KR102241140B1 - Half-Nut Combining Apparatus with Structure for Prevention the Interference of Extract Device, Moving Plate Including with The Same - Google Patents

Abstract

The present invention improves the connection type of the connecting bar that simultaneously fastens the half nuts in a pair, and interferes with the size of the ejector provided on the moving template or the high-speed fastening device of the half nut when the ejector is operated. And first and second half nuts arranged so that a collision can be prevented, wherein the first and second split nuts and the third and fourth split nuts, which are a pair of forming a pair, face each other at a distance. Drive cylinders respectively connected to move the first and third split nuts; A position fixing bracket detachably coupled to a moving platen for fixing the position of the driving cylinder; First and second connection bars disposed outside the reference line passing through the centers of the first and second half nuts and connected to the first and second half nuts; A structure for preventing interference of an extractor comprising a third connection bar connected to the first half nut and a fourth connection bar connected to the second half nut in an arrangement structure in which a clearance space is secured at the inner center of the reference line A half nut high-speed fastening device having a is provided.

Description

Half-Nut Combining Apparatus with Structure for Prevention the Interference of Extract Device, Moving Plate Including with The Same}

The present invention relates to a high-speed half-nut fastening device having a structure for preventing interference of an ejector, and to a moving platen having the high-speed half-nut fastening device, and more particularly, a connection for fastening simultaneously between half nuts forming a pair at high speed. By improving the connection type of the bar, it is possible to prevent interference and collisions with the high-speed fastening device of the half nut when the size of the ejector provided in the moving template or when the ejector is operated.

In general, injection molding machines are largely divided into a clamping device and an injection device. The double clamping device is composed of a fixed plate that is fixed in position, and a movable plate that is installed to correspond to the fixed plate in close contact with or separated from each other.

In addition, the fixed mold plate and the moving mold plate are respectively coupled to the fixed mold and the moving mold plate, and the center of the moving plate plate has a structure in which an ejector for taking out the injected molded product is installed.

In addition, the half-nut fastening device installed on the movable plate is installed equal to the number of tie bars, and in general, the half-nut fastening devices are mounted in four places, that is, upper, lower, left, and right, respectively, and the half The nut fastening device has a coupling structure through which the tie bar passes. In addition, the half-nut fastening device includes a connecting bar for connecting the half-nuts so that the half-nuts forming a pair can be simultaneously fastened.

Briefly explaining the operation of the injection molding machine configured as above. First, when the booster cylinder provided in the injection molding machine applies hydraulic pressure to the moving platen, the moving platen moves in the direction of the fixed platen and is in a state in which it is completely in close contact with the fixed mold.

As described above, when the movable platen is in close contact with the fixed platen, hydraulic pressure is applied to the driving cylinder of the half nut, and the half nut presses the tie bar when fastening and fixing are completed, the process for injection molding is performed, and injection molding is performed. After the completion of the injection molding process, the ejector installed on the moving platen proceeds with the ejection operation to eject the molded product, thereby completing the injection molding.

In FIG. 1, a perspective view showing a moving platen of an injection molding machine equipped with a general half nut high-speed fastening device is shown. In FIG. 2, a side view of FIG. 1 is shown, and in FIG. 3, it is developed along line AA of FIG. A cross-sectional view is shown.

As shown in FIGS. 1 to 3 introduced above, the half nut high-speed fastening device 100 has a pair of first and second half nuts 110 and 120 coupled to both upper and lower sides of the movable plate 200 It is arranged in a structure that can be used.

The first and second half nuts 110 and 120 are composed of two first, second, third, and fourth split nuts 111, 112, 121, 122, the first, second, and third ,A drive cylinder 130 and 140 are respectively connected to one of the first and third split nuts 111 and 121 among the four split nuts 111, 112, 121, and 122, and thus The connected drive cylinders 130 and 140 are fixedly installed on the movable plate 200.

Specifically, the rods 131 and 141 of the drive cylinders 130 and 140 are connected to the first and third split nuts 111 and 121, respectively, so that the first and third split nuts 111 and 121 are It has a structure that interlocks with the rods 131 and 141.

Meanwhile, between the first half nut 110 and the second half nut 120, two first, second, third, and fourth connecting bars 150, 151, 152, and 153, respectively, up and down, respectively. Are connected in a structure in which the first, second, third, and fourth connecting bars 150, 151, 152, and 153 are connected to each other, and the first half nut 110 and the second half nut 120 are Simultaneous fastening is performed.

