KR101854416B1 - Apparatus of heat treatment for metal pipe in tubing roller - Google Patents

Abstract

The present invention relates to a heat treatment apparatus for a tubing roller fixed by fixing a carbon fiber-reinforced plastic pipe having a metal boss in an expanded metal pipe by heat-treating a metal pipe using a thermal expansion coefficient of a metal pipe, A supporting bar supported by the pedestal and capable of rotating the metal pipe by being hung on an outer circumferential surface of the frame; A drive shaft connected to the support rod through a universal joint and adapted to receive a rotational force from a deceleration motor through a chain gear to rotate the support rod; And a heating hot wire longitudinally installed on the floor so as to uniformly heat the metal pipe rotated by the support bar.

Description

 BACKGROUND OF THE INVENTION 1. Field of the Invention [0001] The present invention relates to a tubing roller,

[0001] The present invention relates to a metal pipe heat treatment apparatus for a tubing roller, and more particularly, to a metal pipe heat treatment apparatus for heating a metal pipe by using a thermal expansion coefficient of the metal pipe, The present invention relates to a metal pipe heat treatment apparatus for a tubing roller of a carbon fiber-reinforced plastic member, which can manufacture a tubing roller by welding a fixed and tubed metal pipe and a metal boss.

Generally, rollers used in a production line such as a polyester film, a polyvinyl chloride-based film, and the like are made of steel. The roller made of such a steel material is excellent in physical properties such as strength but has a high specific gravity and a large rotational inertia moment, which causes slippage of the film and also limits the increase in productivity.

However, since a rigid metal roll is excellent in strength and durability, it is heavy in weight and has a large moment of inertia, which leads to poor followability in the processing of film and paper, And a long time is required for starting and stopping.

To overcome these disadvantages, so-called fiber reinforced composites such as carbon fiber reinforced plastics (CFRP) have been developed as alternative materials.

In the industry as a whole, CFRP has evolved from simple functions to complex functions due to its higher stiffness, superior resilience and lower specific gravity.

CFRP is divided into 24ton, 45ton, and 90ton due to the development of resins such as epoxy and phenol resin suitable for the purpose of use, and the range of use temperature is also increased from 150 ℃ to 230 ℃.

Up to now, a method of reinforcing metal by various methods such as plating, fusing and bonding has been introduced in CFRP, but the complexity, economical efficiency, and durability of the manufacturing process in the precision field have been problematic and the demand is limited and it is not widely spread.

In addition, if the plating process is applied to the CFRP, it is easy to make the excellent physical properties of the CFRP. However, because of the CFRP characteristics, the plating process requires a lot of time and labor since copper plating, nickel plating and chrome plating are all required. .

In addition, as a method of reinforcing CFRP and metal by bonding, it is easy to manufacture by filling a gap between the CFRP pipe and the metal pipe and filling the gap therebetween. However, when a shock is applied to the surface of the roller, There is a disadvantage in that deformation occurs.

The present invention has been conceived to solve the conventional problems as described above, and its object is to manufacture a tubing roller by shrinking a metal pipe in a CFRP pipe using a thermal expansion coefficient of a metal, To a metal pipe heat treatment apparatus of a tubing roller for producing a tubing by joining a CFRP inner diameter to a roller to manufacture a tubing, and then finishing the precision-honed metal pipe while heating it in a heating device to heat the CFRP pipe into a thermally expanded metal pipe .

The metal pipe heat treatment apparatus of the tubing roller according to the present invention is characterized in that a carbon fiber reinforced plastic pipe having a metal boss in an expanded metal pipe after heat treatment of the metal pipe is tightened by using the thermal expansion coefficient of the metal pipe, A heat treatment apparatus comprising: a frame provided on an inner circumferential surface of a box-shaped inner wall of a rectangular parallelepiped shape having a space extending in the longitudinal direction; A pedestal installed to be slidable in a longitudinal direction of the frame; A support rod supported by the pedestal and capable of rotating the metal pipe by being hung on the outer circumferential surface thereof; A drive shaft connected to the support rod through a universal joint and adapted to receive a rotational force from a deceleration motor through a chain gear to rotate the support rod; And a heating hot line provided on the floor in the longitudinal direction so as to uniformly heat the metal pipe rotated by the support bar.

Further, in the metal pipe heat treatment apparatus of the tubing roller according to the present invention, the heat treatment apparatus is constituted by a wall made of an inner wall and a double wall of an outer wall, and glass fibers are placed between the inner wall and the outer wall.

