FR2708069A1 - Static seal - Google Patents

Abstract

Static seal between a first element (1) engaged in a second element (2) which cannot move relative to one another, the two elements (1, 2) being mounted so that they can slide in a housing of a support and subjected simultaneously to a high fluid pressure. This seal includes, in a blind housing (9) delimited between the two elements (1, 2), on the one hand a first elastic ring (11) applied against the first element (1) and a second elastic ring (2) inserted in the second element (2), these elastic rings being arranged concentrically and spaced apart and, on the other hand, a piston (13) subjected to the fluid pressure and exhibiting a rod (14) engaged between the two elastic rings (11, 12) in order to compress them against the bottom of the housing (9) using the piston (13) under the action of the pressure. Such a seal may especially be used in a weapon with liquid propellant.

Description

 The technical sector of the present invention is that of seals between two parts subjected to a high pressure of liquid or gaseous fluid.

 In this type of assembly, it is sometimes necessary to immobilize one part with respect to another, then authorize their joint movement or allow their translation in isolation using or against the ambient pressure. A mechanical blocking mechanism is often used to ensure immobility on the one hand, and a sealing system is provided to prevent the passage of fluid on the other.

 The object of the present invention is to design a seal ensuring not only the seal, but the blocking of two parts to ensure between them a contact pressure greater than the pressure to be sealed.

 To this end, the invention provides a static seal between a first element engaged in a second element, stationary with respect to each other, the two elements being slidably mounted inside a housing provided in a support and subjected simultaneously to a high fluid pressure, characterized in that it comprises in a blind housing delimited between the two elements on the one hand a first elastic ring applied to the first element and a second elastic ring inserted in the second element, these elastic rings being arranged concentrically and spaced from one another, and on the other hand a piston subjected to fluid pressure having a rod engaged between the two elastic rings, the rings being compressed against the bottom of the housing by the piston under the action of pressure.

 The seal may include a first metal ring applied to the first element and a second metal ring inserted into the second element, the metal rings being disposed between the bottom of the housing and the elastic rings concentrically with respect to each other .

 The metal rings are spaced from each other, the piston rod engaging between them.

 The piston can be held in the housing using a nut screwed at the open end of the housing.

 The piston rod has a height less than the depth of the housing to delimit the stroke of the piston.

 The elastic rings can be of identical height.

 The first elastic ring has a thickness greater than that of the second ring.

 The elastic rings are made of a material compatible with the fluid to be sealed, for example a rubber.

 The metal rings can have dimensions identical to those of the respective elastic rings.

 The elastic rings can be prestressed by the piston to achieve the low pressure seal between the two elements.

 A very first result of the invention lies in the fact that the sealing and the blocking of the two parts are carried out simultaneously by a single element.

 Another advantage lies in the fact that it is the pressure of the fluid which controls the level of tightness and blocking of the two parts.

 Yet another advantage lies in the simplicity of producing the seal.

 Such a seal can for example be used in a liquid propellant weapon, being housed in a pipe which ensures the pressurized delivery of the propellant between a storage tank and the combustion chamber of the weapon. Such an application will be described later in which the high pressures are pressures of the order of 5 to 10,000 bars.

Other advantages, characteristics and details of the invention will emerge from the following explanatory description given with reference to the appended drawings, given solely by way of example and in which
FIG. 1 is a section view of the seal according to the invention in the rest position,
FIG. 2 is a sectional view of the same seal in the sealing position,
- Figure 3 is a schematic sectional view of a liquid propellant weapon which is equipped with a seal according to the invention.

 According to an embodiment represented in FIGS. 1 and 2, this involves ensuring the sealing and immobilization of the parts 1 and 2 placed in a housing 3 of a body 4. In this example, the part 1 is an axis or a piston and the part 2 is a sheath or a guide screwed into the body 4 inside which the part 1 can slide. The housing 3 of the body 4 delimits a chamber 5 filled with a fluid under a gas or liquid pressure of 5,000 to 10,000 bars. The seal between the part 2 and the body 4 is ensured by a conventional metal gasket 6 disposed between a shoulder 7 of the part 2 and a shoulder 8 of the housing 3, which is crushed by the abutment of the part 2.

