KR100961779B1 - Air cooled capstan of drawing machine - Google Patents

Abstract

PURPOSE: An air-cooled capstan of a wire drawing machine is provided to prevent the contraction of steel wire by reeling the wire in a wiring bobbin after cooling. CONSTITUTION: An air-cooled capstan of a wire drawing machine comprises a shaft(310), a cover(320), and a winding unit(330). The winding unit is composed of an open surface, a winding surface, and a discharging side. An intake hole is formed on the center of the open surface. The winding surface is behind combined of the open surface. A steel wire is reeled in the external side of the winding surface. The discharging side is expanded from the winding surface from the guide groove of the cover. A plurality of discharge holes is formed on the discharge side.

Description

Air cooled capstan of drawing machine

The present invention relates to an air-cooled capstan of a drawing machine, and more particularly, to an air-cooled capstan of a drawing machine which allows the steel wire to be air-cooled by using the wind generated by the rotational force of the capstan being drawn out while being drawn out.

In general, the drawing process refers to the process of extending the wire such as stainless wire, copper wire, steel wire to a wire having a certain diameter and roundness so that it can be used in other processes.

Wire drawing is a cold process that increases wire rods such as stainless steel to wire rods with small diameters. After drawing, roundness must be good, surface roughness must be good, and the diameter of the cross section must be uniform.

Hereinafter, with reference to the accompanying Figure 1 will be briefly described for the drawing machine for drawing the steel wire.

FIG. 1 is a schematic view showing a drawing machine. The wire W coated with copper or copper alloy on an iron or iron alloy wire supplied from a supply bobbin 20 mounted on a supply table 10 is guided as shown. Guided to the roller 30 is transferred to the wet drawing tank 40 filled with lubricating oil.

At this time, the drawer cone 50 having a plurality of steps is installed inside the wet drawer 40, the steel wire (W) transferred to the wet drawer 40 is wound several times in the drawer cone (50) After it passes.

At this time, a plurality of drawing die device 60 is installed between the drawing device cone 50, the steel wire (W) is passed through the drawing die device 60, the stepwise drawing is made.

Thereafter, the fresh steel wire W 'is guided to the withdrawal capstan 70 to sequentially pass through the upper roller 81 and the tension roller 82 and finally wound in the winding bobbin 90 to draw the wire for the wire saw. Is completed.

However, the conventional drawing capstan 70 installed in the above-described drawing machine has the following problems.

In the process in which the steel wire W 'is drawn by the drawing capstan 70, high temperature heat is generated in the steel wire W' due to frictional force.

Then, when the steel wire (W ') that generates a high temperature heat is wound in the winding bobbin as it is, the winding bobbin 90 is deformed after a time has elapsed.

That is, in a state in which the steel wire W 'having high temperature heat is wound around the winding bobbin 90, when the heat of the steel wire W' cools down over time, the wound steel wire W 'contracts.

In this process, the contracting force of the steel wire (W ') with respect to the winding bobbin (90) acts not only to cause deformation of the winding bobbin 90, but also the tension of the steel wire (W') is not constant, the line in the next process When unpacking, the problem is that it is not solved well but is disconnected.

Of course, in order to solve the above problems, a water cooling type was formed to form a flow path inside the capstan 70 and cool the heat of the capstan 70 as water flows along the flow path. The necessity of various equipments causes a large manufacturing cost, as well as difficulties in maintaining the equipment.

The present invention has been made to solve the above problems, an object of the present invention is to cool the steel wire drawn by using the wind generated by the rotational force of the capstan to prevent the deformation of the winding bobbin winding the steel wire while the structure is simple It is to provide an air-cooled capstan of a fresh machine to maintain the tension of the.

To this end, the shaft is rotated by a drive motor; disposed on the front end of the shaft, the guide groove is formed therein, the cover is formed in the opening hole in the front; coupled to the end of the shaft is disposed in the guide groove of the cover, The part exposed through the opening hole is configured to include a winding part: the winding wire is wound, the winding part, the exposed surface is formed in the suction hole in the center, and the portion of the steel wire is wound on the outer peripheral surface is coupled to the rear It provides a winding surface to provide an air-cooled capstan of the fresh machine, characterized in that consisting of a discharge surface extending from the winding surface to the guide groove of the cover and formed with a plurality of discharge holes communicating with the guide groove of the cover.

