KR102313231B1 - Automatic aligning device for drawing dies to prevent torsion of Linear motion guide rail shape material - Google Patents

Abstract

The present invention relates to an automatic aligning device for drawing dies to prevent torsion of shape material for a linear motion guide rail. The technical gist of the present invention is as follows. When the shape material is drawn out, arc-shaped inclined surfaces of a die housing (including a cemented carbide die for cold drawing) correspond to each other based on a hemispherical slip contact surface of a die block and come to slide or slip slightly in a vertical or circumferential direction. The die block and die housing are assembled at an outer side end (fee end) of an opening by a link bolt having an elastic spring so that a center axis against distortion at the beginning of drawing or during drawing is always maintained or restored. Therefore, this fundamentally prevents one-way bending of the shape material caused by a long axis during drawing (i.e., long strands bent to either side), a change in straightness (i.e., wave generation), or distortion in the circumferential direction based on the axis, enabling the implementation of ultra-precision cold processing. That is, the present invention provides excellent product quality due to high-precision drawing performance when drawing out release material, processability can be improved by the shape material with a non-deformation structure. Moreover, since conventional several rounds of straightness setting work carried out during drawing and a correcting step dedicated to multi-stage release material after drawing are fundamentally excluded, workability, productivity, and economic feasibility can be greatly improved.

Description

Automatic aligning device for drawing dies to prevent torsion of Linear motion guide rail shape material

According to the present invention, when the shape material is drawn, the arc-shaped sloped surfaces of the die housing (including the cemented carbide dies for cold drawing) are slightly slid or slip (slip) in the vertical or circumferential direction based on the hemispherical slip contact surface of the die block. However, as for the die block and the die housing, the outer end (free end) of the opening is assembled by a link bolt having an elastic spring so that the center axis against distortion at the beginning of drawing or during drawing is always maintained or restored. Super-precision cold working is realized while fundamentally preventing the occurrence of one-way bending of the shape material caused by the long axis during drawing (long strands are bent to either side), straightness deformation (wave generation), or distortion in the circumferential direction based on the axis. It relates to an automatic aligning device for drawing dies for preventing torsion of a linear motion guide rail-shaped material, characterized in that it becomes possible.

That is, the present invention has excellent product quality due to high-precision drawing performance when drawing a release member, and improved workability by a shape member with a non-deformation structure. It is characterized in that workability, productivity, and economic efficiency are greatly improved by fundamentally excluding the correction step for multi-stage mold release materials after drawing.

In general, drawing is a deformation processing method of metal to make a wire or a thin tube, and by pulling a wire of a predetermined thickness to the other side through a die or a die, the cross section according to the shape of the hole in the die It refers to the operation of pulling with a shaped wire rod.

Meanwhile, during the drawing process, an axial tensile force is applied to the material as a drawing load while the material passes through the drawing die.

Accordingly, FIG. 5 is a graph showing a drawing load with respect to a stroke during a drawing process using a conventional drawing die.

That is, section 1 in FIG. 5 means that the pointed material first comes into contact with the drawing die and reaches the bearing part, and section 2 is a section in which all pointing parts pass through the bearing part in a normal state and reach a stable drawing process. it means.

In this case, section 3 means the case where the end of the material approaches or passes the bearing, and section 4 means the state where the material exits the die.

Based on this, the load is abruptly dissipated in the 4th section where the material comes out of the die.

That is, due to the sudden disappearance of the pull-out load in section 4, recoil occurs in the material, which causes bending or bent shape of the material, which causes defects. .

In addition, if the die center in section 2 does not match, continuous axial distortion occurs during the drawing process, causing continuous deformation, and improvement is also required at the same time.

1. Republic of Korea Patent Publication No. 10-1583629 (registered on Apr. 2016)

The present invention is to solve the above problems, and the technical gist of the present invention relates to an automatic drawing die aligning device for preventing torsion of a linear motion guide rail shape member, and a die housing (cold The arc-shaped inclined surfaces of the carbide dies for pultrusion processing) are allowed to slide or slip (slip) slightly in the vertical or circumferential direction while corresponding to each other, but the die block and the die housing are opened by a link bolt having an elastic spring. An object of the present invention is to provide that the outer end (free end) is assembled so that the center axis against distortion in the initial stage of drawing or during drawing is always maintained or restored.

The present invention provides ultra-precision while fundamentally preventing the occurrence of unidirectional bending of the shape material (long strands bent to either side), straightness deformation (wave generation), or distortion in the circumferential direction of the axis caused by the long axis during drawing. An object of the present invention is to provide a way to enable cold working to be implemented.

