EP0215294A2 - Apparatus for the hydraulic expansion of tubes - Google Patents

Abstract

1. A hydraulic tube expander having : a cylindrical probe (3) introducible into the tube ; at least two spaced-apart ring seals (4) each received in an annular groove (6) in the probe (3) ; and a connecting line (7) which is connected to a pressure medium supply and which supplies pressure medium to the seal-receiving grooves (6) and to the probe outer periphery disposed between the at least two ring seals (4), characterised in that the pressure medium supply to the probe outer periphery disposed between the at least two ring seals (4) is solely by way of at least one of the seal-receiving grooves (6) and at least one aperture (9, 9a) between the groove (6) and the said outer periphery, such aperture being disposed on that side of the groove (6) which is near the outer periphery, is closed in the normal state by the ring seal (4), the same being operative as a valve lid, and is open only when the ring seal (4) engages sealingly in the expanded state with the tube (2).

Description

The invention relates to a device for the hydraulic expansion of pipe sections, preferably pipe ends within a pipe disk, by means of a cylindrical probe which can be inserted into the respective pipe and which, by means of at least two spaced-apart sealing rings, forms an annular space with the pipe section to be expanded, which is filled with pressure medium for expansion is, the two sealing rings are each arranged in an annular receiving groove of the probe, in the initial state when inserting the probe into the tube have an outer diameter which at most corresponds to the outer diameter of the probe and before the start of the expansion process to seal the annular gap between the probe and the tube by acting on it Pressure medium are expanded, which is supplied to the receiving grooves through a connecting line connected to the pressure medium supply.

Such devices for the hydraulic expansion of pipe sections are known. In order to facilitate the insertion of the probe into the tube to be widened, the sealing rings arranged in receiving grooves have an outer diameter in the initial state which does not exceed the outer diameter of the cylindrical probe. Compared to the still known construct tions in which the sealing rings constantly protrude from the cylindrical outer surface of the probe, large forces are avoided when inserting the probe, which were caused by the friction between the sealing rings and the pipe to be expanded and could lead to damage to the sealing rings. In order to ensure a reliable seal of the annular space corresponding to the pipe section to be expanded, the sealing rings lying in the initial state within the outer surface of the probe must be widened. For this purpose, they are elastically expanded by applying pressure medium before the expansion process begins. This expansion is achieved in that the sealing rings are acted upon on their inside with pressure medium, which is supplied to the respective receiving groove before the actual expansion process begins. In a construction known from Japanese Laid-Open Publication 55-50 933, the sealing rings are pressurized with the aid of control slides which are arranged in the pressure medium supply and which first supply the pressure medium to the receiving grooves of the sealing rings before it is fed via a pressure medium line into the annular space sealed by the sealing rings between the probe and the pipe to be expanded.

In another device of the type described at the beginning of DE-PS 3 105 736, another method is selected. Here, the pressure medium supplied through parallel connecting lines to the receiving grooves of the sealing rings and the annular space should first be supplied to the annular space by different flow velocities in order to displace the air in the cavity before the sealing rings are to be widened by an increased flow velocity.

While the disadvantages of the Kon structure in the use of expensive and fault-prone control spools, difficulties arise in practical application with the construction mentioned in the second place. The diameter differences occurring in practice and different roughnesses of the pipes to be expanded often prevent the sealing rings from expanding, which is necessary for reliable sealing of the annular space after it has been filled, since these are subjected to pressure medium of the same pressure on opposite surfaces.

The invention has for its object to design a device of the type described in such a way that a reliable expansion of the sealing rings and thus sealing of the annular space is achieved before the actual expansion process begins, without the need for expensive and failure-prone control slides.

The solution to this problem by the invention is characterized in that the pressure medium supply to the annular space takes place exclusively via at least one of the receiving grooves and is controlled by the sealing ring serving as a valve body, which closes at least one opening formed between the receiving groove and the annular space until it is elastic Expanding has reached its sealing effect.

