KR102182138B1 - method for removing residual stress of multi layers seamless tube - Google Patents

Abstract

In the method for cleaning the inner and outer surfaces of the multi-structure seamless cladding pipe of the present invention and removing stress, a pilger operation is performed using a pilger device while the seamless tube is heated, and then the primary stress removal operation by the primary stress relief device. And the secondary stress removal operation by the secondary stress relief device is sequentially performed, thereby removing residual surface stress on the inner and outer surfaces of the seamless cladding tube.

Description

Method for removing residual stress of multi layers seamless tube

The present invention relates to a multi-structure seamless cladding pipe, and more particularly, to prevent cracks caused in subsequent processes by removing different stresses for each portion of the inner and outer surfaces generated during manufacture of the multi-structure seamless cladding pipe. The present invention relates to a method for cleaning the inner and outer surfaces of a seamless multi-structured seamless cladding pipe and removing stress from a new method that allows the inner or outer surface of the seamless cladding pipe to be cleaned together.

In general, a seamless tube, unlike a welded tube, is not made by bending a steel plate and joining a joint, but a hollow pipe made using a mandrel by using a roll from a steel ingot, which means a seamless steel pipe.

The structure of such a seamless tube is used for a variety of purposes, and is mainly applied to structures that can withstand high temperatures such as nuclear fuel cladding tubes.

On the other hand, in the case of the nuclear fuel clad pipe, by forming a variety of coverings such as silicon carbide fibers, ceramics, zirconium alloys, etc. on the inner and outer sides of the seamless tube in a multiple structure, it is possible to obtain improved mechanical strength and heat transfer efficiency and corrosion resistance at high temperatures. In this regard, as described in Registration Patent No. 10-1526305, Registration Patent No. 10-1595436, Patent Publication No. 1992-0009646, and the like.

However, in the multi-structure seamless cladding tube such as the nuclear fuel cladding tube according to the prior art described above, it is difficult to precisely match the dimensions for the inner and outer diameters of the seamless cladding tube as each cladding layer is formed after processing the seamless tube to a preset dimension. There was a drawback that was very difficult.

Of course, it may be possible to precisely shape the dimensions for the inner and outer diameters of the seamless cladding tube through the pilger operation.

However, in such a pilger work, various stresses remain in each coating layer after the pilger work due to a rapid dimensional change, and the stress remaining in each coating layer causes cracks in post-process work (e.g., heat treatment work, etc.). there was.

In other words, in the case of a cladding layer having different materials and properties from the seamless cladding pipe, a variation in stress occurs in the process of pilgering the Simle 6 cladding pipe due to the difference in physical properties between dissimilar metals. The stress remaining on the inner and outer surfaces of the cladding pipe increased the probability of cracking during post-processing.

In addition, in the case of a seamless cladding pipe manufactured using a pilger operation, there is a disadvantage that various foreign substances are bound to remain in the multi-layered coating layer formed on the inner circumferential surface of the seamless cladding pipe.

Registered Patent No. 10-1526305 Registered Patent No. 10-1595436 Patent Publication No. 1992-0009646

The present invention removes different stresses for each area on the inner and outer surfaces generated during the manufacture of a multi-structure seamless cladding pipe to prevent cracks caused during subsequent processing, while also surface cleaning of the inner or outer surface of the seamless cladding pipe. It is to provide a method for cleaning the inner and outer surfaces of a multi-structure seamless cladding tube and removing stress of a new method that can be made together.

According to the method for cleaning the inner and outer surfaces of the multi-structure seamless cladding tube of the present invention for achieving the above object and for removing stress, a perforation step of perforating the center of the prepared billet material to form a seamless tube; A coating layer forming step of forming one, two or more coating layers on the inner or outer circumferential surface of the molded seamless tube; A pilger step of performing a pilger operation by inserting the seamless tube on which the covering layer is formed into a pilger device; An outer surface stress removing step of removing residual stress on the outer surface of the seamless tube in which the pilger has been worked; Inner surface stress removing step of removing residual stress on the inner surface of the seamless tube; characterized in that it is made in sequence.

