KR101024109B1 - Clamping apparatus for processing ingot - Google Patents

Abstract

The present invention relates to a clamping device for processing ingots that can be freely rotated or transported while preventing the risk of safety accidents by working mechanically from the clamping of the ingot to the transfer operation.

To this end, the support plate for mounting on the column top; A tilting device unit for tilting the tilting lever up and down through a tilting cylinder coupled to the support plate; An arm connected to the tilting lever and extending forward; A sliding device unit installed at the arm end to transfer the finger unit back and forth; It characterized in that it comprises a clamping device portion which is installed in the sliding device portion to clamp the ingot through the finger portion.

According to the above configuration, since the lifting and forwarding and the plane rotation and the plane rotation of the finger portion is possible, there is an effect to improve the processing performance of the ingot by moving the ingot freely, the safety of the ingot conveying work can be mechanically applied to the operator It also has the effect of preventing the risk of an accident.

Ingot, billet, press, clamping, finger, cylinder.

Description

Clamping apparatus for processing ingot

The present invention is to mechanically work from clamping to conveying of the ingot as a whole, thereby preventing safety accidents and industrial accidents that may be inflicted on the worker while improving the productivity of the product and freely turning or conveying the clamped ingot. A clamping device for an ingot processing.

Ingots are generally solidified by melting a metal or alloy once and then pouring it into a mold, which refers to a metal mass hardened in a form suitable for processing or remelting such as rolling or forging.

Such ingots are formed into steel pieces such as billets, which are usually materials for rolling and forging, before being processed into plastic processing such as forging, rolling, and extrusion. In other words, the ingot is pressed or ground to form a billet which is a material for rolling and forging a steel.

As such, in order to form the billet, the ingot must be moved at various angles and placed in the upper and lower press working spaces. The billet was formed by driving.

However, in the conventional ingot forming process, since the operator has to lift the ingot directly to the inside of the press, there is a risk of causing a fatal injury to the operator due to the press processed at high pressure and high speed when the press malfunctions.

Moreover, due to the nature of the manual work of the worker lifting the ingot as described above, it is necessary to repeatedly transport relatively heavy ingots, and thus, industrial accidents such as musculoskeletal disorders such as waist, knee, and shoulder frequently occur due to excessive transfer work. There is an end to it.

In addition, since it is practically impossible for the worker to continuously transport the ingot without stopping, there is a problem that it is difficult to secure a uniform product quality as well as a product production efficiency, and it is difficult to secure sufficient manpower due to a hard working environment. In addition, significant labor costs have contributed to the deterioration of corporate profitability.
On the other hand, in order to solve this problem, various forms of technology have been developed from the prior art, and the related technologies will be briefly described as follows.
First, Korean Patent Publication No. 10-2000-0055700 (name: automatic transfer device of forging material) is processed by clamping the forging material and supplying the processed material to the transfer means to process and transfer the material It relates to an automatic transfer device of forged material made possible.
In addition, Korean Patent Registration No. 0728559 (Name: Transfer device for forging material) relates to a forging material transfer device that can be transferred to the forging press in a vertical state of the material being supplied in a lying down state will be.

The present invention has been made in order to solve the conventional problems as described above, by mechanically working from the clamping to the transfer of the ingot as a whole, thereby preventing safety accidents and industrial accidents that may be inflicted on the worker while product productivity It is to provide a clamping device for ingot processing to improve the quality.

Another object of the present invention is to provide a clamping device for processing ingots that can freely pivot or convey the clamped ingot.

The structure of the present invention for achieving the above object, the support plate for mounting on the column top; A tilting device unit for tilting the tilting lever up and down through a tilting cylinder coupled to the support plate; An arm connected to the tilting lever and extending forward; A sliding device unit installed at the arm end to transfer the finger unit back and forth; It characterized in that it comprises a clamping device portion which is installed in the sliding device portion to clamp the ingot through the finger portion.

