FR2862377A1 - Seal system for firearm chamber taking rounds without shell cases has elastic ring fitting between chamber and piston when breech is closed - Google Patents

Abstract

A seal system for a firearm with a barrel (1), a shell chamber (3) and a piston or seal chamber (4), comprises an elastic ring (13) that makes a seal between the chamber and piston (5) when the breech is closed. The ring, made e.g. from steel, bronze or brass, also forms a joint between the breech and barrel as gas pressure causes it to contract. An independent claim is included for an elastic ring with a number of diaphragm lips located in series inside the seal chamber and having as mean curvature with a generating surface parallel to the barrel's axis.

Description

ROOM SEALING SYSTEM FOR AMMUNITION WITHOUT ETUIS

TECHNICAL FIELD OF THE INVENTION

  The present invention relates to a particularly simple and reliable chamber sealing system for shooting ammunition without a case. Its formula requires only a minor modification of the known firing chamber principle of the ammunition case and can be combined with formulas of coupling gun / cylinder head using gas as described in PCT application FR / 03/01220 of the same author. Adaptability to all calibres (from 4 mm to over 155 mm) is evident.

  The ammunition without a case is preferably of the telescoped type, ie composed of a ball surrounded by a solidified thruster or a thruster attached to the back of the bullet. They have a circular extraction groove machined recessed at the rear periphery of their body in the manner of ammunition case to allow their extraction.

PRIOR STATE OF THE TECHNIQUE

  The use of ammunition without a case necessitates a perfectly sealed ammunition chamber during combustion of the propellant. Many formulas have been patented and tested without apparent success, probably due to the maintenance of the classic mechanical percussion and the complexity of the sealing devices retained.

  Thus US Pat. No. 3,345,770 A (Scanlon J.J.), dating from October 1967, proposes a weapon intended for firing ammunition without a case that has the particularity of not having an extraction groove. The author designs a chamber whose sealing is provided by a mandrel comprising a plastic O-ring seal located between two open segments. The author does not specify anything about the leakage inherent in the opening of these segments to the square section not conducive to a real tightness as evidenced by their drawing in Figures 2 and 3.

  The sealing principle retained by Scanlon, as stipulated in lines 22 to 24 of ≈2, clearly states a diameter of the O-ring greater than the bore of the piston since the rounded funnel neck is supposed to compress said seal in order to put it in format, all without prejudging the friction generating delays at the closing of the breech, is therefore an altered firing rate with risks of blockage. It is therefore on this single plastic seal that rests the seal, that moreover a single segment of head, open moreover, can not fully protect from the onslaught of hot gases.

  The choice of the plastic material (neoprene, Teflon ... column 2 line 18) raises questions about the temperature resistance of this joint when we know that these materials have a melting point located near 250 C for more resistant and that the temperature of the gases reaches 1800 C.

  The apure being planned for the automatic shooting, it is a safe bet that the heating of the chamber and the segments does not lead to a fast softening, a cooking or a fusion of the joint with risk of fouling, sticking to the room , stopping of the weapon then rupture with escape of the gases towards the shooter with the key.

  To increase the longevity of the O-ring, the author should have used two segments joined to each other and placed before the plastic seal (and not separated by this seal, the rear segment providing no protection) and indexed so that their openings are not facing each other. This solution would have had the advantage of eliminating gas leaks by opening the head segment and improve the conformity of the segments with the cylinder without ensuring a real tightness in the short term.

  The presence of the segments flanking the seal also suggests that their diameter is greater than the bore 45 of the piston on pain of having no reason to be.

  Now, curiously Scanlon JJ does not evoke the consequence of this oversizing of the diameter of the segments likely to cause a scraping or planing of the entrance of the neck of the supply ramp by the sharp square section (see Figure 2) of the segment acting like a plane. This effect will be manifest regardless of the profile of the neck (rounded, conical ...) and the angle of attack, as small as it is, since it presides over the principle of the plane.