Further, in the metal pipe heat treatment apparatus according to the present invention, the cover of the heat treatment apparatus is openable and closable by a hinge shaft, and the cover is provided with a ventilation hole for ventilating the internal air of the heat treatment apparatus, Is provided so as to be openable and closable.

In the present invention, a CFRP pipe is inserted into a metal pipe by applying a thermal expansion coefficient and is contracted after the cooling process and is integrally joined. The bonding force is superior to bonding by chemical adhesive such as a bond, It is sufficiently bonded to the resin of the material to sufficiently resist the heat generated in the polishing process during the surface rewinding, thereby maintaining a perfect integral type connection even in a thin thickness.

According to the present invention, by applying a thermal expansion coefficient, a CFRP pipe is inserted into a metal pipe, the tubing roller is contracted after the cooling process to heat the tubing roller, and after the tubing roller is rotated, There is an effect that no post-warping occurs.

In addition, according to the present invention, there is no occurrence of an excursion space in a rear impact, as compared with bonding and plating, so that surface rehabilitation can be facilitated.

Further, according to the heat treatment apparatus of the present invention, even if the center of the metal pipe is rotated while being eccentric, it is possible to rotate without difficulty by the drive shaft connected through the universal joint.

Further, according to the heat treatment apparatus of the present invention, the variable pedestal can be slidably moved in the longitudinal direction, and the position can be variably set according to the length of the heat-treated metal pipe.

1 is a longitudinal sectional view of a tubing roller according to an embodiment of the present invention.
2A is a perspective view of a heat treatment apparatus for manufacturing a tubing roller according to the present invention.
FIG. 2B is a perspective view of a heat treatment apparatus for manufacturing a tubing roller according to the present invention. FIG.
3 is an embodiment of a rapid feed device for manufacturing the tubing roller according to the present invention.
4 is a process diagram illustrating a method of manufacturing a tubing roller according to an embodiment of the present invention.
FIGS. 5A to 5F illustrate a process of a tubing roller according to an embodiment of the present invention.

Hereinafter, a method of manufacturing a tubing roller and a tubing roller according to an embodiment of the present invention will be described in detail with reference to the accompanying drawings.

1 is a longitudinal sectional view of a tubing roller according to an embodiment of the present invention.

Referring to FIG. 1, the tubing roller according to an embodiment of the present invention includes a central roller formed in a CFRP pipe 10 having a boss and a shaft coupled to a central rotation axis, And the outer surface of the metal pipe 20 is plated after precision polishing.

The CFRP pipe 10 is formed into a hollow cylindrical shape made of carbon fiber-reinforced plastic.

The CFRP pipe 10 is formed by laminating multiple layers of carbon fiber-reinforced plastics and then molding them at a high pressure and a high temperature.

The hollow metal pipe 20 coupled to the outer peripheral surface of the CFRP pipe 10 is, for example, an SUS pipe. However, the pipe 20 may be made of stainless steel or aluminum alloy, And may be made of a metal material.

The CFRP pipe (10) prepares a center roller in advance before the metal pipe (20) is shrunk.

In order to construct the center roller, a boss member 14 which is in tight contact with the boss flange 12 and the boss flange 12 at both ends of the CFRP pipe 10, a shaft member 14 which is axially joined to the boss member 14, The boss member 16 is engaged.

The boss flange 12 is formed with a circular hollow at its center. A bolt fastening hole 121 is formed in the circular hollow peripheral portion. The boss flange 12 is inserted into and bonded to the inner main surface at both ends of the CFRP pipe 10, And welded to the pipe 20.

The boss member 14 is inserted into a circular hole of the boss flange 12 to be connected to a central shaft and to be engaged with a bolt fastening hole 121 corresponding to the bolt fastening hole 121 of the boss flange 12 141 are formed.

In addition, the boss member 14 is fixedly coupled to the shaft joint at a shaft engaging portion in order to engage with the shaft corresponding to the central axis of rotation.

The shaft boss member 16 includes a central shaft portion fixedly coupled to the shaft coupling portion of the boss member 12 and is rotatably supported by the bolt fastening hole 121 of the boss member 12, And a bolt fastening hole 161 for bolt fastening is provided corresponding to the bolt fastening hole 141 of the fastening member 14.

The boss flange 12, the boss member 14 and the axial boss 16 are integrally coupled with each other through the bolt fastening holes 121, 141 and 161 and the bolts 15 therebetween.