The connection relationship between the first, second, third, and fourth connecting bars 150, 151, 152, and 153 for simultaneous fastening of the first half nut 110 and the second half nut 120 will be described, One end of the first connection bar 150 is fixedly coupled to the first split nut 111, is not coupled to the second split nut 112, and the other end of the first connection bar 150 is a third The split nut 121 is coupled and fixed with the fourth split nut 122 while passing through so as to be slid.

One end of the second connection bar 151 is coupled and fixed with the second split nut 112 while passing through the first split nut 111 to slide, and the other end of the second connection bar 151 is a third The split nut 121 is coupled and fixed, and is not coupled with the fourth split nut 122.

One end of the third connection bar 152 is coupled and fixed with the second split nut 112 while passing through the first split nut 111 to slide, and the other end of the third connection bar 152 is a third The split nut 121 is coupled and fixed, and is not coupled with the fourth split nut 122.

In addition, one end of the fourth connection bar 153 is fixedly coupled to the first split nut 111, is not coupled to the second split nut 112, and the other end of the fourth connection bar 153 is The third split nut 121 is passed through so as to be slid, and has a coupling relationship that is fixedly coupled to the fourth split nut 122.

Therefore, a general half-nut high-speed fastening device configured as described above includes the first, second, third, and fourth connecting bars 150 (150) so that the first half nut 110 and the second half nut 120 can be simultaneously fastened. 151, 152, and 153 are connected. However, as shown in FIG. 3, when the installation area of the ejector 202 installed in the center of the movable platen 200 is wider than the area of the movable platen 200, the ejection operation of the ejector 2020 There is a problem in that a high-speed half-nut fastening device or ejector 202 configured in the structure described above cannot be applied because a collision occurs in contact with a connecting bar adjacent to the ejector 202 in parallel.

Accordingly, the present invention was invented to solve the problems of the related art as described above, and the problem to be solved by the present invention is to improve the connection type of the connecting bar that simultaneously fastens the half nuts forming a pair to move the template. Half nut high-speed fastening device having an interference prevention structure of the take-out device so that interference and collision with the high-speed fastening device of the half nut can be prevented when the size of the take-out device provided in the take-out device or the operation of the take-out device. An object thereof is to provide a movable plate having a fastening device.

The solution means of the present invention for solving the above problems includes: first and second half nuts disposed so that the first and second split nuts and the third and fourth split nuts of a pair of forming a pair face each other at a distance; Drive cylinders respectively connected to move the first and third split nuts; A position fixing bracket detachably coupled to a moving platen for fixing the position of the driving cylinder; First and second connection bars disposed outside the reference line passing through the centers of the first and second half nuts and connected to the first and second half nuts; A third connection bar connected to the first half nut and a fourth connection bar connected to the second half nut in an arrangement structure in which a clearance space is secured at an inner central portion of the reference line; The purpose can be achieved through a half-nut high-speed fastening device having a structure for preventing interference of the ejector configured including.

In addition, one end is coupled to the first split nut and the other end is coupled to the fourth split nut through the third split nut, the first connection bar; The second connection bar at one end passing through the first split nut and coupled to the second split nut and the other end coupled to the third split nut; The third connection bar having one end through the first split nut and coupled to the second split nut and the other end of the third connection bar coupled and fixed to the position fixing bracket; The fourth connecting bar at one end being coupled and fixed to the fourth partitioning nut through the third partitioning nut and the other end being coupled and fixed to the position fixing bracket; The purpose can be achieved through a half-nut high-speed fastening device having a structure for preventing interference of the ejector configured including.

In addition, the position fixing bracket is supported by a structure that presses the movable plate and a fixed piece to fix the position of the driving cylinder, a support piece disposed toward the side of the fixed piece, and a corresponding connecting bar passing through the side of the support piece. The purpose can be achieved through a half-nut high-speed fastening device having an interference prevention structure of the ejector comprising a coupling piece that is detachably coupled to the piece.

In addition, in the present invention, the first and second half nuts of the high-speed half nut fastening device configured as described above are coupled to both upper and lower sides of the moving platen, and the clearance space formed between the first half nut and the second half nut is The purpose can be achieved through a movable template arranged in a structure adjacent to the ejector provided in the center of the movable template.

