RU2254949C1 - Method of making dowel joints for tubes - Google Patents

Abstract

FIELD: plastic working of metals, possibly manufacture of dowel joints for tubes, mainly of similar materials for U-shaped heat exchange apparatuses.

SUBSTANCE: method comprises steps of preparing tubes for welding, bending end of one tube along radius, assembling bent end of tube with reciprocal tube having rectilinear generatrix; forming non-detachable joint of tubes by means of argon-arc welding. Non-detachable joint is formed before bending by making combination type welding seam designed for plastic deforming. At forming welded joint inner annular seam is made by diffusion welding of joined tubes along butt and outer annular seam is made by surfacing additive material onto outer surface of tube butt. At assembling tubes ring of additive material is placed between them. Then tubes are subjected to axial compression until creation of contact pressure on tube ends and lateral faces of ring. Combination type joint is formed during melting additive material of ring in space of outer annular recess.

EFFECT: enhanced quality of welded joints, elimination of internal burr occurring.

8 dwg

Description

The invention relates to the field of metal forming, in particular to processes for producing pipe rods of U-shaped heat exchangers using the effect of localized plastic deformation of the weld and adjacent heat-affected zones.

A known method of producing pipe hairpins of U-shaped heat exchangers, including measuring pipe lengths for straight sections of the hairpin, measuring pipe lengths for manufacturing flexible to a given kalach radius, cleaning the outer surface of the ends of the connected elements to be welded, their subsequent welding with the formation of two welds in the resulting pipe stud (see GOST 14245-79 Shell-and-tube heat exchangers with U-shaped pipes).

The main disadvantage of the known method for producing pipe hairpins of U-shaped heat exchangers is the increased cost of producing compounds. Firstly, large waste of pipe billets due to the multiple use of working lengths. And, secondly, the increased cost, determined by the large percentage of defective welds, which is detected during radiological tests. The quality of one-piece joints in this case is entirely determined by the professional skills and skills of the welder and his assistant, as well as the presence of slipways for pipe and pipe assembly before welding.

There is also a known method for producing pipe studs mainly from homogeneous materials, including preparing pipes for welding, bending the end of one of the pipes along the radius, assembling this end of the pipe with a return pipe having a rectilinear generatrix, and forming an integral pipe joint by argon-arc welding (see. document RD 153-34.1-003-01. Welding, heat treatment and control of pipe systems of boilers and pipelines during installation and repair of power equipment, Moscow, PIO OBT 2001 - prototype).

The disadvantage of this method is that the weld and heat-affected zones are not subjected to finishing plastic deformation. As a result, possible defects in the weld are not eliminated and similar studs are rejected. In addition, the big problem here is the presence of an internal burr, which reduces the bore of the pipe, which also leads to significant rejection of the pipe studs and requires testing such as rolling the pipe stud with a ball.

The objective of the invention is to develop such a method for producing pipe hairpins of U-shaped tube bundles, which would ensure the required quality of the welds and not lead to the formation of internal burrs.

The technical result is achieved by the fact that in the method for producing pipe rods, including preparing pipes for welding, bending the end of one of the pipes along the radius, assembling this end of the pipe with a return pipe having a straight-line generatrix, and forming an integral pipe joint by argon-arc welding, according to the invention , one-piece pipe connection is formed before flexible by forming a combined weld with subsequent plastic deformation of the specified weld and heat-affected zones, when combined of the weld, form an inner circumferential seam, which is obtained by diffusion welding of the pipes to be joined at the joint, and an outer circumferential seam, which is obtained by depositing filler material on the outer surface of the pipe joint, to form the said combined weld, the ends of the pipes to be joined are preformed to obtain an outer circumferential assembly recesses, during assembly between the pipes coaxially with them set a ring of filler material, which is placed in the said outer annular recess, and gave axial compression of the pipes is carried out until contact pressures are obtained at the ends of the pipes to be joined and the side faces of the ring, the combined weld is formed during the melting of the filler material of the ring in the volume of the outer annular recess, and then the bead is removed to obtain the outer diameter of the combined weld equal to the diameter of the heat-affected zones and the aforementioned plastic deformation of the combined weld and heat-affected zones is carried out by straightening the pipe by giving it a rotational and translational motion genius.

Implementation of the proposed method for producing pipe hairpins of U-shaped beams allows to eliminate defects of welds by their final plastic deformation.

This is due to the fact that they form a combined weld - diffusion welding of the pipes to be joined at the joint and welding of filler material onto the external surface at the location of the welded joint. The ends of the pipes before welding undergo surface activation by alternating plastic deformation of the pipe material (for pipes of homogeneous materials) with the formation of a step having a minimum external diameter.