  The end of use of the aune is ultimately unavoidable, the shooter having no ability to compress the segments inside their housing to avoid scraping and promote the introduction of the mandrel in his room. Once the phenomenon appears, any new attempt to move before the bolt will result in a blockage.

  More hazardous still is the risk of destruction of ammunition by planing their bodies by segments.

  We can easily imagine the effects of scraper segments on a compacted powder loaf. No doubt in order to mitigate this risk, the author reports a busc on the lower face of the breech (level 44 of figure 2), the function of which is obviously to produce a depression of the cartridges during the recoil of the head. cylinder head to prevent contact of the segments with said cartridges. The author does not seem, moreover, to perceive the consequences of the necessary depression produced by the passage of this busc on the cartridges stacked in the loader during the movement of the cylinder head with risk of blocking said cylinder head and destruction of the powdered bread ammunition.

  This busc also avoid contact segments with the base of the ammunition despite the presentation of the cartridges at a high angle to nose up. To be convinced of this it suffices to simulate the recoil of the breech to find that there is necessarily contact, once the busc discovers the base of said ammunition, segments with the powdered bread. The destruction of the latter by tearing / scraping is then inevitable.

  Finally, no device for extracting a chambered cartridge is provided, exposing the user to the jamming of his weapon in case of defective ammunition. It should then remove the magazine, open the breech and push from the entrance of the barrel with an ad hoc rod to try to extract the cartridge with the danger that is known in case of long fire.

  The author also specifies nothing about the length of the sealing chamber, however, a determining factor for the safety of the weapon: a room that is too short irreparably leads to an opening too early exposing the shooter and the ammunition of the charger to the hot gases of the detonation.

  In conclusion, the patent Scanlon weapon intended for repetitive shooting by mechanical percussion ammunition without case corresponds to an incomplete study where the author proposes a dangerous sealing formula based on the use of a fragile joint consisting of segments with irrational scheduling (a segment behind the plastic seal), without prejudging their inevitable planing of the introduction neck as ammunition with jamming of the weapon at the key, all without prejudice to the absence of extractor which exposes the user in case of cartridge failure.

  The present patent, on the other hand, mitigates these design errors by using a sealing device housed inside the chamber making it possible to use a perfectly smooth piston at its periphery, thus without any risk for the ammunition.

  This formula also ensures a lack of jamming during the forward movement of the cylinder head and an absolute reliability of temperature resistance. This patent finally ensures the firing of electric ammunition and cartridge extraction, which can not ensure the patent Scanlon J.J.

  Patent FR 2 308 076 A (CIVOLANI Bruno) of November 1976 describes a weapon percussion system using self-propelled projectiles equipped with peripheral primers as described in Italian patents Nos. 932,381 and 972,058.

  These projectiles constitute true ammunition without a case but suffer from serious problems of stability on trajectory and precision attributable to the deformation caused by the percussion on the cylindrical wall of the projectile. The delay in opening the chamber is obtained by retreating a closing pivot, similar to the mandrel of US Pat. No. 3,345,770, of the same diameter as the projectile and whose length is such that the opening intervenes after the exit. of the barrel projectile.

  The sealing of such a chamber is not evoked by the author who affuble the mandrel, in the accompanying figures, radial grooves not mentioned in the description.

  It is clear in any event that the mere presence of these grooves can not ensure proper gas tightness, or, if they received segments, prevent a blockage of the bolt during forward movement, making the weapon unusable.

  Finally, no mention of an extractor is made both in the description and on the attached sheets, suggesting that the author, like JJ Scanlon with his US patent 3,345,770, failed to solve this crucial problem. The principle of this weapon is further limited to automatic operation since there is systematic percussion of the projectile as soon as the chamber is closed.

  However, the movement of an inertial mass forward at the moment of firing results in an inexorable disturbance of the line of sight, thus detrimental to precision. The weapons (MAT 49, UZI ...) operating according to this principle are too imprecise and have been removed from service or modified (UZI) to adopt a cartridge chamber percussion mode.

  This patent describes, on the other hand, an ammunition without a particularly precise case since the projectile is not affected, during firing, by any incision or deformation likely to impair its accuracy. The weapon thus proposed comprises a perfect sealing chamber provided with a defective ammunition extractor.