At this time, it is preferable that a plurality of wings are further formed along the periphery of the suction hole on the rear surface of the exposed surface.

In addition, it is preferable that the inclined portion inclined toward the winding surface is formed on the inner side surface of the edge forming the opening hole of the cover.

At this time, it is preferable that the guide portion formed inclined along the inclined portion is formed in a portion corresponding to the inclined portion of the winding surface.

According to the air-cooled capstan of the fresh machine according to the present invention has the following effects.

First, the wind is generated by using the rotational force of the capstan for drawing the fresh steel wire, and the structure for cooling the steel wire is simplified by cooling the steel wire wound on the capstan using the wind.

Second, after cooling of the steel wire, as the steel wire is wound around the take-up bobbin, the shrinkage action of the steel wire does not occur even over time.

Accordingly, there is an effect that the tension of the steel wire can be kept constant without deformation of the winding bobbin due to the shrinkage of the steel wire.

Hereinafter, an air-cooled capstan of a fresh machine according to a preferred embodiment of the present invention will be described with reference to FIGS. 2 to 5b.

Attached Figure 2 schematically shows the front of the drawing machine is installed air-cooled capstan, the body 100 constituting the appearance of the drawing machine, the die device 200, the air-cooled capstan 300, the guide roller 400 and And a spooler 500.

Body 100 protects various parts, and constitutes the appearance of the fresh machine.

At this time, one side of the body 100 is provided with a supply bobbin B wound around the steel wire (W) to be drawn.

In addition, an indicator 101 is displayed above the body 100 to display the progress of the fresh machine.

In addition, the body 100 is composed of a fresh wire 110, the wire (W) is drawn, and a guide 120 for guiding and winding the wire (W ') is completed.

At this time, the fresh portion 110 and the guide portion 120 is preferably partitioned by a partition wall.

Next, the die apparatus 200 serves to draw the steel wire W supplied from the supply bobbin B, and is installed in the drawing unit 110.

The dice device 200 includes a plurality of dice 210 and a dice holder 220 in which the dice 210 are installed.

At this time, the die 210 is coupled to a tip (not shown) to be fresh while passing the steel wire (W).

At this time, the tips coupled to each of the dice 210 are formed to have a hole having a different diameter.

On the other hand, the dice device 200 is preferably provided in plurality, a pair of guide capstan (C) is disposed in each dice device (200).

The guide capstan (C) serves to guide the steel wire (W) provided from the supply bobbin (B) to the dice 210 of the dice device 200, one each of the upper and lower portions of the die device 200 It is installed and provided in pairs.

Next, the air-cooled capstan 300 serves to draw the steel wire (W ') drawn from the die device 200 and to wind the spooler 500 through the guide roller 400, the guide portion of the body 100 It is installed at 120.

At this time, the air-cooled capstan 300 is installed to be rotated by a separate drive motor (not shown) to have a driving force to draw the steel wire (W), fresh wire (W ') using the wind formed by the rotational force (W') ) Also serves to cool.

The air-cooled capstan 300 is configured to include a shaft 310, a cover 320, and a winding portion 330.

The shaft 310 receives the rotational force of the drive motor to rotate the winding unit 330 and is connected to the drive motor.

At this time, the shaft 310 is protected by the housing 311. A bearing 312 is installed between the housing 311 and the shaft 310 to smoothly rotate the shaft 310.

In addition, the cover 320 serves to guide the wind formed by the rotational force of the winding unit 330 to the winding unit 330 and is fixed to the front end of the housing 311.

At this time, the shape of the cover 320 is preferably made of a circular shape, the guide groove 321 having a predetermined space is formed therein.

The guide groove 321 serves to guide the wind formed backward by the rotational force of the winding unit 330 to blow back to the winding unit 330 side.

