KR20120004734U - Cutter using multiple blades - Google Patents

Abstract

The present invention relates to a multi-blade cutter using a plurality of blades for enhancing efficiency in cutting operation and facilitating the installation and replacement of such blades.
The multi-blade cutter includes a frame, a first cartridge accommodated in the frame and having a plurality of first holders spaced apart from each other at a predetermined interval, a first cartridge accommodated in the frame and opposed to the first cartridge, A second blade having a second holder, a first blade having a plurality of teeth inserted and fixed in parallel with each other in the first holder, a plurality of second blades inserted in parallel to each other in a position opposite to the first blade, An actuator for applying an external force to at least one of the second blade, the first cartridge, and the second cartridge for cutting an object so that at least one of the first cartridge and the second cartridge is parallel to move the first blade and the second blade in sliding contact with each other .

Description

{Cutter using multiple blades}

The present invention relates to a multi-blade cutter, and it is an object of the present invention to provide a multi-blade cutter that enables efficient cutting operation using a plurality of blades, and facilitates installation and replacement of such blades.

The cutter has a cutting edge and moves the cutting edge mechanically to cut the object. However, in most cutting machines, the cutting edge is exposed to the outside as it is, and when cutting is actually performed, it is often the case that the cutting edge is adjusted by a human hand. Therefore, when using a cutter, the operator needs considerable safety precautions. These cutters typically use rotary blades or line saw blades as the cutting blades. Most of the cutting blades are made up of individual blades. In order to cut the blades into various parts, the work must be repeated, The cutting work has a problem that the work is inefficient as well as the safety problem of the worker.

Accordingly, there is a need for a cutter capable of working more safely and efficiently.

The technical task of the present invention is to improve the efficiency of cutting operation by using several blades at the same time and to design the cutter for easy installation and exchange of the blades, thereby facilitating the operator's convenience. Thereby securing the safety of the operator.

The technical problems of the present invention are not limited to the technical problems mentioned above, and other technical problems which are not mentioned can be clearly understood by those skilled in the art from the following description.

According to an aspect of the present invention, there is provided a multi-blade cutter including a frame, a first cartridge accommodated in the frame and having a plurality of first holders spaced apart from each other at a predetermined distance, A second cartridge opposed to the first cartridge, the second cartridge having a plurality of second holders on one surface thereof facing the first holder, a first blade having a plurality of the first and second blades inserted and fixed in parallel with each other, And a second blade for cutting an object and sliding the first blade and an external force applied to at least one of the first cartridge and the second cartridge, One of the first cartridge and the second cartridge is moved in parallel to move the first blade and the second blade in sliding contact with each other And an actuator.

The multi-blade cutter according to the present invention has the following effects.

First, by using multiple blades as cutting blades, efficiency is improved by reducing the number of repetitions of work.

Second, the cutting blade is composed of a cartridge and a blade coupled thereto, which facilitates installation and replacement.

Third, the intervals of the blades coupled to the cartridge can be adjusted in various ways, thereby enhancing the applicability of the work.

Fourth, the work space where the cutting work takes place is blocked from the outside, thereby enhancing the safety of the work.

Fifth, by attaching a sensor that generates a cutter control signal, it automates the cutting operation and at the same time prevents one safety accident.

Sixth, not only the cutting operation itself but also the process before and after the cutting operation can be automated to a certain level.

1 is a perspective view of a multi-blade cutter according to a first embodiment of the present invention.
FIG. 2 is a perspective view showing a state where a first blade and a second blade included in the multi-blade cutter of FIG. 1 are combined.
3 is a plan view of the first blade and the second blade.
4 is an exploded perspective view showing a state in which the first and second cartridges, the first blade and the second blade are coupled.
5A to 5C are front views showing a state where the blade is engaged with the cartridge.
6A and 6B are operation diagrams for explaining the operation of the multi-blade cutter of FIG.
7A and 7B are operation diagrams for explaining the operation of the multi-blade cutter according to the second embodiment of the present invention.
8 is a perspective view of a multi-blade cutter according to a third embodiment of the present invention.
9A and 9B are front views showing a blade according to a modified embodiment of the blade of the multi-blade cutter of FIG.
10 is a plan view showing the operation of the multi-blade cutter of FIG.

BRIEF DESCRIPTION OF THE DRAWINGS The advantages and features of the present invention, and how to accomplish them, will become apparent with reference to the embodiments described in detail below with reference to the accompanying drawings. It should be understood, however, that the present invention is not limited to the embodiments disclosed herein but may be embodied in many different forms and should not be construed as limited to the embodiments set forth herein, To the person having the invention, and this invention is only defined by the scope of the claims. Like reference numerals refer to like elements throughout the specification.