The tubing roller according to an embodiment of the present invention is used to heat the outer circumferential surface of the CFRP pipe 10 constituting the center roller in order to reinforce mechanical rigidity and durability.

The metal pipe 20 is shrunk on the outer circumferential surface of the CFRP pipe 10 by heating the metal pipe machined to have an inner diameter smaller than the outer diameter of the CFRP pipe 10 while rotating the circumferential direction in the heating device, The CFRP pipe 10 is rapidly inserted with the inner diameter of the pipe 20 expanded beyond the outer diameter of the CFRP pipe 10 and the outer peripheral surface of the CFRP pipe 10 and the metal So that the inner main surface of the pipe 20 is integrally joined.

It is preferable that the inner diameter of the metal pipe 20 is made to be smaller than the outer diameter of the CFRP pipe 10 in one embodiment so that the thickness of the CFRP pipe is approximately 0.05 to 0.1 when the metal is an SUS pipe .

For this purpose, the inner diameter of the SUS pipe is precisely honed to 0.01. The roundness is 0.01, and the diameter of the inner diameter is reduced by 0.05 mm.

On the other hand, the outer diameter of the CFRP pipe was 0.00, and the cylindrical diameter was 0.01. Keep roundness 0.01.

The SUS boss flange 12, the boss member 14 and the shaft boss 16 are precisely machined so as to fasten the bolts 15 to the bolt fastening holes 121, 141 and 161 .

At this time, only the minimum thickness is left in the shaft boss 16 to reduce the roller weight, and it is preferably about 10T.

On the other hand, when replacing the bearing, the shaft boss 16 is machined so as to secure a jig insertion space.

In order to heat the metal pipe 20 on the outer circumferential surface of the CFRP pipe 10, the metal pipe 20 is preheated while rotating the metal pipe 20, and the inner diameter of the metal pipe 20 is set to be larger than the outer diameter of the CFRP pipe 10 The CFRP 10 pipe is quickly inserted and cooled in the expanded state to complete the tubing roller.

The tubing roller according to the present invention rapidly inserts the CFRP 10 pipe in the state where the inner diameter of the metal pipe 20 is expanded than the outer diameter of the CFRP pipe 10, The rollers are rotated at 150 ° C for about 30 minutes while being rotated by a rotatable heating device, and then cooled naturally to prevent twisting and post-warping of the metal pipe.

Here, it is important to heat uniformly at a sufficient temperature using the thermal expansion coefficient of the metal.

In order to heat the metal pipe 20 on the outer circumferential surface of the CFRP pipe 10, the entire area of the metal pipe 20 must be uniformly heated while continuing to rotate the metal pipe 20. Otherwise, Or deformation occurs, and the heat shrinking process becomes impossible.

As described above, the apparatus for uniformly heating the entire area while continuously rotating the metal pipe 20 is the heat treatment apparatus 200 shown in Figs. 2A and 2B.

2A and 2B, the entire shape of the heat treatment apparatus 200 is a rectangular parallelepiped extending in the longitudinal direction. The support pipe 210, which is capable of rotating while supporting the metal pipe 20 while supporting the metal pipe 20, And is connected to the drive shaft 230 via the joint 220.

The driving shaft 230 receives rotational force from the decelerating motor 250 through the chain gear 240 and the supporting rod 210 is rotated by the driving shaft 230 to be engaged with the supporting rod 210 The metal pipe 20 is uniformly heated by the heating wire 205 installed in the longitudinal direction on the bottom of the heat treatment apparatus while being rotated.

At this time, even though the metal pipe 20 hung on the support rod 210 rotates and its center is eccentrically rotated, it can be smoothly rotated by the driving shaft 230 connected through the universal joint 220.

If the metal pipe 20 is an SUS pipe, it is preferable to start the heating, raise the temperature to 200 DEG C, and maintain the temperature for about 40 minutes.

At this time, a control control plate 260 is provided to control the temperature setting and control and the rotation speed of the metal pipe through the drive shaft.

The metal pipe 20 attached to the support rod 210 is supported by a movable pedestal 270 provided in the longitudinal direction of the frame 215 attached to the inner wall of the heat treatment apparatus, The variable pedestal 270 can be slidably moved in the longitudinal direction, and the position of the variable pedestal 270 can be varied according to the length of the metal pipe 20. [

The heat treatment apparatus has a wall made up of a double wall of an inner wall 290 and an outer wall 295, and glass fibers are disposed between the inner wall and the outer wall to prevent heat loss.