In other words, the present invention has excellent product quality due to high-precision drawing performance during drawing of a release member, and improved workability by a shape member with a non-deformation structure. The purpose of this is to provide greatly improved workability, productivity, and economic feasibility by fundamentally excluding the correction step dedicated to multi-stage mold release members after overdrawing.

In order to achieve this object, in the present invention, the drawn cross-section is processed differently according to the step-by-step shape of the shape material and selectively mounted, but the drawn cross-section is a side cross-section from the entrance 110 to the outlet 120 where the shape material is inputted. The cemented carbide die 100 is formed to form a mortar shape, and a coupling jaw 130 is provided at the end of the outlet 120; A mounting groove 210 is provided so that the cemented carbide die 100 is mounted therein, and the mounting groove 210 has an insertion hole 211 and a discharge hole 212 formed on one side and the other side, respectively, and the discharge The ball 212 and the dice case 200 so that the coupling jaw 130 of the carbide die is mounted while corresponding; A receiving groove 310 is provided so that the dice case 200 is mounted therein, and the receiving groove 310 has an inner entrance hole 311 and an opening hole 312 formed on one side and the other side, respectively, and the inner An assembling flange 320 having a plurality of fastening holes 321 is formed outside the end of the inlet 311 side, and a hemispherical slip contact surface 330 is formed on the outer peripheral surface of the opening hole 312 side ( 300) and; In the form of a hollow tube having a space portion 410 formed therein, a coupling flange 420 is formed on one side to be screwed to one surface of the assembly flange 320 side of the die housing, and a receiving groove through the inner hole 311 The end pressing surface 430 of the tube diameter inserted into the 310 includes a fixing guide 400 for pressing and fixing the rear surface (the inserted rear surface) of the die case 200; A storage container 510 is provided so that the slip contact surface 330 side of the die housing 300 is inserted and mounted, and the storage container 510 has a coupling hole 511 and a communication hole 512 on one side and the other side, respectively. ) is formed, and on the inner periphery of the communication hole 512 side, an arc-shaped inclined surface 520 is formed so as to correspond to the slip contact surface 330 of the die housing (when the arc-shaped inclined surface is in close contact with the slip contact surface, it is up and down relative to the axis) Sliding contact or slip is induced during microfluid flow in the left and right and circumferential directions or in all directions), and a plurality of support holes 530 are formed at the end of the coupling hole 511 side, and a link bolt inserted based on the support hole The long shaft fixing bolt 542 protrudes outward from the sphere 541 of the 540, but the fixing bolt 542 penetrates the fastening hole 321 of the die housing and has a plurality of high-tensile elastic springs on the axial outer circumferential surface. When the 543 is mounted, a plurality of elastic springs 543 divided based on the assembly flange 320 are mutually expanded and contracted and the drawing axis of the shape material for distortion is restored to the center point axis at all times, and the die block can be drawn out 500 this; made up of

Accordingly, the die block 500 is provided with an air levitation induction module 550 of the die housing on one side, and the air flotation induction module 550 has a plurality of air supply tabs 551 formed therein, and the air supply The tab 551 is connected as a through-circuit with the front end conduit 552, the rear end conduit 553, and the cross conduit 554 for pressurization, so that the slip contact surface 330 and the sloped surface 520 and the container 510. It is formed so that high-pressure air containing lubricating oil is supplied between the inner and outer peripheral surfaces of the die housing 300 (rubber packings are inserted into the front and rear ends to ensure airtightness).

That is, the slip contact surface of the die housing is formed so that even if a fine lifting (gap) occurs or is in close contact with the sloped surface of the die block, it is formed so that the slip occurs smoothly, not with strong compression, but with a light touch.

This is to facilitate the restoration to the centrifugal shaft according to the rotation of the shaft while pushing forward at all times while making it possible to buffer the shock when the initial shape material is pulled at a small distance apart to facilitate pulling.

In addition, the die housing 300 has a longitudinal outer circumferential surface between the assembly flange 320 and the slip contact surface 330 (the outer circumferential cross-sectional diameter in this section is 0.5 to 2 mm smaller than the inner diameter of the housing of the die block. Formation), it is preferable that the curved body 340 capable of reinforcing the support of the pivot point C when flowing in the circumferential or free direction or up and down direction based on the drawing axis is formed.

