KR101142817B1 - Ultra-fast horizontal cutting device using circular saw blade - Google Patents

Abstract

The present invention relates to a horizontal cutting device for cutting an elongated metal material made of a circle, polygon, etc. to a certain length within a short time, and automatically cuts at a high speed by simply loading the elongated material on a heavy chain. It allows labeling and then unloading.

To this end, the lower frame (2), the upper frame (4), the loading unit 10, the side clamping unit 20, the material cutting unit 30, the material cutting length control unit 50, the cutting material conveying unit 60, In the ultra-fast horizontal cutting device consisting of a loading unit 70, the material cutting unit 30 and a pair of linear motion rail 31 is installed on the upper portion of the lower frame (2) orthogonal to the conveying direction of the material (5) , A sliding bed 32 mounted on the linear motion rail and moving, an electric motor 34 fixed to the sliding bed by the dustproof means 33 and generating power, an output shaft and a belt of the electric motor ( 35) connected to the reducer 36 to reduce the rotational speed of the electric motor, a circular saw blade 37 is fixed to the output shaft of the reducer while cutting at high speed while cutting the material, and installed in the reducer of the circular saw blade Wrap the saw blade guide 38 and the circular saw blade to prevent shaking during rotation And a brushing means 39 installed on the lower frame 2 so as to remove chips fused at this end of the circular saw blade 37 when cutting the raw material 5 and at one side of the saw blade guide. Cooling means 40 to cool the blowing air to cool the frictional heat, and the lower surface of the lower frame (2) is installed to be rotatable so that the drive of the servomotor 41 is reduced by another reducer 42 and rotates. One end is characterized by consisting of a ball screw 43 screwed to the sliding bed (32).

High speed cutting of material, variable cutting speed, variable speed of circular saw blade, labeling

Description

Ultra-fast horizontal cutting device using circular saw blades {omitted}

The present invention relates to a horizontal cutting device for cutting an elongated metal material made of a circle, a polygon, etc. to a certain length within a short time, and more specifically, simply by automatically loading the elongated material of the heavy chain into the loading unit. The present invention relates to an ultrafast horizontal cutting device using a circular saw blade which automatically cuts and labels and then unloads at an extremely high speed.

In general, a band saw, circular, and oxygen cutting are mainly used as a device for cutting a metal material having a circular or polygonal shape (square, pentagon, hexagon, etc.). Although there is an advantage that the cutting of the material is possible, it takes a long time according to the cutting of the material, which lowers the productivity. Therefore, when a large amount of the cut material is required, several band saws must be purchased and installed. As a result, the space occupancy is increased, and a large number of expensive workers are required according to the operation of the equipment.

On the other hand, Circula is capable of high-speed cutting of materials, so it is possible to supply a large amount of materials quickly, but only cutting of materials with small outer diameters is impossible, so it is impossible to cut materials with large outer diameters. Not suitable for forging line.

On the other hand, oxygen cutting is possible to cut not only the material having a small outer diameter but also the material having a large outer diameter, but not only takes a long time according to the cutting, but also the loss of the cutting material (Loss) is uneconomical.

In addition, since the cut part hardens due to a phase change in the cooling process, many limitations are involved in the secondary processing. In particular, when the secondary processing is forging, the probability of defects increases considerably, which increases the cost of production. .

The present invention has been made to solve such a conventional problem, simply by loading a large material with a large outer diameter in the loading unit to reduce the loss by cutting the material to the ultra-high speed to the exact dimensions and then control number according to the type of material By automatically labeling and unloading to the unloading unit, the purpose is to prevent the defects due to the secondary work of the material in advance and to maximize the work efficiency according to the cutting of the material.