Here, the tilting device unit, and the tilting cylinder mounted on the lower support plate; A tilting link hinged to the rod end of the tilting cylinder; A tilting lever coupled to the support plate, the both ends of which are hinged to the tilting link and the connecting plate, respectively; It comprises a horizontal adjustment lever hinged to the support plate and the upper end of the connecting plate so that the connection plate can be moved up and down in a horizontal state.

The sliding device may include: a guide frame pivotally mounted to the lower portion of the arm by pivot means; A plurality of guide rails mounted on the bottom of the guide frame; Saddles and guide grooves respectively formed on the upper surface so as to be inserted into the respective guide rails for sliding transfer; The guide frame and the bottom of the saddle is installed on the transfer block is configured to include a moving means for moving the saddle back and forth through the operation of the handle.

Here, the pivot means includes: a jig coupled to the arm end to be fitted into the bearing housing mounted to the guide frame end; A plurality of ball grooves formed at equal intervals along the circumference of the flange on the jig; A bracket coupled to the guide frame to cover a portion of the flange; It is configured to include a locking ball coupled to the upper and lower ends of the bracket in the elastic state and fitted in the elastic state of any one of the upper and lower ball grooves of the ball groove.

And, on the flange of the jig, the lower surface circumference further provided with an angle indicator plate, the ball groove is formed radially a plurality of intervals 15 degrees around the center of the jig.

The moving unit may include: a fixing block formed at a rear end of the guide frame by forming a screw guide hole in a center thereof; A feed screw that is inserted into the screw guide hole and rotates and is fed back and forth; A handle installed at one end of the transfer screw; Installed at the bottom of the saddle, it is configured to include a transfer block for rotatably coupling the other end of the transfer screw.

In addition, the scale bar is fixed to one side of the guide frame to measure the moving distance of the birds.

In addition, stoppers are formed at both ends of the guide rail.

And, the clamping device unit, and the socket coupled to the bottom of the saddle; A clamp arm having a portion through the center of the socket; And a finger portion mounted on the clamp arm tip to clamp the ingot.

Here, the finger portion, the clamping cylinder mounted to the clamp arm tip; A palm member mounted at one end of the clamping cylinder by forming a clamping hole at a center thereof; A feed pin inserted into the clamping hole and coupled to a rod of the clamping cylinder to transfer the back and forth along the clamping hole; First finger joints on both sides rotatably coupled to the transfer pins; A second finger joint rotatably coupled to each of the first finger joints and the palm member; And a clamping finger coupled to each of the second finger joints to clamp the ingot.

Then, one clamping finger is coupled to the second finger joint, or a finger plate is coupled to the second finger joint, and at least two or more clamping fingers are coupled to the finger plate.

On the other hand, the column is fixed to the upper surface of the transport carrier having a wheel, the plurality of jacking bar is coupled to the bottom plate of the transport carrier, it is configured by combining the jacking handle on the top of the jacking bar.

The present invention through the above-described problem solving means, by allowing the upper and lower lifting movement and the front, rear transfer and planar rotation of the finger portion clamping the ingot, to move the ingot as freely as possible to position the ingot in the desired position by the operator In addition, the ingot clamping operation can also be performed easily, there is an effect that can maximize the performance of the device.

In particular, since a series of processes such as clamping of the ingot, moving work, and transfer to the processing device are mechanized as a whole, the ingot transfer by manual labor is unnecessary, and the worker's muscle musculoskeletal disease caused by manual labor and press work There is also the effect of reducing the risk of injury to prevent industrial accidents, such as safety accidents, and also has the effect of improving the productivity of the ingot by maximizing the processing performance of the ingot forming operation by mechanization.

When described in detail with reference to the accompanying drawings a preferred embodiment of the present invention.

1 to 8d illustrate the clamping device for ingot processing according to the present invention, which includes a column 100, a support plate 110, a tilting device part, an arm 210, a sliding device part, It consists of a clamping device.

As shown in Figure 1, the column 100 serves to support the clamping device for ingot processing of the present invention as a whole, can be installed on the ground, but in the present invention, the column 100 is fixed to the upper surface of the carrier carrier 160 do.

