FR2513343A3 - Seat for a ball valve - has a dual function of sealing and supporting the rotating valve - Google Patents

Abstract

The ball valve consists of a cylindrical housing clamping between two pipe flanges. The spherical valve rotates through ninety degrees between open and closed positions. The valve seals (11) are mfd. from PTFE and combine the role of valve seat and support. The PTFE seal is in the form of a shallow dish (18) with a spherical inner surface (12) to match the ball. An annular extension (17) provides a circumferential edge (13) which locates the seal in the body of the valve whilst the back, plane surface (16) is supported against the pipework flange.

Description

 The present invention relates to a seat for ball valves of the kind comprising a substantially tubular body tightly enclosed between two flanges, and a spherical valve pierced by a conduit. The seat of the type targeted by the invention is intended to sealingly support the rotary shutter in the tubular body. This seat is made from a material having a certain flexibility of the polyfluorinated resin type, such as polytetrafluoroethylene, and has an annular contact surface with the shutter, and bearing surfaces against the internal wall of the tubular body and against the adjacent flange.

 To make such a seat, it is known to use a solid ring, the cross section of which is substantially a rectangular trapezium whose oblique side, which corresponds to the face of contact with the shutter, is however curved and concave. The other side of the trapezoid corresponds to a bearing face against the valve body, while the large base corresponds to a bearing face against the clamping flange.

 This known seat leads to a satisfactory seal provided that it undergoes a relatively energetic tightening on the part of the flanges. The disadvantage of such tightening is that it determines a relatively high torque for the shutter. In addition, the known seat is heavy and expensive in resin. It requires great precision in its dimensions, but also in those of the surfaces on which it is intended to rest. Otherwise, the supports will be excessive or insufficient.

 The object of the invention is to remedy these drawbacks by producing a seat leading to a lower operating torque, less costly in raw material and less demanding in construction precision.

According to the invention, the seat is characterized
in that it includes a transversely extending core
to the axis of the duct, and taking support
against the inner wall of the tubular body, this
core being connected by its inner edge to a wing
which carries the abovementioned annular surface and whose end
directed towards the flange serves to support the seat on this
last.

Thus, the massive ring of the state of the art
is replaced by a profiled ring whose cross section
right can be studied to present
the necessary contact and support surfaces, without
superfluous matter. The seat is therefore lighter and
less expensive in raw material. In addition, the wing
of the ring present in relation to the latter's friend
flexibility, which surprisingly decreases the
shutter operating torque, without damaging the span
in the closed position. This flexibility allows
in addition to compensate for any slight inaccuracies in the manufacturing dimensions
Other features and advantages of the invention
The following description will further result.

In the accompanying drawings, given by way of examples
non-limiting,
- Figure 1 is a longitudinal sectional view
the of a ball valve in the closed position, fitted
two seats according to the invention, the left flange being slightly loosened for illustrative purposes;
- Figure 2 is a half sectional view of one of the seats in Figure 1;
- Figures 3, 4, and 6 to 8 are views
similar to Figure 2 but showing variants
realization of the seat according to the invention; and
- Figure 5 shows, by two half-views
adjoining, in axial section, two neighboring variants of the seat according to the invention.

 In the example shown in Figure 1, the ball valve comprises a tubular body 1 tightly enclosed between two annular flanges 2 biased towards each other by tie rods 3. The seal between the body and the flanges is provided by seals 4 each embedded in a groove 6 formed at the corresponding end of the body 1.

 Inside the body 1 is mounted a spherical obturator 7 linked in rotation to an operating rod 8 whose axis is perpendicular to the tubular body 1. The obturator 7 has an axial duct 9 which, according to the angular position of the operating rod 8 around its axis, can take a closed position, in which the conduit 9 is perpendicular to the axis of the body 1, and a fully open position in which the conduit 9 and the body 1 are co-axial.

The shutter 7 can also be positioned intermediate between the two aforementioned extreme positions.

 The shutter 7 is rotatably supported in the body 1 by means of two annular seats 11 made of material endowed with a certain flexibility, preferably made of polytetrafluoroethylene. In service, as can be seen on the right of FIG. 1, the swe is inserted between the shutter and the circular corner defined by the internal wall of the tubular body 1 and the front surface 15 of the adjacent bend 2, the internal diameter is smaller than that of body 1.

Each seat 11 has an annular surface 12 for contact with the shutter 7, a cylindrical annular surface 13 for bearing against the internal wall 14 of the tubular body 1, and a flat annular surface 16 for bearing against the front face 15
flange 2 Surface 12, which directly supports
the sphere 7 and at the same time ensures the seal between the sphere 7 and the seat 11, is a concave spherical sector having the same radius and same center as the sphere 7.