As described above, in the present invention, the half nut fastening device for fastening the upper half nut and the lower half nut at the same time is improved to a new connection structure type, so that the ejector installed in the center of the moving platen is installed area compared to the area of the moving platen. Even if this is widened, it is possible to expect the effect that the half nut high-speed fastening device can be applied as it is, along with the effect of preventing the occurrence of a collision that comes into contact with the connecting bar adjacent to the ejector during operation of the ejector.

1 is a perspective view showing an entire half nut fastening device according to an embodiment of the present invention provided on a movable platen.
Figure 2 is a side view of Figure 1;
3 is a cross-sectional view taken along line AA of FIG. 2.
4 is a perspective view showing a half-nut high-speed fastening device having a structure for preventing interference of an ejector according to the present invention, and a movable plate having the half-nut fastening device.
5 is a plan view showing FIG. 4.
6A and 6B are perspective views illustrating the half nut high-speed fastening device of FIG. 4, and FIG. 6A is a perspective view as viewed from an upper outer side, and FIG. 6B is a perspective view as viewed from an inner lower portion.
7A is a plan cross-sectional view showing the coupling structure of the first and third connecting bars and the first and second half nuts by cutting along the line BB of FIG. 6A.
FIG. 7B is a cross-sectional plan view showing the coupling structure of the second and fourth connecting bars and the first and second half nuts by cutting along the CC line of FIG. 6A.
8A to 8C are schematic diagrams showing the operation of the high-speed half nut fastening device according to the present invention, and FIG. 8A is a schematic diagram showing a state in which the tie bar and the fastening are released, and FIG. It is a schematic diagram showing the appearance, and FIG. 8C is a schematic diagram showing a state in which the second and fourth split nuts are fastened to the tie bar.

Hereinafter, specific contents for carrying out the present invention will be described in detail based on the accompanying exemplary drawings. Prior to the description, even if the components are the same as those of FIGS. 1 to 3, different reference numerals are assigned to prevent confusion in the description and for convenience of description.

As shown in FIGS. 4 to 6B, the half nut high-speed fastening device 300 according to the present invention includes a pair of first and second half nuts 310 and 320 on both upper and lower sides of the movable plate 302. It is equipped with a combined structure.

The first and second half nuts 310 and 320 are composed of two first, second, third, and fourth split nuts 311, 312, 321, 322, and the first, second, and third ,The first and third split nuts 311, 321 located on one of the four split nuts 311, 312, 321, and 322 are interlocking structures connected to the corresponding driving cylinders 330, 340, respectively. Is taking.

Specifically, the driving cylinders 330 and 340 are mounted on the fixing pieces 351 and 361 and fixed to the moving platen 302. The rods 331 and 341 of the driving cylinders 330 and 340 are connected to the first and third split nuts 311 and 321, respectively. Accordingly, the first and third split nuts 311 and 321 are interlocked with the rods 331 and 341.

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Between the first half nut 310 and the second half nut 320, first and second connection bars 370 and 371 are formed of the first half nut 310 and the second half nut 320. The first half nut 310 and the second half nut 320 are arranged on the outside of the reference line W passing through the center (refer to FIG. 5), that is, at the far side from the extractor 202 based on the reference line W. ).

In addition, between the first half nut 310 and the second half nut 320, a side close to the ejector 202 based on the reference line (W), connected to the first half nut 310 A third connection bar 372 and a fourth connection bar 373 connected to the second half nut 320 are connected in a structure in which each is individually arranged.

In particular, the third and fourth connecting bars 372 and 373 are shorter than the lengths of the first and second connecting bars 370 and 371, and thus between the third and fourth connecting bars 372 and 373 It is arranged in a structure in which a free space (S) is secured in a space of, that is, in an inner central portion close to the ejector 202 based on the reference line (W).

In addition, a driving in which the first half nut 310 and the second half nut 320 are simultaneously fastened through the first, second, third, and fourth connecting bars 370, 371, 372, and 373 described above. The first half nut 310 and the second half nut 320 are connected to the first, second, third, and fourth connecting bars 370, 371, 372 and 373 for simultaneous fastening of the first half nut 310 and the second half nut 320. The relationship will be described in detail below.