The cover 280 of the heat treatment apparatus is openable and closable with a hinge shaft. The cover 280 is provided with a ventilation hole 282 for ventilating the internal air of the heat treatment apparatus. A damper is provided so that it can be opened and closed when necessary.

A check window 281 is provided on the cover 280 so that the internal state of the heating device can be confirmed from outside.

In the tubing roller according to the present invention, the metal pipe machined to have an inner diameter smaller than the outer diameter of the CFRP pipe 10 is heated while rotating the metal pipe in the circumferential direction in the heat treatment apparatus, The CFRP 10 pipe must be rapidly inserted into the metal pipe 20 at an insertion speed of 300 to 600 mm / s. In this case, It is possible to prevent the CFRP from being difficult to insert.

3 is a schematic view of a rapid feed device for manufacturing a tubing roller according to the present invention.

3 is a device for rapidly inserting the CFRP 10 pipe into the metal pipe 20. As shown in FIG.

A fixture 320 for fixing one end of the metal pipe 20 is mounted on the left lathe 310 and a fixing projection 330 for fixing the center of the metal pipe 20 is inserted into the metal pipe 20 Fix two in the longitudinal direction.

Meanwhile, the other end of the metal pipe 20 is aligned with one end of the shaft portion of the central roller of the CFRP pipe 10, and the outer circumferential surface of the CFRP pipe 10 is aligned with the inner circumferential surface of the metal pipe 20 do.

The other end of the shaft portion of the center roller of the CFRP pipe 10 is aligned with the push rod 342 of the transfer member 340 and aligned with the center.

The push rod 342 is advanced by the high speed rotation of the pinion gear 360 engaged with the rack gear 350 provided at the bottom of the feed member 340 so that the CFRP pipe 10 And quickly inserted into the metal pipe 20.

A rotational force is transmitted to the pinion gear 360 coupled to the rack gear 350 through the chain gear 380 to the reduction motor 370 provided on the upper portion of the feed member 340.

It is preferable that the deceleration motor 370 controls the rotation speed under the control of the electric control box 380, and the deceleration motor induces a rotation deceleration of about 20: 1.

Meanwhile, when the CFRP pipe 10 is inserted into the metal pipe 20 rapidly according to the firing process, the CFRP pipe 10 is prevented from being excessively inserted into the metal pipe 20 A stopper 110 is provided at an end of the CFRP pipe.

That is, the boss flange 12, which is inserted into the inner main surface at both ends of the CFRP pipe 10 and is coupled to at least one end of the boss flange 12 to be welded and fixed to the metal pipe 20, And a stopper 110 protruding from an end portion of the CFRP pipe 10 to prevent the CFRP pipe 10 from being excessively inserted into the metal pipe 20.

Further, the stopper 110 may be removed in the surface precision polishing process after the tubing roller according to the heat shrinking process is completed.

4 is a process diagram illustrating a method of manufacturing a tubing roller according to an embodiment of the present invention.

4, the boss flange 12 is first inserted into the inner circumferential surface of the CFRP pipe 20 and the boss member 14 and the axial boss 16 are axially coupled to the boss flange 12, A roller is produced (S10).

In order to insert the boss flange 12 into the CFRP pipe 20, the outer diameter of the CFRP pipe 20 is first machined.

The CFRP pipe 20 is bonded to the SUS boss member 14 and the boss flange 12 at both ends and has a deviation of 0.05 to 0.1 mm according to the diameter of the inner roller. The CFRP roller is completed.

The CFRP roller has an outer diameter of 0.00, roundness, and a degree of turning of 0.01 mm.

The inner diameter of the hollow metal pipe 20 is machined so as to have an inner diameter smaller than the outer diameter of the CFRP pipe 10 (S20).

That is, the inner and outer diameters of the metal pipe 20, for example, the SUS pipe, are processed and honed to be processed in advance to an inner diameter of -0.05, roundness, and an overall degree of 0.01 mm.

Next, the metal pipe 20 is heated while rotating in the longitudinal direction in the heating apparatus shown in FIG. 2 (S30).

If the metal pipe 20 is an SUS pipe, it is preferable to start heating, raise the temperature to 200 ° C, and maintain the pipe uniformly for about 40 minutes.

Here, the heating temperature should be adjusted by varying the temperature and time according to the diameter and the length of the finished roller.

The heated metal pipe 20 is adjusted by adjusting the center and the gap of the yearly pipe in the rapid acceleration transfer device shown in FIG. 3, and then the CFRP pipe 10 is heated into the heated and thermally expanded metal pipe 20 So that the tubing process is performed (S40).