  Patents 79 06 106, 83 07602 & 83 07603 of Heckler & Koch describe a rifle using ammunition without case whose chamber sealing is ensured by a particularly complex device based on a rotation of 90 of the chamber. Cartridge feeding occurs by gravity, lending itself to many problems when the weapon is in motion. The rotation of the chamber (borrowed also from the old principle of the water taps) does not guarantee no imperviousness to the propellant gases free to go back to the supply channel. This formula causes a great complexity of the rotation mechanism of the chamber leading to its abandonment.

DESCRIPTION OF THE INVENTION

  The present invention is in the field of automatic weapons ammunition without case whose principle can be extended to all calibers. The weapon comprises a barrel provided with a munition chamber contiguous to a chamber of a sealing piston integral with the bolt. This arrangement is perfectly compatible with the reciprocating movement of the arms' breech using a magazine feed for automatic firing. The piston which comprises a firing bowl and an extractor conventionally ensures the introduction of the cartridges from the lips of the magazine into the ammunition chamber via the piston sealing chamber. The latter plays the parallel role of cone / funnel supply overcoming many problems such as the transverse presentation of the cartridges following a violent escape lips of the charger, for example.

  The absence of gas to the rear of the weapon, therefore the user, is obtained by sealing the chamber around the piston. The latter, unless there is a breech / barrel securing device to introduce a delay in opening, recedes when shooting. The gas pressure is used to cause a variation of the chamber / piston relative bore either by increasing the bore of the piston or by contraction of that of the chamber to ensure a perfect seal and prevent gas leakage during the shoot. A suitable dimensioning of the recoil stroke of the piston during the travel time of the ammunition in the barrel produces the delay to the desired opening. For this purpose, the length of the piston or the stroke of its recoil in the chamber is such that the opening occurs only when the projectile is out of the barrel. In the case of heavy ammunition or heavy caliber two formulas for securing the piston with the chamber are proposed to ensure the additional delay to the desired opening.

  The relative bore variation of the chamber with respect to the sealing piston is ensured either by the symmetric expansion under the pressure of the gases of a bi-lip diaphragm seal or one or more diaphragm lip (s) mounted ( s) in series within said chamber, or by the uniform contraction of the inner wall of said chamber via the thrust of the gas flowing in an annular chamber housed in the thickness of said wall, in order to contract around the piston .

  The variation of the bore of the piston relative to the chamber is ensured by the symmetrical expansion of the gases flowing in an inner annular chamber causing the radial uniform expansion of its cylindrical wall or an annular ring in order to make a next contact. a single peripheral generator with the wall of the chamber.

  These formulas guarantee an absolute security by creating a perfectly sealed chamber during the shooting thanks to simple mechanisms, inexpensive and reliable over time, eliminating any disappointment peculiar to the current formulas which rest on the fragile resistance of a holster and a cup of primer.

  Indeed, ammunition cases have a conceptual weakness generally ignored by users: the strength of the weapon during shooting follows the principle of resistance of a chain, subordinate to that of the weakest link. The holster is in many ways the weakest link in the chain of fire. Indeed, the case not only plays the role of seal when it is pressed against the walls of the room at the start of the stroke, but it is still he who cashes all the force of effort on its rear part (base) . But the latter is in the open on most current automatic weapons, conditioning the tightness of the firing chamber to its only resistance.

  The primer is also another weak link since it suffices that the striker pierces his cup to dangerously release the gas to the shooter.

  We therefore measure the importance of the risk that users run a formula whose case logic is historically borrowed revolvers which, they, guarantee a better resistance since the base of the case is embedded in the barrel and is found in full support on the shield (or barrel back) of the weapon during firing.

  No user of automatic weapon is therefore protected against the risk of cracking of the primer or rupture of the wall of case, especially at the base, and the terrible release of hot gases that follows. The numerous accidents identified as a result of successive reloading are there to testify.