Hereinafter, a multi-blade cutter according to an embodiment of the present invention will be described in detail with reference to FIGS. 1 to 5. FIG.

FIG. 1 is a perspective view of a multi-blade cutter according to an embodiment of the present invention, FIG. 2 is a perspective view showing a state where a first blade and a second blade included in the multi- 4 is an exploded perspective view showing a state where the first and second cartridges, the first and second blades are coupled to each other, and Fig. 5 is an exploded perspective view showing a state where the blade is engaged with the cartridge 6A and 6B are operation diagrams for explaining the operation of the multi-blade cutter of FIG. 1. FIG.

A multi-blade cutter 1 according to an embodiment of the present invention includes a plurality of first blades 110 and a second blade 120, a first blade 110 and a second blade 120, An actuator 400 that provides an external force to the first cartridge 210 or the second cartridge 220 inside the frame 300, a frame 300 that receives the cartridge 210 and the second cartridge 220, And a housing 500 and a discharging conveyor belt 600 for accommodating the actuator 300 and the actuator 400 therein.

A plurality of first and second blades 110 and 120 are formed and each pair of the first and second blades 110 and 120 is configured as a set for sliding and cutting operations .

The first blade 110 and the second blade 120 are in sliding contact with each other and cut an object. The surface of the first blade 110 contacting the direct object and cutting the object (hereinafter referred to as the blade surface) faces the blade surface of the second blade 120 on the opposite side. In the cutting process, the two blades are overlapped while moving in parallel to each other. At this time, the blade surface of the first blade 110 intersects with the blade surface of the second blade 120, The object to be located is cut. The sliding contact means that the two blade blades are in sliding contact with each other while being parallel to each other so as to be in contact with each other. In this case, instead of one blade, the two blades apply pressure to the object in opposite directions, It is possible to cut the object finely and stably by effecting the same effect as that of the intersection of the upper and lower edges.

It is very important that the blade surfaces of the two blades are stably contacted with each other without the space to be separated when the two blades are used for cutting. therefore,

A pair of guide rails 111 may be formed on both sides of the first blade 110 so that the first blade 110 and the second blade intersect in parallel to each other and have no gap on the intersecting surface.

2, the second blade 120 is inserted or coupled between a pair of guide rails 111 through which the first blade 110 and the second blade 120 stably and parallelly move .

In addition, a bumper 114 may be formed on at least one of the first blade 110 and the second blade 120 to provide a certain amount of force toward the blade surface. The bumper 114 is in contact with an object and pushes the object toward the blade surface to align it. It is possible to connect the elastic member to the rear of the portion contacting the object or to form the entire bumper 114 as an elastic member .

Referring to FIGS. 6A and 6B, it can be seen that the object is aligned toward the blade surface by the bumper 114. At least one bumper 114 is provided for each pair of the first blade 110 and the second blade 120 to push each part of the object toward the blade surface. The bumper 114 directly contacts the object and stably positions the object between the first blade 110 and the second blade 120. The bumper 114 moves due to inertia when the blade is moved in parallel It fixes the object which is opposite to the edge of the blade and makes the cutting process stable until the end.

The first blade 110 and the second blade 120 that intersect with each other and cut the object are formed in a rectangular plate shape having a constant thickness.

Referring to FIG. 3, the first blade 110 and the second blade 120 have a blade surface formed at one end of a rectangular plate-like shape. The blade surface is directly contacted with various kinds of objects during the cutting operation and is also in contact with the blade surface of the opposite blade, so that the sharpened surface is liable to be worn.

Therefore, it is preferable that the first blade 110 and the second blade 120 including the blade surface are formed of a corrosion-resistant and wear-resistant material such as a stainless steel alloy forged cast.

Also, the shape of the blade surface may be formed inwardly of the blade so that the central part of the blade surfaces of the first blade 110 and the second blade 120 has a circular or semicircular curved shape. Since the blade surface has this shape, the cutting operation can be performed after inserting the object through the space in the center without completely separating the two blades. In the cutting process, the two curved blade surfaces intersecting each other are parallel to the blade At each point where the intersection between the blade surfaces is caused by the movement, they are staggered to form the intersecting surfaces of the same shape as the intersection of the upper and lower sides continuously. In other words, the blade applies force from both sides of the object, and it has the effect of cutting off the surface of the object like scissors along the intersecting plane of the two blades.

