RU2238165C2 - Method for securing tubes to tube plates - Google Patents

Abstract

FIELD: plastic working of metals, possibly tube securing to tube plates of heat exchange apparatuses.

SUBSTANCE: method comprises steps of profiling tube ends for forming cylindrical tube end portions joined with tube through transition cone portion; forming on outer surface of loaded zone of end portions annular protrusion with trapezoidal cross section. Said protrusion is formed in detachable die with annular groove due to stepped radial squeezing of part of length of tube end portion for its subsequent expansion by drifting opening at simultaneously profiling inner surface of loaded zone. At stepped squeezing part of length of loaded zone of tube end portion is arranged by cantilever fashion relative to edge of annular groove of die and volume of said groove is partially filled with material of profiled end portion non-subjected to radial squeezing. During expansion process volume of annular groove of die is finally filled with tube material. Then tube end portion is placed in tube plate opening having annular grooves with trapezoidal and triangular cross sections; tube is fixed against possible movements and it is fixed.

EFFECT: enhanced reliability of securing tubes due to high-quality annular tightness zones between joined members.

9 dwg

Description

The invention relates to the field of metal forming, in particular to the processes of fixing pipes in the tube sheets of heat exchangers using the effect of localized directed plastic deformation of the pipe material.

A known method of securing pipes in tube sheets, including installing a heat exchange pipe at one end in a pipe hole, fixing it from possible movements, welding the pipe end to the front surface of the pipe lattice, followed by flaring the pipe by applying compressive force to its inner surface, for example, by mechanical rolling ( see Doroshenko P.A. 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 known method has a certain limitation in 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 endings containing cylindrical sections mating with a transitional conical section, the subsequent formation on the outer surface of the loaded section of the shaped ends of the annular protrusion of a trapezoidal cross section, the installation of each ending in the hole of the tube sheet, made with annular grooves of trapezoidal and triangular cross-section, fixing the pipe from possible displacements and its subsequent fixing in the hole of the tube sheet by applying compressive forces to the inner surface of the tip (RU 2171155 C2, 07.27.2001, B 21 D 39/06 - prototype).

The disadvantage of this method is the significant dependence of the service characteristics of one-piece connections from the alignment of the holes of the tube sheets and annular grooves cut into them. An annular protrusion of a profiled tip, having high strength characteristics, is placed in the corresponding annular groove of the hole of the tube sheet with an orbit that is variable in the gap relative to the surface of the latter. In this case, the fixing of the profiled end of the pipe in the hole of the tube sheet is associated with increased forces on the deforming end of the tool. The formed annular densities between the connected elements are determined by the intensity of the local plastic deformation of the bridge of the tube sheet, since the circumferential deformation of the pipe material in the protrusion is difficult.

The above is very acute when repairing tube bundles, when there are certain deviations of the diameters of the holes of the tube sheets from the nominal value.

The objective of the invention is to develop such a method of securing pipes in tube sheets, which would provide high-quality annular densities between the connected elements due to plastic deformation of the pipe material in the annular protrusion.

The technical result is achieved by the fact that in the method of fixing the pipes in the tube sheets, including profiling the ends of the pipe with the formation of the ends containing cylindrical sections, mating transitional conical section, the subsequent formation on the outer surface of the loaded section of the profiled ends of the annular protrusion of a trapezoidal cross section, the installation of each ending in the hole of the tube sheet made with annular grooves of a trapezoidal and triangular cross section, f ixing the pipe from possible movements and its subsequent fixing in the hole of the tube sheet by applying a compressive force to the inner surface of the ending, according to the invention, the formation of the trapezoidal cross-section of the annular protrusion of the annular protrusion on the outer, surface of the loaded portion is carried out in a detachable matrix with an annular groove by step radial crimping part of the length of the ending and the subsequent distribution of the ending by the burning of its hole with simultaneous by coating the inner surface of the loaded section, while the stepwise radial crimping of the length of the pipe ending is made with the cantilever arrangement of the length of the loaded section of the profiled ending relative to the edge of the annular groove of the matrix and partially filling the volume of the annular groove by placing in it the material of the part of the shaped ending that is not subject to radial crimping and retained its outer diameter, and in the process of distribution, the final filling of the ma erialom pipe volume annular groove matrix.