According to an aspect of the present invention for achieving the above object, in the ultra-fast horizontal cutting device consisting of a lower frame, an upper frame, a loading part, a side clamping part, a material cutting unit, a material cutting length control unit, a cutting material conveying unit, an unloading unit, The material cutting part is a pair of linear motion rails installed on the upper part of the lower frame orthogonal to the conveying direction of the material, a sliding bed mounted on the linear motion rails, and fixed to the sliding bed by dustproof means to generate power. An electric motor to be connected to the output shaft of the electric motor and a belt to reduce the rotation speed of the electric motor, a circular saw blade fixed to the output shaft of the reducer to rotate at high speed, and cutting the material. Saw blade guide is installed to prevent shaking during rotation of the circular saw blade, the lower portion to surround the circular saw blade Brush means for removing the chip fused to this end of the circular saw blade when cutting the material, and cooling means for cooling the frictional heat by blowing cold air when cutting the material, the lower frame The high speed horizontal cutting device using a circular saw blade is provided so that the rotation of the servo motor is slowed down by another reducer, and the ball screw is screwed to the sliding bed. .

The present invention has several advantages as compared to the conventional cutting machine and cutting method.

First, by using one cutting machine, it is possible to quickly cut not only small-diameter material but also large-diameter material within a short time, so that efficiency can be more than 10 times compared to the conventional cutting method, thereby minimizing the space occupancy of the factory. Of course, there is no need to operate multiple pieces of equipment, thereby reducing expensive labor costs.

Second, since the material can be cut to the correct length, the loss caused by the secondary processing of the material is minimized.

Third, the labeling of the cut material is managed, thereby reducing work efficiency due to poor management of the material, as well as significantly reducing the material loss.

Hereinafter, the present invention will be described in more detail with reference to FIGS. 1 to 17.

Figure 1 is a front view showing the configuration of the present invention, Figure 2 is a plan view of Figure 1 and Figure 3 is a left side view of Figure 1, the present invention is a lower frame (2) installed on the floor surface (1) of the building, and A diverter in which an upper frame 4 installed as a support 3 on a lower frame and a material 5 to be cut and installed on one side of the lower frame are positioned in a loading position 12. The loading unit 10 for transferring it to the transfer position 13 as it is mounted on the (11), and is installed in-line (in-line) to the loading unit is conveyed by a predetermined length by the loading unit (5) Side clamping portion 20 for clamping the side of the clamp) and the material cutting portion 30 is installed orthogonal to the side clamping portion to the high-speed cutting the material while being transferred to the material side as the material is clamped by the side clamping portion (30) And, the material is installed on the opposite side of the material cutout Material cutting length control unit 50 for adjusting the cutting length, a cutting material transfer unit 60 for transferring the cut material (5a) is installed so as to be movable directly below the material cutting length control unit, and the cutting material transfer unit As the material is transferred by the unloading unit (70) for unloading (unloading) it is characterized in that consisting of.

4 is a front view showing a loading unit in the present invention, FIG. 5 is a plan view of FIG. 4 and FIG. 6 is a left side view of FIG. 4, wherein the loading unit 10 has a loading position 12 provided in the lower frame 2 and At least two sliders (14) are provided between the lower frame (2) and the sliders (14), and the sliders (14) are installed to move the sliders left and right. A moving cylinder 15, a diverter 11 mounted on the upper and upper sides of each slider, and having a long material 5 mounted thereon, and installed between the slider and the diverter. As the sensor (not shown) senses that the material 5 is placed on the diverter, the elevating cylinder 16 which raises and lowers the diverter and the transfer position 13 interfere with the slider 14. A large number of materials 5 are installed by shifting the diverter 11 so as not to be generated, As the sensor (not shown) detects the mounting and drives the motor 17, the driving roller 18 transfers the motor 17 to the side clamping part.

At this time, when the power base 19 consisting of a rack and pinion is mounted on the slider 14 and the diverter 11, the load of the diverter 11 due to the driving of the elevating cylinder 16 increases and decreases. The diverter 11 on which the material 5 of the heavy body is placed is more preferable because it prevents the phenomenon of falling and falling.

