GB2105424A

GB2105424A - Bore seal

Info

Publication number: GB2105424A
Application number: GB08210404A
Authority: GB
Inventors: Raymond E Latham
Original assignee: Individual
Current assignee: Individual
Priority date: 1981-08-31
Filing date: 1982-04-08
Publication date: 1983-03-23
Also published as: GB2105424B

Abstract

An annular bore seal S is provided for sealing between connected first and second coaxially aligned members 12, 13 which are provided with internal frusto-conical seating surfaces 19, 20 tapering inwardly from their adjoining ends. The seal comprises: an inner cylindrical surface 30; annular end surfaces 31, 32 at opposite ends thereof; frusto-conical outer sealing surfaces 33, 34 adjacent each of the end surfaces and tapering outwardly therefrom; an outer alignment ring surface 35 midway between the end surfaces; and annular relieved areas 36, 37 between the alignment ring surface and the frusto-conical sealing surfaces. <IMAGE>

Description

SPECIFICATION bore seal The present invention pertains to fluid seals.

More specifically, it pertains to annular seals for sealing the connection between coaxially aligned members. Still more specifically, it pertains to bore seals of the flexible pressure-energized type.

There are many types of seals or gaskets for sealing between flanges or in other types of connectors. These seals may be broadly categorized as those that seal on the face of the connector and those that seal on the bore. In both categories, sealing may be achieved by crushing or yielding the gasket; by elastically loading a flexible gasket utilizing a soft coating or plating on the seal surface; or by a combination of both. The seals may or may not be pressure energized as dictated by their geometry and location in the connector.

Because of their relatively massive crosssections, some bore seals require considerably more bolt up loading than do face seals. On the other hand, bore seals may be more economic because of lower manufacturing tolerances. In addition, most bore seals are self-centering, whereas face seals are generally extremely sensitive to misalignment. Flexible bore seals are particularly adaptable to high temperature use because they are radially compressed during make-up, resulting in residual seal loading.

An extremely popular bore seal of the past few years is one which comprises a flange portion having oppositely disposed flexible lips and a centrally disposed rib portion. The lips are provided with annular seating surfaces which taper outwardly toward the rib portion. Examples of this type of bore seal may be seen in U.S.

Patent Nos. 2,766,829; 2,766,998; 2,766,999; and 3,325,176. While this type of seal is basically a bore seal, it has some of the characteristics of a face seal, due to the rib portion which is normally disposed between the end faces of the connectors with which it is used. Consequently, it requires higher manufacturing tolerances and is more expensive to manufacture than some bore seals.

Most recently developed is a seal, as in the present invention, which is a flexible, pressureenergized type bore seal, shown in U.S. Patent No.

4,214,763. It is primarily designed for sealing between connected first and second coaxially aligned members, such as flanges, each of which may be provided with an internal frusto-conical seating surface tapering inwardly from the adjoining ends thereof. The surfaces of the seal may comprise: an inner cylindrical surface; annular end surfaces at opposite ends thereof; frustoconical outer sealing surfaces adjacent each of the end surfaces tapering outwardly therefrom; and an outer alignment ring surface midway between the end surfaces. While this seal is extremely efficient, some of its dimensions are critical for best use.

The present invention is a flexible, pressureenergized seal of the type shown in U.S. Patent No. 4,214,763. Like such, the seal of the present invention may comprise: an inner cylindrical surface; annular end surfaces at opposite ends thereof; frusto-conical outer sealing surfaces adjacent each of the end surfaces tapering outwardly therefrom; and an outer alignment ring surface midway between the end surfaces. In addition, annular relieved areas may be provided between the alignment ring surface and the frusto-conical sealing surfaces.

Due to the alignment ring surface and the shoulders provided at the end surfaces of the seal, the seal is self-aligning. It requires relatively low bolt-up loading. It has critical dimensions and predetermined sealing areas and consequently a predetermined load. It is pressure-energized so that any increase in pressure internally of the connected members results in greater sealing forces. It provides a smooth bore eliminating turbulence and the erosion and corrosion associated therewith. In addition, it is reusable.