 The part 2 is provided with a first chamfer 9 forming a blind housing inside which is housed the static seal according to the invention and with a second chamfer 10 of upper section receiving a means for locking the joint. The seal comprises a first elastic ring 11 applied directly to the part 1 and a second elastic ring 12 inserted in the housing 9, these two rings preferably being arranged concentrically, that is to say opposite, and at a distance from each other. A piston 13 is engaged in the housing 9 in close contact with the part 1 and comes to prestress the rings 11 and 12 either against the bottom of the housing 9, or preferably against metal rings 15, 16 disposed at the bottom of the housing 9 To this end, the piston has a tubular rod 14 engaging in the free space delimited by the two elastic and metallic rings. The metal rings are in the form of a first ring 15 applied to the part 1 and has a thickness substantially identical to the elastic ring 11 and a second ring 16 inserted in the housing 9 and has a thickness substantially identical to the elastic ring 12. The piston rod 14 has a length such that its end is located substantially at the median level of the rings 15 and 16. Finally, the piston 13 is blocked by a nut 17 screwed into the housing 10 and is braked by a system stop for example a screw 25 without a cup head. This nut is in the form of a tube section which then delimits a chamber 18 in communication with the chamber 5. This chamber 5 has a volume adjustable as a function of the movement of the element 1.

 In FIG. 2, the position of the piston 13 has been shown when the pressure develops in the chamber 5. It can be seen that the latter has moved by a value e away from the nut 17. This displacement is sufficient to compress the elastic rings 11 and 12 and quench the pressure.

 The operation is as follows. After having placed the metal rings 15 and 16, then the elastic rings 11 and 12, the piston 13 is engaged, which is blocked with the nut 17. The appropriate screwing of this nut results in little precompression of the elastic rings and guarantees a low pressure sealing between parts 1 and 2. Low pressure means a pressure value of the order of 15 bar. After adjusting this precompression by tightening the nut, stopping the rotation of the nut 17, on the sleeve 2, the volume of the chamber 5 is adjusted by displacement along the arrow F of the element 1, in screwing or unscrewing parts 1 and 2, the movement mechanism not being shown. When the pressure develops in the chamber 5, it is transmitted to the face 20 (fig. 2) of the piston 13 which multiplies this pressure on the faces 21 and 22 of the elastic rings 11 and 12 by the ratio of the surfaces S20 / (S21 + S22), which causes compression of the elastic rings on the faces 23 and 24 greater than the pressure to be sealed.

 When the pressure disappears, the elastic rings 11 and 12 return to their initial position shown in Figure 1 by pushing the piston 13 until contact with the nut. The volume of chamber 5 can be adjusted again.

 The elastic rings II and 12 can be made of any elastic material provided that it is compatible with the fluid to be sealed, that is to say a resistant material without degrading said fluid. By way of example, mention is made of rubbers.

 The embodiment shown in FIG. 3 corresponds to an inverted assembly with respect to the embodiment according to FIGS. 1 and 2, in which the rings are mounted on the piston 1 which slides inside the sheath 2.

 The end 1a of the piston has two sections 1b and 1c of decreasing diameter. The section lb delimits a shoulder 26 which itself defines with the internal surface of the part 2 and the external surface of this section lb a housing for receiving the device according to the invention. The metal rings 15 and 16 are applied against the shoulder 26 while being separated from each other by a free space. The external diameter of the ring 16 is adapted to the internal diameter of the sleeve 2 and the internal diameter of the ring 15 is adapted to the diameter of the section lb of the piston 1. The elastic rings 11 and 12 are placed respectively against the metal rings 15 and 16, the dimensions of these rings being provided as above.

The piston 13, provided with its tubular rod 14 engaged in the free space delimited by the rings, may include an internal lug 27 capable of coming into abutment on the shoulder 28 of the piston 1. The ring 17 is screwed on the lo section and is immobilized in rotation by the screw 25 and makes it possible to fix the initial prestressing of the rings 11 and 12. The operation is identical to that of the preceding embodiment.

 In the figures, it can be seen that the inner rings 11 and 15 have a thickness greater than that of the corresponding outer rings 12 and 16. This difference in thickness makes it possible to equalize the stress exerted by the piston 13.

 Among the possible applications of the invention, mention will be made of guns using propellant fluids such as liquid propellant guns or else electric fluid cannons.

 An example of application of such a seal is given by way of example in FIG. 4, which partially and schematically illustrates a tube 50 of a medium or large caliber weapon with liquid propellant, with a projectile 51 stationed in the tube 50 at a forcing cone 52, in a manner known per se.

 The rear end of the tube 50 can be sealed in a sealed manner by a breech obturator 53. A combustion chamber 55 is delimited in the tube 50 between the projectile 51 and the breech obturator 53 in the closed position thereof.