Therefore, more detailed and stable cutting operation is possible by using the formed blade surface formed by curving the center portion. In addition, since the pair of blades that are not completely separated at the time of cutting can move in parallel with the second blade 120 being continuously inserted into the guide rail 111 formed at the first blade 110, The effect of the guide rail 111 can be maximized and the cutting operation can be performed stably.

However, according to circumstances, the first blade 110 and the second blade 120 may be formed so as to completely separate from each other and then cross each other again. It is also necessary to form the blade surface in a straight line, a slanting line, or other irregular shape It is possible.

Referring to FIG. 4, a plurality of coupling holes a and 112 are formed at opposite ends of the first blade 110 or the second blade 120, which are formed with blade surfaces. These engaging holes are formed in the first cartridge 210 and the second cartridge 220 when the first blade 110 or the second blade 120 is inserted into the first cartridge 210 or the second cartridge 220 And has a role of fixing each blade to the cartridge by using a coupling screw 230 which is aligned at the same position as the coupling bores 212 and 221 and coupled through the coupling holes 112 and 121 and the coupling holes b and 221 .

On both sides of the first blade 110, a number of rail coupling holes 113 are formed in accordance with the direction of movement of the blade. The above-described guide rail 111 is attached to the rail coupling hole 113 through screw connection, pin coupling, rivet coupling, or the like. The guide rails 111 are positioned on the outer side of both sides of the second blade 120 to guide the movement of the second blade 120 so that the first blade 110 is guided by the second And may be formed by further extending both sides than the blade 120.

The first cartridge 210 has a plurality of first holders 211 formed on one side thereof and the second cartridge 220 is also formed with a plurality of holders on one side thereof such that the first cartridge 210 and the second cartridge 220 The first holder 211 and the second holder 222 are disposed opposite to each other so as to face each other. The first cartridge 210 and the second cartridge 220 are not limited to each other in shape but refer to one side or the other of the two cartridges disposed facing each other with the respective holder formed thereon. The cartridge to which the second blade 120 is coupled is used as the second cartridge 220 while the holder formed in the first cartridge 210 is used as the first holder 211, 2 cartridge 220 is referred to as a second holder 222. [

The first holder 211 or the second holder 222 is formed in parallel on one surface of the first cartridge 210 or the second cartridge 220 with grooves having a distance corresponding to the thickness of the blade, One groove, that is, one holder, can accommodate one blade. In addition, since a plurality of holders are continuously formed in each of the cartridges, one of the holders can be selected and coupled to any one of the holders.

That is, the blade can adjust the coupling position with the cartridge by selecting the position of the holder, through which the first cartridge 210 and the second cartridge 210 are arranged so that the first holder 211 and the second holder 222 face each other, It is possible to form a blade pair of the first blade 110 and the second blade 120 at any position of the second cartridge 220.

5A to 5C, it is possible to change the number and position of the first cartridge 210 and the second cartridge 220 facing each other to form a plurality of pairs of the first blades 110 and the second blades 120 It is possible. This is accomplished by simply selecting the positions of the first holder 211 and the second holder 222 and by later changing the position again to form a plurality of blade pairs, the number and spacing of the blade pairs can be adjusted You can make changes to the method.

The plurality of blade pairs coupled to the respective cartridges are connected to a plurality of engaging holes b and 212 formed through all the holders of the cartridge and a plurality of engaging screws 230 engaging with the engaging holes b and 221, .

The engaging holes 212 and 221 are formed to penetrate through all the holders of the cartridge in a direction perpendicular to the longitudinal direction of the holder formed parallel to each other and completely overlap the engaging holes 112 and 121 of the respective blades inserted into the cartridge . Therefore, the engaging screw 230 can simultaneously pass through the engaging holes b and 212 and the engaging holes a and 112, which are overlapped with each other at the time of engaging and are engaged with the cartridge through the engaging holes b and 221, And the blade are fixed to each other. The blades and cartridges can be easily disassembled and assembled as the coupling screws are combined or disassembled.

The frame 300 serves as an orbit for receiving and fixing the first cartridge 210 and the second cartridge 220 or for moving either of them.