Here, the outer surface stress removing step and the inner surface stress removing step are characterized by being performed by spraying fine particles made of glass onto the outer surface or inner surface at high speed with high-pressure air.

In addition, in the step of removing the inner surface stress, one side closing process of closing either side of the open side of the seamless tube with a cover having a vacuum hole, and a plug insertion process of inserting a plug into the other side of the seamless tube to close it. A vacuum process of evacuating by evacuating air in the inner space of the seamless tube through the vacuum hole, and glass through the outer surface of the plug while entering the plug until reaching any one side of the seamless tube. It characterized in that it proceeds including a short process of high-speed spraying of fine particles made of high-pressure air.

In addition, after performing the shorting process, the plug is removed from the inside of the seamless tube and the cover is removed so that both sides of the seamless tube are opened, and high-pressure air is forced through either side of the seamless tube. It is characterized in that the process of discharging the residue by spraying and discharging the residue remaining in the seamless tube further proceeds.

In addition, the plug is formed of a plunger part having an empty pipe inside, and is formed as a tube body that is enlarged compared to the plunger part while extending from the tip of the plunger part, and the tip is formed to be closed, and a plurality of particles pass through the circumferential surface. It is characterized in that it comprises a head portion formed through the hole.

As described above, in the method for cleaning the inner and outer surfaces of the multi-structure seamless cladding pipe and removing the stress of the multi-structure seamless cladding pipe, the fine particles made of glass balls are transferred to the outer and inner surfaces of the seamless cladding pipe, respectively. By spraying to remove residual stress, cracks can be prevented during post-processing.

In addition, in the method for cleaning the inner and outer surfaces of the multi-structure seamless cladding tube of the present invention and removing stress, the pilger step is successively performed immediately after heating of the seamless tube 20 before the temperature of the seamless tube 20 is lowered. By performing rolling, it is possible to prevent breakage or physical property deformation of each coating layer 30 during rolling due to temperature change.

In addition, since the method of cleaning the inner and outer surfaces of the multi-structure seamless cladding tube of the present invention and removing stress is performed by spraying fine glass balls toward each surface with high-pressure air at high speed, not only the surface stress but also various foreign substances present on the surface can be removed. It has the effect of being able to achieve an improvement in surface roughness as well as that removal can be performed additionally.

In addition, the method of cleaning the inner and outer surfaces of the multi-structure seamless cladding tube of the present invention and removing stress is performed in a state in which the inside of the seamless tube is vacuumed when the stress on the inner surface of the seamless tube is removed. In the process of spraying to the inner surface of the seamless tube, it is possible to uniformly spray over the entire area without being focused on either side, thereby having the effect of being able to smoothly remove residual stress on the inner surface.

1 is a schematic diagram illustrating an apparatus for manufacturing a multi-structure seamless cladding pipe according to an embodiment of the present invention.
Figure 2 is a flow chart illustrating the manufacturing process of the multi-structure seamless cladding pipe according to an embodiment of the present invention
3 to 5 are state diagrams illustrating a manufacturing process of a multi-structure seamless cladding tube according to an embodiment of the present invention.
6 is a state diagram illustrating a stress relief process on the outer surface of the multi-structure seamless cladding tube according to an embodiment of the present invention
7 and 8 are state diagrams illustrating a process of removing stress on the inner surface of a multi-structure seamless cladding tube according to an embodiment of the present invention.

Hereinafter, a preferred embodiment of a method for cleaning the inner and outer surfaces of the multi-structure seamless cladding pipe and removing stress of the present invention will be described with reference to FIGS. 1 to 8.

First, the accompanying FIG. 1 is a schematic diagram illustrating an apparatus for manufacturing a multi-structure seamless cladding pipe according to an embodiment of the present invention.