The device according to the invention thus does not require any control slide to be arranged in the probe, in order to achieve, after inserting the probe with sealing rings lying within its outer surface in the pipe section to be expanded, first of all sealing rings and thus sealing of the annular space before the actual expansion process by supplying pressure medium in the annulus begins. Since the pressure medium supply to the annulus is not, in contrast to the known devices Via one or more connecting lines, which are formed in addition to and parallel to the connecting lines to the receiving grooves in the probe, but exclusively via at least one of the receiving grooves, there is an inevitable consequence in the application of the sealing rings and the filling of the annular space, which leads to a reliable sealing effect of the sealing rings. The sealing ring itself is used here as a valve body which closes the opening formed between the receiving groove and the annular space until it is widened to such an extent that it achieves a reliable sealing effect. Due to the design according to the invention, the device can also be used for the hydraulic expansion of pipe sections of pipes whose diameters fluctuate within a larger tolerance range and which have different roughnesses.

According to a further feature of the invention, each receiving groove is sealed in the initial state by the sealing ring against the lateral surface of the probe and is provided on the side facing the annular space with at least one opening through which the receiving groove is connected to the annular space when the sealing ring is expanded. The cross section of the sealing rings can be of any design; Various configurations are also conceivable for the formation of the openings between the receiving groove and the annular space.

In a preferred embodiment of the invention, the receiving groove has a U-shaped cross section; it is provided in its edge adjacent to the annular space with at least one oblique incision which forms the opening to the annular space which can be closed by the sealing ring. In the simplest version, the sealing ring has a circular cross section.

In order to achieve the fastest possible filling of the annular space with pressure medium after the sealing rings have been widened, according to a further feature of the invention both receiving grooves can be provided in their edge adjacent to the annular space with a plurality of incisions evenly distributed over the circumference. Alternatively, the opening between the annular space and the receiving groove can be formed by a peripheral chamfer on the side of the receiving groove facing the annular space.

Furthermore, it is possible to provide the two receiving grooves with a chamfer on their edge facing away from the annular space, as a result of which an increased sealing effect of the sealing rings, which are preferably in the form of D-rings, is achieved when these are expanded during the expansion process with the increased pressure of the pressure medium located in the annular space be charged.

Since the hydraulic expansion of pipes works with a pressure in the order of 3000 bar, the air trapped in the annular space by the expansion of the sealing rings first is not only compressed to a fraction of its original volume; the air is also in the usual use of water as a pressure medium at such a high pressure in solution, so that venting of the annular space is not necessary. Due to the elasticity of the sealing rings, these automatically return to their starting position after the expansion process and reduction of the pressure, in which their outside diameter is not greater than the outside diameter of the probe, so that it can be easily extracted from the widened pipe section and any subsequent not expanded tube can be pulled out.

• Fig. 1 eine Ansicht einer Sonde, die in das Ende eines Rohres eingeführt ist, das zur Anlage an einer Rohrscheibe aufgeweitet werden soll,
• Fig. 2 einen Querschnitt durch die Sonde gemäß der Schnittlinie II - II in Fig.l,
• Fig. 3 einen Schnitt durch den in Fig.l eingekreisten Teil, der einen in einer Aufnahmenut liegenden Dichtring zeigt, und zwar nach dem Einführen der Sonde in das Rohr und vor Beginn der Druckmittelzufuhr,
• Fig. 4 einen der Fig.3 entsprechenden Schnitt zu Beginn der Druckmittelzufuhr, die zu einem Aufweiten des Dichtringes geführt hat,
• Fig. 5 eine weitere Schnittdarstellung gemäß den Figuren 3 und 4 während des eigentlichen Aufweitvorganges,
• Fig. 6 einen weiteren Schnitt gemäß den Figuren 3 bis 5 nach Beendigung des Aufweitvorganges und nach Ablassen des Druckmittels,
• Fig. 7 eine der Fig.3 entsprechende Darstellung einer zweiten Ausführungsform und
• Fig. 8 diese zweite Ausführungsform in einer Darstellung gemäß Fig.5.

