EP2265415A1

EP2265415A1 - Method for the permanent connection of workpieces, compression tool, and attachment for a compression tool

Info

Publication number: EP2265415A1
Application number: EP09713367A
Authority: EP
Inventors: Frank Hofmann; Sudi Sinoplu; Andreas HÜTTE
Original assignee: Viega GmbH and Co KG
Current assignee: Viega Technology GmbH and Co KG
Priority date: 2008-02-19
Filing date: 2009-01-30
Publication date: 2010-12-29
Anticipated expiration: 2029-01-30
Also published as: PL2265415T3; EP2265415B1; DK2265415T3; PL2265415T6; CA2716178C; EP2602062A1; CA2716178A1; ES2449384T3; WO2009103605A1; US20110016696A1; US8567034B2; AU2009216886B2; DK2265415T4; CN101977735B; RU2446934C1; PT2602062E; DE102008010083A1; MX2010009167A; PL2602062T3; PT2265415E

Abstract

The invention relates to a compression tool (2) for the permanent connection of workpieces (14, 16, 18, 30, 34) having two pivot elements (4), which each have a compression jaw (10), and having at least one rotational axis (6), on which the pivot elements (4) are hinged, wherein the inner contours of the opposing compression jaws (10) form a receiving area (12). The present invention is based on the technical problem of disclosing an alternative compression tool (2), with which a permanent connection can be provided between workpieces (14, 16, 18, 30, 34) by axial compression. The technical problem is solved in that the inner contours have at least one sliding face (2), which is inclined relative to the receiving area axis (20). A compression tool (2) can thus be provided which, starting from a radial inward movement, performs a compression in the axial direction, nonetheless requires little installation space, and offers weight advantages due to a smaller axial extension, for example. Furthermore, the invention relates to an attachment for a compression tool (2) and to a method for the permanent connection of workpieces using a compression tool.

Description

Process for the permanent joining of workpieces, pressing tool and attachment for a pressing tool

The invention relates to a pressing tool for non-detachable joining of workpieces with two pivoting elements each having a pressing jaw and having at least one axis of rotation, on which the pivoting elements are articulated, wherein the inner contours of the opposing pressing jaws form a receiving area. The invention further relates to an attachment for a pressing tool with two pressing jaws, each pressing jaw having an inner contour and wherein the opposing inner contours of the pressing jaws form a receiving area. Furthermore, the invention relates to a method for non-detachable joining of workpieces using a pressing tool.

Press tools, attachments for pressing tools and methods of the type mentioned are from the prior art, for example from the drinking water or

Heating installation area already known. Preferably, the tools and methods are used to radially compress workpieces such as fittings, pipes, sleeves or the like. Pressing radially means essentially to transform by means of a pincer-like closing movement of two pressing jaws exhibiting pivoting two two at least partially arranged in overlapping workpieces and thus inextricably linked together. However, this procedure can be disadvantageous. With provided for this purpose pressing tools and methods, for example, the exercise of an all-round homogeneous pressing force on the workpieces to be pressed is much more difficult. Preferably, pipes and fittings have a rotationally symmetric and largely round shape before the pressing process. However, after the pressing process, this symmetry may be disturbed due to inhomogeneously acting pressing forces at the connection point between the pipe and the fitting, which on the one hand can impair the visual impression as well as the functionality of the connection.

Furthermore, the materials, especially plastics or metals of the claimed in the pressing workpieces can have a directed against the pressing forces inertia. This inertia can lead, in the form of restoring forces, to the fact that the material formed during the pressing process at least partially endeavors to restore the starting state or the starting structure of the workpieces. This requires the user of a radially inward pressing process to have to increase the radially inward pressing forces to obtain the desired pressing result. However, this is beyond the actual measure beyond and therefore generally undesirable use of the materials of the workpieces to be pressed.