As shown, the apparatus for manufacturing a multi-structure seamless cladding tube according to an embodiment of the present invention is largely a perforation device 100, a covering device 200, a heating device 300, and a pilger device 400. And, a first stress removing device and a second stress removing device, and in particular, after performing the pilger work by the pilger device 400, the first stress removal work by the first stress removing device 600 and As the secondary stress removal operation by the secondary stress removal device 700 is sequentially performed, residual surface stress on the inner and outer surfaces of the seamless cladding tube can be removed.

This will be described in more detail for each configuration as follows.

First, the drilling device 100 is a device for drilling the billet material 10.

Such a drilling device 100 may be a conventional drilling device and boring device.

Next, the covering device 200 is a device provided to form the covering layer 30 on the inner or outer surface of the perforated billet material (hereinafter referred to as “seamless tube”) 20.

In this case, the coating layer 30 may be a layer formed by a conventional deposition process, or may be formed as a tube made in a hollow shape separate from the seamless tube 20.

In the embodiment of the present invention, it is assumed that the above-described coating device 200 is an overlay welded device in which coating layers of different kinds of metals are grown on the seamless tube 20.

In particular, by forming the coating layer 30 by the overlay welding, not only can the wear resistance and corrosion resistance be improved, but also the seamless tube 20 is exposed to the external environment when heated in the heating device 300 to be described later. Oxidation phenomena that may occur as they may be exposed may be reduced.

Next, the heating device 300 is a device provided to heat the seamless tube 20 on which the plurality of covering layers 30 are formed before the pilger operation.

That is, by heating the seamless tube 20 before the pilger operation by the above-described heating device 300, breakage or peeling of each covering layer 30 despite a rapid dimensional change can be prevented. .

Such a heating device 30 is constructed by installing a coil-type induction heater 320 inside a pipe-type duct 310 that is open and has a circumferential surface closed, whereby the seamless tube 20 is While passing through the duct 310, the induction heater 320 enables sequential heating.

In particular, argon (Ar) gas is injected to the inlet and outlet sides of the heating device 300 to prevent oxygen from flowing into the duct 310 of the heating device 30, and thus the seamless tube 20 ) To prevent oxidation of the coating layer 30 due to oxygen during heating.

Next, the pilger device 400 is a device for expanding the pipe (or shaft pipe) by rolling the seamless tube 20 covered with the plurality of covering layers 30.

Such a pilger device 400 is made of a pilger mill including a plurality of dice 410 and a mandrel 420.

In particular, in the embodiment of the present invention, the pilger device 400 is installed to form an in-line arrangement while being positioned on the same horizontal line as the duct 310 of the heating device 300, and the seamless tube 20 is a conveyor ( It is suggested that the induction heater 320 and the pilger device 400 are continuously passed through 510 and 520.

That is, the seamless tube 20 is provided to the pilger device 400 immediately after being heated while passing through the induction heater 320 of the heating device 300 so that the pilger work is continuously performed so that the seamless tube 20 While preventing the fracture phenomenon of each of the coated covering layers 30, it is possible to perform stable rolling without stressing the seamless tube 20.

Next, the primary stress relief device 600 is a device provided to remove residual stress on the outer surface of the seamless tube 20.

Such a primary stress relief device 600 injects fine hard particles to the outer surface of the seamless tube 20 in a state in which the seamless tube 20 is positioned in the closed chamber 610 from the external environment to provide a minute impact. It is made so that residual stress on the surface can be removed by repeatedly applying. At this time, it is suggested that the fine hard particles are made of glass balls 601, and the primary stress relief device 600 is a device that performs a shot blasting operation to inject the glass balls 601 at high speed using high-pressure air. Is provided as. This is as shown in the accompanying FIGS. 1 and 6.

Next, the secondary stress relief device 700 is a device provided to remove residual stress on the inner surface of the seamless tube 20.