  The present invention provides, on the other hand, a perfect fire safety based on a total charging technique of the ammunition by a piston in a chamber sealed during firing. This formula offers the strength of the thick steel walls of the piston and barrel uncommon with that of brass cases.

Description of the boards 1 to 8/8

  The plate 1/8 includes 1 figure (1) describing the principle of sealing gas pressure by diaphragmatic contraction of the wall of an annular chamber on a swiveling portion of a sealing piston.

  The board 2/8 comprises 1 figure (2) describing the principle of sealing by diaphragmatic contraction of one or more lip (s) -diaphragm arranged (s) inside the chamber of reception of a piston of smooth sealing. The board 3/8 comprises 2 figures (3 & 4) describing the principle of sealing by centrifugal and centripetal variation in the bore of a bi-lip diaphragm seal.

  The plate 4/8 comprises 3 figures (5, 6 & 7) describing the sealing principle by bore variation of a lip-diaphragm arranged at the inlet of the sealing chamber, combined with a cylinder head fastening device. / gun by contraction, under the effect of gases, an open bayonet ring or a closed ring around a piston. The board 5/8 comprises 1 figure (8) describing the sealing principle by bore variation of a lip-diaphragm arranged inside the chamber, combined with a bolt / barrel joining device by mechanical contraction, under the action of a clamping ring moved by the gas, said lip-diaphragm around the piston.

  The plate 6/8 comprises 2 figures (9 & 10) describing the principle of sealing by expansion, gas pressure borrowed from the bowl of firing, a swivel ring surrounding the piston head.

  The plate 7/8 comprises 2 figures (Il & 12) describing the principle of sealing by expansion, gas pressure borrowed at the level of the firing bowl, the swivel wall of the piston head.

  The plate 8/8 comprises 2 figures (13 & 14) describing the principle of sealing by expansion, gas pressure borrowed from the inner periphery of the firing bowl, the swivel wall of the piston.

  DESCRIPTION AND OPERATION OF THE SEALING SYSTEM (Boards 1 to 8/8) The sealing system consists of a limited number of parts. This feature is expected to result in significant economic impacts in terms of cost of production, maintenance and reliability.

  According to the principle of the invention the system comprises: a sealing device consisting of a piston integral with the cylinder head of the weapon and a chamber for accommodating said piston contiguous to the ammunition chamber, a combined device of ignition / ejection of cartridge passing through the piston, a device for extracting cartridges secured to the piston, a device for borrowing propellant gas at the bottom of the firing bowl of the piston, a gas pressure sealing device by diaphragmatic variation of one or more diaphragm lip (s) mounted in series within the sealing chamber, a gas pressure sealing device by centrifugal and centripetal diaphragm variation of a seal bi-lip diaphragm with double peripheral sealing, a gas pressure sealing device by varying the bore of the wall of an annular chamber arranged inside the piston chamber, a sealing device at a gas pressure by varying the bore of a ring surrounding the sealing piston, a gas pressure sealing device by varying the bore of the peripheral wall of the sealing piston, a bolt securing device / barrel by open ring ring of the bayonet segment type or ring closed and sealed with peripheral slots, a bolt / barrel fastening device with a closed elastic ring. The system comprises the following elements (boards 1 to 8/8): - (1) gun, - (2) cylinder head, - (3) ammunition chamber, - (4) piston chamber or seal, - (5) piston, - (6) extractor, - (7) ring (removable) of the piston chamber inlet neck, - (8) pin, - (9) firing bowl, - (10) light or niche firing bowl for gas supply, - (11) sealing chamber inlet cone, - (12) inner annular chamber, - (13) elastic wall, (14) swiveling piston protrusion, 30 - (15) chamber inlet diaphragm lip, - (16) stackable diaphragm lip (comb), - (17) bi-lip diaphragm seal, - (18) peripheral double-seal annular seal housing, - (19) external lip rotulante of diaphragm seal bi-lip, - (20) inner lip of diaphragm seal bi-lip, - (21) ring clamping type bayonet segment, - (22) cone clamping.

