FR2618517A1 - Stop valve - Google Patents

Abstract

a) The invention relates to a stop valve. b) Stop valve characterised in that the disengageable linkage means 9 is housed inside the body 1 on the side of the butterfly 2 beyond the bearing 11 and the sealing means 14, 17 traversed by the spindle 10 connected to the control means. c) The invention relates to stop valves.

Description

"Tap valve"
The present invention relates to a check valve comprising a body receiving a butterfly connected to a control means by means of an at least partially disengageable connection allowing, depending on the position of the control means, to operate the butterfly like the butterfly of a tap in the closed or open position or like the butterfly of a valve.

 Indeed, in certain applications, it is desirable to have a valve preventing reverse circulation of the fluid in a pipe, valve which is associated with a tap allowing to open the passage of the pipe or to close the passage.

 Such a valve is already known. However, in this known device, the butterfly is carried by an axis which passes through the bearing and the sealing means of the valve body in order to be connected to the actual control means such as a flywheel, with a reduction gear via a partially disengageable connection, that is to say allowing to put the butterfly in the closed position, the open position or the valve position.

 This known solution has the drawback that the axis downstream of the disengageable link must pass through the bearing and the sealing means, which considerably reduces its freedom due to the friction of the axis on the sealing elements and on the throttle bearing.

 I1 results in a difficulty of operation in the valve position; the throttle valve may not close at low reverse flow rates. However, a valve must operate as freely as possible precisely to be implemented at the least reverse flow.

 The object of the present invention is to remedy the drawbacks of this known solution and proposes to create a valve having a safer operation than the known valve, in particular in valve position, which is less bulky and of a low weight.

 To this end, the invention relates to a check valve of the above type, characterized in that the disengageable connecting means is housed inside the body, on the side of the butterfly, beyond the bearing and the sealing means. crossed by the axis connected to the control means.

 As the disengageable connecting means is housed inside the body of the valve beyond the bearing and the sealing means, the butterfly valve can tilt freely when the valve is in valve position. Indeed, the only friction to overcome are those of the disengageable link, friction which can be reduced to a minimum.

 Under these conditions, the valve is in no way influenced by the friction of the seals and sealing rings. The valve butterfly can then close for very low flow rates and actually operate as if it were a valve not belonging to a valve, while offering the advantages of this combination, that is to say that is, the reduction in size and weight.

 According to another characteristic of the invention, the disengageable link consists of two parts with claws and cams, one of the parts belonging in rotation to the butterfly and the other part belonging to the end of the axis of the means of control, these two coaxial parts being able to pivot one relative to the other by a fraction of a turn.

 According to another characteristic of the invention, the disengageable connecting means allows free movement of the butterfly relative to the axis of the control means, free movement which, when the control means is in the valve operating position, corresponds to tilting of the part of the disengageable link integral with the valve, at an angle substantially equal to half the angle described by the axis, between the open position and the closed position.

The present invention will be described in more detail with the aid of the accompanying drawings in which
FIG. 1 is a view of the valve according to the invention, with a partial diametrical section of the body of the valve,
FIG. 2 is a view in partial axial section of a valve showing the butterfly,
FIG. 3 is a perspective view of the disengageable link,
- Figures 4A-4C show the three positions of the valve control lever,
FIGS. 5A-5C2 show the different possible positions of the butterfly depending on the position of the control lever,
- Figures 6A-6C show the positions of the disengageable link members for the different positions of the control lever.

 According to Figures 1 and 2, the valve of the invention comprises a body 1 in which is housed a butterfly 2 mounted movable around the geometric axis X-X, generally horizontal. The edges of the butterfly 2, generally convex in shape, can come to bear against the seat 3 provided with a seal 4. For reasons of construction and operation, the butterfly is offset, the axis XX is generally horizontal and the lower part of the butterfly is heavier than the upper part, so that the weight of the butterfly tries to push it towards the closed position.

 The valve comprises a control means 5 comprising, for example, a flywheel 6 and a reduction gear 7 driving an axis 8 connected to the butterfly 2 via a link 9 at least partially disengageable.

