DE2046962C3 - Pipe coupling - Google Patents

Description

The invention relates to a pipe coupling as described in the preamble of claim 1 and for example from US-PS 34 29 587 is known.

If in this known embodiment of the pipe coupling the radial plastic deformation of the metal sleeve takes place, then it is difficult to avoid dents in the metal sleeve in the pipe end pushes in. However, this is sometimes undesirable because it reduces the flow cross-section.

The invention is based on the object of designing the pipe coupling so that such a Depression of dents in the pipe both during the radial plastic deformation of the metal sleeve and avoided under all circumstances during a later bending of the pipe provided with the pipe coupling is, but that the pipe coupling strong tensile forces between the coupled .Einsteckrohrenden can transfer without loosening.

According to the invention, this object is achieved by the characterizing features of claim 1
The trapezoidal cross-section of the sealing ring produces higher values with regard to tensile strength and since this sealing ring swells laterally out of the ring groove during radial plastic deformation of the metal sleeve and forms an intermediate layer that lies between the plug-in pipe end and the end of the sleeve, the sealing ring protects the pipe end from that this is pressed in through the edge of the metal sleeve. A pipe coupling is already known (CA-PS 6 96 020), which consists of a metal sleeve surrounding a plug-in pipe end and an elastic sealing ring with flanks inclined to the radial plane, which is mounted in an inner ring groove of the metal sleeve that corresponds to the cross-section of the sealing ring The sealing ring has a larger inside diameter than the outside diameter of the plug-in tube, but has a flank angle of 70 °, the ratio of the axial length to the radial depth of the annular groove, as well as the corresponding ratio of the sealing ring, being approximately 2: 1.

But it was not obvious to deform this well-known trapezoidal ring in the case of plastically Metal sleeves to be used, as the expert either O-ring-shaped sealing rings or slightly curved Has used sealing rings. So sealing rings with a curved outer surface. Obviously, the skilled person is so far assumed that the deformation of the sealing ring at the same time as the deformation of the Metal sleeve needs a rounded surface but the subject matter of the invention differs from this because there the sealing ring has a trapezoidal cross-section, which is higher in terms of tensile strength Bringing values.

Even if sealing rings are common, which expand axially in the event of radial deformation, it is It is surprising that such a measure can also be achieved with radial deformation of the metal sleeve. So far it was obviously of the opinion that a sealing ring when the sleeve is radially compressed must not emerge from the side of the ring groove, otherwise the sealing ring could be squeezed off.

The subclaims relate to expedient embodiments of the invention.

In the drawings, in which an embodiment of the invention is illustrated, shows

F i g. 1 is a perspective view of two male pipe ends being passed through the pipe coupling of the invention are connected,

F i g. 2 shows a longitudinal section through the in F i g. 1 pipe coupling shown in the state before the radial plastic deformation of the metal sleeve,

F i g. 3 the right end of FIG. 2 with the plug-in tube end shown in section and

F i g. 4 the in F i g. 3 shown section through the pipe coupling in the state after the radial plastic deformation of the metal sleeve.

The pipe coupling consists of a plug-in pipe end 11 or 12 surrounding metal sleeve 10 and an elastic sealing ring 18 with the radial plane

inclined flanks formed in an inner one corresponding to the cross section of the sealing ring 18 Annular groove 19 is supported Here, the sealing ring 18 has a larger inner diameter in the pre-coupling state, than the outer diameter of the insert tube 11 or 12. The sealing ring 18 is also much wider than thick As in Fig. 4 shown, it is sealed by radial plastic deformation of the metal sleeve 10 to the circumference of the Pipe end 12 pressed on while flowing in the axial direction at the same time Touched in the fully assembled state the metal sleeve 10 does not have the plug-in pipe end 11 or 12

Each of the two annular grooves 19 is surrounded by one of the two ends 16, 17 of the metal sleeve 10. These ends are profiled so that the sealing ring 18 resting on the inner wall of the annular groove 19 is symmetrical and trapezoidal in cross section and has a flank angle β of 17-75 °, based on the radial plane Metal sleeve 10 connected by a center piece 14, inclined portions 21 and 23 connected by an approximately cylindrical portion 20 of the metal sleeve. The ratio of the axial length / to the radial depth t of the annular groove 19 (FIG. 3), and likewise the ratio of the axial length to the radial depth of the sealing ring 18, is between 1.5: 1 and 2: 1.

The bore 24, which receives the plug-in pipe end 11 or 12, is in the end wall 25 of the metal sleeve 10 provided and has a clear width which is the clear width of the inner surface 26 of the sealing ring before Exceeds radial plastic deformation of the metal sleeve.

The metal sleeve end 16 or 17 is approximately uniform over its entire length a Wall thickness.

As shown more clearly in Figure 3, the section 20 has an outside diameter which is twice the amount of the "R" dimension larger than the outside diameter of the central section 14. The original annular space in the radial direction between the inner sealing ring surface 26 and the outside of the pipe ends 11 or 12 is represented by the dimension "c" .