The presence of a step at the end of the pipe during its assembly allows the formation of an external annular recess. Placing filler material in the form of a ring between the ends of the pipes to be welded by means of easy pressing and creating physical contact at the ends of the pipes and the annular surfaces of their contact with the filler material ring when applying axial compressive force creates the conditions for the diffusion process to occur at the junction of the connected elements. A prerequisite, as is known, is the heating temperature of the junction of the connected elements.

The latter is achieved by melting the filler material in the volume of the outer annular recess, creating a heat-containing liquid phase. As a result, the outer surface of the annular recess is heated by heat transfer from the heat flux source — the liquid phase from the filler material.

The pressures that occur on the end contact surfaces cause plastic deformation of the materials to be joined and, accelerating the diffusion process, lead to the formation and growth of new grains at the junction in the joint. The molten filler material during its cooling contributes to maintaining the temperature in the joint zone, which explains the possibility of the diffusion process in a relatively short time.

The molten filler material completely fills the volume of the outer annular recess with the formation of an external gart. The latter is necessary, since there is a relationship between the volume of molten filler material and the temperature of the inner layers of the pipes.

The melting of the filler material greatly simplifies the technology of the formation of one-piece connection, since in this case it is only necessary to rotate the non-consumable electrode or pipe. Giving the filler material a ring shape provides its preliminary heating and heating of the materials of the connected pipes from the heat source due to thermal conductivity. The above has a positive effect on reducing the diffusion time of pipe materials at their junction.

The external bead obtained after cooling the filler material is removed, which leads the outer diameter of the latter to the outer diameter of the heat-affected zones. Subsequent straightening of the pipe with a thickening at the location of the weld in the braid machine provides a given degree of deformation of the weld and heat-affected zones, significantly strengthening the material of the latter.

Pipe bending by rolling according to a known technology in the practice of manufacturing pipe hairpins is completed by monitoring the weld with eddy currents using special sensors, which makes quite significant savings compared to the radiological method.

The invention is illustrated by drawings, where figure 1 shows a pipe and a rigid stepped punch before performing the operation of distribution - calibration; figure 2 - the end of the operation of distribution - calibration of the end of the pipe; figure 3 - matrix and fixed from movement of the pipe before performing the operation of axial crimping of the length of the calibrated section; figure 4 - the end of the axial crimping of the calibrated section of the pipe; figure 5 - Assembly of connected pipes using a centering ring of filler material; figure 6 - the operation of axial compression of the connected elements to achieve contact pressure on the inner and outer annular surfaces; in Fig.7 - one-piece connection with a remote external burr and new grains crystallizing in the joint zone (conventionally shown by dashed lines); on Fig - one-piece connection after straightening the pipe in Kosovalkovy straightening machine.

An embodiment of the invention is as follows.

On straight heat exchange tubes, operations are performed to prepare the outer surface of one of their ends for profiling: to cut their measured lengths and to clean the outer surfaces to a metallic sheen. Next, each stripped end of the pipe 1 (with diameters D ₁ and D ₂ ) is subjected to distribution - calibration by a rigid punch 2 and fixed by radial force from possible movements (Fig. 1). Then, informing the axial movement of the stepped punch 2, cause its introduction into the hole of the pipe. There is plastic deformation of the end of the pipe with the acquisition of an inner diameter equal to the working diameter of the stepped punch D ₃ (figure 2), and the formation of annular conical stiffness (conventionally marked with dots).

Then replace the stepped punch on the matrix 3 with a profiled working surface (figure 3) and produce a partial crimp of the calibrated section of the pipe to an outer diameter D _{5 by} moving the matrix relative to the fixed end of the pipe (figure 4).

Similar operations are performed at the mating end of the second pipe, mating in one-piece connection.

The surfaces of the profiled ends of the pipes and the intermediate ring 4 of the filler material before their assembly (Fig. 5) are degreased using a technique known in practice. The use of an intermediate ring, as well as profiled sections of connected pipes, greatly simplifies the alignment of the latter. After assembly, a gap is observed between the ends of the pipes to be joined (conventionally shown in enlarged view).

An axial compression force is applied to the pipes through the conical sections of the bulges (Fig. 6), which leads to the deformation of the intermediate ring and the appearance of contact pressures on the mating annular surfaces of the connected elements (conventionally shown by arrows).

After that, the material of the intermediate ring is melted by means of an electric arc in a protective medium, for example argon. The melting procedure can be performed both in automatic mode and in manual mode. In this case, the main technological parameters of argon-arc welding will be argon pressure, current value and rotation speed, for example, of a pipe, as well as the amount of molten filler material and the magnitude of the axial force previously applied to the pipes.