Accordingly, the die housing 300 is located on one side of the curved body 340 on the longitudinal outer circumferential surface between the assembly flange 320 and the slip contact surface 330 (the opposite side to the direction in which the die housing is inserted into the housing - the coupling hole side). When the mast groove 350 is formed and high-pressure air is injected from the rear end pipe 553 extending from the air supply tab 551 , the die housing is strongly pushed in the moving direction of the drawn material.

This is so that the die housing can continue to maintain the drawing axis with respect to the pivot point without being pulled back.

And, the through-diameter of the rear end conduit 553 is formed to be 1.5 to 2 times wider than the through-diameter of the front end conduit 552, so that the pushing force from the back to the front acts more strongly than the gap at the front. It is formed so that the reference of the pivot point (C) is made based on the slip contact surface and the inclined surface.

As described above, in the present invention, when the shape material is drawn out, the arc-shaped sloped surfaces of the die housing (including the cemented carbide dies for cold drawing) based on the hemispherical slip contact surface of the die block are slightly slid or slip (slip) in the vertical or circumferential direction while corresponding to each other. sliding), but the die block and the die housing are assembled at the outer end (free end) of the opening by a link bolt having an elastic spring so that the center axis against distortion at the beginning of drawing or during drawing is always maintained or restored It works.

The present invention provides ultra-precision while fundamentally preventing the occurrence of unidirectional bending of the shape material (long strands bent to either side), straightness deformation (wave generation), or distortion in the circumferential direction of the axis caused by the long axis during drawing. There is an effect that cold working is implemented.

That is, in the present invention, the quality of the product is excellent due to the high-precision drawing performance when the release material is drawn, and the workability is improved by the shape material of the deformation-free structure.

In addition, the present invention has the effect of greatly improving workability, productivity, and economic feasibility by fundamentally excluding the secondary straightness setting work performed several times after drawing and the correction step dedicated to the multi-stage release member after drawing compared to the prior art.

1 is an exemplary view of a drawing die automatic alignment device for preventing torsion of a linear motion guide rail shape material according to the present invention;
Figure 2 is a side cross-sectional view of Figure 1;
Figure 3 is an exemplary view of the use state of Figure 1,
4 is a side cross-sectional view showing a cemented carbide die and a die case according to the present invention;
5 is a side cross-sectional view showing a die housing and a fixing guide according to the present invention;
6 is a side cross-sectional view showing a die block and a link bolt according to the present invention;
7 is a table of changes in the pulling load occurring during the conventional drawing process.

Hereinafter, the present invention will be described in more detail with reference to the accompanying drawings.

First, as shown in FIGS. 1 to 6 , the present invention is largely composed of a cemented carbide die 100 , a die case 200 , a die housing 300 , a fixing guide 400 , and a die block 500 .

Accordingly, the cemented carbide die 100 is formed so that the drawn cross-section is processed differently according to the step-by-step shape of the shape material and selectively mounted.

At this time, the drawing cross-section is formed so that a lateral cross-sectional shape from the entrance 110 to which the shape material is input to the outlet 120 forms a mortar shape, and a coupling jaw 130 is provided at the end of the outlet 120 side. do.

That is, the coupling jaw is formed so as to be fitted and assembled while corresponding to the discharge hole of the dice case to be described later as an uneven protruding to the outside.

At this time, the coupling jaw and the discharge hole are formed such that a key and a key groove are respectively formed to prevent rotation in the circumferential direction with respect to the axis when assembling each other.

Accordingly, the die case 200 is formed to be provided with a mounting groove 210 so that the cemented carbide die 100 is mounted therein.

At this time, the mounting groove 210 is formed such that an insertion hole 211 and a discharge hole 212 are formed on one side and the other side, respectively, and the coupling jaw 130 of the cemented carbide die is mounted while corresponding to the discharge hole 212 . do.

That is, the die case is a type of holder bushing that holds the carbide dice, and is formed so that the load applied to the carbide dice is not directly transferred to the die housing to be described later (drawing stress distribution), and is formed to facilitate exchange and replacement of the carbide dies, If the case itself is damaged, it is formed so that only this part can be exchanged.

On the other hand, the die housing 300 is formed to be provided with a receiving groove 310 so that the die case 200 is mounted therein.

At this time, the receiving groove 310 has an inner hole 311 and an opening hole 312 formed on one side and the other side, respectively, and an assembly flange having a plurality of fastening holes 321 on the outer side of the inner hole 311 side end. 320 is formed.