The secondary stress removing device 700 is configured to remove residual stress on the surface by repeatedly applying fine impact by spraying fine hard particles onto the inner surface of the seamless tube 20. At this time, it is suggested that the fine hard particles are made of glass balls 701, and the secondary stress relief device 700 uses a plug 710 installed to be movable along the inside of the seamless tube 20. Performed.

Here, the plug 710 is formed of a plunger portion 711 formed of a hollow pipe, and a pipe body that is extended compared to the plunger portion 711 while extending from the front end of the plunger portion 711 and Is formed to be closed, and comprises a head portion 712 formed through a plurality of particle passage holes 713 penetrating through the circumferential surface. This is as shown in the accompanying FIGS. 1 and 7.

In addition, the secondary stress removing device 700 further includes a cover 720.

The cover 720 is a stopper that closes one of both open sides of the seamless tube 20, and a vacuum hole 721 is formed in the cover 720. At this time, the cover 720 may be a pre-made individual product as shown in the embodiment, but a structure formed by applying to close one open side of the seamless tube 20 using silicon or paraffin It could be.

In the following, the manufacturing process of the multi-structure seamless cladding pipe according to the embodiment of the present invention described above will be described in more detail in each order.

2 is a flowchart illustrating a process of manufacturing a multi-structure seamless cladding tube including a process of cleaning the inner and outer surfaces and removing stress according to an embodiment of the present invention.

Accordingly, the method of manufacturing a multi-structure seamless cladding pipe according to an embodiment of the present invention includes a material preparation step (S100), a perforation step (S200), a covering layer forming step (S300), a tube heating step (S400), and a pilger. Step (S500) and the stress removal step is performed sequentially, and in particular, the addition of stress removal steps (S600, S700) before performing the post-treatment work of the multi-structure seamless tube 20 made through the pilger step Through the implementation, it is possible to prevent the occurrence of peeling or cracking between each coating layer that occurs during post-treatment work.

This will be described in more detail for each process with reference to the flow chart of FIG. 2 and the state diagrams of FIGS. 3 to 8.

First, a material preparation step (S100) of preparing the billet material 10 is performed.

Such billet material 10 is provided in the form of a round bar or block as shown in FIG. 3 and is formed of a metal material such as a zirconium alloy.

In addition, when the billet material 10 is prepared, the center of the prepared billet material 10 is drilled to form a seamless tube 20 (S200).

At this time, the portion to be perforated in the perforating step (S200) is formed to have an inner diameter in consideration of the thickness of the coating layer 30. This is as shown in the accompanying FIG. 4.

Of course, it is more preferable to adjust the thickness and inner diameter of the seamless tube 20 to a set dimension through a separate machining or rolling operation after the drilling by the drilling step (S200) is completed.

Next, a coating layer forming step (S300) of forming one, two or more coating layers 30 as shown in FIG. 5 attached to the inner circumferential surface or the outer circumferential surface of the molded seamless tube 20 is performed.

At this time, the covering layer 30 may be made of ceramic, silicon, or composite fiber.

Further, the plurality of coating layers 30 are formed by sequentially coating the coating layers 30 of different kinds of metals by overlay welding by the coating device 200.

On the other hand, after completion of the perforation step (S200) and before performing the cover layer forming step (S300), a rolling operation of primarily adjusting the dimensions for the inner and outer diameters of the perforated seamless tube 20 may be additionally performed. That is, through the additional execution of such a rolling operation, it is possible to reduce the amount of abrupt dimensional change during the pilger step (S500) performed after the subsequent coating layer forming step (S300), so that each coating layer 30 formed during the coating layer forming step (S300) Damage is further prevented, and in this case, the rolling operation is performed by cold rolling, so that the change in physical properties of the seamless tube 20 can be prevented.

Next, the tube heating step (S400) of heating the seamless tube 20 on which the covering layer 30 is formed and the pilger step (S500) of rolling the heated seamless tube 20 are successively performed.