To this end, the inner surface of the cover 320 forming the guide grooves 321 are all formed in a blocked state so that the wind is guided forward after the impact of the wind, the front of the cover 320 is discharged to the wind hit the inner surface It is made of an opening hole 322 that is open to allow.

At this time, the inner surface of the edge forming the opening hole 322 of the cover 320 is preferably made of an inclined portion 322a inclined toward the winding portion 330.

That is, since the inclined portion 322a is formed to be inclined toward the winding surface to be described later, the discharged wind may be guided to the inclined portion 322a to be immediately discharged to the winding surface.

Accordingly, the cooling efficiency for the steel wire W 'wound on the winding surface can be increased.

Next, the winding unit 330 serves to draw and transfer the completed steel wire (W ') to the guide roller 400, and to cool the steel wire (W') by using the wind obtained while rotating. .

The winding part 330 is axially coupled to the tip of the shaft 310, a part of which is installed to be disposed in the guide groove 321 of the cover 320.

In this case, the winding unit 330 will be described in detail as follows.

The winding portion 330 includes an exposed surface 331, a winding surface 332, and a discharge surface 333.

The exposed surface 331 constitutes a front side of the winding part 330, and is preferably formed in a disc shape.

At this time, the exposed surface 331 is a portion exposed from the cover 320, the suction hole 331a is formed in the center.

The suction hole 331a is a part for smoothly rotating the winding part 330 by allowing the outside air to flow into the winding part 330 when the winding part 330 rotates.

At this time, it is more preferable that a plurality of wings 331b is formed on the rear surface of the exposed surface 331.

The wing 331b serves to increase the cooling efficiency for the steel wire (W ') by allowing the wind to be generated more effectively during the rotation of the winding unit (330).

In this case, the wings 331b are formed in plural along the periphery of the suction hole 331a of the exposed surface 331 as shown in FIG. 5A, and protrude from the rear surface of the exposed surface 331 as shown in FIG. 5B. It is formed in the form.

At this time, the shape of the wing 331b is not limited, and may be provided in various forms.

In addition, the winding surface 332 is a portion where the fresh wire W 'is wound when the winding part 330 is rotated, and is coupled to the rear surface of the exposed surface 331.

In this case, the winding surface 332 is provided in a flat shape, and corresponds to a portion exposed to the outside of the cover 320.

At this time, it is preferable that the guide portion 332a formed to be inclined along the inclined portion 322a is formed at an end of the winding surface 332 corresponding to the inclined portion 322a of the cover 320.

That is, the guide part 332a is to allow the wind supplied from the guide groove 321 of the cover 320 to be efficiently discharged to the winding surface 332 together with the inclined part of the cover 320.

The discharge surface 333 blows the wind formed by the rotation of the outside air and the winding unit 330 introduced through the suction hole 331a of the exposed surface 331 to the guide groove 321 of the cover 320. It plays a role and is formed integrally with the winding surface 332.

At this time, the discharge surface 333 is preferably formed to be inclined so that the space with the guide groove 321 can be efficiently secured.

At this time, the discharge surface 333 is formed with a plurality of discharge holes (333a) that is a passage through which the outside air and wind can be discharged to the guide groove 321.

Next, the guide roller 400 serves as a guide for transferring the steel wire (W ') drawn and cooled by the air-cooled capstan to the spooler 500, it is installed in a plurality of guides 120 of the body 100 do.

Next, the spooler 500 is a portion in which the steel wire after the drawing is completed is finally wound, and is installed in the guide portion of the body.

At this time, the spooler 500 is installed to be rotated by the drive motor 510.

Hereinafter, the operation of the drawing machine including the air-cooled capstan will be described.

When the drawing machine starts to drive, the driving motors installed on the drawing machine rotate, and the steel wire W wound around the supply bobbin B moves the guide capstan C of the drawing part 110 and the die device 200. The wire is drawn into steel wire W 'having a predetermined diameter.

Subsequently, the steel wire (W ') is drawn is drawn to the guide portion 120 of the body 100 by the air-cooled capstan 300.