The aforementioned problems can be solved or at least mitigated, in particular, by means of an axial compression technique. A homogeneous application of force is much easier to ensure in an axial pressing process. Although the restoring properties of the materials to be deformed basically also act in the axial direction, they can the effects of increased stress on the material due to the usually compared to the radial expansion long axial extent of the workpieces are kept low. A disadvantage of axially acting pressing tools, however, is that they occupy a wide mounting space and have a high weight. The use of such tools or the application of such methods is difficult for the installer.

The present invention is therefore based on the technical problem of specifying an alternative pressing tool, an attachment for a pressing tool or an alternative method, with which a permanent connection between workpieces by axial compression can be created.

The technical problem is solved with a pressing tool for permanent connection of workpieces with two each having a pressing jaw pivoting elements and at least one axis of rotation to which the pivot elements are hinged, wherein the inner contours of the opposed pressing jaws form a receiving area, that the inner contours at least have a sliding against the receiving area axis sliding surface.

The receiving area axis runs approximately perpendicularly to the surface located between the inner contours of the pressing jaws and substantially corresponds to the axis of a workpiece insertable for the purpose of pressing into the receiving area, for example a pipe or fitting.

By virtue of the sliding surface inclined towards the receiving region axis, the dynamics of a radially inwardly directed movement can at least partially extend in an axial direction Press force to be converted. During the pressing process, the pivoting elements and in particular the pressing jaws are moved toward one another about the axis of rotation, while the workpieces to be pressed are arranged in the receiving region between the pressing jaws. The inner contours of the pressing jaws are brought into contact with surfaces arranged on the workpieces to be pressed. By continuing the radially inward movement, the area remaining between the workpieces and the inner contours is narrowed. The lying in abutment with the workpieces sliding surfaces thus act as Kraftübertragungs- and Kraftumlenkungsflachen, because the sliding surface and the surface of the workpiece slide over each other while the workpiece is set in motion. In this way, although starting from a radially inward movement, a relative movement between the workpieces to be pressed in the axial direction can be generated and used for pressing.

As a result, a pressing tool can be provided which performs a compression in the axial direction, yet takes little mounting space and, for example, by a smaller axial expansion offers weight advantages.

It is possible to provide the inner contour of each pressing jaw with exactly one sliding surface. In this case, however, the inner contour preferably also has a projection acting as an abutment, which is arranged opposite the sliding surface on the other side of the inner contour of the pressing jaw. Preferably, this projection can engage behind a portion of a workpiece to be compressed, in particular of the workpiece, which is not in contact with the sliding surface, and thus for axial compression build up the necessary back pressure. A force deflection from a radially inward in an axial direction is not effected by the projection.

But it is also possible to provide two inclined against the receiving area axis, facing sliding surfaces. In this way, the deflected and applied for axial compression force can be increased. With symmetrical design of the two sliding surfaces and corresponding interaction surfaces on the workpieces, the deflected pressing force is for example doubled. It should be noted, however, that the design of the two sliding surfaces do not correspond to each other or must be symmetrical, but can also be carried out differently, if it is expedient for the application.

It is particularly advantageous if at least one sliding surface is designed as a cone segment. In this way, in particular the production of the inner contours of the pressing jaws and optionally the production of workpieces with adapted to these pressing jaws interaction surfaces, which are provided for the previously described type of pressing, simplified. As a result, a high degree of compatibility between the pressing tools described above and the workpieces to be pressed, such as pipes, fittings and the like, can be achieved.

Preferably, the angle of inclination of the sliding surface relative to the receiving area axis is between 35 ° and 55 °, in particular at 45 °. The angle of inclination essentially determines the distance of the radially inward movement which is to be covered in order to effect an axial movement over a certain distance. The flatter the angle of inclination, the farther it must go extend the inner contour of the die in the axial direction to achieve a certain Pressing result, whereas the radial extent of the die can be made quite narrow. An angle of, for example, 35 ° thus causes a quite efficient from the radial movement force deflection, whereas an angle of 55 °, although a longer radial path result, but ensures a higher stability during compression. The angle of 45 °, in turn, is particularly suitable to compensate between the two effects. In addition, the outer dimensions of the pressing jaws can be optimized in this way both in the radial and in the axial direction.