Accordingly, a hemispherical slip contact surface 330 is formed on the outer circumferential surface of the opening hole 312 side of the receiving groove, so that it corresponds to a sloping surface to be described later, and the fine rotation of the die housing together with the rotation axis of the curved body 340 is smoothly performed. formed to be able to

In addition, the fixing guide 400 is a hollow tube shape with a space 410 formed therein, and a coupling flange 420 is formed on one side to be screwed with respect to one surface of the assembly flange 320 side of the die housing. .

At this time, the end pressing surface 430 of the tube diameter inserted into the receiving groove 310 through the inner hole 311 is formed to support and fix the rear surface (inserted rear surface) of the die case 200 by pressing.

Accordingly, the die block 500 is formed to be provided with a housing container 510 so that the slip contact surface 330 side of the die housing 300 is inserted and mounted.

At this time, the housing container 510 has a coupling hole 511 and a communication hole 512 formed on one side and the other side, respectively, and the inner periphery of the communication hole 512 side corresponds to the slip contact surface 330 of the die housing. An arc-shaped gradient surface 520 is formed.

That is, the arc-shaped inclined surface induces sliding contact or sliding while the die housing smoothly flows in the vertical, left, right and circumferential or all directions free directions based on the axis when the arc-shaped inclined surface is in close contact with the slip contact surface.

Accordingly, a plurality of support holes 530 are formed at the end of the coupling hole 511 so that the long shaft fixing bolt 542 protrudes outward from the sphere 541 of the link bolt 540 inserted based on the support hole. is formed

At this time, a plurality of high-tensile elastic springs 543 are mounted on the axial outer circumferential surface of the fixing bolt 542 through the fastening hole 321 of the die housing.

These elastic springs are divided based on the assembly flange 320, and while mutually expanding and contracting based on the washer or snap ring in contact with the assembly flange, the drawing axis of the shape material for the distortion of the axis (the same axis of the die housing based on the drawing axis) It is formed so as to be able to be drawn out while always restoring and returning to the center point axis.

Accordingly, the die block 500 is formed such that the air flotation induction module 550 of the die housing is provided on one side.

At this time, the air levitation induction module 550 has a plurality of air supply tabs 551 are formed, and the air supply tab 551 includes a pressurizing front end conduit 552 , a rear end conduit 553 , and an intersecting conduit 554 . ) and is connected to a through circuit so that high-pressure air containing lubricating oil is supplied between the slip contact surface 330 and the inclined surface 520 , and the inner and outer peripheral surfaces of the container 510 and the die housing 300 .

Accordingly, a rubber packing is inserted between the inner and outer peripheral surfaces of the housing container 510 and the die housing 300 and between the slip contact surface 330 and the inclined surface 520, thereby preventing leakage of high-pressure air and ensuring airtightness. formed to be

That is, the slip contact surface of the die housing is formed so that even if a fine lifting (gap) occurs or is in close contact with the sloped surface of the die block, it is formed so that the slip occurs smoothly, not with strong compression, but with a light touch.

This is to make it easier to restore and return to the centrifugal shaft according to shaft rotation while always pushing forward while always pushing forward and forming a small gap to facilitate pulling and centering when pulling the initial shape material. .

In addition, the die housing 300 has a longitudinal outer circumferential surface between the assembly flange 320 and the slip contact surface 330 to reinforce the support of the pivot point C when flowing in the circumferential or free direction or up and down direction based on the drawing axis. It is preferable that the curved body 340 is formed.

At this time, the outer circumferential cross-sectional diameter in the longitudinal section between the assembling flange 320 and the slip contact surface 330 is formed to have a slightly narrower diameter than the inner diameter of the housing of the die block by 0.5 to 2 mm. This is to ensure that a predetermined rotation or flow can be smoothly secured compared to the drawing reference axis.

Accordingly, the die housing 300 is located on one side of the curved body 340 on the longitudinal outer circumferential surface between the assembly flange 320 and the slip contact surface 330 (the opposite side to the direction in which the die housing is inserted into the housing - the coupling hole side). When the mast groove 350 is formed and high-pressure air is injected from the rear end pipe 553 extending from the air supply tab 551 , the die housing is strongly pushed in the moving direction of the drawn material.

This is so that the die housing can continue to maintain the drawing axis with respect to the pivot point without being pulled back.

And, the through-diameter of the rear end conduit 553 is formed to be 1.5 to 2 times wider than the through-diameter of the front end conduit 552, so that the pushing force from the back to the front is stronger than the gap at the front. .