At this time, the steel wire (W ') is wound on the winding surface 332 of the air-cooled capstan 300 several times, and then transferred to the guide roller 400.

In this process, the winding part 330 is rotated by the shaft 310 rotated by the driving motor, and the winding part 330 rotated while sucking the outside air through the suction hole 331a of the exposed surface 331. Generates wind

The wind is discharged to the guide groove 321 of the cover 320 through the discharge hole 333a formed in the discharge surface 333 of the winding unit 330.

Thereafter, the discharged wind hits the inner surface of the cover 320, and then is discharged again through the opening hole 322 of the cover 320.

At this time, the wind is guided by the inclined portion 322a of the cover 320 and the guide portion 332a of the winding surface 332 and discharged toward the steel wire W 'wound on the winding surface 332.

Accordingly, the steel wire (W ') is drawn by the completion of the fresh wire having a high temperature heat is cooled by the action of the wind as described above.

That is, the steel wire (W ') is drawn is completed and is wound on the winding surface 332 of the winding unit 330 and air-cooled by the wind at the same time.

Thereafter, the steel wire (W ') is transferred to the guide roller 400, the winding process is completed by being finally wound on the spooler 500 by the rotation of the guide roller 400.

As described so far, according to the air-cooled capstan according to the present invention, the drawing is completed, the steel wire (W ') having a high temperature heat is cooled and then wound up in the spooler (500), due to the shrinkage of the steel wire (W') Deformation and change in tension of the spooler 500 is characterized in that does not occur.

In addition, by cooling the steel wire (W ') by using the wind generated by using the rotational force for winding the steel wire (W'), the configuration as a cooling means is simply provided, reducing the manufacturing cost and the cost for maintaining the cooling means There is a characteristic to become.

1 is a schematic diagram schematically showing a drawing process according to the prior art

Figure 2 is a schematic view showing a freshener installed in the air-cooled capstan according to a preferred embodiment of the present invention from the front

3 is a perspective view showing part "A" of FIG.

Figure 4 is a side cross-sectional view showing an air-cooled capstan according to a preferred embodiment of the present invention

Figure 5a is a rear view showing the back of the exposed surface of the air-cooled capstan according to a preferred embodiment of the present invention

Figure 5b is a side view showing the exposed surface of the air-cooled capstan according to a preferred embodiment of the present invention.

* Description of the major symbols in the drawings *

100: body 101: indicator

110: fresh part 120: guide part

200: dice device 210: dice

220: die holder C: guide capstan

300: air-cooled capstan 310: shaft

311 housing 312 bearing

320: cover 321: guide groove

322: opening hole 322a: inclined portion

330: winding 331: exposed surface

331a: suction hole 331b: wing

332: winding surface 332a: guide part

333: discharge surface 333a: discharge hole

400: guide roller 500: spooler

Claims (4)

A shaft rotated by a drive motor; A cover disposed at the front end of the shaft and having a guide groove formed therein and an opening formed at the front thereof; It is coupled to the end of the shaft is disposed in the guide groove of the cover, the portion exposed through the opening hole of the cover is configured to include a winding portion: wound around the steel wire, The winding unit, An exposed surface having a suction hole formed at the center thereof, a winding surface coupled to the rear of the exposed surface and providing an area on which the steel wire is wound, and a plurality of windings extending from the winding surface to the guide groove of the cover and communicating with the guide groove of the cover Air-cooled capstan of the fresh machine, characterized in that the discharge surface formed with a discharge hole formed. The method of claim 1, An air cooled capstan of a fresh machine, characterized in that a plurality of wings are further formed on the rear surface of the exposed surface. The method according to claim 1 or 2, An air-cooled capstan of a fresh machine, characterized in that the inclined portion inclined toward the winding surface is formed on the inner surface of the edge forming the opening hole of the cover. The method of claim 3, wherein Air-cooled capstan of the fresh machine, characterized in that the guide portion formed inclined along the inclined portion in the portion corresponding to the inclined portion of the winding surface.

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