It is further particularly preferred that the sliding surface is designed to promote sliding. In this way, the inertia, which oppose the workpieces to be compressed to an axial evasive movement, at least be reduced, so that the pressing operation is easier to perform. The sliding surface to form sliding, can be done in different ways. It is possible to form the portion of the inner contour of the pressing jaw, which comprises the sliding surface, in two parts with the rest of the pressing jaw, and to manufacture the sliding surface of a material such as polytetrafluoroethylene or the like. However, it is also possible to increase the slipperiness by means of a sliding-promoting coating of the sliding surface, for example with a bonded coating. Likewise, it is possible, by smoothing the sliding surface, for example by polishing the sliding surface to form this slide-promoting.

According to a further teaching of the present invention, the technical problem is also solved by an attachment for a pressing tool with two pressing jaws, each pressing jaw a Having inner contour and wherein the opposing inner contours of the pressing jaws form a receiving area, solved by the inner contours have at least one inclined against the receiving area axis sliding surface.

In this way, originally provided for the radial compression pressing tools can be made suitable for axial compression in a simple manner. The new production of the changed requirements correspondingly adapted pivoting elements is therefore no longer necessary, resulting in particular economic benefits.

With regard to further advantages of the article according to the invention for pressing tools, reference is made to the subclaims or to the comments on the pressing tool according to the invention.

According to another teaching of the present invention, the technical problem is also solved by a method for non-detachably connecting workpieces using a pressing tool, in particular as described above, in which the pressing tool is actuated radially inwardly, wherein at least one of the pressing tool arranged against the workpiece axis inclined sliding surface and a workpiece surface are brought into abutment with each other, in which the radially inwardly exerted pressing force is transmitted from the sliding surface to the workpiece surface and at least partially deflected in the axial direction and in which the workpieces are pressed in the axial direction.

The sliding surface preferably faces a correspondingly adapted workpiece surface. As a result, in particular, a larger contact surface between sliding surface and workpiece surface created. In this way, for example, the stability of the pressing process can be increased.

With regard to further advantages of the method according to the invention, reference is made to the subclaims or to the statements relating to the pressing tool according to the invention or to the attachment according to the invention for pressing tools.

In the following the invention will be explained in more detail with reference to embodiments illustrated in a drawing. In the drawing show:

1a, b an embodiment of the pressing tool before the pressing process in two different views,

Fig. 2a, b, the embodiment of the pressing tool of FIGS. Ia, b after the pressing process in two different views and

Fig. 3 shows another embodiment of the application of a pressing tool according to the invention.

Fig. Ia shows a pressing tool 2 in a side view. The pressing tool 2 has two pivoting elements 4, which are pivotable about an axis of rotation 6 associated therewith. By providing two axes of rotation 6, the pivoting movements of the pivot elements 4 can be made more flexible. However, the provision of only one axis of rotation 6, to which both pivoting elements 4 are articulated, is also possible. By the pivot elements 4 in this example associated support members 8, the pivot elements 4 are interconnected. At a portion of the pivot elements 4 pressing jaws 10 are arranged, which each other form between them by means of their inner contours a receiving area 12. Depending on the position of the pivoting elements 4, the receiving region 12 can be kept closer or closer to one another. In this exemplary embodiment, a tube end 16 encompassed by a sleeve 14 and a fitting 18, which are particularly suitable for axial compression, are introduced into the receiving region 12. The sleeve 14 is connected to the tube 16 by fixing protrusions (not shown) disposed on the inner peripheral surface of the sleeve 14, which are anchored in the outer peripheral surface of the tube 16, so that the sleeve 14 and the tube 16 are not movable relative to each other.

The following describes the pressing process. Of course, the pressing tool 2 according to the invention or the method according to the invention is not limited to the use of the tubes 16, sleeves 14 or fittings 18 shown here by way of example.