  - (23) tightening ring return spring, - (24) sealed and tight ring with peripheral slots, - (25) clamp-type closed ring, - (26) clamping cone of the closed ring of clamp type, - (27) diaphragm lip conical shoulder, - (28) circumferential groove elastic ring housing, - (29) elastic ring, - (30) beveled circular groove of piston body, - (30 bis) circular groove beveled piston skirt, - (31) bevelled edge of cylindrical ring, - (32) throttle groove, - (33) gas supply ports, - (34) gas supply channels, - ( 35) igniter / ejector, - (36) piston skirt, (37) skirt wall rotulance zone, - (38) internal gas expansion chamber, 55 - (39) gas supply groove , - (40) cylindrical crown, - (41) rotulance, 10 - (42) annular chamber, - (43) igniter valve / ejector rod, - (44) igniter buffer / ejector, (45) extension igniter / ejector.

  The relative piston / chamber seal can be obtained either by uniform diaphragmatic contraction of the inner wall of the chamber on the piston or by uniform diaphragm expansion of the cylindrical wall of the piston inside the chamber. The following modes describe the mechanisms implemented to achieve this.

  SEALING BY DIAPHRAGMIC CONTRACTION OF THE CHAMBER

  In the embodiments below, the firing bowl located at the end of the cylinder head piston may be of either conventional type or advantageously comprise radial lumens, channels or crenellations (10) arranged symmetrically around its periphery, such as described in PCT patent FR / 03/01220, and whose role is to ensure the peripheral diffusion of the gases (feeding) to the annular chambers (12), joint housing (s) and lip (s) -diaphragm ( 15, 16).

  First mode (Plate 1/8, Fig. 1): In a first embodiment of sealing, the sealing chamber (4) comprises an inner annular chamber (12) open substantially at the height of the piston head ( 5) and defining a wall (13) elastic contact with the piston. The profile of this wall (FIG 1) adopts a generatrix which has a medium curvature at its base in extension of the sealing chamber inlet cone (11), to be then parallel to the axis of the barrel and offer the advantage of radial elasticity in expansion as in radial contraction.

  The piston (5), in order to facilitate its introduction into the sealing chamber, has a slight taper (some 1/10 of a millimeter) from the base to the firing bowl. Its bore is, at the base, slightly greater than that of the elastic wall of the annular chamber so as to be advantageously in contact with the latter end of travel in the chamber (4). This arrangement ensures systematic contact of the wall with that of the piston as soon as the cylinder head (2) is fully closed, eliminating any risk of leakage that may result from a diaphragmatic contraction delay of said wall during the rise in pressure of the gases at departure of the shot.

  In order to ensure contact along a single peripheral generatrix of the elastic wall (13) of the chamber (4) sealing with the piston, the latter may advantageously comprise a swiveling protrusion (14) with said wall (13) of which the the bore is, at this level, slightly lower than that of said protrusion so as to ensure a systematic contact of the wall with that of the piston (5) when the latter is at the end of the race.

  Principle of operation: At the start of the stroke the propellant gases take the volumes relative to the mechanical clearance between the piston and the chamber or, better, the lights or crenels (10) peripheral of the firing bowl of the piston head (5) and exert immediately a uniformly distributed pressure (symmetry of the slots and lights) on the rear face of the wall (13) producing a variation of its curvature reinforcing its uniform contact with the wall of the piston, or better its rotulance (14), for a perfect sealing against peripheral gases that are blocked by the contact of a generatrix of the elastic wall with that of the piston.

  In the case of using a non-locked cylinder head where the rotulance is more preferably positioned near the piston head, the elastic wall remains in contact during the recoil of the piston with said rotulance due to its radial centripetal elasticity. This elasticity also plays the role of wear compensator to ensure a perfect contact of a generator with the wall of the piston, expanding as in compression.

  As soon as the bullet comes out of the barrel, the pressure drops instantly and the elastic wall returns to its nominal internal bore in order to ensure a next contact with the piston at the bottom of the reception chamber after the introduction of a new cartridge. .

  Achievement: Those skilled in the art will adapt the dimensions, materials and thicknesses of the elastic wall to the pressures involved (several thousand bars).