Here, the transport carrier 160 is configured to be smoothly transporting the transport carrier 160 by installing wheels 165 on the bottom four corners, respectively, before the bottom plate of the transport carrier 160, In the middle of the rear, the jacking bar 170 is screwed to lift the transport carrier 160 to the ground, and the jacking handle 170 can be rotated on the top of each jacking bar 170. 175).

In addition, the support plate 110 is installed on both sides of the column 100, and the support plate 110 is provided with a tilting device part for tilting the tilting lever 140 up and down.

The tilting device unit tilts the tilting lever 140 through the tilting cylinder 120 coupled to the support plate 110, and again the tilting cylinder 120, the tilting link 130, and the tilting lever 140. ), And the horizontal adjustment lever 150.

2A and 2B, the tilting cylinder 120 is mounted on the lower rear side of the support plate 110, and the rod 125 of the tilting cylinder 120 is upwardly provided. 125) hinge the end of the tilting link 130 to the end. The hinge plate 140 is hinged to the front of the support plate 110, and one end of the tilt lever 140 is rotatably hinged to the tilting link 130 and the other end of the tilt lever 140. By hinge rotatably coupled to the lower end of the connecting plate 200, it is configured to be able to tilt the tilting lever 140 through the driving of the tilting cylinder (120).

At this time, when the tilting lever 140 of the tilting of the horizontal adjustment lever 150 on the upper end of the support plate 110 and the upper end of the connecting plate 200 so as to elevate the connecting plate 200 in a horizontal state. To combine. Here, the horizontal adjustment lever 150, as described above, by lifting the front device including the connecting plate 200 in a horizontal state as a whole, the tilting lever 140 in the same horizontal state as the tilting lever 140 It is provided at the top.

Next, the arm 210 is connected to the tilting lever 140 and extends forward, and the connection plate 200 is provided at one side of the tilting lever 140 and the horizontal control lever 150 as described above. The hinge is coupled, and the end of the arm 210 is mounted to the bottom of the connecting plate 200.

On the other hand, the sliding unit is installed at the end of the arm 210 serves to transfer the front and rear finger portion, the guide frame 300, the guide rail 310, the saddle 320, and move again Means.

3A to 4, the guide frame 300 is pivotably mounted at a predetermined angle by a third pivot means at the lower end of the arm 210, and the guides are provided on both sides of the bottom surface of the guide frame 300. The guide rail 310 is mounted in the longitudinal direction of the frame 300, and the saddle 320 is slid and transferred to each guide rail 310, and the saddle 320 is fitted to the guide rail 310. Guide grooves 325 are formed on the saddle 320 to be slidable. In addition, stoppers 330 are formed at both ends of the guide rail 310 to limit excessive conveyance of the saddle 320.

In addition, the guide frame 300 and the saddle 320 is provided with a moving means to transfer the saddle 320 back and forth by the operation of the handle 385.

Such, the moving means is composed of a fixed block 360, a transfer screw 380, a handle 385, and a transfer block 370, specifically described in the lower end of the guide frame 300 The fixed block 360 is installed in the direction, and the center of the fixed block 360 to form a screw guide hole 365, the screw guide hole 365, the feed screw 380 is inserted into the feed screw 380 Is rotated at the same time as the forward and backward, and is provided, the rear end of the transfer screw 380 is equipped with a handle 385 is responsible for the rotation operation of the transfer screw 380.

Then, the saddle 320 is fixed to the bottom of the transfer block 370, the transfer block 370 in the center coupled to the front end of the transfer screw 380, the transfer screw 380 transfer block ( It is configured to be moved forward or backward with the saddle 320 in a state rotatably coupled to 370. Here, one side of the guide frame 300 is fixed to the scale bar 390 of the shape of the child so that the movement distance of the saddle 320 to move as described above.

