KR101139596B1 - apparatus for controlling angle of dies for drawing of steel bar - Google Patents

Abstract

The present invention relates to a die angle regulating device for drawing a barrel and comprises a driving part 50 connected to a die holder 20 by a connecting rod 40, a sensor part 60 for detecting a straightness change of the bar 1, And a control unit 70 for controlling the driving unit 50 according to detection information of the sensor unit 60.
Therefore, it is possible to adjust the angle of the die 30 in accordance with the straightness change immediately after the drawing of the barrel 1, thereby making it possible to manufacture a bar having excellent straightness.

Description

BACKGROUND OF THE INVENTION 1. Field of the Invention [0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention [0001] The present invention relates to a die angle adjusting device for drawing a bar, which can adjust the angle of a die used when a bar is manufactured by a drawing process.

Drawing means that the material is passed through a machining hole of a dice and machined to the minimum cross-sectional dimension of the machining hole.

As an external force, a pulling force for pulling one end of the material and a compressive force acting on the material from the wall surface of the die act.

The drawing is usually carried out at room temperature, and a large amount of heat is generated by the deformation of the work, and the surface is processed smoothly and precisely.

The wire material, the bar material, and the pipe material can be processed through the drawing process as described above.

On the other hand, straightness of bars is an important quality variable when producing bars through drawing process.

Factors influencing the straightness of the bar are the straightness of the material before passing through the die, the die shape, the lubrication condition, and the angle of the die installation (hereinafter referred to as angle). Among them, the die angle is the straightness Is a crucial factor in determining.

Therefore, it is possible to produce a bar having excellent straightness only by appropriately adjusting the angle of the die in accordance with the straightness change of the product.

Now, we have completed the production and machining of bars and manually adjust the die angle by measuring the straightness of the final product.

Accordingly, since the die angle error can not be corrected quickly, the straightness of the product is inevitably lowered, and the die assembly is disassembled and assembled to adjust the angle of the die.

SUMMARY OF THE INVENTION Accordingly, the present invention has been made in order to solve the above-mentioned problems, and it is an object of the present invention to provide a dicing machine, The angle adjustment of the die can be performed more quickly and easily.

According to an aspect of the present invention,

A main body;

A die holder rotatably mounted on the main body and having a die;

A driving unit for rotating the die holder;

A sensor unit for detecting a bar passing through the die;

A control unit for recognizing the straightness change of the bar based on the detection result of the sensor unit and operating the driving unit according to the straightness;

.

Further, the sensor unit measures the surface velocity and the radial displacement of the bar at a position immediately after the bar has passed the dice.

The control unit may calculate the straightness of the bar from the data measured by the sensor unit, and may operate the driving unit according to the pre-bar straightness-driving unit control amount map input in advance.

Also, the controller may operate the driving unit such that a difference between data values measured by the sensor unit is minimized.

In addition, the controller may operate the driving unit such that the data values measured by the sensor unit become a target value set by an operator.

In addition, a plurality of sensor portions are provided at equal intervals around the bar.

According to the present invention as described above,

The angle of the die can be adjusted immediately in accordance with the straightness change immediately after drawing the bar, so that the optimum angle of the die can be always maintained by the quick feedback control.

Therefore, it is possible to produce high-quality bars having excellent straightness.

Further, there is no need to disassemble and assemble the dice mounting part for adjusting the angle of the dice, and the angle of the dice is automatically adjusted, so that the dice angle can be quickly and easily adjusted.

1 is a schematic view of a die angle adjusting device for drawing a barrel according to the present invention,
FIG. 2 is a detailed sectional view of the dice installed state,
Fig. 3 is a state in which the sensor unit of the present invention is installed,
4 is a schematic front view of a die angle adjusting device for drawing a barrel according to the present invention.

Hereinafter, embodiments of the present invention will be described with reference to the accompanying drawings.

The embodiment of the present invention shown in Figs. 1 and 2 includes a main body 10, a dice holder 20 rotatably mounted on the main body 10, A connecting rod 40 connected to the outer periphery of the die holder 20, a driving part 50 for pushing or pulling the connecting rod 40, a bar 50 passing through the die 30, A control unit 70 for recognizing the straightness change of the bar based on the detection result of the sensor unit 60 and operating the driving unit 50 according to the straightness, .

The main body 10 provides a place where the die holder 20 and the driving unit 50 are mounted as a part of the body of the apparatus.