On the other hand, although the roller installed at the rear end of the lower frame 2 (left side in the drawing) may be a driving roller driven by the motor 17, it only serves to guide the transfer of the raw material 5, so that one of the present invention In the example, a non-driven roller was applied.

7 is a cross-sectional view taken along the line A-A of Figure 5 showing the side clamping portion in the present invention, the side clamping portion 20 is a non-driven roller 21 is installed rotatably at the end of the loading portion 10, and Drive roller 23 is installed at the tip of the non-drive roller to change the feed speed of the material 5 as the rotation speed of the motor 22 is changed by the inverter, and is installed on both sides of the drive roller to transfer the material Completion is composed of a clamper 24 for clamping the side of the material and the clamping cylinder 25 for conveying the clamper to the left and right.

The plurality of driving rollers 23 are connected to each other by a chain 26 to be rotated at the same time as the motor 22 is driven. The two clamping cylinders 25 are controlled by a tuning valve (not shown). It is operated at the same speed to clamp the center of the material 5.

On the other hand, as shown in Figure 9 is further provided with an upper clamper 27 for clamping the upper surface of the material (5) on the upper side of the side clamping portion 20 is a natural phenomenon that the material moves during high-speed cutting of the material (5) Since it becomes possible to block | block, it is more preferable.

8 is a cross-sectional view taken along the line B-B of Figure 2 showing the raw material cut in the present invention, Figure 9 is a left side view of Figure 8 and Figure 10 is a plan view of Figure 9, the material cut portion 30 of the lower frame (2) A pair of linear motion rails 31 installed at right angles to the conveying direction of the raw material 5, a sliding bed 32 mounted on the linear motion rails and moving, and dustproof means 33 in the sliding bed. It is fixed to the electric motor 34 for generating power, connected to the output shaft of the electric motor and the belt 35, a reducer 36 to reduce the rotational speed of the electric motor, and fixed to the output shaft of the reducer Circular saw blade 37 for cutting the material while rotating at high speed, the saw blade guide 38 is installed in the reducer to prevent shaking during rotation of the circular saw blade, and is installed in the lower frame (2) to surround the circular saw blade Teeth of circular saw blade 37 when cutting material 5 Brushing means (39) for removing the chip fused to, the cooling means (40) installed on one side of the saw blade guide blows cool air (air) when cutting the material to cool the frictional heat, and the lower frame (2) It is installed on the bottom of the () is rotatable, the drive of the servo motor 41 is reduced by another reducer 42 is rotated and consists of a ball screw 43 one end screwed to the sliding bed (32). .

At this time, the sliding bed 32 is coupled to the linear motion rail 31 so as to be able to move smoothly by the L-bearing (not shown) and circular saw blade 37 in the front, rear direction of the sliding bed (32) The cover 44 is formed to be foldable so that the chip generated in the process of cutting the material 5 at high speed can be prevented from flowing into the material cutting part 30.

On the other hand, when the oil film is formed on both sides of the circular saw blade 37 at the time of cutting the material 5 by supplying mist oil through the saw blade guide 38, the friction part with the material 5 Since it slides well in the has the advantage of being able to extend the life of the circular saw blade 37.

11 is a front view showing a material cutting length control unit in the present invention, Figure 12 is a plan view of Figure 11 and Figure 13 is a left side view of Figure 11, the material cutting length control section 50 is the same as the conveying direction of the material (5) A locator frame 51 installed along a direction, a slider 53 provided to be movable along a pair of LM guides 52 provided on an upper portion of the locator frame, and a rotary actuator rotatably installed on an upper portion of the slider. 54), the deceleration limit switch 56 and the stop limit switch 57 installed on the support 55 fixed to the rotary actuator, and the locator frame 51 are rotatably installed, and serve another servomotor 58. It consists of another ball screw 59 which is rotated by) and screwed to the slider 53.

The rotary actuator 54 is rotatably installed by the support 55 provided with the deceleration limit switch 56 and the stop limit switch 57. The material 5a cut by the cutting material transfer unit 60 is rotated. In the process of transferring to the unloading unit 70 is to prevent the interference by the support 55 in advance.