Furthermore, it is less expensive to manufacture than bore seals of the aforementoned type having a centrally disposed rib portion. Many other objects and advantages of the seal of the present invention will be apparent from the description which follows in conjunction with the accompanying drawings.

Fig. 1 is an elevation view, partially broken away and partially in section, showing a clamptype connection utilizing a seal according to a preferred embodiment of the present invention; and Fig. 2 is a detailed cross-sectional view of the seal of the present invention and its relationship with the pair of flange members shown in Fig. 1.

Referring first to Fig. 1, there is shown coaxially aligned pipe sections 10 and 11 connected by a pair of flanges 12 and 13. The flanges 12 and 13 may be attached to the pipe sections 10 and 11 by welding, as at 14 and 15, or any other suitable means. The flanges 12 and 13 may be connected by bolts, clamps, or any other suitable means. As illustrated in Fig. 1, these flanges are held together by a clamp arrangement which includes a pair of "C" clamps 16 and 17 connected by bolts 18.

Prior to connection, a bore seal S, according to a preferred embodiment of the invention, is placed in the bore of the flanges for sealing the connection therebetween.

Referring now also to Fig. 2, each of the flanges 12 and 13 are provided with internal or frustoconical seating surfaces 19 and 20, respectively, tapering inwardly from the adjoining end faces 21 and 22 of the flanges. The opposite ends of the frusto-conical seating surfaces 19 and 20 may terminate at annular shoulders 23 and 24 at the ends of flange bores 25 and 26, respectively. The angle of taper between the axes of the flange members 12 and 13 and their respective frustoconical seating surfaces 19 and 20, as illustrated at "a", is preferably in the range of 150 to 200.

The surfaces of the seal member S include an inner cylindrical surface 30 and annular end surfaces 31 and 32 at the opposite ends thereof.

The external surfaces include frusto-conical sealing surfaces 33 and 34 adjacent each of the end surfaces 31 and 32 and tapering outwardly therefrom at an angle substantially the same as the taper angle "a" of the flange seating surfaces 19 and 20.

The outer surfaces also include a ring surface 35 midway between the ends 31 and 32. As viewed in cross-section, as in Fig. 2, the ring surface 35 is actually a point. Annular relieved areas 36 and 37 are preferably provided between the alignment ring surface 35 and the frustoconical sealing surfaces 33 and 34. These relieved areas 36 and 37 may be provided by machining other frusto-conical surfaces 38 and 39 adjacent the ring surface 35 which taper inwardly therefrom. These other frusto-conical surfaces 38 and 39 may be joined to the first-mentioned frusto-conical sealing surfaces 33 and 34 by cylindrical surfaces 40 and 41.

In the embodiment shown in Fig. 2, the outer alignment ring surface 35 substantially coincides with the circular intersection of the projection of frusto-conical sealing surfaces 33 and 34 when the seal member S is fully seated. Thus, the angle of taper "a" between the axis of the seal member S and the sealing surfaces 33 and 34 is less than the angle of taper "b" between the axis of the seal member S and the other frusto-conical surfaces 38 and 39. In an alternate embodiment, the other frusto-conical surfaces may be machined at the same taper angle "a" as the sealing surfaces 33 and 34 resulting in the configuration illustrated by dotted lines at 38a and 39a. In such a case, the alignment ring 35a, will be the intersection of frusto-conical surfaces 38a and 39a, rather than 33 and 34.

From practical application and manufacturing experience it has been determined that certain dimensions and dimensional relationships of the seal of the present invention are critical. To understand these relationships reference is made to the dimensions referenced by the letters A, B, C, and D in Fig. 2. A represents the diameter of the seal S at the alignment ring surface 35. B represents the bore diameter of the seal S. C is the axial length of the seal S. D is the width of frusto conical sealing surfaces 33 and 34.

Following is a table of optimum ratios involving the above-described dimensions for seal bore diameters B in the ranges shown: B Dí C C/B A/B 1" to 6" 0.135 0.36 1"to8" 0.135 1.1 to 1.2 6 to 12 0.135 0.13 8"to24" 0.135 1.01 toll 12" to 24" 0.135 0.10 If these ratios are adhered to, best results will occur.