The cylindrical surface 13 ensures the centering of the seat 11, and consequently of the shutter 7, on the axis XX of the tubular body 1. The flanges 2 exert on the face 16 of the seats 11 a pressing force which seals between these flanges 2 and the seats 11. At the same time, this pressing force in turn generates, between the face 12 of the seats 11 and the shutter 7, a contact pressure sufficient to ensure the seal between the seats 11 and the shutter 7.

 According to the invention, the seats 11 comprise a core 17 extending transversely to the axis X-X of the tubular body 1 and the surface 13 of which bears against the tubular body constitutes the outer edge. On its inner edge, the core 17 is connected to a wing 18 which carries the annular surface 12 of contact with the shutter 7.

 In the example shown, the friend 17 is connected to the edge of the wing 18 which is adjacent to the flange 2.

The surface 16 serving to support the seat 11 against the flange 2 occupies the entire lateral face of the friend 17, up to the end of the wing 18 which thus bears directly against the flange 2.

 The wing 18 has a substantially constant thickness when it is moved along the axis X-X. Similarly, the friend 17 has a substantially constant thickness when moving away from the axis X-X. However, the intersection between the faces 12 and 16 has a slight chamfer 19. This thickness of the core 17 and the wing 18 can for example be 3 to 4 mm in a tap provided for 50 mm piping. diameter.

 The seat which has just been described performs the same functions as a conventional solid seat, namely to support the ball in rotation in the body 1, and to ensure the seal between the body 1 and the ball 7, at least in the position closure shown in Figure 1.

 However, the seat 11 is lighter and more economical in terms of raw material, and its flexibility makes it possible to reduce the torque necessary to rotate the shutter 7 by means of the control rod 8. In addition, if it has not not exactly the dimensions vou read to fit perfectly between the tubular body 1 and the shutter 7, its flexibility will still allow it to take place and function properly.

 The example shown in FIG. 3 will only be described with regard to these differences from the example in FIG. 2.

 In this example, the friend 17 points on its outer edge a cylindrical wing 21 directed opposite the adjacent flange 2. The free end of the wing 21 is in the same plane as the free end of the wing 18. In this example, the surface 13 allowing the seat 11 to rest on the tubular body 1 is the outer lateral wall of the wing 21.

Furthermore, in this embodiment, in the core 17, on the side of the flange 2, at the right end of the wing 18, an offset 22 in the form of a very flared cone was practiced.
This embodiment is distinguished by better centering of the seat 11 relative to the body 1, thanks to the wing 21. Despite this, this seat is more flexible than the previous one due to the bottoming 22 which allows the wing 18, such as seen in section in FIG. 3, to flex not only counterclockwise but also clockwise relative to the core 17.

 In the example of FIG. 4, on the contrary, more rigidity has been sought than in the example of FIG. 2, without however of course returning to the massive forms of the prior art.

 In this example, the offset 22 has been eliminated, and the wing 21 has been thickened. In addition, the wing 18 has been given a thickness which decreases as it moves along the axis XX from the flange 2 adjacent to the operating rod 8.

 In the example on the left of FIG. 5, which is similar to FIG. 2 in that it does not have a wing 21, the core 17 is to limit on the side opposite to the flange 2, by a surface concave annular 23 which extends from the edge of the wing 18 opposite the flange 2. In addition, the bearing surface of the seat 11 on the flange 2 is subdivided into two flat annular surfaces 116 separated by an annular recess 24. Correlated with the concave surface 23, the outer edge of the recess 24 defines a thinned part 26 of the core 17. In the example of a material intended for pipes of 50 mm in diameter, this thinned part can destroy 1, 5 to 3 mm thick.

 This version of the invention is distinguished by an excellent support against the flanges 2 due to the presence of the two support surfaces 116 and of the thinned part 26 which gives them a certain flexibility with respect to one another.

 The example of the right part of FIG. 5 differs from that of the left part, in that the contact surface with the shutter 7 comprises two sectors of concave spheres 112 separated by an annular recess 27 of substantially triangular section.

The bottom edge 28 of the recess 27 is directed towards the inner edge of the recess 24, and defines with it a thinned part 29 of the wing 18.

 In this version, the invention ensures good conformability of the seat on the shutter, thanks to the thinned part 29, and also provides a double seal between the seat 11 and the shutter 7 thanks to the two surfaces 112.

 In the example of Figure 6, the core 17 is connected to the wing 18 by the edge of the latter which is opposite the adjacent flange 2. At its end directed towards the flange 2, the wing 18 carries a flat surface 216, perpendicular to the axis XX and intended to bear on the flange 2. However, in the direction of the axis XX, the wing 18 has a conical offset 22 of the kind of that of FIG. 3. The wing 18 has a substantially constant thickness, when one moves along the axis XX.

 On its outer edge, the core 17 further carries a wing 121 bearing against the tubular body 1.

The wing 121 is cylindrical and its external lateral wall constitutes the surface 13 for bearing against the body 1.

Its end is in the same plane as the surface 216, and constitutes a surface 316 reinforcing the support of the seat 11 against the flange 2.