  Its realization can easily be obtained by machining in the mass of the material (steel, inconel ...) constituting the chamber and more particularly the inlet cone formed by a ring (7) made integral with the chamber by any mounting (screw, bayonet ...) at the discretion of those skilled in the art while taking the precaution of ensuring the centering by a conical shoulder for example.

  The diaphragm contraction of the elastic wall (13) also ensuring a perfect centering of the piston in its chamber during the rise in gas pressure, said piston will advantageously mounted floating. This floating, very light considering the piston / chamber tolerances which are of the order of a few hundredths of a millimeter, will be included in the game of the slide of the weapon or the guides of the breech.

  Note: when firing the ammunition, the recoil of the sealing piston favors the depositing of the combustion residues of the propellant on the walls of the chamber, which are thus self-lubricated. This lubrication will facilitate the introduction of the piston and increase the life of the sealing lip or lips. In order to guarantee a long life to the pistons and elastic wall these will be made of an elastic material (UE9P bronze, steel, cast iron ...) able to withstand the forces of temperature and friction. A self-lubricating treatment (titanium nitride, Diamond Like Carbon, amorphous carbon, molybdenum, graphite ...) can also be applied.

  Second mode (Plate 2/8, Fig. 2): In a second embodiment of the seal, the chamber (4) comprises one or more lip-s (15) and (16) in comb-like series. ", one behind the other integral, that is to say machined from the material constituting the piston chamber or reported by mounting / stack (16). The profile of a lip-diaphragm constitutes a "tongue" intended to be in contact with the cylindrical wall of the piston. The profile of this tongue has a mean curvature whose generator may be either parallel to the axis of the barrel or adopt an angle close to that of the chamber inlet cone (II) in order to be arranged within said cone. This latter arrangement makes it possible to integrate the lip-diaphragm (15) with the chamber inlet (II) providing the longest sealing stroke to the piston.

  The profile of the lip (16) has the advantage of offering a certain radial elasticity in expansion as in contraction. The thickness of its section decreases regularly, along a generatrix preferably but not exclusively curved, so as to favor, under the pressure of the gas or piston, a narrowing or an increase in the internal bore of the lip-diaphragm.

  To facilitate its introduction, the piston (5) has a slight taper (some 1/10 of a millimeter) from its base to the top. Its bore at the base is slightly greater than that of the lip (s) (15 or 16) so as to be advantageously in contact with them before being at the end of the race in the chamber (4). This arrangement ensures systematic contact of the lip (s) with the wall of the piston (5) as soon as the breech is fully closed, eliminating any risk of leakage that may result from a diaphragmatic contraction delay of the lip or lips ( s) when the gas pressure rises.

  The piston may optionally comprise, similarly to the previous mode, a swiveling protrusion cooperating with the or the lips mounted in series.

  Operating principle: At the start of the stroke the propellant gases take the volumes relative to the mechanical clearance between the piston and the chamber, or better the lights or crenellations (10) periphery of the firing bowl of the piston head and immediately exert a uniformly distributed pressure (symmetry of the crenellations and lights) on the upstream wall of the lip or lips (15 or 16) producing a variation of the or their curvature reinforcing the uniform contact with the wall of the piston (5) for a perfect seal against the peripheral gases which are blocked by the contact of a generatrix of the lip or lips with the wall of the piston.

  The lip or lips remain in contact with the wall of the piston during its recoil while accompanying the conicity thanks to their radial centripetal elasticity. This elasticity also plays the role of wear compensator to ensure always perfect contact with the wall of the piston, expanding as in compression.

  As soon as the bullet comes out of the barrel the pressure drops instantly and the lip (s) regain a nominal internal bore to ensure a next contact with the piston in the back of the room at the end of the introduction of a new cartridge.

  Achievement: Those skilled in the art will adapt the dimensions, materials and thicknesses of the lip (s) -diaphragm to the pressures involved (several thousand bars) and their number to mount in series (comb) the one behind the other inside the chamber so as to offer, if necessary, greater security in case of accidental breakage of one of them.