First, as shown in FIGS. 7A and 7B, one end of the first connection bar 370 is fixedly coupled to the first split nut 311 and is not coupled to the second split nut 312, and the first The other end of the connection bar 370 passes through the third split nut 321 so as to slide, and is coupled and fixed with the fourth split nut 322.

One end of the second connection bar 371 passes through the first split nut 311 so as to slide, and is coupled and fixed with the second split nut 312, and the other end of the second connection bar 371 is a third It is fixedly coupled to the split nut 321 and is not coupled to the fourth split nut 322.

The third connection bar 372 has one end coupled and fixed to the second split nut 312, and the opposite end connects both the first split nut 311 and the support piece 353 of the position fixing bracket 350 Penetrate to slide. A stop nut 354 is fastened to the end of the third connection bar 372 that has passed through the support piece 353. The stop nut 354 prevents the support piece 353 from leaving the third connection bar 372.

In addition, the fourth connection bar 373 has one end coupled and fixed to the fourth split nut 322, and the opposite end of the fourth connection bar 373 is a support piece 363 of the third split nut 321 and the position fixing bracket 360 It penetrates so as to slide all of them. A stop nut 364 is fastened to the end of the fourth connecting bar 373 passing through the support piece 363. The stop nut 364 prevents the support piece 363 from leaving the fourth connection bar 372.

On the other hand, when explaining the structure of the above-mentioned position fixing brackets 350 and 360 in more detail, first, it is fixed to the bottom surface of the moving platen 302, and the driving cylinders 330 and 340 are mounted and fixed. It is provided with a fixed piece (351, 361) to be.

In addition, support pieces 353 and 363 are provided between the drive cylinders 330 and 340 and the first and third split nuts 311 and 321, respectively. That is, the support piece 353 is installed between the drive cylinder 330 and the first split nut 311, and the support piece 363 is installed between the drive cylinder 340 and the third split nut 321.
The support piece 353 disposed on the side of the first split nut 311 has a hollow portion 353a through which the rod 331 of the drive cylinder 330 can freely pass. In addition, one side of the support piece 353 is fixed to the second connection bar 371 by pressing the coupling piece 352, and the other side of the support piece 353, as described above, the third connection bar 372 ) Penetrates so as to slide, and is supported so as not to escape from the third connection bar 372 by a stop nut 354.
The support piece 363 disposed on the side of the third split nut 321 has a hollow portion 363a through which the rod 341 of the drive cylinder 340 can freely pass. In addition, one side of the support piece 363 is fixed to the first connection bar 370 by pressing the coupling piece 362, and the other side of the support piece 363, as described above, the fourth connection bar 373 ) Penetrates so as to slide, and is supported so as not to escape from the fourth connection bar 373 by a stop nut 364.

According to an embodiment of the present invention configured in the above structure, as shown in FIGS. 8A to 8C, first and second half nuts 310 (310) ( The driving cylinders 330 and 340 respectively connected to the 320 are driven at the same time.

First, as shown in FIGS. 7A, 8A, and 8B, an operation according to the operation of the driving cylinder 330 will be described as follows.

When the driving cylinder 330 is driven to push the rod 331, the first split nut 311 moves toward the second split nut 312 and is fastened in a state in close contact with the tie bar T. At this time, the first split nut 311 penetrates through the third connection bar 372 so as to slide, but the first connection bar 370 is coupled and fixed. Therefore, when the first split nut 311 moves toward the second split nut 312 by the driving of the driving cylinder 330, the first connection bar 370 is divided into the second split together with the first split nut 311. It moves toward the nut 312.
As above, when the first connection bar 370 moves toward the second split nut 312 together with the first split nut 311, the third split nut 321 slides with the first connection bar 370. Although it does not move, since the fourth split nut 322 is coupled and fixed to the first connection bar 370, the fourth split nut 322 moves simultaneously with the movement of the first connection bar 370, and the fourth split nut 322 It is fastened to the tie bar T while moving from right to left in the direction 321), that is, in the direction of the arrow in FIG. 8B.
At the same time, the support piece 363 is fixed to the first connecting bar 370 through the coupling piece 362, and the fourth connecting bar 373 penetrates through the support piece 363 so as to slide. 4 A stop nut 364 is fastened to the end of the connecting bar 373 to block the support piece 363. Therefore, as described above, when the first connection bar 370 moves in the moving direction of the first split nut 311, the support piece 363 moves together with the first connection bar 370, and the support piece The stop nut 364 is pushed by the movement of 363, the fourth connection bar 373 to which the stop nut 364 is fastened is moved, and the fourth connection bar 373 is the fourth split nut 322 Will move. Accordingly, the fourth split nut 322 moves toward the third split nut 321 by the first connection bar 370 and the fourth connection bar 373 and is fastened to the tie bar T.
In this way, by the driving of the driving cylinder 330, the first split nut 311 moves toward the second split nut 312 and is fastened to the tie bar T, and the fourth split nut 322 is It moves toward the three-part nut 321 and is fastened to the tie bar T at the same time.