Two exemplary embodiments of the device according to the invention are shown in the drawing, namely:

• Fig. 1 is a view of a probe in the end of a Pipe is introduced, which is to be expanded to rest against a pipe disc,
• 2 shows a cross section through the probe along the section line II - II in Fig.l,
• 3 shows a section through the part encircled in FIG. 1, which shows a sealing ring lying in a receiving groove, specifically after the probe has been inserted into the tube and before the pressure medium is started,
• 4 shows a section corresponding to FIG. 3 at the start of the pressure medium supply, which has caused the sealing ring to widen,
• 5 shows a further sectional view according to FIGS. 3 and 4 during the actual expansion process,
• 6 shows a further section according to FIGS. 3 to 5 after the expansion process has ended and after the pressure medium has been released,
• 7 shows a representation corresponding to FIG. 3 of a second embodiment and
• 8 shows this second embodiment in a representation according to FIG. 5.

1 shows the end of a tube 2 inserted into a bore of a tubular disk 1, which is to be expanded hydraulically for pressure-tight fastening in the tubular disk 1. This hydraulic expansion is carried out with the aid of a device which comprises a probe 3 to be inserted into the pipe end to be expanded. In the part shown in FIG. 1, this probe 3 has a circular cylindrical shape, the outer diameter of which is slightly smaller than the inner diameter of the pipe 2 to be expanded.

Corresponding to the pipe section to be expanded, two sealing rings 4 are arranged in the probe 3, which in the exemplary embodiment have a circular cross section and consist of elastic material, preferably rubber or plastic. Due to the spaced-apart sealing rings 4 in the probe 3, an annular space 5 is formed with the pipe section to be expanded, which is filled with pressure medium to expand the corresponding pipe section. A liquid, preferably water, is used as the pressure medium. The pressure required to expand the pipe section is of the order of 3000 bar.

Each sealing ring 4 is arranged in a receiving groove 6 which, in the exemplary embodiment, has a U-shaped cross section, as can be seen in particular from FIGS. 3 to 8. The outer diameter of the sealing rings 4 corresponds at most to the outer diameter of the probe 3; in the exemplary embodiment, it is slightly smaller than the outer diameter of the probe 3. The sealing rings 4 are therefore within the lateral surface of the probe 3 when it is pushed into the end of the tube 2 to be widened as shown in FIG. This situation is shown for a sealing ring in Figures 3 and 7.

In order to seal the annular space 5 before the actual expansion process begins, the sealing rings 4 lying in the receiving grooves 6 are expanded. For this purpose, the annular receiving grooves 6 are each connected to the pressure medium supply 8 by means of at least one connecting line 7, which is shown in the embodiment in the form of a central bore in the probe 3 and leads to a pressure medium source not shown in the drawing. According to FIG. 4, the pressure medium supplied via the connecting line 7 to the respective receiving groove 6 leads to an expansion of the Sealing ring 4 so that it rests on the inside of the pipe 2 to be expanded and thereby seals the annular space 5.

According to the sectional view in FIG. 2, in the illustrated embodiment of the probe 3, each receiving groove 6 is provided with four openings on the side facing the annular space 5, which in the exemplary embodiment are each formed by an oblique incision 9 in the edge of the receiving groove 6 but also by a different type of passage can be formed. These incisions 9 are closed in the initial state by the sealing ring 4, which rests sealingly on the mutually opposite surfaces of the U-shaped receiving groove 6 in cross section, as long as it is not pressurized. Only when, according to FIG. 4, the sealing ring 4 has been expanded by the application of pressure medium and is in contact with the inner surface of the pipe 2 to be expanded, are the cuts 9 released, as shown in FIG. 5. The sealing rings 4 thus serve as valve bodies for the incisions 9 leading as openings to the annular space 5. The pressure medium is supplied to the annular space 5 exclusively via these incisions 9. A further connecting line between the annular space 5 and the pressure medium supply 8 is not provided in the probe 3.