The swivel elements 4 shown here by way of example can also be provided with removable pressing jaws 10. In this way, by means of an attachment according to the invention for a pressing tool 2 already manufactured pressing tools 2, which were originally provided for a radial compression, are made suitable for axial compression.

FIG. 1b shows, in a cross-sectional view of the arrangement from FIG. 1a, a fitting 18, a sleeve 14 and a tube 16 before a permanent connection between these three workpieces 14, 16, 18 is produced.

The inner contours of the pressing jaws 10 have, in this example, two mutually inclined towards the receiving area axis 20 facing sliding surfaces 22. Both sliding surfaces 22 are formed in this example as cone segments. Other forms are also conceivable. In particular, the inclination angle of the sliding surfaces 22 can be chosen freely. However, the inclination angle of the sliding surfaces 22 relative to the receiving area axis 20 is in this example constant at about 45 °. However, deviations from this value, for example up to 35 ° or 55 ° or possibly beyond, are also possible. In this exemplary embodiment, not shown, the sliding surfaces 22, for example by means of a coating to be designed to be slippery.

The fitting 18 has centrally at its Grundkorper a recess 24 with chamfered Rare walls. The inclination angle of the side walls is in this example advantageously adapted to the inclination angle of the sliding surfaces 22 on the pressing jaws 10. Further, the sleeve 14 on its flange-like projection on a chamfer 26, which is also adapted to the inclination angle of the sliding surfaces 22, that is about 45 ° in this example. In this way, the pressing process can be stabilized in particular. Before the pressing operation, the sliding surfaces 22 are in contact with the aforementioned Werkstuckflachen, for example, the chamfer 26 of the sleeve 14 or the side wall of the recess 24 of the fitting 18th

Fig. 2a shows the state of the pressing tool 2 and the workpieces 14, 16, 18 after the pressing process m a side view. The pivot elements 4 are pivoted inwardly, so that the abutment surfaces 28 of the pressing jaws 10 abut each other. FIG. 2b shows the arrangement of FIG. 2a in a cross-sectional view. Due to the radially inward movement of the pressing jaws 10, the exerted force was at least partially transmitted via the abutting sliding surfaces 22 and workpiece surfaces of the pressing tool 2 onto the workpieces, in this example FIGS Sleeve 14 and the fitting 18 and thereby deflected in the axial direction. As a result, in this example, the sleeve 14 and the tube 16 connected to the sleeve 14 as well as the fitting 18 are moved toward one another, or in other words, pressed together.

After the axial pressing process is an on the

Outer circumferential surface of the sleeve 14 arranged latching projection locked in a arranged on the inner peripheral surface of the outer body of the fitting 18 locking groove, so that an axial removal of the encompassed by the sleeve 14 pipe end 16 from the fitting 18 is not possible.

The permanent connection is made with it. An axial movement of the tube 16 out of the fitting 18 is prevented by the latching. The support body of the fitting 18 was at least partially molded into the inner peripheral surface of the tube 16 during the pressing operation and thus seals the connection between the tube 16 and the fitting 18, for example against fluids (not shown) guided in the tube 16 under pressure.

As a result, a pressing tool 2 has been used which, despite the radial output movement of the pressing jaws 10, performs a pressing in the axial direction, requires little installation space and, in particular, offers improved handiness. Fig. 3 shows in a cross-sectional view an assembly of a pipe 16, a support body having a fitting 18, wherein the support body engages the tube 16, a arranged on the tube outer peripheral surface transmission element 30 which is a wedge shape in cross-section and at the wider end of the wedge Having opening 32 for visual control of the pressing state, and an externally applied to the transmission element 30 sliding sleeve 34 which is also formed in cross-section also approximately wedge-shaped, but at the wider end has a flange-like projection 36. The flange-like projection 36 of the sliding sleeve 34 has a chamfer 38, the surface of which is provided for interaction with one of the sliding surfaces 22 of the pressing jaws 10 shown schematically in this example. The sliding sleeve 34 includes an opening for visually checking the pressing state of the workpieces 16, 18, 30 and 34. The fitting 18 has on its base a recess 24 with an inclined wall surface, wherein the inclination of the inclined wall surface to the inner contour of the pressing jaws 10th is adjusted.