In addition, the guide frame 300 is pivotally mounted by a pivot means, and the pivot means includes a jig 350, a ball groove 352, a bracket 353, and a locking ball 354.

5 to 6b, the bearing housing 340 is mounted on the rear upper surface of the guide frame 300, and the jig 350 is mounted on the lower end of the arm 210 to mount the jig 350. The upper part is rotatably inserted into the bearing housing 340.

A flange 351 is formed around the middle of the jig 350, and a plurality of ball grooves 352 are formed at equal intervals along the circumference of the flange 351. Here, the ball groove 352 is formed in the radially centered around the center of the jig 350, in the present invention, the ball groove 352 so that one rotation angle of the guide frame 300 can be 15 ° By providing 15 degrees at equal intervals, 24 ball grooves 352 are formed in the upper surface and the lower surface of the flange 351, respectively.

In addition, the angle indicating plate (A) is formed along the upper and lower surfaces of the flange 351 so that the angle of rotation of the guide frame 300 can be measured. The angle indicating plate (A) is formed in the ball groove (352). It is provided so as not to interfere.

In addition, the upper surface of the guide frame 300 has a bracket 353 of approximately 'c' shape so as to cover the ball groove 352 is located on any one of the ball groove 352 formed on the flange 351, the lower portion The locking ball 354 can be fitted in an elastic state to the upper and lower pair of ball grooves 352 by engaging the locking ball 354 in the tension state on the upper and lower surfaces of the bracket 353. Configure it.

That is, since a compression spring (not shown) is built in between the locking ball 354 and the bracket 353, the locking ball 354 may be provided in a tensioned state, and the locking ball 354 may be formed in the guide frame 300. The ball groove 352 of the rotation is fitted in an elastic state, it is possible to control the rotation of the guide frame 300 at a predetermined angle (15 ° in the present invention).

Next, the clamping device part is installed at the lower end of the sliding device part so as to clamp the ingot through the front finger part. The clamping device part includes the socket 410, the clamp arm 400, and the finger part.

In this case, the socket 410 having a hole in the center is fixed to the transfer block 370 at the bottom of the saddle 320, and the socket 410 is provided at the center of the rear portion of the clamp arm 400. In addition, the finger portion is mounted at the tip of the clamp arm 400 to clamp the ingot, and again, the clamping cylinder 500, the palm member 510, the transfer pin 520, and the first finger joint 530. ), A second finger joint 540, and a clamping finger 550.

7A and 7B, the clamping cylinder 500 is rotatably coupled to the front of the clamp arm 400, and the palm member 510 is provided on the front and the bottom of the clamping cylinder 500, respectively. The clamping holes 512 are formed at the center of the palm member 510 in the front and rear longitudinal directions, respectively. Then, a transfer pin 520 is inserted through the clamping hole 512 up and down, and the rod 505 of the clamping cylinder 500 is coupled to the transfer pin 520 to form the rod 505. According to the driving, the transfer pin 520 is configured to be transported before and after the clamping hole 512.

In addition, one end portion of the first finger joint 530 is rotatably coupled to the transfer pin 520, and the first finger joint 530 is provided at both sides of the left and right sides of the transfer pin 520, respectively. The second finger joint 540 is rotatably coupled to the other ends of the first finger joints 530, respectively, and the middle portions of the second finger joints 540 are respectively opposite to the front sides of the palm member 510. It is rotatably provided, and the clamping finger 550 is coupled to the front end of the second finger joint 540 to clamp the ingot.

Here, the clamping finger 550 can be provided in various sizes and various numbers according to the type of ingot to be clamped. For example, one clamping finger 550 in the second finger joint 540 as shown in FIG. ) Can be combined.

In addition, as another embodiment for coupling the clamping finger 550 as shown in Figures 8b, 8c, 8d coupled to the finger plate 545 of the 'c' shape with the upper and lower gaps open, and the At least two clamping fingers 550 may be coupled to the finger plate 545.