At this time, when a plurality of covers 45 are foldably installed on both sides of the slider 53 which are movably installed in the LM guide 52, chips generated when cutting the material 5 may be formed. It is possible to prevent the phenomenon flowing into the material cutting length control unit 50 in advance.

14 is a front view showing the cutting material transfer unit and the unloading unit in the present invention, Figure 15 is a plan view of Figure 14 and Figure 16 is a right side view of Figure 14, the cutting material transfer unit 60 is a material cutting length control unit 50 and Bogie that moves horizontally as the travel roller 63 rotates with the driving of the motor 62 while the raw material 5a cut and installed on the upper surface of the moving rail frame 61 in the section between the unloading parts 70 ( 64, the unloading part 70 is installed at the stop position of the trolley 64, which is the cutting material conveying part 60, and pushers 71 for pushing the conveyed material, and a pushing cylinder for driving the pusher. 72 and the inclined pile up base 73 provided in the direction opposite to the installation direction of the said pusher 71. As shown in FIG.

At this time, the round bar holder (73a) and the square material (5a) of the cross-section is smoothly rolled so that the material (5a) having a circular cross section is rolled along the inclined portion by its own weight. If a plurality of rollers are installed so that the rectangular loading stand 73b is installed, and the pusher 71 is installed to extend to each loading stand, it is possible to quickly change the loading stand 73 according to the cross section of the cutting material 5a. It is possible to unload the material 5a.

FIG. 17 is a front view showing the labeling unit in cross section in the present invention, wherein the labeling unit markings a management number according to the type of the material 5a cut between the material cutting length control unit 50 and the unloading unit 70 ( It is more preferable to further include 80) because it is possible to more efficiently manage the cut material (5a) to prevent defects due to incorrect use of the material in advance.

In an embodiment of the present invention, the labeling unit 80 is provided with information on the frame 81 installed at the rear end of the material cutting length control unit 50 and the material 5a installed and cut inside the frame. A bar coder printing unit 82 for printing with a bar coder, a stamper 83 installed at one side of the bar coder printing unit, and attaching a printed bar code to the cut surface of the material 5a, and lifting and lowering the stamper. The lifting cylinder 85 to be inputted, and the information of the material to be cut is input and controlled to configure the bar code printing unit 82 and the controller 84 for driving the lifting cylinder 85.

In this case, since the structures of the bar coder printing unit 82 and the stamper 83 are well known structures, detailed illustration and description thereof will be omitted.

Hereinafter, the operation of the present invention will be described.

First, the slider 14 installed in the loading section 10 is located in the loading position 12, while the diverter 11 is located at the bottom dead center, and the clamper 24 of the side clamping section 20 is The open state is maintained, and the clamper 27 of the upper clamping part is located at the top dead center.

In addition, the sliding bed 32 of the material cutting unit 30 is located at a point as far as possible from the side clamping unit 20, and the material cutting length control unit 50 is a slider 53 according to the length of the material 5 to be cut. Is positioned and the support 55 on which the deceleration limit switch 56 and the stop limit switch 57 are installed by the rotary actuator 54 is erected in a vertical state.

In this state, the sensor (not shown) senses that the material 5 of the weight is placed on the upper surface of the diverter 11 located at the bottom dead center of the loading position 12 by the material supply means (crane, etc.). The lifting cylinder 16 operates to raise the diverter 11 to the top dead center.

At this time, the bottom surface of the material 5 placed on the diverter 11 is a point higher than the top surface of the drive roller 18.

As such, after the diverter 11 on which the material 5 is placed by the elevating cylinder 16 rises to the top dead center, the elevating cylinder 16 is temporarily stopped and the moving cylinder 15 is operated to move the slider ( 14) is transferred to the transfer position 13, the drive rollers 18 installed in the transfer position so that the material (5) is mounted and transported are arranged to be shifted from the diverter 11 as shown in FIG. No interference occurs.