The pressing jaws 10 in this example comprise two mutually facing sliding surfaces 22, which are formed as cone segments, and have an angle of inclination relative to the receiving area axis 20 of about 60 °. By choosing this slightly higher angle, in particular the stability of the pressing process can be improved.

During the pressing operation, the sliding surfaces 22 of the pressing jaws 10 interact with the inclined wall surfaces on the recess 24 of the fitting 18 and with the chamfer 38 of the flange-like projection 36 of the sliding sleeve 34. The by a radial univalent movement of the pressing jaws 10 caused dynamics is transmitted via the sliding surfaces 22 to the sliding sleeve 34 and the fitting 18, so that the fitting 18, the sliding sleeve 34 and thus also the transmission element 30 are pushed together in the axial direction. The wedge-shaped design of the sliding sleeve 34 and the transmission element 30 and their conditioning effect that the pressing forces are transferred during the pressing operation on the Rohraußenumfangsflache and at least partially redirected again in the radially inward direction. Thereby, the tube 16 is pressed with the support body of the fitting 18, wherein material of the tube 16 is formed in particular in arranged on the outer peripheral surface of the support body recesses 40, so that an axial movement is prevented after the completion of the pressing operation. In this way, thus a permanent permanent connection between a pipe 16 and a fitting 18 can be created.

Claims

claims

1. pressing tool (2) for permanent connection of workpieces (14, 16, 18, 30, 34) with two each having a pressing jaw (10)

Pivoting elements (4) and with at least one axis of rotation (6) on which the

Swivel elements (4) are articulated, wherein the inner contours of the opposite

Press jaws (10) form a receiving area (12), characterized in that the inner contours at least one against the

Receiving area axis (20) inclined sliding surface (22).

2. Press tool according to claim 1, characterized in that two against the receiving area axis (20) inclined, facing sliding surfaces (22) are provided.

3. Press tool according to claim 1 or 2, characterized in that at least one sliding surface (22) is designed as a cone segment.

4. Press tool according to one of claims 1 to 3, characterized the angle of inclination of the sliding surface (22) relative to the receiving area axis (20) lies between 35 ° and 55 °, in particular at 45 °.

5. Press tool according to one of claims 1 to 4, characterized in that the sliding surface (22) is designed to promote sliding.

6. Attachment for a pressing tool (2) with two pressing jaws (10), wherein each pressing jaw (10) has an inner contour and wherein the opposing inner contours of the pressing jaws (10) form a receiving area (12), characterized in that the inner contours at least have a against the receiving area axis (20) inclined sliding surface (22).

7. attachment for a pressing tool according to claim 6, characterized in that two against the receiving area axis (20) inclined, facing sliding surfaces (22) are provided.

8. attachment for a pressing tool according to claim 6 or 7, characterized in that at least one sliding surface (22) is designed as a cone segment.

9. attachment for a pressing tool according to one of claims 6 to 8, characterized the angle of inclination of the sliding surface (22) relative to the receiving area axis (20) lies between 35 ° and 55 °, in particular at 45 °.

10. attachment for a pressing tool according to one of claims 6 to 9, characterized in that the sliding surface (22) is designed to promote sliding.

11. A method for permanent connection of workpieces using a pressing tool, in particular according to one of claims 1 to 5, wherein the pressing tool is actuated radially inwardly, wherein the at least one arranged on the pressing tool against the workpiece axis inclined sliding surface and a workpiece surface in contact with each other be brought, in which the radially inwardly exerted pressing force is transmitted from the sliding surface to the workpiece surface and at least partially deflected in the axial direction and in which the workpieces are pressed in the axial direction.

12. The method of claim 11, wherein the sliding surface is opposite to a correspondingly adapted workpiece surface.

13. The method of claim 11 or 12, wherein the deflection over an angle between 35 ° and 55 °, in particular 45 ° is effected.