CH615369A5 - Method for the hydraulic pressure-tight fixing of tubes in holes of tube plates - Google Patents

Description

The invention relates to a method for the hydraulic pressure-tight fastening of tubes in bores of tube plates, in particular in heat exchangers, in which the tubes are inserted into the bores with play, then expanded by a hydraulic pressure medium and pressed against the bore wall.

The long-known method of mechanically rolling in the tubes has hitherto been used for fastening tubes in bores of tube plates for heat exchangers. The connection between the tube and the tube plate represents a manufacturing process of great safety and procedural importance in apparatus engineering. The requirements for the safety and service life of such a tube fastening have increased significantly in recent years in general and especially with regard to the use of heat exchangers in nuclear power plants . These increased quality requirements cannot be met with mechanical rolling to a sufficient extent, apart from the fact that the rolling process is relatively time-consuming.

According to another known method for fastening tubes in bores, the tube is expanded using a hydraulic pressure medium and pressed against the bore wall, the material of the tube plate surrounding the wall being partially deformed as well.

A device by means of which pipes can be fastened in bores by hydraulic expansion is known from DE-OS 24 00 148.

The process of hydraulically expanding pipes is superior to mechanical rolling in terms of handling and economy. As far as the reliability of the tightness under all expected operating conditions is concerned, however, the results of the hydraulic expansion methods which have become known so far are not yet satisfactory.

The object of the invention is to further develop known methods of fastening pipes pressure-tightly in bores by hydraulic expansion in such a way that, taking into account the materials and the geometric dimensions, a desired tensioning of the tube in the bore, i. H. a previously determinable adhesive pressure is achieved. The adhesive pressure is a measure of the force with which the tube is held in the tube plate against axial pulling out of the bore.

This object is achieved according to the invention in that the pressure of the hydraulic pressure medium is increased up to a pressure value at which such an expansion of the tube and the bore wall has occurred that after the pressure relief, the difference between the unobstructed elastic return paths of the tube and the bore wall is positive and thus a permanent clasping of the tube is generated by the bore wall.

A further embodiment is that the pressure of the hydraulic pressure medium can be increased continuously.

The invention conveys the knowledge that it is necessary to increase the expansion pressure above a predetermined limit value in order to achieve a perfect pipe fastening, in which the pipe is under a predetermined clamping force after the expansion process in the bore. This limit is the pressure at which the unobstructed elastic return paths of the bore and the pipe are the same, i.e. H. their difference is zero. The physical relationships are explained below.

An important advantage of the new method is that the required expansion pressure can be set precisely on account of the measurable working pressure of the liquid pressure medium, and consequently a high degree of accuracy can be achieved in achieving the desired tensioning of the pipe. The precisely measurable working pressure also ensures a high level of uniformity with the large number of repeated pipe attachments on a single pipe plate. In addition, the expansion zones can be precisely limited when using a device as is known from the aforementioned publication. This makes it possible to reliably avoid a gap between the tube and the tube plate, even at the end of the hole on the inside of the plate. The expansion zone is placed up to the edge of the hole. Until now, it was not possible to roll to the edge without endangering the pipes. Existing gaps in pipe fastening are known causes of corrosion nests.

Details of the invention are explained below using an exemplary embodiment and with the aid of drawings. Show it:

Fig. 1 is a schematic representation of a device for hydraulic expansion of pipes with the aid of a probe and

Fig. 2 is a diagram of the course of the deformation of the tube and tube plate during the expansion process.

The device for expanding shown in FIG. 1 contains a probe 1, a pump 2, a pressure converter or multiplier 3, a pressure measuring device 4, an overflow valve 5, a reservoir 6 for pressure fluid and a switching valve 7.

The pipe 8 to be expanded is inserted into the bore of a pipe plate 9. The probe 1 contains a cylindrical mandrel, on which two sealing rings 10 are mounted in circumferential grooves, which seal an annular expansion space between them at the ends.

The expansion device works as follows:

Before the expansion begins, the secondary area is filled with liquid and the step piston of the multiplier 3 is pressed into the starting position shown in the drawing. This state is achieved in that the switching valve 7 is brought into the “fill” position. The switching valve is then switched to the "expand" position. The pressure generated by means of the high-pressure pump 2 acts on the large cross-sectional area of the step piston of the multiplier 3, as a result of which a correspondingly increased pressure is generated in accordance with the cross-sectional ratio of the step piston in the secondary region. The working pressure in the secondary area is checked using the pressure measuring device 4 in the primary area. The primary pressure is limited by the overflow valve 5. As soon as the desired one

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Maximum pressure has been reached, the liquid is discharged from the primary area into the reservoir 6 via the overflow valve.

After the expansion process has been completed, the switching valve is moved to the "Relieve" position. The probe 1 can then be pulled out of the expanded tube 8 without difficulty.

Fig. 2 shows the course of the deformations of the tube 8 and the tube plate 9 during the expansion process. In area a, the tube 8 is subjected to elastic stresses up to the yield point with constantly increasing pressure of the pressure medium. In area b, the pipe 8 flows until it has bridged the clearance between the outer wall of the pipe and the wall of the bore. This process takes place without any appreciable increase in the pressure of the pressure medium. The elastic deformation of the bore wall in the tube plate 9 takes place in the area c, the tube 8 simultaneously being plastically deformed.

The final pressure is calculated taking into account the materials, the geometry of tube 8 and tube plate 9 and with regard to the desired adhesive pressure and set at the overflow valve 5.

The distances a and c plotted on the radial coordinate in FIG. 2 are a measure of the elastic deformation of the tube and the tube plate. At the same time, they also reflect the unimpeded elastic return paths of these two components. As can be seen from the diagram, the distance c is greater than the distance a, d. H. the difference between the unobstructed elastic return paths of the plate bore and the tube is positive.

The expansion pressure at which the unimpeded elastic return paths of the plate bore and tube are the same size, i.e. H. c '- a = o, is called the limit pressure. If the working pressure just reaches this limit during expansion, the pipe is in contact with the wall of the bore after the pressure relief, but there is practically no clasping and therefore no adhesive pressure. This shows that in order to achieve a firm pipe connection, it is necessary to increase the working pressure to above the limit pressure mentioned during the expansion process.

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Numerical example

Pipe outside diameter

Pipe wall thickness

Pipe material

Pipe plate material

Triangle division results:

Flow pressure of the pipe

Limit pressure

Final pressure

Adhesive pressure, calculated

22 mm 2.9 mm Incoloy 800 22 NiMoCr 37 30 mm

1995 bar 3106 bar 4700 bar 728 bar s

1 sheet of drawings

Claims (2)

615 369 2 P ATENTANS PRÜCH E 1. A method for hydraulic pressure-tight fastening of pipes in the bores of tube plates, in particular in heat exchangers, in which the tubes are inserted into the bores with play, expanded by a hydraulic pressure medium and pressed against the bore wall, characterized in that the pressure of the hydraulic pressure medium is increased up to a pressure value at which such an expansion of the tube and the bore wall has occurred that after the pressure relief the difference between the unrestricted elastic return paths of the tube and the bore wall is positive and thus a permanent clasping of the tube is generated by the bore wall. 2. The method according to claim 1, characterized in that the pressure of the hydraulic pressure medium is continuously increased.