After the material 5 placed on the diverter 11 is positioned at the transfer position 13 by driving the moving cylinder 15, the driving cylinder 15 is temporarily stopped and the lifting cylinder 16 is restarted. Since the driving device lowers the diverter 11 positioned at the top dead center to the bottom dead center, the material 5 placed on the diverter 11 is placed on the driving roller 18 positioned at the transfer position 13. After reaching the bottom dead center, the diverter 11 returns to the loading position 12, which is the initial position, by re-driving the moving cylinder 15, and waits for a new material to be loaded.

In the above operation, the diverter 11 is equipped with a power base 19 consisting of a rack and a pinion on the slider 14 to prevent the tilting due to the piece load by the material 5 of the heavy body during the rise and fall. do.

By the above-described operation, the material 5 is placed on the upper surface of the driving roller 18 located at the transfer position 13 so that a sensor (not shown) detects this and then each motor installed in the driving roller 18. (17) is driven to rotate the drive roller 18 in the clockwise direction, so that the material (5) placed on the drive roller (18) is transferred to the side clamping portion (20), at which time of the material (5) The feed amount is a distance set by the material cutting length control unit 50.

That is, the slider 53 of the material cutting length controller 50 is moved by the cutting length of the material 5 input to the controller (not shown) by rotating the ball screw 59 by the servo motor 58. At the same time, the support 55 is connected to the chain 26 as the driving roller 23 of the side clamping part 20 rotates while the support 55 is rotated 90 ° clockwise in the direction of the arrow shown in FIG. When the material 5 is conveyed by the rotation of the remaining drive rollers, the deceleration limit switch 56 is operated first. Therefore, the controller transmits a signal to the controller to stop the rotation of the drive roller 18 located in the loading unit 10. The driving roller 23 of the side clamping part 20 is to reduce the rotation speed.

Thereafter, when the material 5 is further conveyed to operate the stop limit switch 57 of the material cutting length control part 50, the driving roller 23 of the side clamping part 20 is provided with a brake (shown in the motor 22). Rotation is stopped), and thus the transfer of the material 5 is completed by the length to be cut.

After the material 5 is conveyed by the length to be cut by the above operation, the slider 53 of the material cutting length control part 50 is moved to the right on the drawing by the reverse rotation of the servo motor 58, and the support table 55 ) Is returned to its original position by the rotary actuator 54 so that interference does not occur when the trolley 64 of the cutting material conveying unit 60 moves, and the clamper 24 of the side clamping unit 20 is clamped to the clamping cylinder 25. 7 is driven simultaneously in the direction of the arrow in Figure 7 to clamp the side of the material (5), at this time, if the upper surface clamper 27 for clamping the upper surface of the material (5) is further provided ) Can be clamped more stably.

After the clamper 24 of the side clamping part 20 clamps the material 5, the electric motor 34 of the material cutting part 30 for rotating the circular saw blade 37 by the controller is driven to adjust the rotational force thereof. The circular saw blade 37 rotates because the saw blade is cut to the reducer 36 through the belt 35. At this time, the gear ratio of the final reducer gear and the driven gear (not shown) of the reducer 36 is 1: 1. By maximizing the usable range of the circular saw blade 37, it is possible to cut a strong force at a high speed to a large diameter material 5 with the smallest diameter circular saw blade.

That is, in the process of rotating the circular saw blade 37 by the driving of the electric motor 34, the rotation speed of the servomotor 41 is decelerated by another reducer 42 and screwed with the sliding bed 32 ( When the 43 is rotated, the sliding bed 32 having the circular saw blade 37 installed thereon moves along the linear motion rail 31 toward the material 5 clamped by the clamper 24, and the sliding bed 32 is circular. The controller (not shown) controls the driving of the servomotor 41 to move the ball screw 43 at a high speed so that the saw blade 37 moves rapidly until the saw blade 37 approaches the material 5, but the circular saw blade ( When 37) approaches the material 5, the sliding bed 32 is moved slowly.