The frame 300 is formed in a rectangular parallelepiped shape and accommodates the first cartridge 210 and the second cartridge 220 on one surface and the other surface facing each other. The first cartridge 210 and the second cartridge are arranged such that the first holder 211 and the second holder 222 are horizontally aligned and opposed to each other. At least one of the first cartridge 210 and the second cartridge 220 moves parallel to the frame of the frame 300 and the first blade 110 or the second blade 120 installed on the moving cart And slides with the second blade 120 or the first blade 110 to cut the object. The cartridges other than the parallel moving cartridges are fixed to one surface of the frame 300. Fixation can be accomplished by screw-fastening pins, riveting or welding.

The upper surface of the frame 300 is an upper surface of the frame 300 that is inserted into the frame 300 and positioned between the two blade surfaces, And the lower surface of the frame 300 becomes the discharge port 320 through which the charged object is cut and discharged to the outside of the frame 300. The injection port 310 and the discharge port 320 are spaces formed by the skeleton of the frame 300.

At this time, the discharge port 320 can be formed by adding an opening / closing device for opening or closing the discharge port 320. The opening / closing device includes a pneumatic cylinder 321, a sliding door, and a connection part for transmitting the pressure generated by the pneumatic cylinder 321 to the sliding door (322).

The actuator 400 applies an external force to at least one of the first cartridge 210 and the second cartridge 220 to move at least one of the first cartridge 210 and the second cartridge 220 in parallel within the frame 300 .

The actuator 400 may be formed to include a hydraulic cylinder. One end of the hydraulic cylinder is coupled to the outer wall of the cartridge, that is, the rear surface of the holder-formed surface of the cartridge. The hydraulic cylinder is contracted or elongated through a piston action to move the cartridge coupled to the one end of the hydraulic cylinder to the left and right so that the blade provided on the cartridge moving in parallel to the left and right slides with the blade provided on the opposite side to cut the object .

Since the first blade 110 and the second blade 120 slide and cross each other to cut an object, the first blade 110 and the second blade 120 move only one of them to cut the object, It is possible to cut the object by moving it. The actuator 400 may be connected to either the first cartridge 210 or the second cartridge 220 or may be connected to both the first cartridge 210 and the second cartridge 220 . The hydraulic unit 410 provides a constant pressure to the hydraulic cylinder through a pump action or the like.

The first sensing sensor 311 and the second sensing sensor 312 are formed on one side of the frame 300 where the charging port 310 is formed and on the other side where the discharging port 320 is formed to sense an object and generate a sensing signal. Each of the generated sensed signals is transmitted to the actuator 400 and the opening and closing device of the outlet 320 and functions as an operation signal for controlling them.

6A and 6B, a sensing signal is generated by the first sensing sensor 311 while an object is once inserted. The cutting operation should not be performed until the object completely passes through the input port 310 and enters the inside of the frame 300. Therefore, when only the detection signal of the first detection sensor 311 is generated, the actuator 400 does not operate.

When the object completely passes through the input port 310 and reaches the discharge port 320, the detection signal of the first detection sensor 311 disappears and a detection signal of the second detection sensor 312 is newly generated.

In this case, since the object is completely located inside the frame 300, the actuator 400 receives the sensing signal of the second sensing sensor 312 and operates, and the cutting operation is performed inside the frame 300. At the same time, the sensing signal of the second sensing sensor 312 is also transmitted to the opening / closing device of the discharging port 320 to operate the discharging port 320, and the discharging port 320 is opened.

When the cutting operation is completed and the object is discharged out of the frame 300 through the discharge port 320, the detection signal of the second detection sensor 312 disappears. At this time, the actuator 400 returns to the standby state after finishing the cutting operation, and the opening / closing device of the discharge port 320 is operated again, so that the discharge port 320 is closed. Here, the standby state refers to a state in which the hydraulic cylinder fully contracts and the gap between the first cartridge 210 and the second cartridge 220 is maximized.

The first sensing sensor 311 and the second sensing sensor 312 are formed on the inlet 310 and the outlet 320 so that the sensor 400 and the outlet 320 ) To operate the multi-blade cutter (1) automatically.

In addition, the sensor is used to automate the operation of the cutter, and is also used as a safety sensor to prevent accidents.

When the detection signal is generated only by the first sensor 311, the cutter does not operate as described above. Therefore, even if a part of the person's body accidentally enters the input port 310, the cutter does not operate. In addition, when a detection signal is generated in both the input port 310 and the ejection port 320, it is considered that a certain object is escaping from the input port 310 through the inside of the frame 300, At this time, it is also possible to prevent the accident by preventing the actuator 400 from operating, thereby making it possible to create a safer working environment.