The clamping finger 550 used as described above is suitable to use a plurality of clamping finger 550 by the size of 5mm to use the clamping finger 550 of various sizes according to the ingot to be clamped, and clamping When the plurality of fingers 550 are combined, the size (height) may be the same, but in some cases, the clamping fingers 550 having different sizes may be used in combination.

Referring to the operation and effect of the present invention configured as described in detail as follows.

The clamping device for processing ingot of the present invention clamps the ingot so as to settle the ingot in the working space of the processing apparatus such as the press P or move the clamped ingot freely inside the press P.

2A and 2B illustrate an operating state in which the arm 210 including the clamp device portion is lifted or lowered as a whole while the ingot is clamped, and a tilting cylinder coupled to the support plate 110 to raise and lower the ingot. The ingot is raised and lowered by rotating the tilting lever 140 through 120.

That is, when the ingot is to be lifted upward as shown in FIG. 2A, when the rod 125 of the tilting cylinder 120 is driven to pull down the tilting link 130 coupled with the rod 125, the tilting is performed. One end of the tilting lever 140 coupled with the link 130 is lowered together in the downward direction, and the other end of the tilting lever 140 can be lifted upward by the principle of the lever.

On the other hand, when the ingot is to be lowered as shown in FIG. 2B, the tilting link 130 coupled with the rod 125 is raised upward as opposed to the operating state of the tilting cylinder 120 described above. Then, one end of the tilting lever 140 coupled with the tilting link 130 is raised together in the upward direction while being able to lower the other end of the tilting lever 140 by the principle of the lever.

Here, the tilting lever 140, the horizontal adjustment lever 150 is rotatably coupled to the support plate 110 and the connecting plate 200, respectively, by horizontally arm 210 configured to be coupled to the connecting plate 200 It can be raised or lowered in a state, which is to raise or lower the sliding unit and the clamping unit connected to the arm 210 in a horizontal state.

In addition, in order to transfer the ingot coupled to the finger part before and after, the saddle 320 is moved forward and backward along the guide rail 310 to transfer the clamping device part.

That is, in order to transfer the ingot to the front, as shown in Figure 3a, by turning the handle 385 to rotate the feed screw 380, thereby the feed screw 380 in the screw guide groove formed in the fixed block 360 The saddle 320 is moved forward while being guided and moved forward.

Then, since the guide groove 325 formed in the saddle 320 is fitted to the guide rail 310 coupled to the guide frame 300, the saddle 320 slides forward along the guide rail 310. While being made, the clamping device portion coupled with the saddle 320 is smoothly forwarded, thereby transferring the ingot coupled to the clamping device portion forward.

On the other hand, if you want to convey the ingot to the rear as shown in Figure 3b, by turning the handle 385 in the opposite direction to rotate the feed screw 380, thereby the feed screw 380 to the fixed block 360 The saddle 320 is moved backward while being guided by the formed screw guide groove.

In this case, the saddle 320 is slidably moved backwards along the guide rails 310, in contrast to the above operating state, and the clamping device coupled with the saddle 320 is smoothly transferred backwards, thereby clamping. Ingots coupled to the device can be transported to the rear.

In addition, in order to clamp the ingot through the finger part, the clamping cylinder 500 is driven as shown in FIG. 7A to transfer the transfer pin 520 coupled with the rod 505 to the front along the clamping hole 512.

Then, the first finger joints 530 of both sides coupled to the transfer pin 520 are opened to both sides around the transfer pin 520, and the second finger joints coupled to the first finger joint 530. The 540 rotates about the pins at both ends of the palm member 510 to position the clamping finger 550 coupled to the second finger joint 540 to be retracted inward. Therefore, the ingot located between the two second finger joints 540 may be clamped through the clamping finger 550.

On the other hand, in order to release the clamping of the ingot clamped to the clamping finger 550, the conveying pin 520 coupled with the rod 505 of the clamping cylinder 500 is transported backward along the clamping hole 512 as shown in FIG. Let's do it.