 The seat thus formed has a great deal of flexibility in mounting, but becomes relatively rigid once the flanges 2 are tightened simultaneously against the surfaces 216 and 316.

 The example shown in FIG. 7 is close to deceluideaflgu'e6, except that the wing 121 has been thickened and that, on the other hand, a thinned part 31 has been made at the root of the wing 18. The wing 121 thus becomes a real seat anchoring block, while the wing 18 can adapt fairly well to the shutter during assembly.

 The example in FIG. 8 is interesting because of the numerous possibilities of flexing the seat that it offers. fanes this example, which will only be described with regard to its differences from that of FIG. 2, the core 17 is connected to the wing 18 at an axial distance D substantially equal from the annular end 316 directed towards the flange and of the annular end 416 directed opposite the flange.

 From this connection, the core 17, the thickness of which is uniform, is directed radially to its annular end 13 intended to bear against the internal wall of the duct 14.

 In addition, the annular end 316 of the wing 18 is in direct contact with the flange 2 by two concentric annular surfaces (36) separated by an annular groove 37.

It can therefore be seen that the invention offers numerous possibilities from which one will choose according to the applications envisaged. It is thus for example that in the case of high pressures, one may prefer an embodiment offering more rigidity at least once the flanges 2 are tight
Of course, the invention is not limited to the examples described and shown, and numerous modifications can be made to these examples, without departing from the scope of the invention.

 In the examples of FIGS. 5 to 8, one could for example provide that the end of the wing 18 is a little longer in the direction of the flange 2 than the end of the core 17, so that the tightening of the flanges are preferably carried out on wing I 18.

 Furthermore, the resin constituting the seats II can advantageously be loaded with glass fibers or metallic powder.

Claims (12)

 1. Seat for ball valves of the kind comprising a body (1) substantially tubular tightly enclosed between two flanges (2), and a spherical valve (7) pierced with a conduit (9), this seat (11) being intended to tightly support the shutter (7) in rotation in the tubular body (1), this seat (ll) being made from a material having a certain flexibility, of the polyfluoreal resin type such as polytetrafluoroethylene, and having a surface annular (12, 112) in contact with the shutter (7) and surfaces (13, 16, 116, 216, 316), bearing against the internal wall (14) of the tubular body (1) and against the flange adjacent (2), characterized in that it comprises a core (17) extending transversely to the axis (XX) of the tubular body (1). and taking support against the internal wall (14) of the tubular body (1), this core (17) being connected by its inner edge to a wing (18) which carries the abovementioned annular surface (12, 112), and whose end (16, 116, 216) directed towards the flange (2) serves to support, at least indirectly the seat (11) on the latter.  2. Seat according to claim 1, characterized in that the core (17) is connected to the wing (18) in contact with the shutter (7) at the edge of the latter, intended to be adjacent to the flange (2), and in that one of the lateral surfaces (16, 116) of the core (17) serves to support the seat (11) against the flange (2).  3. Seat according to claim 2, characterized in that the core (17) has an annular recess (24) on the side of the flange (2).  4. Seat according to any one of claims 2 or 3, characterized in that the core (17) tapers from the wing (18) in contact with the shutter (7) to the edge (13) bearing against the internal wall (14) of the tubular body (1).  5. Seat according to any one of claims 2 to 4, characterized in that the core further carries, on its outer edge, a wing (21) bearing against the body (1), substantially cylindrical and directed opposite the flange (2).  6. Seat according to claim 1, characterized in that the core (17) is connected to the wing (18) in contact with the shutter (7) at the edge of the latter intended to be opposite the flange ( 2), and in that the core (17) further carries, on its outer edge, a wing (121) bearing against the body (1), substantially cylindrical, directed towards the flange (2), and of which the end (316) serves to support the seat (11) against the flange (2).  7. Seat according to any one of claims 1 to 6, characterized in that the wing (18) in contact with the shutter (7) has a substantially constant thickness when moving along the axis (XX) of the tubular body (1).  8. Seat according to any one of claims 1 to 7, characterized in that the wing (18) of contact with the shutter (7) is untwisted at its end directed towards the flange (2).  9. Seat according to any one of claims 1 to 8, characterized in that the annular contact surface with the shutter (7) comprises two sectors of concave spheres (112) adapted to be applied against the spherical shutter (7) and separated by an annular recess (27).  10. Seat according to claim 9, characterized in that the wing (18) of contact with the shutter (7) has a thinned part (29) in line with the aforementioned recess (27).  11. Seat according to claim 1, characterized in that the core (17) is connected to the wing (18) of contact with the shutter substantially at equal axial distance from the two annular ends (316, 416) of the wing (18) and extends substantially radially to its end (13) bearing against the internal wall of the duct  12 Seat according to claim 11, characterized in that the wing (18) in contact with the shutter (7) has at its end (316) directed towards the flange (2) two annular surfaces (36) concentric of support on the latter, separated by a groove (37).