A discharge conveyor belt 600 is formed below the discharge port 320. All the objects discharged out of the frame 300 through the discharge port 320 reach the discharging conveyor belt 600 and are moved to another point through the conveyor belt. The discharging conveyor belt 600 can be formed by connecting one or more of them to each other depending on the position of the moving point.

The housing 500 is formed by including therein the main components of the multi-blade cutter 1 including the frame 300, the hydraulic unit 410, and the actuator 400. [ The housing 500 protects the inside of the housing 500 from the external environment, and protects the inside of the frame 300 from the inside by isolating the inside of the frame 300 where the cutting operation takes place. The housing 500 can be formed in various forms to secure a space in which the frame 300, the actuator 400, the oil pressure unit 410, and the like can be installed. The housing 500 may be formed with or without a portion of the discharging conveyor belt 600.

Hereinafter, a multi-blade cutter according to a second embodiment of the present invention will be described in detail with reference to FIGS. 7A and 7B.

FIGS. 7A and 7B are operation diagrams for explaining the operation of the multi-blade cutter according to the second embodiment of the present invention

The multi-blade cutter 1 according to the second embodiment of the present invention is formed such that the actuator 400 further includes a crank shaft 430 and a connecting rod 440.

Referring to FIGS. 7A and 7B, the crankshaft 430 switches the rotational force of the operation motor 420 to a horizontal force and transmits the rotational force to the cartridge, so that the pair of blades slidably contact each other to cut the object.

The crank shaft 430 is formed by forming different rotational axes on one side and the other side of the mass body having a predetermined size. One of the two rotary shafts may be formed so as to be located at the center of mass of the mass.

One rotation axis of the crankshaft 430 is connected to the operation motor 420 through the belt 421. [ The rotational force generated by the motor is transmitted to one rotation shaft of the crank shaft 430 through the belt 421 to rotate the entire crank shaft 430 around the rotational axis connected to the belt 421. At this time, the other rotary shaft not connected to the belt 421 rotates about the rotary shaft connected to the belt 421.

The connecting rod 440 is a linear rod, one end of which is connected to a rotary shaft to which the belt 421 is not connected, and the other end is connected to one surface of the cartridge.

When the crankshaft 430 rotates, one end of the connecting rod 440 connected to the crankshaft 430 rotates along a virtual circumferential surface of a predetermined size, and the connecting rod 440 is rotated by a distance corresponding to the diameter of the circumferential surface Whereby the other end of the connecting rod 440 connected to the cartridge is horizontally moved left or right together with the cartridge, and the blade coupled to the cartridge slides on the opposite blade and cuts the object.

By mechanically transmitting the force using the crank shaft 430 and the connecting rod 440, the number of reciprocations of the connecting rod 440 can be easily increased by adjusting the speed of the operation motor 420, It becomes possible to carry out the work.

However, due to the characteristics of the operation motor 420, it is relatively difficult to precisely control the blade than to apply an external force to the cartridge through the pressure type cylinder. Therefore, the type of the object to be cut and the type The cutter can be configured to suit the operator's convenience.

Hereinafter, a multi-blade cutter according to a third embodiment of the present invention will be described in detail with reference to FIGS. 8 and 10. FIG.

FIG. 8 is a perspective view of a multi-blade cutter according to a third embodiment of the present invention, FIGS. 9A and 9B are front views showing an operation process according to a modified embodiment of the blade of the multi- FIG. 4 is a plan view showing the operation of the multi-blade cutter of FIG.

The multi-blade cutter according to the third embodiment of the present invention further includes a plurality of distributors each having an inlet disposed between the second blades and an outlet formed at an opposite side of the inlet to be separated from each other and inclined downward from the inlet to the outlet, The first blade and the second blade are formed in parallel in the vertical direction.

Referring to FIG. 8, the first blade 110 and the second blade 120 are formed such that the sliding surfaces thereof are perpendicular to each other. The first cartridge 210 and the second cartridge 220 are horizontally arranged up and down with the first and second holders 211 and 222 facing each other and the actuator 400 is also vertically To transmit an external force to the first cartridge 210 or the second cartridge 220 to move at least one of the first cartridge 210 and the second cartridge 220 in a vertical direction.

The feeding conveyor belt 700 has one end facing the frame 300 and the other end lying on the opposite side to move the object from the other end to one end facing the frame 300. The object reaching the frame 300 through the putting conveyor belt 700 is separated from the conveyor belt and dropped into the frame 300 and is separated into a first blade 110 and a second blade 110 which are arranged in parallel in the vertical direction inside the frame 300 And is temporarily positioned between the blade surfaces of the second blade 120.