The shape of the intermediate ring allows preliminary heating of both the ring itself due to thermal conductivity and heat transfer due to the presence of contact pressure on the annular surfaces. Note that heating of the elements to be connected causes a decrease in strength characteristics and the appearance of a low-melting eutectic at the interface of the liquid phase. The consequence of this is accelerated diffusion at the junction of the connected elements. At the stage of cooling the weld, crystallization takes place with the formation and growth of new grains at the junction of the pipes being joined, as if flashing the joint with new grains (Fig. 7 is conventionally shown by dashed lines). The axial force applied before melting to the pipes is also maintained at the stage of formation of the solid phase of the joint, which provides a fine-grained structure of the weld. Thus, the inner weld of the joint is formed due to the diffusion process. In this case, reinforcement of the weld is achieved by increasing the wall thickness and there is no uncontrolled internal burr in the usual sense of the word.

After removing the external burr on the lathe (Fig. 7), the filler material that fills the volume of the outer annular groove provides some protection for the weld in both increasing its strength and improving corrosion resistance under certain conditions.

Giving the pipe straightness with minimal curvature, as well as plastic deformation of the weld and its heat-affected zones, is carried out by the dressing operation in a Kosovalkovy machine. The pipe acquires the same external diameter with additionally worked out plastic deformation by the weld and heat-affected zones, as well as ring stiffnesses that are plastic deformed during dressing and is characterized by increased strength properties of pipe materials in heat-affected zones (Fig. 8).

The resulting long pipe is subjected to bending by the running method with subsequent control of the weld.

A pilot test of the developed method took place in the manufacture of single-seam pipe studs from steel 10.

The initial geometric dimensions of the pipes were: outer diameter - 25 mm, wall thickness - 2.5 mm and lengths of 6.0 and 2.0 m. The pipe ends mating in the assembly along the outer surface of the ends were calibrated at a length of 40 mm to a diameter equal to 25 , 6 mm. Calibration of the ends of the pipes was carried out in a tooling on a horizontal double-acting hydraulic press with forces not exceeding 0.2 MN. The calibrated ends of the pipes were also crimped on a horizontal hydraulic press using a die, the minimum diameter of the working profile of which was 24.3 mm.

Then the pipes were laid on the lodgements, placing the ends to be mated in welding towards each other. Before assembly, the ends of the pipes and rings of filler material (for several samples) were degreased with acetone. Having placed an intermediate ring (also made of steel 10) between the profiled ends of the pipes, they were mechanically axially loaded to forces not exceeding 30 kN. The latter provided contact pressure at the ends of the joined pipes of steel 10 within 170 MPa, which amounted to approximately 80% of the yield strength of the processed material at room temperature.

Welding was carried out in manual mode with an argon pressure of 0.15 MPa and a welded current of 80–100 A. The welding time did not exceed 180 seconds. The weld was cooled under axial loading conditions.

External burr removal was performed on a lathe, giving it an external diameter of 25.6 mm.

Pipe straightening was carried out on the correct Kosovalkovaya machine when it was rotated with a speed of 400 rpm.

The final bending operation was performed on a TG-5 model bending machine using the method of rolling a pipe on a stationary mandrel using a roller.

Quality control of the welds was carried out by x-ray scanning, as required by the production conditions. All pipe studs had welds meeting the full package of requirements for them. And including the diameter of the holes in the weld. Its decrease was less than 8% in comparison with the initial diameter.

Tensile tests did not reveal a loss of strength properties of the welds and the destruction of the samples took place along the initial section of the pipe.

The invention is applicable in the manufacture of tube bundles of heat exchangers for oil refining, petrochemical, gas and other industries.

Claims (1)

A method of obtaining pipe studs mainly from homogeneous materials, including preparing pipes for welding, bending the end of one of the pipes along the radius, assembling this end of the pipe with a return pipe having a rectilinear generatrix, and forming a one-piece pipe joint by argon-arc welding, characterized in that the one-piece pipe joint form before flexible by forming a combined weld with subsequent plastic deformation of the specified weld and heat-affected zones, when forming a combined weld the weld seam is formed by an inner circumferential seam, which is obtained by diffusion welding of the pipes to be joined at the joint, and the outer circumferential seam, which is obtained by depositing filler material on the outer surface of the pipe joint, to form the said combined weld, the ends of the pipes to be joined are preformed to obtain an external ring recess during assembly when assembling between the pipes coaxially with them set the ring of filler material, which is placed in the said outer annular recess, and then pr axial compression of the pipes is carried out until contact pressures are obtained at the ends of the pipes to be joined and the side faces of the ring, the combined weld is formed in the process of melting the filler material of the ring in the volume of the outer annular recess, and then the bead is removed to obtain the outer diameter of the combined weld equal to the diameter of the weld zones, and the aforementioned plastic deformation of the combined weld and heat-affected zones is carried out by straightening the pipe by giving it a rotational and translational motion .

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