The illustration in FIG. 5 shows that the sealing ring 4 is reliably pressed onto the inner surface of the pipe 2 to be expanded even during the supply of the pressure medium to the annular space 5, so that it ensures a secure sealing of the annular space 5 even at high pressures. The pipe section lying in the tubular disk 1 can thus be hydraulically expanded by applying a high pressure, as shown in the illustration in FIGS. 5 and 8. After the expansion process has ended, the pressure is released and the pressure drained medium. As a result, the sealing rings 4 return to their starting position due to their inherent elasticity, in which they lie according to FIG. 6 within the respective receiving groove 6, so that the probe 3 can subsequently be pulled out of the tube 2 without difficulty.

The design and number of openings shown in the embodiment in the form of incisions 9, as well as the design of the sealing rings 4, can be matched to the respective application. FIGS. 7 and 8 show a second embodiment in which the receiving groove 6 is provided with a chamfer 10 on its edge facing away from the annular space 5. The sealing ring 4, which is circular in the initial state, is pressed onto this chamfer 10, which extends over the entire circumference, when the full pressure has been built up for the hydraulic expansion process, as shown in FIG. In this embodiment, the opening between the receiving groove 6 and the annular space 5 is formed by a peripheral chamfer 9a, which is formed in the side of the receiving groove 6 facing the annular space 5.

• 1 Rohrscheibe
• 2 Rohr
• 3 Sonde
• 4 Dichtring
• 5 Ringraum
• 6 Aufnahmenut
• 7 Verbindungsleitung
• 8 Druckmittelzuführung
• 9 Einschnitt
• 9a Fase
• 10 Anfasung

List of reference numbers:

• 1 pipe disc
• 2 pipe
• 3 probe
• 4 sealing ring
• 5 annulus
• 6 receiving groove
• 7 connecting line
• 8 pressure medium supply
• 9 incision
• 9a bevel
• 10 chamfer

Claims (6)

1.Device for the hydraulic expansion of pipe sections, preferably pipe ends within a pipe disk, by means of a cylindrical probe which can be inserted into the respective pipe and which forms an annular space with the pipe section to be expanded by means of at least two spaced-apart sealing rings, which is filled with pressure medium for expansion, wherein the two sealing rings are each arranged in an annular receiving groove of the probe, in the initial state when inserting the probe into the tube have an outside diameter that corresponds at most to the outside diameter of the probe and, before the start of the expansion process, to seal the annular gap between the probe and the tube by applying pressure medium which is fed to the receiving grooves through a connecting line connected to the pressure medium supply,
characterized,
that the pressure medium supply to the annular space (5) takes place exclusively via at least one of the receiving grooves (6) and is controlled by the sealing ring (4) serving as a valve body, the at least one opening (9, 9a) formed between the receiving groove (6) and the annular space (5) ) closes until it has achieved its sealing effect through elastic expansion. 2. Device according to claim 1, characterized in that each receiving groove (6) is sealed in the initial state by the sealing ring (4) against the outer surface of the probe (3) and on the side facing the annular space (5) with at least one opening (9, 9a) is provided, through which the receiving groove (6) is connected to the annular space (5) when the sealing ring (4) is expanded. 3. Device according to claims 1 and 2, characterized in that the receiving groove (6) has a U-shaped cross section and is provided in its annular space (5) adjacent edge with at least one oblique incision (9). 4. The device according to claim 3, characterized in that both receiving grooves (6) in their annular space (5) adjacent edge are provided with several, evenly distributed over the circumference incisions (9). 5. Apparatus according to claim 1 and 2, characterized in that the opening between the annular space (5) and the receiving groove (6) is formed by a circumferential chamfer (9a) on the side of the receiving groove (6) facing the annular space (5). 6. The device according to at least one of claims 1 to 5, characterized in that the two receiving grooves (6) on their edge facing away from the annular space (5) are each provided with a chamfer (10).

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