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On the other hand, as shown in Figs. 7B and 8C, when the drive cylinder 340 is driven to push the rod 341, the third split nut 321 moves toward the fourth split nut 322 and moves toward the tie bar. It is fastened in close contact with (T). At this time, the fourth connection bar 373 penetrates through the third split nut 321 so as to slide, but the second connection bar 371 is coupled and fixed. Therefore, when the third split nut 321 moves toward the fourth split nut 322 by the driving of the driving cylinder 340, the second connection bar 371 is divided into the fourth part together with the third split nut 321. It moves towards the nut 322.
As above, when the second connection bar 371 moves toward the fourth split nut 322 together with the third split nut 321, the first split nut 311 slides with the second connection bar 371. Although it does not move, since the second split nut 312 is coupled and fixed to the second connection bar 371, the second split nut 312 moves at the same time as the second connection bar 371 moves. 311) It is fastened to the tie bar T while moving from left to right in the direction of the arrow in FIG. 8C.
At the same time, the support piece 353 is fixed to the second connecting bar 371 through the coupling piece 352, and the third connecting bar 372 passes through the support piece 353 so as to slide (Fig. 7a), a stop nut 354 is fastened to the end of the third connecting bar 372 to block the support piece 354. Therefore, as described above, when the second connection bar 371 moves in the moving direction of the third split nut 321, the support piece 353 moves together with the second connection bar 371, and the support piece The stop nut 354 is pushed by the movement of 353, so that the third connection bar 372 to which the stop nut 354 is fastened is moved, and the third connection bar 372 is the second split nut 312 Will move. Accordingly, the second split nut 312 moves toward the first split nut 311 by the second connection bar 371 and the third connection bar 372 and is fastened to the tie bar T.
In this way, by the driving of the driving cylinder 340, the third split nut 321 moves toward the fourth split nut 322 and is fastened to the tie bar T, and the second split nut 312 is the first By moving toward the split nut 311, the operation of being fastened to the tie bar T is performed at the same time.

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In other words, when the driving cylinder 330 is driven, the first and fourth division nuts 311 and 322 move in the same direction at the same time, and when the driving cylinder 340 is driven, the second and third divisions are divided. Nuts 312 and 321 move in the same direction at the same time. Therefore, when the drive cylinder 330 and the drive cylinder 340 are simultaneously driven, the fastening operation of the first split nut 311 and the second split nut 312 with respect to one tie bar T, and the other tie bar The fastening operation of the third split nut 321 and the fourth split nut 322 with respect to (T) is performed at the same time.

In addition, as described above, the half-nut high-speed fastening device 300 according to the present invention is between the third and fourth connecting bars 372 and 373, that is, the first half nut 310 and the second half nut ( 320) has a structure in which a free space (S) is formed inside the reference line (W), so the ejector 202 installed in the center of the movable platen 302 is installed compared to the area of the moving platen 302 Even if the area is enlarged, the free space (S) that can cause contact and interference with the ejector 202 is secured, thereby solving the problems discussed in the background art while maintaining the functions and effects of the stable half nut high-speed fastening device. You will be able to.

Further, in the high-speed half nut fastening device 300 according to the present invention described above, the first split nut 311 of the first half nut 310 has been described as an interlocking structure in which the first split nut 311 is connected to the corresponding drive cylinder 330. , The third split nut 321 of the second half nut 320 has also been described as an interlocking structure connected to the corresponding drive cylinder 340.