Then, in contrast to the above operation, the first finger joints 530 of both sides coupled to the transfer pins 520 are retracted inward with respect to the transfer pins 520, and the first finger joints 530. The second finger joint 540 coupled to the rotation may rotate around the pins at both ends of the palm member 510 so that the clamping finger 550 coupled to the second finger joint 540 may be opened to the outside. Therefore, the ingot clamped by the clamping finger 550 can be de-clamped.

And, the finger portion can be rotated in a predetermined rotation radius on the plane by the pivot means. That is, pivoting of the finger part is possible about the end of the guide frame 300 coupled to the arm 210 by the pivot means.

6A and 6B, when the guide frame 300 is rotated in the forward or reverse direction when viewed in a plan view, the locking ball 354 is fitted into the ball groove 352 to partially rotate the guide frame 300. Although it is limited, the locking ball 354 is fitted in the ball groove 352 in an elastic state, so that the locking ball 354 is moved away from the ball groove 352 is clouded over the flange 351. At this time, the end of the jig 350 is fitted inside the bearing housing 340, the guide frame 300 is naturally rotated by the rolling of the bearing.

When the guide frame 300 is rotated by 15 °, the locking ball 354 is mounted in a tensioned state by the compression spring, so that the locking ball 354 is inserted into another ball groove 352 adjacent thereto to block the turning of the guide frame 300. do. As such, since the ball grooves 352 are formed on the lower surface of the flange 351 at 15 ° intervals, the guide frame 300 can be pivoted at 15 ° intervals around the center of the jig 350, thereby allowing the finger portion to rotate. It can also be turned. Here, the angle indicator plate (A) is provided on the upper and lower surfaces of the flange 351, it is possible to accurately measure and estimate the angle of rotation of the guide frame 300.

On the other hand, the present invention has been described in detail only with respect to the specific examples described above it will be apparent to those skilled in the art that various modifications and variations are possible within the technical scope of the present invention, it is natural that such variations and modifications belong to the appended claims. .

1 is a front view showing an overall clamping device for ingot processing according to the present invention,

Figure 2a, 2b is a partial enlarged front cross-sectional view showing a tilting operation state of the tilting lever by the tilting means of the present invention,

Figure 3a, 3b is an enlarged front view showing a sliding operation state of the sliding device according to the present invention,

Figure 4 is an enlarged side view showing the coupling structure of the saddle and the guide rail sliding device portion according to the present invention,

Figure 5 is a front sectional view showing an enlarged structure of the pivot means according to the present invention,

Figure 6a, 6b is an enlarged plan view showing the swing operation state of the guide frame by the pivot means of Figure 5,

Figure 7a, 7b is an enlarged plan view showing the clamping operation state of the clamping finger by the finger portion of the present invention,

8A, 8B, 8C, and 8D illustrate embodiments of clamping fingers coupled in various forms to a second finger joint of the present invention.

* Description of the major symbols in the drawings *

100: column 110: support plate

120: tilting cylinder 130: tilting link

140: tilting lever 150: horizontal adjustment lever

160: transfer carrier 170: jacking bar

200: connecting plate 210: arm

300: guide frame 310: guide rail

320: Saddle 325: Guide Home

330: stopper 340: bearing housing

350: jig 351: flange

352: ball groove 353: bracket

354: rocking ball 360: fixed block

365: Screw Guide Hole 370: Transfer Block

380: feed screw 385: handle

390: scale bar 400: clamp arm

410: socket 500: clamping cylinder

510: palm member 512: clamping hole

520: transfer pin 530: first finger joint

540: second finger joint 545: finger plate

550: clamping finger A: angle indicator

P: Press

Claims (14)