A die 30 is inserted into the die holder 20 and a through hole is formed concentrically with the hole of the die 30 for passing the bar 1 through.

A cylindrical portion 20a protrudes from the rear center of the die holder 20, and the through-hole is formed through the cylindrical portion 20a.

A ring-shaped contact member 21 is inserted into the base end edge of the cylindrical portion 20a, and the outer circumferential surface of the contact member 21 is formed as a circular arc surface 21a.

Another contact member 11 is provided at the entrance of the through hole formed in the center of the main body 10 and the inner circumferential surface of the contact member 11 is formed as a circular arc surface 11a.

The arc faces 11a and 21a of the contact members 11 and 21 have the same arc center and radius of curvature.

The main body 10 is provided with the dice holder 21 so that the arc face 21a of the contact member 21 of the die holder 20 contacts the arc face 11a of the contact member 11 on the main body 10 side, The dice holder 20 is freely rotatable in all directions with respect to the arc center point of the circular arc surfaces 11a and 21a on the main body 10 when the circular arc 20 is installed.

A cover 25, which is bolted to the main body 10, is provided on the front surface of the die holder 20.

The cover 25 blocks the front edge portion of the dice holder 20, thereby preventing the dice holder 20 from being detached from the main body 10.

The contact surface between the die holder 20 and the cover 25 is also formed by the circular arc surfaces 20b and 25a having the same curvature so that the rotation of the die holder 20 is not hindered.

Although the circular arc surfaces 11a, 21a, 20b and 25a are referred to as 'circular arc surfaces' by their sectional shapes, they are actually partial spherical surfaces as the surfaces formed on the inner and outer circumferential surfaces of the annular part.

Therefore, the die holder 20 is rotatable in the radial direction (assuming that the bar 1 is a central axis) when viewed from the front in a state of being mounted on the contact member 11 of the main body 10. [

The die 30 has a machining hole formed at the center thereof for determining the cross-sectional shape and dimensions of the bar 1, and is inserted into a mounting groove formed on the front surface of the die holder 30.

A connection rod mounting portion 22 is formed at an outer portion of the dice holder 30 to connect the connection rod 40. The connection rod mounting portion 22 is formed to have a short length from the surface of the outer portion of the dice holder 30. [ (See Fig. 4), or vice versa.

The connection between the connection rod mounting portion 22 and the connection rod 40 may be via a pin, a ball joint, or the like.

The connection rod 40 transfers the driving force generated in the driving unit 50 to the dice holder 20.

The driving unit 50 may be implemented by various devices using hydraulic, pneumatic, electric, and magnetic forces.

When a hydraulic cylinder, a pneumatic cylinder, a solenoid type linear actuator, or the like is used as the driving unit 50, there is a rod (piston rod, plunger) acting as a connecting rod 40 in the driving unit 50, It is not necessary to provide the connecting rod 40.

When a motor is used as the driving unit 50, a link for connection between the gear train for deceleration and the connecting rod 40 may be additionally used.

The sensor unit 60 detects the straightness of the bar 1 immediately after passing through the dies 30 and detects the straightness of the bar 1 at a position immediately after the bar 1 passes the dice 30. [ A device for measuring the surface velocity and the radial displacement at one or more points on the main surface is used.

As the sensor unit 60, a laser Doppler velocimeter can be used to measure the surface velocity of the bar, and a distance measuring sensor can be used to measure the displacement (deflection) of the bar in the radial direction.

As shown in FIG. 3, at least one sensor unit 60 is installed around the bar 1 spaced apart from the surface of the bar 1. When two or more sensors are installed, each sensor unit 60 It is preferable that they are provided at regular intervals. For example, they may be installed at intervals of 60 占 (six pieces), 90 占 (four pieces), 120 占 pieces (three pieces), and 180 占 pieces (two pieces) in a virtual circle centering on the bar 1.

Therefore, it is possible to accurately determine the straightness and the bending direction of the bar by analyzing the positional relationship between the installed sensor units and the data measured at the respective sensor units.

3, the upper and lower sensor units 60 detect changes in the straightness of the bar in the vertical direction, and the left and right sensor units 65 detect the change in the straightness of the bar in the left- You can detect straightness changes.

The control unit 70 recognizes the straightness change of the bar by the measurement signal transmitted from the sensor unit 60 and determines the control amount based on the control map (the determination of the driving unit control amount according to the bar straightness) 50).

The control unit 70 may control the operation of the driving unit 50 so as to minimize the difference between the measured values (surface speed and displacement) from the respective sensor units 60 (in the direction of 0).

