 7. The pipe separating apparatus according to claim 6, wherein the upstream outer support part (531) located at the front end of the inner cylinder (520) is provided with a departure preventing part (550) extending to reduce the diameter toward the front. . According to claim 6, The transfer part 200 is provided in the lower portion of the discharge net 115 in the longitudinal direction and the guide portion 210, the inner side of the guide portion 210, the front end portion driving unit 300 A rear end portion consisting of a conveying means 230 connected to the upstream inner support portion 535; The guide portion 210, the upper portion is open, the pipe cross-section is characterized in that the cross-sectional shape in the radial direction is narrower in shape toward the bottom. According to claim 8, The rear of the guide portion 210 is provided with a chute 250 inclined downward toward the inner cylinder 520, the end of the chute 250 is a front end of the inner cylinder 520 Pipe separation device, characterized in that located between the separation prevention portion and 550.

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