It is understood that as with other flexible type bore seals, the radial dimensions of the seal S, prior to installation, are greater than shown in Fig.

2. However, when the connection is properly made, the seal S assumes the position illustrated in Fig. 2. Since the areas of the sealing surfaces 33 and 34 are predetermined, the loading forces may also be predetermined. It is noted that the distance between the annular shoulders 23 and 24 of the respective flanges is slightly greater than the axial length of the seal member S. These shoulders 23 and 24, coupled with the end surfaces 31 and 32 of the seal member S and the alignment ring surface 35 result in self-alignment of the seal as the flanges 12 and 13 are clamped together.

It will also be noted that the diameter B of the inner cylindrical surface 30 of the seal, when the flanges 12 and 13 are properly connected, is substantially the same as the adjoining bore diameters 25 and 26. This eliminates turbulence and the erosion and corrosion associated with such turbulence. Due to this bore configuration, the pressure internally of the connection exerts additional forces against the seal so that it is pressure-energized also.

Thus, it is seen that the flexible pressureenergized bore seal of the present invention is one which offers superior sealing and alignment characteristics, particularly when utilizing the preferred dimensional ratios. It is also easily and economically manufactured.

While a preferred embodiment, one alternate and optimum dimensions have been described herein, many variations of the invention can be made without departing from the spirit of the invention. Accordingly, it is intended that the scope of the invention be limited only by the claims which follow.

Claims

1. An annular bore seal for sealing between connected first and second coaxially aligned and centrally bored members, each of which is provided with an internal frusto-conical seating surface tapering inwardly from the adjoining ends of said first and second members toward the bores thereof, said seal comprising: an inner cylindrical surface; annular end surfaces at opposite ends of said inner surface; frusto-conical outer sealing surfaces adjacent each of said end surfaces and tapering outwardly therefrom at an angle with the axis of said seal, in the range of fifteen to twenty degrees; an outer alignment ring surface midway between said end surfaces defined by the circular intersection of a pair of cones whose axes coincide with said seal axis; and annular relieved areas between said alignment ring surface and said frusto-conical sealing surfaces wherein the ratio of the diameter of said alignment ring surface and the diameter of said inner cylindrical surface is in the range of approximately 1.01 to 1.20.

2. An annular bore seal as set forth in Claim 1 in which the ratio of the axial length of said bore seal and the diameter of said inner cylindrical surface is in the range of approximately 0.10 to 0.26.

3. An annular bore seal as set forth in Claim 1 in which the ratio of the width of said frustoconical sealing surfaces and the axial length of said bore seal is approximately 0.135.

4. Fluid connection apparatus including first and second coaxially aligned and centrally bored members, each of which is provided with internal frusto-conical seating surfaces tapering inwardly from the adjoining ends thereof; means for connecting said first and second members in said coaxial alignment; and an annular bore seal for sealing between said first and second members when connected, said annular bore seal comprising: an inner bore surface; annular end surfaces at opposite ends of said inner bore surface; frusto-conical outer sealing surfaces adjacent each of said end surfaces and tapering outwardly therefrom at an angle substantially the same as the taper angle of said frusto-conical seating surfaces of said first and second connected members; an outer alignment ring surface midway between said end surfaces defined by the circular intersection of a pair of cones whose axes coincide with the axis of said annular bore seal; and annular relieved areas between said alignment ring surface and said frusto-conical sealing surfaces wherein the ratio of the diameter of said alignment ring surface and the diameter of said inner bore surface is in the range of approximately 1.01 to 1.20.

5. Fluid connection apparatus as set forth in Claim 4 in which the ratio of the axial length of said bore seal and the diameter of said inner bore surfaces is in the range of approximately 0.10 to 0.26.

6. Fluid connection apparatus as set forth in Claim 4 in which the ratio of the width of said frusto-conical sealing surfaces and the axial length of said bore seal is approximately 0.135.

7. An annular bore seal as claimed in Claim 1, substantially as described herein.

8. An annular bore seal substantially as described with reference to the accompanying drawings.