The present invention is not limited to the specific preferred embodiments described above, and without departing from the gist of the present invention as claimed in the claims, anyone with ordinary skill in the art to which the invention pertains can implement various modifications. Of course, such modifications are intended to be within the scope of the claims.

100 ... Carbide Dies 110 ... Entrance
120 ... outlet 130 ... joint jaw
200 ... die case 210 ... mounting groove
211 ... insertion hole 212 ... discharge hole
300 ... die housing 310 ... storage groove
311 ... internal hole 312 ... open hole
320 ... assembly flange 321 ... fastener
330 ... slip contact surface 340 ... curved body
350 ... Mast groove 400 ... Fixed guide
410 ... space part 420 ... coupling flange
430 ... pressurized surface 500 ... die block
510 ... storage bin 511 ... joiner
512 ... plumb hole 520 ... draft surface
530 ... support hole 540 ... link bolt
541 ... Sphere 542 ... Fixing bolt
543 ... elastic spring 550 ... air levitation induction module
551 ... air supply tap 552 ... shear pipe
553 ... back end pipe road 554 ... cross pipe road

Claims (3)

The drawn cross section is processed differently according to the step-by-step shape of the shape material so as to be selectively mounted. a cemented carbide die 100 such that a coupling jaw 130 is provided at the end of the outlet 120;
A mounting groove 210 is provided so that the cemented carbide die 100 is mounted therein, and the mounting groove 210 has an insertion hole 211 and a discharge hole 212 formed on one side and the other side, respectively, and the discharge The ball 212 and the dice case 200 so that the coupling jaw 130 of the cemented carbide die is mounted while corresponding;
A receiving groove 310 is provided so that the dice case 200 is mounted therein, and the receiving groove 310 has an inner entrance hole 311 and an opening hole 312 formed on one side and the other side, respectively, and the inner An assembling flange 320 having a plurality of fastening holes 321 is formed outside the end of the inlet 311 side, and a hemispherical slip contact surface 330 is formed on the outer peripheral surface of the opening hole 312 side ( 300) and;
In the form of a hollow tube having a space portion 410 formed therein, a coupling flange 420 having a fixing hole 421 on one side is formed so as to be screwed with respect to one surface of the assembly flange 320 side of the die housing, but the inner hole The end pressing surface 430 of the tube diameter inserted into the receiving groove 310 through 311 includes a fixing guide 400 for pressing and fixing the back surface of the die case 200;
A storage container 510 is provided so that the slip contact surface 330 side of the die housing 300 is inserted and mounted, and the storage container 510 has a coupling hole 511 and a communication hole 512 on one side and the other side, respectively. ) is formed, and an arc-shaped inclined surface 520 is formed on the inner periphery of the communication hole 512 side to correspond to the slip contact surface 330 of the die housing, and a plurality of support holes are formed at the end of the coupling hole 511 side. 530 is formed so that the long shaft fixing bolt 542 protrudes outward from the sphere 541 of the link bolt 540 inserted with reference to the support hole, and the fixing bolt 542 is the fastening hole of the die housing ( 321), when a plurality of high-tensile elastic springs 543 are mounted on the axial outer circumferential surface, the plurality of elastic springs 543 divided based on the assembly flange 320 are mutually expanded and contracted and the drawing axis of the shape material for distortion A die block 500 that allows it to be drawn while restoring and returning to the normal axis of the center point;
An automatic aligning device for drawing dies for preventing torsion of a linear motion guide rail-shaped material, characterized in that it is composed of: According to claim 1, wherein the die block (500)
An air levitation induction module 550 of the die housing is provided on one side, and the air levitation induction module 550 has a plurality of air supply tabs 551 formed, and the air supply tab 551 is a shear pipe for pressurization. 552 and the rear end conduit 553 and the cross conduit 554 are connected as a through-circuit with the slip contact surface 330 and the inclined surface 520, and the inner and outer circumferential surfaces of the housing container 510 and the die housing 300. Automatic aligning device for drawing dies for preventing torsion of linear motion guide rail shaped materials, characterized in that high-pressure air containing lubricating oil is supplied between them. According to claim 2, wherein the die housing (300)
On the outer circumferential surface in the longitudinal direction between the assembly flange 320 and the slip contact surface 330, a curved body 340 capable of reinforcing the support of the pivot point C when flowing in the circumferential or free direction or up and down direction based on the drawing axis is formed. An automatic aligning device for drawing dies for preventing torsion of linear motion guide rail shaped materials.

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