Furthermore, when the material 5 to be cut is circular or rectangular, the cutting load is changed according to the forward distance of the circular saw blade 37. Accordingly, the controller automatically moves the sliding bed 32 to the servo motor 41. It is to increase and decrease the rotational speed of the circular saw blade 37 to reduce the load as much as possible to maximize the life of the circular saw blade 37.

At the same time, the electric motor 34 which is the driving source of the circular saw blade 37 also uses an inverter (not shown) to accelerate or decelerate the rotational speed in response to the load according to the working position of the circular saw blade 37. In particular, to optimally adjust the rotation speed of the sliding bed 32 and the circular saw blade 37 to prevent breakage of the circular saw blade 37, which occurs a lot when the cutting of the material (5) at the end of the work is completed. do.

The vibration generated by the driving of the electric motor 34 is almost absorbed by the dustproof means 33 provided between the sliding bed 32 and the electric motor 34, but transmits the power of the electric motor 34. It is understood that vibration is absorbed to some extent by the belt 35.

In the process of cutting the material 5 by the circular saw blade () by the operation as described above, the circular saw blade 37 is installed to be wrapped by the saw blade guide 38, so the shaking does not occur when rotating the material (5) It is to prevent the phenomenon that the cutting direction of the switch is inadvertently and cool air is supplied by the cooling means 40 to cool the heat generated during cutting of the material 5, thereby preventing the surrounding pollution due to the use of cooling water or cooling oil. At the same time, the oil is formed on both sides of the circular saw blade 37 when cutting the material 5 by supplying mist oil through the saw blade guide 38 at the same time, thereby increasing the durability of the circular saw blade 37 to the maximum.

On the other hand, if the chip (chip) generated during the cutting of the material 5 is pinched at this end of the circular saw blade 37, the cutting surface of the material (5) may be poor, or in severe cases the circular saw blade 37 may be damaged, The brush of the brushing means 39 installed in the lower portion of the circular saw blade 37 rotates in a direction opposite to the rotational direction of the circular saw blade 37 to remove the chips stuck at the tip, thereby preventing this, and the sliding bed 32 The upper portion of the linear motion rail 31 is covered with a cover 44 which is divided into a plurality of pieces and is folded to prevent the phenomenon that chips generated when cutting the material 5 flow into the material cutting part 30. You can do it.

After cutting the material 5 clamped by the clamper 24 in the operation as described above in a short time by the rotation of the circular saw blade 37 according to the driving of the electric motor 34, the circular saw blade 37 is installed sliding The bed 32 is returned to the initial position shown in Figure 1 because the ball screw 43 is reversed at a high speed in accordance with the reverse drive of the servomotor 41 to wait for the next cutting of the material (5).

After the cutting of the material 5 is completed as the sliding bed 32 moves forward and backward by the driving of the servo motor 41 in the process of driving the electric motor 34 of the material cutting part 30 ( 5a) falls freely downward due to its own weight and is placed on the trolley 64 of the cutting material conveying unit 60 that is waiting at the lower portion thereof.

After the cut material 5a is placed on the trolley 64 of the cutting material transfer unit 60, the driving roller 63 is rotated by the driving of the motor 62 installed on the trolley 64, so that the moving rail frame ( The drive of the motor 62 which transfers the raw material 5a cut by the trolley | sk 64 provided in the upper surface of 61 to the labeling part 80, and drives the driving roller 63 is stopped.

When a sensor (not shown) located in the labeling unit 80 detects that the cut material 5a placed on the trolley 64 is transferred, the information input to the controller 84 of the labeling unit 80 is detected. By printing the material, cut dimensions, the job serial number, etc. of the material as a bar code by the barcode printing unit 82, the stamper 83 is attached to the cut surface of the material (5a), and thus the cut material Since management of (5a) becomes easy, defects due to misuse of the material can be prevented in advance.