A support plate 110 mounted on the column 100; The tilting cylinder 120 mounted on the lower support plate 110, the tilting link 130 hinged to the end of the rod 125 of the tilting cylinder 120, and hinged to the support plate 110, Tilting lever 140 is tilted up and down by hinged to the tilting link 130 and the connecting plate 200, respectively, and the support plate 110 so that the connecting plate 200 can be raised and lowered in a horizontal state. And a tilting device unit including a horizontal adjustment lever 150 hinged to an upper end of the connecting plate 200; An arm 210 connected to the tilting lever 140 and extending forward; A sliding device unit installed at the end of the arm 210 to transfer the finger unit back and forth; Ingot processing clamping device comprising a clamping device that is installed on the sliding device so that the ingot can be clamped through the finger. delete The method of claim 1, wherein the sliding device, A guide frame 300 pivotably mounted to the lower portion of the arm 210 by pivot means; A plurality of guide rails 310 mounted on a bottom of the guide frame 300; Saddle 320, each formed with a guide groove 325 on the upper surface so as to be inserted into each of the guide rails 310 and slidingly transported; Ingot processing characterized in that it comprises a moving means for moving the saddle 320 before and after through the operation of the handle 385 is installed in the transport block 370 of the guide frame 300 and the saddle 320 Clamping device. The method of claim 3, wherein the pivot means, A jig 350 coupled to the end of the arm 210 to be fitted into the bearing housing 340 mounted to the end of the guide frame 300; A plurality of ball grooves 352 formed on the flange 351 of the jig 350 at equal intervals along a lower surface thereof; A bracket 353 coupled to the guide frame 300 to cover a portion of the flange 351; It is characterized in that it comprises a locking ball 354 coupled to the upper and lower ends of the bracket (353) in the elastic state to any one of the upper, lower ball groove 352 of the ball groove (352) Ingot clamping device. [5] The clamping device for ingot machining according to claim 4, further comprising an angle indicator plate (A) around the bottom and the bottom of the flange (351) of the jig (350). The ingot processing clamping device according to claim 4, wherein the ball grooves 352 are formed radially in a plurality of 15 ° intervals about a center of the jig 350. According to claim 3, The means for moving, A fixing block 360 formed at a rear end of the guide frame 300 by forming a screw guide hole 365 in the center; A feed screw 380 which is inserted into the screw guide hole 365 and rotates and is fed back and forth; A handle 385 installed at one end of the transfer screw 380; Installed in the bottom of the saddle 320, ingot processing clamping device comprising a transfer block 370 for rotatably coupling the other end of the transfer screw (380). The ingot machining clamping device according to claim 3 or 7, wherein a scale bar (390) is fixed to one side of the guide frame (300) to measure a moving distance of the saddle (320). 4. The clamping apparatus for processing ingots according to claim 3, wherein stoppers (330) are formed at both ends of the guide rail (310). The method of claim 1, wherein the clamping device unit, A socket 410 coupled to the bottom of the saddle 320; A clamp arm 400 partially provided at a center of the socket 410; Ingot processing clamping device comprising a finger portion for clamping the ingot is mounted to the end of the clamp arm (400). The method of claim 10, wherein the finger portion, A clamping cylinder 500 mounted at the tip of the clamp arm 400; A palm member 510 formed at one end of the clamping cylinder 500 by forming a clamping hole 512 at a center thereof; A feed pin 520 inserted into the clamping hole 512 and coupled to the rod 505 of the clamping cylinder 500 to move forward and backward along the clamping hole 512; First finger joints 530 on both sides rotatably coupled to the transfer pins 520; A second finger joint 540 rotatably coupled to each of the first finger joints 530 and the palm member 510; And a clamping finger (550) coupled to each of the second finger joints (540) to clamp the ingot. 12. The clamping device for ingot processing according to claim 11, wherein one clamping finger (550) is coupled to the second finger joint (540). The ingot of claim 11, wherein a finger plate 545 is coupled to the second finger joint 540, and at least two clamping fingers 550 are coupled to the finger plate 545. Machining clamping device. The method of claim 1, wherein the column 100 is fixed to the upper surface of the transport carrier 160 having a wheel 165, and combines a plurality of jacking bar 170 on the bottom plate of the transport carrier 160, Ingot processing clamping device, characterized in that for coupling the jacking handle 175 on the top of the jacking bar 170.

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