The implementation of the proposed method of fixing pipes in the tube sheets of the repair option allows to obtain high-quality annular densities between the connected elements and in cases where there are wide deviations of the geometric dimensions of the annular grooves from the nominal values.

This is due to the fact that using the design of the profiled tip the annular protrusion of a relatively non-hardened material, create the conditions of plastic deformation of the material (both in the radial and circumferential directions) in the annular protrusion during the formation of an integral connection. As a result, on the inner surface of the profiled tip after fixing the pipe in the hole of the tube sheet, peeling of the surface layers does not appear and the corrosion resistance does not deteriorate.

The invention is illustrated by drawings, where figure 1 shows the initial position of the segment of the split matrix and the profiled end of the pipe with increased geometrical dimensions in outer diameters; figure 2 is the stage of completion of the stepped radial crimping within a portion of the length of the profiled ending; figure 3 is the stage of implementation of the small stage of the conical mandrel in the opening of the ending; figure 4 - the end of the stage of formation of the annular protrusion by the introduction of a large step of the mandrel into the opening of the tip; figure 5 - connected elements before the preliminary fixing of the pipe with its profiled tip in the hole of the tube sheet; Fig.6 - the end of the stage of preliminary fixing of the pipe in the hole of the tube sheet; Fig.7 - the initial position of the stepped mandrel and the connected elements before their final fixing; on Fig - stage of the formation of the bell on the edges of the holes of the tube sheet; figure 9 - one-piece connection of the pipe with the tube sheet.

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, measuring length section 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, with the help of a rigid punch, the end is distributed to an external diameter exceeding the diameter of the hole in the tube sheet, for example, for a pipe 25 × 2.5 mm, the external diameter of the end after its distribution is 25 , 5 ... 25.7 mm.

Then the pipe is fixed from possible movements and, by moving the matrix with a stepped working cavity relative to its end, stepwise radial crimping is performed. As a result, three cylindrical sections with outer diameters D ₁ , D ₂ and D _{3 are formed} , mating with transitional conical sections. The pipe with its profiled tip is installed in the hole of a detachable matrix consisting of three segments (Fig. 1). The cavity formed by the segments upon their closure comprises an annular groove of a trapezoidal cross section. The pipe is fixed from possible movements outside the technological equipment (shown by arrows).

After that, the matrix segments are closed, causing a radial stepwise crimping within the part of the profiled ending, i.e. reprofiling it in this way to smaller external diameters D ₄ and D ₅ . However, part of the length of the profiled ending, retaining its geometric dimensions in terms of the outer diameter D ₂ and cantileverly located relative to the edge of the annular groove of the matrix, is placed in the volume of the latter, partially filling it (figure 2). It should be emphasized that stepwise radial crimping, on the one hand, causes transverse shear in the web of cylindrical sections, and on the other hand, forms a field of compressive stresses in the radial and tangential directions. This forms the immobility of the deformation zone during the subsequent operation on the pipe and eliminates the axial flow of the pipe material.

A stepped mandrel 3 is introduced into the hole of the profiled tip, which distributes a cylindrical section with an outer diameter D ₃ to the diameter of the matrix, with placement by bending deformation of the conical transitional section in the volume of the annular groove. Opposite the annular groove of the matrix, an annular cavity is formed (Fig. 3).

Further axial movement of the stepped mandrel leads to the plastic flow of the pipe material and the final formation of an annular protrusion by the influence of its larger step. Moreover, due to relatively small deformations, the pipe material in the annular protrusion does not undergo much hardening. The movement of the large step of the mandrel is limited by the inner edge of the annular groove of the matrix, which provides profiling of the inner surface of the tip (figure 4).