After the bar code is attached to the cut surface of the material 5A in the labeling unit 80, the motor 62 for transporting the truck 64 is driven again to rotate the driving roller 63 so that the material 5a is loaded on the truck. (64) is conveyed to the unloading portion 70, if the bogie 64 is circular according to the type of the material (5a) cut from the unloading portion 70 at the point of the round bar loading rack 73a When the pusher 71 moves forward by the driving of the pushing cylinder 72 because the transfer is stopped by the detection of a sensor (not shown) at the point of the square loading rack 73b, the pusher 71 moves forward to the bogie 64. The material 5a that has been placed is automatically stacked on the loading deck 73.

As described above, the clamper as the material 5 loaded in the loading position 12 of the loading unit 10 moves to the transfer position 13 and is conveyed 1 pitch by the length set in the material cutting length control unit 50. When the 24 clamps the material 5, the cutting material is cut in a short time by the circular saw blade 37 of the material cutting part 30, and then loaded on the trolley 64 according to the type and length of the material 5 a cut. The first cycle (cycle) for labeling and then unloading on the loading deck 73 of the unloading unit 70 is described. If the material 5 is loaded in the loading unit 10, the same operation is continuously performed. It is understandable.

Although the technical spirit of the present invention has been described in detail according to the above-described preferred embodiment, it should be noted that the above-described embodiments are for the purpose of description and not of limitation.

In addition, it will be understood by those skilled in the art that various changes can be made within the scope of the technical idea of the present invention.

1 is a front view showing the configuration of the present invention

2 is a plan view of FIG. 1

3 is a left side view of FIG.

Figure 4 is a front view showing a loading portion in the present invention

5 is a plan view of FIG.

6 is a left side view of FIG.

7 is a cross-sectional view taken along the line AA of Figure 5 showing the side clamping portion in the present invention;

8 to 10 is a view showing a cutting material in the present invention,

8 is a cross-sectional view taken along the line B-B of FIG.

9 is a left side view of FIG. 8;

10 is a top view of FIG. 9

11 to 13 is a view showing a material cutting length control unit in the present invention,

11 is a front view of the material cutting length control unit

12 is a plan view of FIG.

FIG. 13 is a left side view of FIG.

Figure 14 is a front view showing the cutting material transfer portion and the unloading portion in the present invention

15 is a top view of FIG. 14.

16 is a right side view of FIG. 14;

17 is a front view showing the labeling portion in cross section in the present invention;

Explanation of symbols for the main parts of the drawings

2: lower frame 4: upper frame

5: material 10: loading part

11: diverter 12: loading position

13: transfer position 14, 53: slider

15: moving cylinder 16: lifting cylinder

17, 22, 62: motor 18, 23: drive roller

20: side clamping portion 24: clamper

30: cutting material 31: linear motion rail

32: sliding bed 34: electric motor

36, 42: reducer 37: circular saw blade

38: saw blade guide 39: brushing means

40: cooling means 43, 58: ball screw

45: cover 50: material cutting length control

54: rotary actuator 56: deceleration limit switch

57: stop limit switch 60: cutting material transfer unit

64: balance 70: unloading unit

71: pusher 73: loading deck

80: labeling unit 82: barcode printing unit

Claims (12)