 The partially disengageable link 9 is located on the side of the butterfly 2 connected to the control 5 inside the body 1 of the valve.

 This disengageable link 9 consists of a part 91 secured to the butterfly 2 and a part 92 secured to the axis 8 of the control means 5. This axis 8 passes through the bearing 11 of the body 1. This bearing 11 is provided with seals 12, 13 ensuring the seal between the bearing and the axis 8 as well as a seal 14 between the bearing 11 and the tubular part 15 of the body 1 of the valve.

 As the disengageable link 9 is located beyond the bearing 11, inside the body 1, on the side of the butterfly 2, the part 91 of this disengageable link is in no way influenced by the friction forces between the axis 8 and the seals 12, 13. The butterfly 2 can therefore, when in the valve position, pivot freely without this pivoting being braked or prevented by friction on seals.

In more detail and according to the embodiment shown, the structure of the disengageable link 9 is as follows
The part 91 integral with the butterfly 2 consists of a sleeve 910 provided with a hole 911, inside. This sleeve 910 carries two diametrically opposite teeth 912.

 The other part 92 of this connection is constituted by the axis 8 and its end 8A coming inside the bore 911 with clearance to allow relative pivoting, the end 8A thus constituting a pivot. The part 92 also comprises at least two cams forming stops 920 which limit the relative pivoting movement of the part 91 by cooperating with the teeth 912 of this part 91.

 On the other side of the geometric axis X-X of pivoting of the butterfly 2, the mounting is also done by a pivot 20 secured to a sealing boot 21 fixed to the body 1 of the valve; the butterfly 2 also includes a sleeve 21 which receives the pivot 20.

 Figure 3 shows more explicitly the shape of the partially disengageable link 9.

 This FIG. 3 shows in exploded view, the arrangement of the different parts and pieces constituting the partially disengageable connection 9.

 The operation of the above valve will be described using Figures 4A-6C.

 Figures 4A, 4B, 4C show the three possible positions of the valve. To schematize the drawings and make them clearer, the flywheel 6 in FIG. 1 has been replaced by a lever 6 ′ controlling the butterfly 2 via the partially disengageable link 9, the various relative positions of which are shown in the figures. 5A-5C2.

 In FIG. 4A, the lever 6t is in the locked closed position (V).

 In Figure 4B, the lever 6 'is in the intermediate valve position (I).

 In FIG. 4C, the lever 6 ′ is in the locked open position (H).

 FIGS. 5A-5C2 show the positions of the throttle valve for the three positions V, I and H of the lever 6 '.

 In FIG. 5A which corresponds to the locked closed position of the lever 6 ′, the butterfly 2 is applied against its seat 3. The fluid A pushes in the direction of the arrow A but cannot open the butterfly.

This position is the closing position of the valve.

 FIGS. 5B1 and 5B2 show the two positions that butterfly 2 can take in the direction of thrust of the fluid, the lever 6 'occupying the intermediate position (I) in which butterfly 2 can operate as a one-way valve, freeing the passage for the fluid flowing in direction A but preventing the passage of fluid in the opposite direction B.

 As already indicated, the geometry of the butterfly 2 and its arrangement on its axis XX (see FIGS. 1 and 2) is such that the fluid flowing in the direction A (FIG. 5B1) controls the tilting of the butterfly in the counterclockwise direction. a watch (direction of rotation P). The butterfly 2 thus switches in the direction of the arrow P until its tilting movement is limited by the partially disengageable link 9 as will be described later.

 By cons, when the fluid pushes in the direction B, due to its geometry, the butterfly 2 pivots in the direction of the arrow M and bears against its seat 3. The butterfly is then closed.

 Figures 5C1 and 5C2 show the locked open position of the throttle corresponding to position H (Figure 4C) of the control lever 6 '. For this position of the lever 6 ', the partially disengageable link 9 is in abutment and the valve 2 can only occupy the open position shown in FIGS. 6C1 and 6C2, whatever the direction of thrust A or B of the fluid.

This position corresponds to that of an open tap.

