RU2238164C2 - Method for securing tubes to tube plates - Google Patents

Abstract

FIELD: plastic metal working, possibly securing tubes to tube plates of U-shaped heat exchanging apparatuses.

SUBSTANCE: method comprises steps of profiling tube ends for forming on them cylindrical end portions joined through cone transition cone portions; placing formed end portion of tube into tube plate opening having inner and outer annular groves. Outer annular grove is in the form of annular recess in which sleeve of plastic material is arranged at minimum gap. Inner groove has triangular cross section. At placing tube end portion, its transition cone portion is arranged in front of said inner annular groove. Tube is fixed against possible motion due to axial compression of sleeve of plastic material and further axial displacement of tube relative to deformed sleeve at arranging transition cone portion of tube in front of inner annular groove of tube plate opening. Then tube is fastened in opening of tube plate by drifting tube and expanding its end portion to cone.

EFFECT: improved reliability of securing tubes to tube plates due to high-quality annular tightness zones on outer surface of tube end portions.

2 cl, 6 dwg

Description

The invention relates to the field of metal forming and, in particular, to processes for fixing pipes in tube sheets of U-shaped heat exchangers using the effect of localized directional plastic deformed pipe material.

A known method of fixing pipes in tube sheets, in which a heat exchange pipe is installed at one end in a pipe hole, it is fixed from possible axial movement, the pipe end is welded to the front surface of the tube sheet, followed by flaring of the pipe by applying a compressive force to its inner surface, for example, mechanical rolling (see. P. Doroshenko. Production technology of ship steam generators and heat exchangers. - Leningrad: Shipbuilding, 1972, 143 pp.).

The main disadvantage of the known method of securing pipes in tube sheets should include the increased cost of production of combined compounds. In addition, the latter have a certain restriction on use, since not all materials forming pairs of connected elements are weldable.

There is also known a method of securing pipes in tube sheets, including profiling the ends of the pipe with the formation of cylindrical sections mating transitional conical section, installing the pipe ending in the hole of the pipe lattice, made with an outer annular groove and an inner annular groove of a triangular cross section, placing a transitional conical section opposite the inner annular grooves, fixing the pipe from possible movement and its subsequent fixing in the hole of the tube sheet by attachment eniya compressive force to the inner surface ending (RU 2174888, C2, B 21 D 39/06, BI 29 of 20.10.2001 - a prototype).

The disadvantages of the known method for tube bundles repair option is a significant dependence of the service characteristics of one-piece connections from the accuracy of the geometric dimensions of the holes of the tube sheets. As a result, the application of increased pressures to the inner surface of the pipe at the stage of bell formation is required.

The objective of the invention is the development of such a method of securing pipes in the tube sheets of the repair option, which would provide high-quality ring densities on the outer surface of the pipe ends when forming a bell.

The technical result is achieved by the fact that in the method of fixing pipes in the tube sheets, including profiling the ends of the pipe with the formation of cylindrical sections mating transitional conical section, installing the pipe ending in the hole of the tube sheet, made with an outer annular groove and an inner annular groove of a triangular cross section, fixing pipes from possible movement and its subsequent fixing in the hole of the tube sheet by applying compressive forces to the inner surface endings, according to the invention, the outer annular groove is made in the form of an annular recess, where a sleeve of plastic material is placed with minimal gaps between the connected elements, when installing the pipe in the hole of the tube sheet, the transition conical section is placed in front of the inner annular groove and the pipe is fixed by axial compression of the sleeve until irreversible deformations of its material, after which the pipe is axially displaced relative to the deformed sleeve, having a transitional conical Astok opposite inner circumferential groove, and in the final fastening operation is performed dornovanija holes ending where the final stage of its distribution on the cone shape ending in a bell flow sleeve material in the direction opposite to the direction of the applied force.

Implementation of the proposed method of fixing pipes in the tube sheets of the repair option allows to obtain high-quality annular densities on the outer surface of the pipe ends when the bell is formed.

This is because, using the intermediate element in the form of a sleeve of plastic material in the joint design, significant frictional forces are realized on the contact surface of the pipe with the material of the intermediate element, when the pre-fixed pipe by plastic deformation of the material of the intermediate element is moved in the axial direction. The latter, in combination with the residual contact pressure of the permanent connection and the temperature effect of the friction forces transferred to heat, as well as taking into account the heating temperature of the tube bundle during its operation, creates prerequisites for the diffusion of the material of the intermediate element into the pipe material. As a result, there is an increase in the mentioned annular densities during the operation of the tube bundle.

In addition, the use of an intermediate element removes the dependence of the service characteristics of the obtained compounds on the stored accuracy by the openings of the tube sheet and does not require increased pressures on the inner surface of the tip.

The invention is illustrated by drawings, where in Fig.1 - shows the initial position of the connected elements and tooling before fixing the pipe in the hole of the tube sheet; figure 2 - stage of fixing the pipe on the walls of the pipe hole; figure 3 - stage of the end of the axial displacement of the pipe relative to the deformed intermediate element; figure 4 is the stage of burnishing the ending of the hole; figure 5 - the end of the stage of formation of the bell; figure 6 - one-piece connection of the pipe with the tube sheet repair option.

An embodiment of the invention is as follows.

On the heat exchange pipe 1 (Fig. 1), operations are performed to prepare the outer surface of its ends for profiling: straightening the pipe, a length of its measured length and cleaning the surface of the ends to a metallic sheen.

Next, the ends of the pipe are profiled, for which the pipe is fixed from possible movements and, by means of a rigid punch, its end is distributed to an external diameter exceeding the diameter of the hole in the tube sheet. Then carry out a radial step crimping of the pipe section, subjected to the operation of distribution. As a result of the formation of the tip, two cylindrical sections are formed, conjugated by a transitional conical section. The cylindrical end portion having the largest diameter is performed with a diametrical clearance with respect to the diameter of the hole in the tube sheet equal to 0.05 mm. This ensures the symmetry of the placement of the pipe in the hole of the tube sheet.