Then, the finally profiled tip is installed in the hole of the tube sheet, controlling the correct location of the pipe by the protrusion of the end face above the front surface of the tube sheet (Fig. 5).

A case of mechanical rolling is introduced into the hole of the ending and distribution of the section is performed (the action of the rolling rollers is conventionally shown by arrows) of the ending with a minimum diameter of the hole (Fig. 6).

The contact deformation of the tip causes non-contact bending deformation of the cylindrical (reference) portion of the tip with an outer diameter of D ₄ , causing the filling of the volume of the annular groove with a triangular cross section.

The final fixing of the pipe in the hole of the tube sheet is achieved by the introduction of the step of the step mandrel 5 into the hole of the tip (Fig. 7). In this case, by its small step, the tip blade is distributed to the diameter of the hole in the tube sheet with the formation of transverse shears in the sheet (shown by dashed lines) and the formation of a bell on the edges of the hole of the tube sheet (Fig. 8).

The permanent connection of the pipe with the tube sheet has enhanced service characteristics, where the density is achieved by annular protrusions, and its conservation is ensured by transverse shear realized in the canvas (Fig.9).

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

A pilot test of the developed method took place when fixing steel (steel 20) pipes with profiled endings in tube sheets made of steel 16GS with a thickness of 80 mm. The initial geometric dimensions of the pipe were: outer diameter - 25 mm, wall thickness - 2.5 mm. The outer surfaces of the ends of the pipes were previously profiled in the technological equipment of a double-acting hydraulic press, developing a maximum force of 0.6 MN. The cylindrical section of the tip with a minimum outer diameter was 23.8 mm, and a maximum outer diameter was 25.6 ^+0.05 mm. ^{By reprofiling,} it decreased to a diameter of 25.3 ^+0.05 mm. The width of the transition conical sections was 2.0 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: base - 6 mm, depth - 0.3 mm; with a trapezoidal cross-section: large base - 4.0 mm, small base - 2.0 mm, depth - 0.4 mm.

The preliminary fastening of the pipe in the pipe hole was performed on a rolling stand of the company Indresco (USA) with domestic-made rolling, and the final fastening was performed on the backing complex manufactured and operated at the Repair and Mechanical Plant LLC of NK YUKOS, with efforts not exceeding 0, 2 MN

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

It has been established that the formation of one-piece joints using tips having profiled both external and internal surfaces, in combination with a bell on the edges of the holes of the tube sheet 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 (failure took place outside the fastening along the initial section of the pipe).

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 (1)

A method of securing pipes in tube sheets, including profiling the ends of the pipe with the formation of endings containing cylindrical sections mating with the transitional conical section, the subsequent formation on the outer surface of the loaded section of the profiled ends of the annular protrusion of a trapezoidal cross section, the installation of each ending in the hole of the tube lattice made with ring grooves of a trapezoidal and triangular cross-section, fixing the pipe from possible movements and its subsequent fixing in the hole of the tube sheet by applying compressive force to the inner surface of the tip, characterized in that the formation on the outer surface of the loaded portion of each profiled tip of the annular protrusion of the trapezoidal cross section is carried out in a detachable matrix with an annular groove by stepwise radial crimping of the length of the ending and the subsequent distribution of the ending by the burning of its hole with the simultaneous profiling of the inner surface of the load of the section, while the stepwise radial crimping of the part of the length of the pipe end is made with the cantilever arrangement of the part of the length of the loaded section of the profiled ending relative to the edge of the annular groove of the matrix and the partial filling of the volume of the annular groove by placing in it the material of the part of the profiled ending that is not subject to radial crimping and retains its the outer diameter, and in the process of distribution, the final filling of the volume of the annular matrix groove with the pipe material s.

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