 This liquid propellant weapon is equipped with an injection system for injecting under pressure into the chamber 55 a propellant, such as a propellant in liquid or gelled form, stored in at least one reservoir 57 defined in an annular body. 40 attached around the tube 50 of the weapon. For this, a longitudinal channel 60 is pierced in the body 40, parallel to the axis of the tube 50, and the variable volume reservoir 57 is defined in the channel 60 between two bottoms 61 and 62 respectively constituted by a plug which closes one end of the channel 60 in a sealed manner, and by a cylindrical element adjustable in axial position inside the channel 60 and which also seals the other end of the latter. The bottom 62 corresponds to the part 1 of FIG. 1 and is sealed by the seal 71 in accordance with FIGS. 1 and 2. A pressure intensifier piston 65 is mounted and sliding inside the tank 57. The bottom 61 formed by the plug extends inside the tank 57 by an axial stop 66 on which the piston 65 is supported, when the tank 57 is filled. In this position of the piston 65, a chamber 67 is delimited in the tank around the stop 66, this chamber 67 communicating with the combustion chamber 55 by an inlet pipe 68 formed by a channel pierced in the body 40 which corresponds in part 2 of FIG. 1 and in the wall of the tube 50.

 The tank 57 also communicates with the combustion chamber 55 by an outlet pipe 69 pierced inside the body 40. This outlet pipe 69 consists of a longitudinal channel or conduit 41 which communicates with the tank 57 by at least a connection duct 70, and with the combustion chamber 55 by a radial duct 42. A valve 43 is housed in the duct 41 at the level of the passage section between the ducts 41 and 42.

 Such an injection system operates in the manner described below.

 Before firing the projectile 51 stationed in the tube 50, the volume of the reservoir 57 is adjusted to store the total amount of propellant necessary for firing the projectile 51. This operation consists in adjusting the axial position of the bottom cylinder 62 by means of an adjustment mechanism 62a. The static seal 71 according to the invention is mounted at the level of the cylinder 62 and makes it possible to seal the pressure of the fluid between the body 40 and this cylinder. Once the volume of the reservoir 57 has been adjusted, the propellant is sent under low pressure to the reservoir 57 which communicates, for this purpose, through a channel 75 with a filling means (not shown). The propellant spreads in the outlet conduit 41. The valve 43 remains in the closed position, as long as the force exerted by a return spring on the rear face of the valve 43 is greater than the difference of the forces exerted by the propellant on the two opposite sides of the front wall of the valve.

 A small quantity of propellant is injected and then ignited directly in the combustion chamber 55. The combustion gases freely penetrate inside the chamber 67 via the inlet pipe 68, and as soon as their pressure becomes sufficient, they cause the piston 65 to move. This pressure is however insufficient to cause the projectile to be ejected 51. While moving, the piston 65 compresses the propellant contained in the reservoir 57 and the associated outlet pipe 69. As soon as the propellant compressed by the piston 65 has reached the pressure necessary to open the valve 43, the latter releases the passage section between the two conduits 41 and 42, and the agent can then flow to the combustion chamber 55, and then cause the projectile 51 to be ejected when the pressure of the combustion gases reaches a sufficient value.

 Of course, the invention is in no way limited to the embodiment of the seal as illustrated in the drawings.

Claims (10)

 1. Static seal between a first element engaged in a second element, stationary with respect to each other, the two elements being slidably mounted inside a housing formed in a support and subjected simultaneously to a high fluid pressure, characterized in that it comprises in a delimited blind housing (9) between the two elements (1,2) on the one hand a first elastic ring (11) applied to the first element (1) and a second elastic ring (12) inserted in the second element (2), these elastic rings (11,12) being arranged concentrically and spaced from one another, and on the other hand a piston (13) subjected to the fluid pressure having a rod (14) engaged between the two elastic rings (11,12), the rings being compressed against the bottom of the housing (9) by the piston (13) under the action of the pressure.  2. Static seal according to claim 1, characterized in that it comprises a first metal ring (15) applied to the first element (1) and a second metal ring (16) inserted in the second element (2) , the metal rings being arranged between the bottom of the housing (9) and the elastic rings (11,12) concentric with each other.  3. Static seal according to claim 2, characterized in that the metal rings (15,16) are spaced from each other, the rod (14) of the piston (13) engaging between them this.  4. Static seal according to any one of claims 1 to 3, characterized in that the piston (13) is held in the housing (9) using a nut (17) screwed at the open end of the housing (9).  5. Static seal according to any one of the preceding claims, characterized in that the rod (14) of the piston (13) has a height greater than the depth of the housing (9) to delimit the stroke of the piston (13 ).  6. Static seal according to any one of the preceding claims, characterized in that the elastic rings (11,12) are of identical height.  7. Static seal according to any one of the preceding claims, characterized in that the first elastic ring (11) has a thickness greater than that of the second ring (12).  8. Static seal according to any one of the preceding claims, characterized in that the elastic rings (11,12) are made of a material compatible with the fluid to be sealed, for example a rubber.  9. Static elastic seal according to any one of the preceding claims, characterized in that the metal rings (15,16) have dimensions identical to those of the respective elastic rings (11,12).  10. Static elastic seal according to any one of the preceding claims, characterized in that the elastic rings (11,12) are prestressed by the piston (13) to achieve the low pressure seal between the two elements (1,2) .