 In summary, at positions V and H shown in FIGS. 4A and 4C, the valve operates as a valve placed respectively in the closed position and in the open position while, in the intermediate position I, the valve works like a valve and not a valve, the valve opening or closing depending on the direction of pressure of the fluid.

 FIGS. 6A-6C show the relative position of the two parts of the partially disengageable link 9 described above.

 According to FIG. 5A which corresponds to the locked closed position of the valve, the cams 920 have pivoted clockwise (arrow M) due to the pivoting of the lever 6 'also in the direction of rotation of the needles d 'a watch (M); by this movement, the cams 920 pushed in the same direction the teeth 912 carrying the butterfly 2 integrally (not shown) until the butterfly is applied against its seat 3.

 This end position of throttle valve 2 corresponds to the "end stop" F1. In this position, the teeth 912 (and consequently the butterfly 2) are immobilized because no movement is possible for the teeth 912. In other words, in this position, the teeth 912 are blocked both in the direction of the arrow M since its butterfly rests on its seat and in the opposite direction since the cams 920 prohibit the pivoting of the teeth 912 (and consequently of the butterfly 2) in the opposite direction from the hands of a watch.

 This end-of-travel position is that shown in FIG. 4A for the lever 6 ′, in FIG. SA for the teeth 912 and the cams 920 and in FIG. 6A for the throttle 2.

 As already indicated, in the closed locking position, the butterfly 2 is pressed against its seat 3 by the cams 920. This stop position is represented by the stops F1 in FIG. 6A.

Similarly, the cams 920 press the teeth 912 against the opening end-of-travel stops
F2 in Figure 6C.

 In the intermediate position I corresponding to the valve function, the drive cams 920 have been pivoted integrally with the lever 6 'so that the teeth 912 can pivot relative to the position they occupied in FIG. 6A in the direction counterclockwise (arrow P) under the effect of the thrust of the fluid acting in direction A. When the thrust of the fluid reverses and goes in the direction of arrow B (FIG. 5B2), the teeth 912 can rotate from the position shown in Figure 6B1 to the position shown in Figure 6B2.

 Finally, when the control lever 6 ′ is pivoted starting from position I in position H in FIG. 4C, this pivoting results in the corresponding pivoting of the drive cams 920.

 In the description of FIGS. 4A-6C, the angular position of the lever 6 'and of the drive cams 920 is offset by 900.

 Thus, according to the example above, the control lever 6 ′ can switch a quarter turn between position V and position H passing through position I which, advantageously, corresponds substantially to the bisecting position positions V and H.

 In the case of the flywheel 6 in FIG. 1, the movement can be multiplied and the quarter-turn movement of the lever 6 ′ can be replaced by a movement of a fraction of a turn or of one or more turns of the flywheel, each positions V, I and H and, especially position I, being materialized by a reference.

 As shown in FIGS. 6A-6C, the drive cams 920 can pivot by a quarter of a turn. The same applies to the teeth 912, the movement of which is limited by the position of the cams 920 and by the stops F1, F2.

Claims (3)

 1) Shut-off valve comprising a body (1) receiving a butterfly (2) connected to a control means (6, 6 ') via an at least partially disengageable connection (9) allowing, depending on the position of the control means (5), to operate the butterfly (2) like the butterfly of a tap (in the closed or open position) or like the butterfly of a valve, tap-valve characterized in that the disengageable connection means (9) is housed inside the body (1) on the side of the butterfly (2) beyond the bearing (11) and sealing means (14, 17) crossed by the axis ( 10) connected to the control means.  2) A valve according to claim 1, characterized in that the disengageable link (9) is made up of two parts (91, 92) with claws (912) and cams (920), the parts belonging to the butterfly in rotation respectively (2) and at the end of the axis of the control means (6, 6 '), these two coaxial parts being able to pivot one relative to the other by a fraction of a turn.  3) A valve according to any one of claims 1 and 2, characterized in that the disengageable connecting means (9) allows a free movement of the butterfly (2) relative to the axis of the control means (6, 6 '), free movement which, when the control means is in the valve operating position, corresponds to the tilting of the part of the disengageable link secured to the valve (2), by an angle substantially equal to half the angle described by the axis between the open position and the closed position.