Similar operations are performed at the second end of the pipe.

Then the beam is packed, i.e. installation of pipes in the tube sheet 2 and partitions. The holes of the tube sheet contain annular recesses and annular grooves of a triangular cross section. As a controlled parameter when stuffing the tube bundle, the tip of the tip ends above the front surface of the tube sheet, which ensures the location of its transition conical section in front of the annular groove. In the gap between the cylindrical portion of the ending with the smallest diameter and the lateral surface of the annular recess, a sleeve 3 of plastic material, for example aluminum, is placed.

On the protruding part of the tip have a sleeve punch 4, and in its hole a small step of the mandrel 5 (figure 1).

Next, pre-fixing the pipe on the walls of the pipe hole. Why axial force is applied to the end of the sleeve punch (figure 2). In the sleeve 3, which receives axial forces, a shear surface is formed (shown by dashed lines) and there is an extrusion of the material of the sleeve into the gap outside the annular recess. Note that the process of extruding the material of the intermediate element into the said gap is accompanied by frictional forces between the intermediate element and the pipe (shown by horizontal arrows). Removing the sleeve deforming force causes the appearance of residual contact pressure by which the pipe is held in the pipe hole.

Then produce the axial loading of the ends at the ends, causing the placement of their transitional conical sections opposite the annular grooves. The work done to overcome the friction forces on the contact surface of the connected elements causes activation of the outer surface of the tip, preparing it for the subsequent formation of metal bonds.

Then apply axial force to the end of the mandrel 5, telling him the movement in the axial direction (figure 3). The introduction of the step of the mandrel in the ending hole leads at the first stage to the distribution of the cylindrical section with the smallest outer diameter and the settlement of the material of the sleeve (figure 4). Further movement of the mandrel in the axial direction causes the formation of transverse shears in the leaf of the tip and filling the pipe material with an annular groove.

At the final stage of final fastening, when a bell is performed by distributing the bell onto the cone, intensive extrusion of the material of the intermediate element in the direction opposite to the direction of the applied force is observed. The plastic flow of the material of the intermediate element is accompanied by its intense heating, which in the presence of a juvenile outer surface of the tip leads to the formation of elastic crystallization centers. The latter are a harbinger of the diffusion process. The operation of the tube bundle with sufficiently high temperatures intensifies the mentioned diffusion of aluminum into steel, which increases the annular density between the connected elements.

A pilot test of the developed method took place when fixing steel (steel 20) pipes with profiled external ends in pipe grids with a thickness of 80 mm from steel 16 GS. The initial geometric dimensions of the pipe were: external diameter 25 mm, wall thickness 2.5 mm. The outer surfaces of the ends of the pipe were previously profiled in the technological equipment of a double-acting hydraulic press, developing a force of 0.6 MN. The cylindrical section of the tip with a minimum outer diameter was 24.3 mm, and a maximum outer diameter was 25.3 ^-0.05 mm. The width of the transition conical section was 2 mm.

Pipe holes were made with diameters equal to 25.35 ^+0.05 mm. The annular grooves of the pipe hole with a triangular cross section had: a base of 6 mm, a depth of 0.3 mm.

The annular recesses had a depth of 10 mm and a diameter of 28 mm.

The intermediate element was made of aluminum of the ADO brand by cutting from a pipe with a length equal to 10 mm.

Preliminary fastening of the pipe in the pipe hole was performed at the back-up complex manufactured and operated by PKU Yukos Repair and Mechanical Plant LLC, with efforts not exceeding 0.07 MN. The axial movement of the tips relative to the intermediate elements was also carried out on the said complex.

Final fixing was performed on the same complex with efforts of not more than 0.2 MN.

The tooling for the production of pipes with external annular endings and their fastening in the pipe holes was made of U8A tool steel with a hardness of HRC after hardening of at least 56 units and an accuracy of executive dimensions of the 9th grade.

It has been established that the formation of one-piece joints using profiled endings, in combination with intermediate elements and residual pressure on the contact surfaces, provides guaranteed enhanced service characteristics of the joints; eliminates any defect affecting the operation of the tube bundle.

Tests for pulling the pipe out of the tube sheet confirmed the increased strength characteristics of one-piece joints.

The density of the compounds combined with high corrosion resistance ensured 100% their suitability for production requirements.

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

Claims (2)

1. The method of securing pipes in tube sheets, including profiling the ends of the pipe with the formation on each of them endings in the form of cylindrical sections mating transitional conical section, installing the pipe obtained by the ending in the hole of the tube sheet, made with outer and inner annular grooves, the last of which has a triangular cross-section, fixation of the pipe from possible movement and its subsequent fixing in the hole of the tube sheet by applying a compressive force to the inner The surface of the tip, characterized in that the outer annular groove is made in the form of an annular recess in which a sleeve of plastic material is placed with a minimum clearance, when installing the pipe in the hole of the tube sheet, the transitional conical section of the pipe is placed in front of the inner annular groove, the pipe is fixed from possible movement by axial compression of the sleeve of plastic material until irreversible deformations appear in it and subsequent axial displacement of the pipe relative to the deformed sleeve with by arranging the transitional conical section of the pipe opposite the inner annular groove of the tube sheet, and fixing the pipe in the hole of the tube sheet is done by burning the hole in the end of the pipe and distributing the tip into the cone, which is carried out at the final stage of the burner with the formation of a bell in the flow material of the sleeve of plastic material in direction opposite to the direction of the applied force. 2. The method according to claim 1, characterized in that it is intended for fastening pipes in U-shaped heat exchangers.

Images