The plastic deformation of the metal sleeve ends 16, 17 is effected by a hydraulically operated tool which has curved contacting jaws, two of which are shown in dashed lines and designated 28. To attach the jaws, the tool is aligned by a flange which is received in the recess 22 of the metal sleeve 10. When the jaws contract radially inward, they uniformly exert a concentric, radially inwardly directed force on the pipe coupling, which force is indicated by arrows 19. The die forging force developed by the tool is sufficient to pull the end 16 or 17 together until it is different from the one shown in FIG. 3 assumes the state of deformation shown in FIG. 4, the portion 20 has been deformed from its original state, shown in dashed lines, to the forged state shown in solid line, by a diameter distance which corresponds to twice the amount of the dimension d shown. At the same time, the angle β 'has been increased from the original angle β by the amount of the angle. The axial dimension A ' has been increased compared to A by the dimension "e" . When the sleeve end 16 or 17 is deformed radially inwards, the sealing ring 18 is increasingly pressed against the pipe end 11 until it is in firm engagement with the outer pipe wall. The drop forging process is continued until the sealing ring 19 is reduced by an amount "s" oozes out of the groove 19, thereby ensuring the physical separation between the inside of the coupling and the outside of the pipe.

Therefore, only the inner surface of the sealing ring 19 engages the pipe end, while the sleeve 10 does not Any inadvertent excessive contraction of the Sleeve i0 causes the sealing ring to be pushed out further between the sleeve and the pipe walls, so that the sleeve is still prevented from attacking the pipe directly or in any other way adversely affecting the pipe.

Typical and approximate dimensions for the above reference characters with a tube size of 50.8mm are the following:

c - Range from 0.3048 mm for max.coated pipe and min.-coupling to 1.143 mm for min. bare pipe and max.-coupling.

R - 2.3368 to 3.3512 mm

d - 1.905 to 4.191 mm

s - 0.794 to 3.175 mm

e - 2.54 to 3.048 mm

/ - 25.4 mm

/ '- 30.15 mm

β - 75-30 °

β '- 83-60 ^r

While the coupling according to the present invention should preferably serve to connect metal pipe sections, the coupling can also be used to connect pipes made of plastic or other synthetic materials. The pipe should of course have sufficient buckling strength to withstand the corresponding pressure of the sealing ring, which in turn should be higher than the line pressure of the pipeline. The ratio of the pressure of the sealing ring to the line pressure should expediently be at least 2: 1. A 50.8 mm pipe can usually withstand an O-ring pressure on the order of 140 kg / cm ² . A suitable coupling material is steel with a buckling strength of about 1680 kg / cm ² , although it is readily feasible to use materials which have buckling strengths of the order of magnitude of 2310 kg / cm ² or more. It is important, however, that the coupling material has a high degree of forgeability, which is expressed by the percentage elongation that takes place during the rupture tests of a test bar 30%. A minimum elongation of around 15% as with malleable iron can be used, as can elongation properties of up to 35%. The desired forgeability can be achieved by completely relaxed or softened the coupling after it has been formed.

forging process only about 8-10% of the total available 30% required.

To establish the connection, the coupling part is first attached to two pipe sections, which Find loosely in the coupling part. Then a suitable forging tool, such as. B. that described above, disposed about one end and the radially inward pressure applied. if If sufficient leakage of the sealing ring appears under the wall 23, the forging pressure is increased ended, whereupon the opposite end of the coupling part processed in a corresponding manner will. The pressing out of the sealing ring under the wall 23 is a sure sign that the required deformation has taken place and that the

Connection has been made in an appropriate and reliable manner. No further testing is required and a double ended connection can be formed on 50.8 mm pipe in approximately 30 to 45 seconds forge time per end. The required forging pressure to be applied to the coupling ends will of course vary with pipe size, choice of materials, etc. in order to limit the kinking of the pipe to no more than about 0.4 mm 19.05 mm pipe for an axial length of 25.4 mm generally has a pressure of about 595-770 kg / cm ² , while a 50.8 mm pipe ^{requires about 350-455 kg / cm 2.} The pumps - or tool pressures are then correspondingly greater.

1 sheet of drawings

Claims (5)

Patent claims: 1. Pipe coupling consisting of a metal sleeve surrounding a plug-in pipe end and a elastic sealing ring with flanks inclined to the radial plane, which is in an inner, corresponding to the Cross section of the sealing ring formed annular groove of the metal sleeve is mounted, wherein the sealing ring in the pre-coupling state a larger inner diameter than the outer diameter of the insert pipe has, is formed much wider than thick and by radial plastic deformation the metal sleeve sealingly to the circumference of the pipe end while flowing into Axial direction is pressed, and the metal sleeve in the fully assembled state the plug-in tube end not affected, characterized in that a) the sealing ring (18) is symmetrical and trapezoidal in cross section and one Has flank angles between 15 and 75 °, based on the radial plane, b) the ratio of the axial length to the radial depth of the annular groove (19) and also of the Sealing ring (18) is between 1.5: 1 and 2: 1, c) the metal sleeve (10) is deformed in its narrowest manner after the plastic deformation Cross-section through an intermediate layer of the laterally swelled out of the annular groove (19) Sealing ring (18) is separated from the plug-in pipe end (11, 12). 2. Pipe coupling according to claim 1, characterized in that the annular groove (19) of the coupling sleeve (10) is housed in an outer circumferential bead (20), which by a around the outer circumference extending bead (22) is offset from the outer peripheral surface of the coupling sleeve (10). 3. Pipe coupling according to one of claims 1 and 2, characterized in that at least the area of the metal sleeve (10) exposed to plastic deformation and containing the sealing ring (18) consists of a material with a buckling strength of at least 1680 kgf / cm ² and an elongation at break of at least 15%. 4. Pipe coupling according to one of claims 1 to 3, characterized in that the area of the metal sleeve (10) containing the sealing ring (18) is plastically deformable ^{at pressures of approximately 350 to approximately 770 kp / cm 2.} 5. Pipe coupling according to claim 4, characterized in that the metal sleeve (10) has a Has wall thickness of about 2.38 mm to about 12.7 mm.