That is, by allowing the pilger operation by the pilger step (S500) to be performed hot rather than cold, the seamless tube during the pilger operation can be prevented from occurring between multiple dissimilar materials forming the covering layer 30. It is possible to minimize the stress provided to the seamless tube 20, and in particular, the heating of the seamless tube 20 and the rolling of the heated tube 20 are continuously performed, thereby causing the coating layer 30 caused by a rapid temperature change. ) To prevent the occurrence of damage.

In addition, as it is possible to minimize the stress applied to the seamless tube 20 by performing the hot pilger work, it is possible to improve the rigidity of the material.

In the above-described tube heating step (S400), the heating control of the induction heater 320 is performed so that the extraction temperature of the seamless tube is within a temperature range of 800 to 900°C. At this time, when the tube heating step (S400) is performed in the temperature range of less than 800° C., there is a risk that each of the covering layers 30 may be broken as each covering layer 30 is not sufficiently heated, and the tube heating step If (S400) is performed in a temperature range exceeding 900°C, since there is a concern that a change in physical properties of each coating layer 30 may be caused, the heating of the seamless tube 20 is performed in a temperature range between 800 and 900°C. Thus, while preventing breakage between each of the coating layers 30, changes in physical properties of each of the coating layers 30 can be prevented.

In addition, while heating the seamless tube using the induction heater 320, argon gas is injected to the inlet side of the induction heater 320 and the outlet side of the induction heater 320 so that the seamless tube 20 While being heated while passing through the induction heater 320, oxygen can be prevented from flowing into the seamless tube 20.

Next, when the pilger operation through the pilger step (S500) is completed, the external stress removal step (S600) of removing residual stress on the outer surface of the seamless tube 20 thus worked is performed.

In this external stress removing step (S600), a fine glass ball 601 is placed toward the entire outer surface of the seamless tube 20 in a state in which the seamless tube 20 is placed in the chamber 610 blocked from the external environment. It is carried out by high-speed injection with high-pressure air.

That is, the residual stress generated on the outer surface of the seamless tube 20 due to the deviation of the stress due to the difference in physical properties for each coating layer 30 during the pilger operation described above by performing the external stress removing step (S600) Is removed.

In addition, when the outer surface stress removing step (S600) by the above process is completed, the inner surface stress removing step (S700) of removing residual stress on the inner surface of the seamless tube 20 is performed.

The inner surface stress removing step (S700) is performed by spraying a fine glass ball 701 on the inner surface of the seamless tube 20 at high speed while vacuuming the inside of the seamless tube 20.

In order to vacuum the inside of the seamless tube 20, one of the open sides of the seamless tube 20 is closed with a cover 720 in which a vacuum hole 721 is formed, and the seamless tube The plug 710 is inserted into the other side of 20 to be closed, and then the air in the inner space of the seamless tube 20 is discharged through the vacuum hole 721 to vacuum.

Thereafter, while entering the plug 710 until reaching any one side of the seamless tube 20, a short process of high-speed injection of a fine glass ball 701 with high-pressure air through the outer surface of the plug 710 is performed. By doing so, residual stress on the inner surface of the seamless tube 20 is removed.

At this time, the reason for evacuating the inside of the seamless tube 20 before performing the short process is that the fine glass balls 701 sprayed to the inner surface of the seamless tube 20 do not move to any one side and are This is to ensure uniform spraying.

In addition, after the shorting process is performed, the plug 710 is removed from the inside of the seamless tube 20 and the cover 720 is removed so that both sides of the seamless tube 20 are opened. Remnants remaining in the seamless tube 20 by forcibly spraying high-pressure air through one side of the less tube 20 (the shim is sprayed with lubricating oil and fine glass balls remaining inside the seamless tube after pilfering work. A process of discharging residues to discharge fine foreign substances removed from the inner surface of the less tube is additionally performed.