At this time, the feed rate at which the CFRP pipe 10 advances into the metal pipe 20 should be maintained at 300 to 600 mm / s.

Here, the outer diameter of the CFRP pipe 10 should be larger by 0.05 mm than the inner diameter of the SUS pipe 20 in the tubing gap.

In addition, each edge is machined at R3 to facilitate insertion during the tubing process to reduce friction.

Next, water is sprayed while rotating the tubing roller having completed the tubing process, thereby rapidly cooling the tubing roller (S50).

When the tubing process is completed, the end of the metal pipe 20 and the end of the boss flange 12 are fixed by argon welding (S60).

The tubing roller integrally joined by heat shrinking of the CFRP pipe 10 and the metal pipe 20 is heated in a heating device while being annealed (S70).

The annealing process is a process in which the tubing roller integrally joined by heat shrinkage of the CFRP pipe 10 and the metal pipe 20 is heated and maintained at 150 캜 for about 30 minutes while being rotated by a rotatable heating device And then naturally cooled to prevent the metal pipe from being twisted or deformed.

Further, a process of processing the shaft end portion and the outer diameter of the finished tubing roller and correcting the first balancing can be further added.

Finally, the tubing roller is finely processed, the outer circumferential surface of the metal pipe is plated, and the surface is polished and polished (S80).

After the annealing process, the tubing roller is finishing and subjected to primary polishing, then the outer circumferential surface of the metal pipe is plated, and subjected to a surface polishing process according to a secondary polishing process and a surface superpinning process.

The final product of the CFRP pipe 7T + SUS pipe 1T tubing roller is completed through the second balancing correction.

5 is a view illustrating a process of a tubing roller according to an embodiment of the present invention.

FIG. 5A is a view showing an inner diameter of an SUS pipe as a metal pipe treated by honing.

5B is a view showing the SUS boss member 14 coupled to both ends of the CFRP pipe and the bolt for fastening the boss flange 12 and the bolt to the shaft boss 16 in order to complete the CFRP pipe with the inner roller.

FIG. 5C shows a state in which the CFRP pipe is completed with the inner roller and just before the metal pipe is shrunk.

FIG. 5D shows a state in which the SUS pipe and the CFRP roller are shrunk to complete the tubing process.

5E shows the SUS pipe and the end portion of the boss flange coupled to the end of the CFRP roller by argon welding.

FIG. 5F shows a state of the final tubing roller product in a state where the tubing roller is finished, the outer circumferential surface of the metal pipe is plated, and the surface is polished and polished.

The finished tubing roller product as described above can be utilized in various fields such as a slitting contact roller, a touch roller, a winding roller used for film production and processing, and a roller of an LCD line.

While the present invention has been particularly shown and described with reference to exemplary embodiments thereof, it is clearly understood that the same is by way of illustration and example only and is not to be construed as limiting the scope of the invention as defined by the appended claims. .

10: CFRP pipe 12: Boss flange
14: Boss member 15: Bolt
16: shaft boss 20: metal pipe
200: Heat treatment apparatus 300: Rapid transfer device

Claims (3)

There is provided a metal pipe heat treatment apparatus for a tubular roller which is fixed by heat-shrinking a carbon fiber-reinforced plastic pipe having a metal boss in an expanded metal pipe by heat-treating a metal pipe using a thermal expansion coefficient of the metal pipe,
A frame provided on an inner circumferential surface of a box-like inner wall of a rectangular parallelepiped shape having a space extending in the longitudinal direction;
A pedestal installed to be slidable in a longitudinal direction of the frame;
A support rod supported by the pedestal and capable of rotating the metal pipe by being hung on the outer circumferential surface thereof;
A drive shaft connected to the support rod through a universal joint and adapted to receive a rotational force from a deceleration motor through a chain gear to rotate the support rod; And
And a heating heat line longitudinally installed on the floor so as to uniformly heat the metal pipe rotated by the support bar,
Characterized in that the cover of the heat treatment apparatus is openable and closable with a hinge shaft, and the cover is provided with a ventilation hole for ventilating the inside air of the heat treatment apparatus, and a separate damper is installed in the ventilation opening so as to be openable and closable. Of metal pipe heat treatment apparatus. The method according to claim 1,
Wherein the heat treatment apparatus comprises a wall by an inner wall and a double wall of an outer wall, and glass fibers are disposed between the inner wall and the outer wall. delete

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