NO119200B - - Google Patents

Description

Gasket ring for use with socket joints for pipes

as well as arrangement for such a socket joint.

The present invention relates to a sealing ring for a socket joint for pipes, in particular for asbestos cement pipes of the type where the socket part is designed with an annular groove whose bottom runs parallel to the axis of the pipe, and the invention further relates to a device at a socket joint for use with the sealing ring as specified in claims 1.

Joints on pipelines that are to be buried, e.g. water pipes, are usually of the so-called sleeve type, as the sleeve is either in the form of a sleeve connecting two pipes, or in the form of a bell arranged at the end of one of the two pipes to be joined. A sealing ring is compressed between the pipe end and the sleeve.

Producing a satisfactory joint is difficult. In a joint that satisfies most requirements, the sealing ring is made in the form of a relatively hard part and a relatively soft part, and it lies in an annular groove in the sleeve. The sealing against the internal pressure in the pipeline is provided primarily by the soft part which is compressed between the pipe end and a wall in the groove which is approximately parallel to the axis of the pipe. The hard part primarily serves to hold the ring in position, especially during assembly of the joint.

The main purpose of the present invention is to provide an improved joint of the kind where a sealing ring is used which is composed of hard and soft parts and which lies in a groove in the sleeve.

In the case of a deed of this type, several conditions must be met. Firstly, the ring must not be displaced from its desired position in relation to the pipe axis. For example, it must not be curled, distorted or rolled, so that the inside comes out. Secondly, there must be sufficient clearance between the pipe end and the sleeve, so that a certain angular deflection can take place between the pipes, i.e. so that the pipes are no longer completely axially flush with each other, which can occur, for example

as a result of ground movements, and furthermore the sealing ring must adapt to any deviations in diameters and other dimensions as a result of inaccurate tolerances during manufacture. The ring must also not be blown out of the joint as a result of the pressure, regardless of the relative position of the pipes.

The sealing ring according to the invention is of the type where the sleeve part is designed with an annular groove, the bottom of which runs parallel to the axis of the pipe and which serves to accommodate the sealing ring, which sealing ring includes hard and soft parts, the soft part having such a radial thickness that that in the finished joint is compressed, and the sealing ring is characterized by the fact that the soft part, seen in longitudinal or axial section before the joint is assembled, has a radial side surface which is connected to the hard part, as well as a cylindrical side surface destined to come into contact with the bottom of the groove in the sleeve part and which merges into a seen in longitudinal section rectilinear side surface which runs obliquely seen outwards in the direction of the hard part, and which terminates in the radial side surface which is too bonded with the hard part, and that the the hard part is composed of an axially seen outer ring-shaped part which has a wedge shape, as well as another radially seen outer ring-shaped flange part.

The hard part of the ring forms the entire side surface of the ring closest to the mouth of the sleeve, and corresponds approximately to the shape of the side wall of the groove. The soft part has such a radial thickness that when fitting the joint it must be compressed and deformed, and it is positioned so that the internal pressure against which the ring forms a seal is transferred to the soft part in its entirety.

The hard and the soft part of the ring meet preferably, but not necessarily along a radial plane. In the preferred embodiment of the ring, the soft part is set

in section, before the assembly of the joint carried out with a radial plane that connects to the hard part, and a cylindrical surface that comes into contact with the bottom of the groove and that transitions into a semicircular surface that further transitions into a straight surface that stands somewhat on oblique in relation to the axis of the joint and which ends with the aforementioned radial plane. The hard part in this preferred embodiment of the ring is composed of an inner ring with a conical cross-sectional shape and an outer ring-shaped flange.

The preferred embodiment for a sealing ring and a device for a socket joint according to the invention is shown in the attached drawing where:

Figure 1 shows the parts before assembly, and

Figure 2 shows the fully assembled joint.

The figures show a pipe 1 with a chamfered end part 2 which is to be joined over a sleeve 3. Only half of the sleeve 3 is shown, the other half extending over another pipe to which it is to be joined in the same way. The sleeve or sleeve 3 is formed with a groove 4. The side wall of the groove near the mouth of the sleeve is made partly chamfered as shown at 5 and partly with a radial surface as shown at 6. The bottom of the groove is shown at 7, and the opposite side wall at 8.

The hard part of the ring is shown at 9, the chamfered part of this being indicated by the number 10 and the ring-shaped flange by the number 11.

The soft part of the ring shown at 12 is connected to the hard part over a radial plane 13, and is further provided with a cylindrical surface which is in contact with the bottom 7, a semi-circular surface 14 and a rectilinear, chamfered surface 15.

If a pipe at a pipe joint with a sleeve should for some reason come out of axial alignment with the other pipe, the sleeve will have a tendency to tilt to the side and the outer edge may come into contact with the pipe. The risk of this can be reduced by the joint shown in the drawings if the inner surface of the sleeve between the mouth and the groove is chamfered outwards as shown at 16. It has thus been found that the ring shown is superior to previously known rings in that it resists tilting or deflection of the sleeve, this undoubtedly because the nose of the conically shaped ring 10 is driven into firm contact with the inclined wall 5.

The ring 6 as a whole must of course be sufficiently elastic so that it can be pushed into the groove through the mouth of the sleeve. If one assumes that the joint between the other half of the sleeve and the second pipe, which is not shown, has already been assembled, the pipe 1 is pushed into place. The first contact with the ring is made by the end 17 of the tube, and the ring will have a tendency to roll, but this is prevented by the contact of the axial surface 18 with the conically shaped ring 10 with the tube. The groove is longer axially than the ring, and the ring moves as a whole towards the wall 8, but maintains its orientation in the groove. The degree of this axial movement of the ring is not critical, and when the internal pressure is applied to the surface 14 of the soft part of the ring, this will be moved back into the position shown in fig. 2, where the surface of the hard part is in contact with the side wall 5 and 6.

If the sleeve has a tendency to change its angular position, for example during ground movements, the hard part 9 will act as a vertical stiffener which counteracts this tendency. The hard part will also effectively resist blowout of the ring under high internal pressures.

The ring is preferably made of rubber, the hard part being made of rubber with 75 - 80 Shore degrees, the soft part being made of rubber with 25 - 65 Shore degrees.

The invention is particularly applicable to joints between pipes and sleeves made of asbestos cement. These must be machined, and the simple shape of the groove will facilitate machining.

Claims (2)

1. Gasket ring for use with a socket joint for pipes of the kind where the socket part is designed with an annular groove, the bottom of which runs parallel to the axis of the pipe and which serves to accommodate the gasket ring, which gasket ring includes hard and soft parts, the soft part having such radial thickness that it is compressed in the finished joint, characterized in that the soft part (12) seen in longitudinal or axial section before the joint is assembled, has a radial side surface (13) which is connected to the hard part (9),> as well as a cylindrical side surface intended to come into contact with the bottom of the groove in the sleeve part and which merges into a longitudinally sectioned rectilinear side surface (15) which runs obliquely outwards in the direction of the hard part, and which terminates in the radial side surface ( 13) which is connected to the hard part (9), and that the hard part (9) is composed of an axially seen outer ring-shaped part (10) which has a wedge shape, as well as another radially seen outer ring-shaped flange part ( 11). 2. Device for a socket joint for pipes for use with a gasket as specified in claim 1, in particular for asbestos cement pipes, characterized in that the side wall (6) of the groove closest to the mouth of the socket part first runs radially or approximately radially from the bottom towards the axis and is then beveled (5) towards the socket part mouth, and that the opposite side wall (8) of the groove extends radially or approximately radially.