In the end, the method for cleaning the inner and outer surfaces of the multi-structure seamless cladding pipe and removing stress of the present invention is to remove the fine particles made of the glass balls 601 and 701 after the pilger work on the multi-structure seamless cladding pipe to the outer surface of the seamless tube 20 and By spraying each on the inner surface to remove residual stress, cracks can be prevented during a post process (eg, a heat treatment process).

In addition, in the method of cleaning the inner and outer surfaces of the multi-structure seamless cladding tube of the present invention and removing stress, the temperature of the seamless tube 20 is lowered immediately after heating of the seamless tube 20 in the pilger step (S500). By continuing to perform rolling beforehand, breakage or deformation of physical properties of each coating layer 30 during rolling due to temperature change can be prevented.

In addition, since the method for cleaning the inner and outer surfaces of the multi-structure seamless cladding tube of the present invention and removing stress is performed by spraying fine glass balls 601 and 701 toward the inner and outer surfaces of the seamless tube 20 with high-pressure air, the surface In addition to the stress, as well as the removal of various foreign substances present on the surface may be additionally performed, the surface roughness may also be improved.

In addition, the method of cleaning the inner and outer surfaces of the multi-structure seamless cladding tube of the present invention and removing stress is performed in a state in which the inside of the seamless tube 20 is vacuumed when the stress on the inner surface of the seamless tube 20 is removed. By doing so, the fine glass balls 601 and 701 can be uniformly sprayed over the entire area without being focused on either side in the process of being sprayed to the inner surface of the seamless tube 20, so that residual stress on the inner surface can be smoothly removed.

10. Billet material 20. Seamless tube
30. Coating layer 100. Drilling device
200. Covering device 300. Heating device
310. Duct 320. Induction heater
400. Pilger device 410. Dice
420. Mendrel 510,520. conveyor
600. Primary stress relief device 601,701. Glass ball
610. Chamber 700. Secondary stress relief device
710. Plug 711. Flange part
712. Head part 713. Particle passing hole
720. Cover 721. Vacuum hole

Claims (5)

A covering layer forming step of forming one or two or more covering layers on the inner or outer circumferential surface of the seamless tube, a pilger step of performing a pilger operation by inserting the seamless tube with the covering layer formed into a pilger device, and the pilger operation An outer surface stress removing step of removing residual stress on the outer surface of the seamless tube, and an inner surface stress removing step of removing residual stress on the inner surface of the seamless tube;
The step of removing the inner surface stress,
One side closing process of closing one of both open sides of the seamless tube with a cover having a vacuum hole, a plug insertion process of inserting and closing a plug into the other side of the seamless tube, and through the vacuum hole A vacuum process of evacuating by evacuating air in the inner space of the seamless tube, and fine particles made of glass through the outer surface of the plug are transferred to high-pressure air while entering the plug until it reaches any one side of the seamless tube. A method for cleaning the inner and outer surfaces of a multi-structure seamless cladding tube and removing stress, characterized in that it proceeds including a short process of high-speed spraying. The method of claim 1, wherein the external stress removing step,
A method for cleaning and removing stress on the inner and outer surfaces of a multi-structure seamless cladding tube, characterized in that the fine particles made of glass are sprayed on the outer or inner surfaces at high speed with high-pressure air. delete The method of claim 1, wherein after performing the short process,
The plug is removed from the inside of the seamless tube and the cover is removed so that both sides of the seamless tube are opened, and then high-pressure air is forcibly injected through either side of the seamless tube to remain in the seamless tube. A method for cleaning the inner and outer surfaces of a multi-structure seamless cladding pipe and removing stress, characterized in that the process of discharging the remnants further proceeds. The method of claim 1, wherein the plug,
A plunger part formed of an empty pipe;
Characterized in that it comprises a; a head portion formed by extending from the tip of the plunger portion and formed as a tube body that is enlarged compared to the plunger portion, and the tip is formed to be closed, and through which a plurality of particle passage holes pass through the circumferential surface. Method for cleaning the inner and outer surface of the multi-structure seamless cladding pipe and removing stress

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