At this time, in order for the object to reach the space between the blade surfaces, the first blade 110 and the second blade 120 should be formed to be completely separated vertically. However, referring to FIGS. 9A and 9B, the first blade 110 and the second blade 120 are formed such that the blade surfaces are asymmetric, but only the surfaces facing the conveyor belt can be completely separated, It is also possible to cut the object by placing the object between the respective blade surfaces.

A plurality of distributors 800 are formed facing the one side of the frame 300. Each distributor 800 is formed in accordance with the horizontal interval between the blades arranged in parallel on the cartridge and has the same number of intervals as the blade and the blade form A number distributor 800 is disposed adjacent to each other.

The dispenser 800 is positioned opposite the conveyor belt with the frame 300 therebetween and the inlet of the dispenser 800 faces between the second blades 120 and the outlet is formed on the opposite side, Is formed at a low point and has a downward inclination at an angle from the inlet to the outlet.

The object cut between the first blade 110 and the second blade 120 falls and reaches the entrance of the distributor 800. To this end, the distributor 800 includes a first blade 110 and a second blade 120 The entrance may be formed at a point lower than the intersection point of the blade surface of the object, that is, the point where the object is actually cut.

The outlet of the distributor 800 is formed at a point lower than the inlet, and an object reaching the inlet slides through an inclined surface formed by the inlet and the outlet and is accelerated and discharged to the outlet.

10, an object reaches a frame 300 through an inputting conveyor belt 700 and is cut inside the frame 300, and a portion of each cut object is cut through the distributor 800 in different directions As shown in FIG. To this end, the outlets of the distributor 800 may be spaced apart from each other.

While the embodiments of the present invention have been described herein with reference to the accompanying drawings, those skilled in the art will appreciate that the present invention can be practiced in other specific forms without departing from the spirit or essential characteristics thereof You will understand. It is therefore to be understood that the above-described embodiments are illustrative in all aspects and not restrictive.

1: multiple blade cutter 110: first blade
111: guide rail 112, 121: engaging hole
113: rail coupling hole 114: bumper
120: second blade 210: first cartridge
211: first holder 212, 221: engaging hole b
220: second cartridge 222: second holder
230: coupling screw 300: frame
310: input port 311, 312: detection sensor
320: Outlet port 321: Pneumatic cylinder
322: connection part 400: actuator
410: Hydraulic unit 420: Operation motor
421: Belt 430: Crankshaft
440: connecting rod 500: housing
600: conveying belt for discharging 700: conveying belt for putting
800: Dispenser

Claims (9)

frame;
A first cartridge accommodated in the frame and having a plurality of first holders spaced apart from each other at a predetermined interval;
A second cartridge accommodated in the frame and opposed to the first cartridge and having a plurality of second holders on one surface facing the first holder;
A first blade in which a plurality of pieces are inserted and fixed in parallel with each other in the first holder;
A second blade that is inserted in parallel to the second holder at a position facing each of the first blades and slides on the first blade and cuts the object; And
And an actuator that applies an external force to at least one of the first cartridge and the second cartridge to move at least one of the first cartridge and the second cartridge in parallel to bring the first blade and the second blade in sliding contact with each other, Me cutter. The method according to claim 1,
And a pair of guide rails formed on both sides of the first blade to guide sliding movement of the second blade. The method according to claim 1,
Wherein the first blade and the second blade are concavely curved or have a beveled shape. The method according to claim 1,
Further comprising a bumper formed on at least one of the first blade and the second blade to provide an elastic force toward the blade surface. The method according to claim 1,
Wherein the actuator further comprises a hydraulic cylinder, a pneumatic cylinder, or a crankshaft and a connecting rod. The method according to claim 1,
An inlet and an outlet formed on one side and the other side of the frame, respectively;
A sensing sensor formed on the inlet and the outlet for sensing an object and generating a sensing signal;
Wherein the actuator is actuated or stopped according to the sense signal. The method according to claim 6,
Wherein the discharge port is opened or closed in response to the detection signal or the operation and stop of the actuator. The method according to claim 6,
And a conveyor belt extending from the outlet to move the object from the outlet to another point. The method according to claim 1,
A conveyor belt conveying an object to place the object between the first blade and the second blade;
Further comprising a plurality of distributors each having an inlet disposed between the second blades and having an outlet separated from one another on the opposite side of the inlet so as to be inclined downwardly from the inlet to the outlet,
Wherein the first blade and the second blade are arranged in parallel in a vertical direction.

Images