Lower frame 2, upper frame 4, loading unit 10, side clamping unit 20, material cutting unit 30, material cutting length control unit 50, cutting material transfer unit 60, unloading unit ( In the ultra-fast horizontal cutting device consisting of 70, the loading unit 10 is provided with at least two sliders (left and right) to be transported to the loading position 12 and the transfer position 13 provided in the lower frame ( 14), a moving cylinder 15 installed between the lower frame 2 and the slider 14 to move the slider to the left and right, and an elongated material that can be installed on the upper and upper sides of the slider so as to be able to move up and down. 5) is placed on the diverter 11, the lifting cylinder 16 is installed between the slider and the diverter to raise and lower the diverter, and do not interfere with the slider 14 in the transfer position 13 The sensor is installed so that a large number of materials 5 are placed by the diverter 11 so as to be shifted so as to shift them. Ultra-high horizontal cutting device using a circular saw blade, characterized in that consisting of a drive roller 18 for transferring it to the side clamping portion 20 side as detected. delete Lower frame 2, upper frame 4, loading unit 10, side clamping unit 20, material cutting unit 30, material cutting length control unit 50, cutting material transfer unit 60, unloading unit ( In the ultra-fast horizontal cutting device consisting of 70, the side clamping portion 20 is a drive-less roller 21 is installed at the end of the loading section 10 so as to be idle, and the drive is installed at the tip of the driveless roller By the rotational speed of the motor 22 is changed by the drive roller 23 for varying the feed speed of the material (5), and is installed on both sides of the drive roller to clamp the side of the material as the transfer of the material is completed Ultra-fast horizontal cutting device using a circular saw blade, characterized in that consisting of a clamper (24), and a clamping cylinder (25) for transferring the clamper to the left, right. The method of claim 3, Ultra-high horizontal cutting device using a circular saw blade, characterized in that it further comprises an upper clamper (27) for clamping the upper surface of the material (5) on the upper side of the clamping portion (20). Lower frame 2, upper frame 4, loading unit 10, side clamping unit 20, material cutting unit 30, material cutting length control unit 50, cutting material transfer unit 60, unloading unit ( In the ultra-fast horizontal cutting device consisting of 70, the material cutting portion 30 is a pair of linear motion rail 31 and the straight line installed on the upper portion of the lower frame 2 orthogonal to the conveying direction of the material (5) Sliding bed 32 mounted on the movement rail, and fixed to the sliding bed by the anti-vibration means 33, the electric motor 34 for generating power, the output shaft and the belt 35 of the electric motor A reducer 36 connected to reduce the rotational speed of the electric motor, a circular saw blade 37 fixed to the output shaft of the reducer to rotate at high speed, and cut at the same time, and installed in the reducer to shake during rotation of the circular saw blade. Saw blade guide 38 for preventing the lower portion to surround the circular saw blade Brushing means (39) installed on the frame (2) to remove the chips fused at this end of the circular saw blade 37 when cutting the material (5), and is installed on one side of the saw blade guide to cool air when cutting the material Cooling means 40 to cool the frictional heat by blowing blowing, and is installed on the bottom of the lower frame 2 so that the rotation of the servo motor 41 is decelerated by another reducer 42 and rotates one end Ultra-fast horizontal cutting device using a circular saw blade, characterized in that consisting of a ball screw 43 screwed to the sliding bed (32). The method according to claim 5, Ultra-fast horizontal cutting device using a circular saw blade, characterized in that the oil film is formed on both sides of the circular saw blade 37 when cutting the material (5) by supplying the mist oil through the saw blade guide 38. Lower frame 2, upper frame 4, loading unit 10, side clamping unit 20, material cutting unit 30, material cutting length control unit 50, cutting material transfer unit 60, unloading unit ( In the ultra-fast horizontal cutting device composed of 70), the material cutting length control unit 50 is a locator frame 51 provided along the same direction as the conveying direction of the material (5), a pair of installed on the upper part of the locator frame A deceleration limit switch 56 mounted on a slider 53 movably mounted along the LM guide 52, a rotary actuator 54 rotatably mounted on an upper portion of the slider, and a support 55 fixed to the rotary actuator. ) And another ball screw 59 which is installed in the stop limit switch 57 and the locator frame 51 so as to be rotatable and rotated by another servomotor 58 and the slider 53 is screwed. A circle characterized by High-speed horizontal cutting apparatus using a saw blade. The method of claim 7, Ultra high-speed horizontal cutting device using a circular saw blade, characterized in that the plurality of cover 45 is installed to be foldable on both sides of the moving direction of the slider (53) which is installed to be movable to the LM guide (52). delete delete delete delete

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