As a result, the amount of deflection of the bar becomes gradually converged to zero, so that it is possible to produce a bar having excellent straightness with little occurrence of warpage.

The control unit 70 may control the operation of the driving unit 50 such that the values measured by the respective sensor units 60 are preset by the operator.

The target value can be input by an operator through an input device provided in the control unit 70. [

That is, by inputting the target value, it is possible to perform a process of imparting a constant curvature to the bar 1.

Meanwhile, in order to adjust the angle of the die 30 in an optimal state corresponding to the straightness and the bending direction of the bar 1 determined by the controller 70 as described above, the die holder 20 is freely rotated Should be able to do.

Therefore, as shown in FIG. 4, the connecting rod mounting portion 22 is formed at one position on the vertical axis passing through the center of the dice holder 20 and one position (connecting rod mounting portion 22 ') on the horizontal axis, And connect the connection rods 40, respectively. Of course, a driving unit 50 for driving each connecting rod 40 is also provided.

The connection rod mounting portions 22 and 22 'and the connection rods 40 are connected via ball joints 80 and 80' so that the rotation of the dice holder 20 due to the behavior of any one of the connection rods, And the connecting rod mounting portion.

Now, the operation and effect of the present invention will be described.

During the withdrawal of the barrel 1, the sensor unit 60 transmits measurement data (surface velocity, displacement) to the control unit 70 in real time.

The controller 70 calculates the straightness based on the data measured by the sensor unit 60 or directly uses the measurement data to operate the driving unit 50 accordingly.

That is, it is possible to previously map the control amount of the driving unit 50 according to the calculated straightness, and to control the driving unit 50 according to the straightness according to the prepared map.

In addition, when the measurement data is directly used, the operation of the driving unit 50 can be controlled such that a difference between data values between the sensor units is zero.

Also, it is possible to control the operation of the driving unit 50 such that the data values measured by the respective sensor units converge to a predetermined value (a target value set by an operator).

In this case, after the data value converges to the target value, the value is maintained, so that it is possible to impart curvature to the rod 1 pulled out as desired.

It is needless to say that the control unit 70 is pre-programmed to execute the control logic.

The control methods are different in that the control unit 70 actually calculates the straightness by the measurement data and directly uses the measurement data, and eventually controls the operation of the driving unit according to the straightness of the bar, As shown in FIG.

When the connection rod 40 is pushed or pulled by the driving part 50, the connection rod mounting part 22 is pushed or pulled so that the dice holder 20 contacts the contact surface of the contact members 11 and 21 11a, 21a, and the angle of the die 30 is adjusted.

Therefore, the straightness defect of the bar is immediately eliminated.

As described above, the straightness of the bar is measured in real time, and the straightness of the bar is always maintained in an optimal state by adjusting the angle of the die 30 immediately by the feedback control method.

Therefore, it is possible to improve the straightness of the bar steel to be drawn and improve the quality.

In addition, since the above-described die angle adjustment is automatically performed by the sensor unit 60, the control unit 70 and the driving unit 50, and the disassembly and assembly of the die attaching unit is not necessary when adjusting the die angle, And can be easily done.

Further, when the present invention is applied to a drafting apparatus, curvature can be imparted to a bar in a desired direction.

10: main body 11: contact member
20: Dice holder 20a:
21: contact member 11a, 21a, 20b, 25a:
22, 22 ': connection rod mounting portion 30:
40: connection rod 50:
60, 65: sensor unit 70:
80, 80 ': ball joint

Claims (6)

A main body;
A die holder rotatably mounted on the main body and having a die;
A driving unit for rotating the die holder;
A sensor unit for detecting a bar passing through the die;
A control unit for recognizing the straightness change of the bar based on the detection result of the sensor unit and operating the driving unit according to the straightness;
/ RTI >
The sensor unit is installed at equal intervals around the bar to measure the surface velocity and the radial displacement of the bar at a position immediately after the bar has passed the dice,
Wherein the control unit operates the driving unit in a direction in which a difference between data values of the surface velocity measured by the sensor units becomes zero. delete The method according to claim 1,
Wherein the control unit calculates the straightness of the bar from the data measured by the sensor unit, and operates the driving unit in accordance with the pre-inputted straightness-driver control amount map input in advance. delete The method according to claim 1,
Wherein the control unit operates the driving unit so that the measured data values of the sensor unit become the target value set by the operator. delete

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