However, it is not necessary to be limited to a structural configuration in which the drive cylinders 330 and 340 are independently connected to the first and second half nuts 310 and 320, respectively, A structural configuration that enables the first half nut 310 and the second half nut 320 to be simultaneously fastened is also included in the present invention.

For example, a driving pulley capable of rotating in both directions by driving of a driving source is installed between the first half nut 310 and the second half nut 320, and the driving pulley and the first and second split nuts 311 The first and second split nuts 311 and 321 may move simultaneously when the driving pulley is rotated by connecting the links between the and 321 respectively.

110, 310: first half nut 111, 311: first split nut
112, 312: second split nut 120, 320: second half nut
121, 321: 3rd split nut 122, 322: 4th split nut
130, 140, 330, 340: drive cylinder 131, 141, 331, 341: rod
150, 370: first connecting bar 151, 371: second connecting bar
152, 372: third connecting bar 153, 373: fourth connecting bar
200, 302: mobile platen 202: ejector
300: half nut high-speed fastening device 350, 360: position fixing bracket
351, 361: fixed piece 352, 362: combined piece
353, 363: support piece

Claims (4)

A movable plate 302 that is in close contact with or detachable from the fixed plate plate;
An extractor 202 installed in the center of the moving platen 302;
A first half nut 310 and a second half nut 320 disposed on both left and right sides of the upper and lower portions of the movable plate 302;
A pair is formed to constitute the first half nut 310, comprising: a first split nut 311 disposed near the second half nut 320 and a second split nut 312 disposed farther away;
The second half nut 320 is formed in a set, comprising: a third split nut 321 disposed near the first half nut 310 and a fourth split nut 322 disposed at a far side;
A drive cylinder 330 fixed to the moving platen 302 with a rod 331 connected to the first split nut 311;
A drive cylinder 340 fixed to the moving platen 302 with a rod 341 connected to the third split nut 321;
The first half nut 310 and the second half nut 320 are disposed farther from the ejector 202 based on the reference line W passing through the center, and one end of the first half nut 311 A first connection bar 370 coupled to and fixed to the fourth split nut 322 through the other end thereof so as to slide through the third split nut 321;
The first half nut 310 and the second half nut 320 are disposed farther from the ejector 202 based on the reference line W passing through the center, and one end of the third split nut 321 A second connection bar 371 coupled to and fixed to the second split nut 312 through the other end thereof so as to slide through the first split nut 311;
It is located between the drive cylinder 330 and the first split nut 311, one side is fixed to the second connection bar 371, a hollow through which the rod 331 of the drive cylinder 330 can pass freely. A support piece 353 provided with a portion 353a;
It is located between the drive cylinder 340 and the third split nut 321, one side is fixed to the first connection bar 370, a hollow through which the rod 341 of the drive cylinder 340 can pass freely. A support piece 363 provided with a portion 363a;
The first half nut 310 and the second half nut 320 are disposed closer to the extractor 202 based on a reference line W passing through the center, and one end thereof is the second split nut 312 A third connection bar 372 that is fixedly coupled to and penetrates at opposite ends to slide through both the first split nut 311 and the support piece 353;
A stop nut 354 fastened to the end of the third connecting bar 372 passing through the support piece 353;
The first half nut 310 and the second half nut 320 are disposed closer to the extractor 202 based on the reference line W passing through the center, and one end thereof is the fourth split nut 322 A fourth connection bar 373 which is fixedly coupled to and penetrated at opposite ends to slide through both the third split nut 321 and the support piece 363;
A stop nut 364 fastened to the end of the fourth connecting bar 373 passing through the support piece 363;
Half nut high-speed fastening device having a structure to prevent interference of the extractor comprising a.
delete The method according to claim 1,
A fixed piece 351 is fixed to the movable plate 302, and the driving cylinder 330 is mounted and fixed on the fixed piece 351,
A fixed piece 361 is fixed to the movable plate 302, and the driving cylinder 340 is mounted and fixed on the fixed piece 361,
The support piece 353 and the second connecting bar 371 are fixed by fastening a connecting piece 352 that presses and fixes the second connecting bar 371 to one side of the support piece 353. under,
The support piece 363 and the first connecting bar 370 are fixed by fastening a connecting piece 362 that presses and fixes the first connecting bar 370 to one side of the support piece 363. A half nut high-speed fastening device having a structure for preventing interference of an extractor, characterized in that. delete

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