  The diaphragm lip or lips can easily be machined from the mass of the material constituting the chamber and more particularly the inlet cone formed by a ring (7) made integral with the chamber by any mounting (screw, bayonet ...) at the discretion of those skilled in the art while taking the precaution to ensure the centering by a conical shoulder for example. The diaphragm lips may also consist of independent rings (16), stacked and held by clamping the inlet ring-cone.

  The diaphragm contraction of each lip ensuring perfect centering of the piston in its chamber, the latter will advantageously mounted floating. This floating, very light considering the piston / chamber tolerances which are of the order of a few hundredths of a millimeter, will be included in the game of the slide of the weapon or the guides of the breech.

  Note: when firing the ammunition, the recoil of the sealing piston favors the depositing of the combustion residues of the propellant on the walls of the chamber, which are thus self-lubricated. This lubrication will facilitate the introduction of the piston and increase the life of the sealing lip or lips. In order to guarantee a long life to the diaphragm lips, these will be made of an elastic material (UE9P bronze, steel, cast iron ...) capable of withstanding the temperature and friction forces. A self-lubricating treatment (titanium nitride, Diamond Like Carbon, amorphous carbon, molybdenum, graphite ...) can also be applied.

  Third Mode (Plate 3/8, Figs 3 & 4): In a third embodiment of sealing, the chamber (4) for receiving the piston comprises a housing (18) characterized in that it has a concave rotulance adapted to co-operate with that of the convex outer lip (19) of a bi-lip diaphragm seal (17) in V. This seal is characterized in that it provides a centrifugal and centripetal peripheral double seal by radial elastic deformation its V-shaped section at the opening facing the ammunition chamber and whose outer lip (19) is rotulante in the reception chamber of the sealing piston and the convex inner lip (20) is in the guide bearing of the piston.

  The profile of each lip has the advantage of being elastic in expansion as in radial contraction. The thickness of their section decreases regularly from the center of the V towards the ends, along a preferably curved generatrix, so as to favor, under the pressure of the gases or the piston, a narrowing or an increase in the bore of each independently of the other.

  This property makes it possible to play on the relative tolerances of inner piston / lip machining (20) so that the edge of said lip is advantageously in contact with the wall of the piston (5) before the latter is at the end of the stroke in the bedroom (4). For this purpose, the piston has a slight taper from the base to the firing bowl and its bore at said base is slightly greater than that of the inner lip (20) so as to be systematically in contact with it from the full. closing of the breech.

  This arrangement eliminates any risk of leakage that may result from a diaphragmatic contraction time of the inner lip (20) during the rise in pressure of the gases. Simultaneously this diaphragmatic expansion of the inner lip caused by the taper of the piston, causes an elastic diaphragmatic expansion of the outer rotational lip (19), a generator of which comes into contact with the housing (18) of the jointing joint of the seal to ensure, initially suddenly during the rise in pressure of the gas, a perfect bore sealing periphery type patellar.

  Operating principle: At the start of the stroke the propellant gases take the volumes relative to the mechanical clearance between the piston and the chamber, or better the lights or crenellations (10) periphery of the firing bowl of the piston head and immediately exert a uniformly distributed pressure (symmetry of crenels and lumens) on the lips (19 & 20) of the joint (17) producing a combined variation of their curvature as well as the angle they form, which reinforces their respective contact with the wall the piston (5) and the swiveling wall (18) of the seal housing for perfect sealing against the peripheral gases. Indeed, they are blocked by the contact of a generatrix of the inner lip with the piston wall and a generatrix of the outer lip with the swiveling wall of its housing.

  During the recoil of the piston, the inner lip (20) remains in contact under the pressure of the gas with the wall of said piston while accompanying the reduction of its diameter due to its conicity due to its radial centripetal elasticity. This elasticity also plays the role of wear compensator to ensure always perfect contact with the piston, expanding as in compression.

  As soon as the bullet comes out of the barrel the pressure drops instantly and the inner lip returns to its nominal bore to ensure a next contact with the piston after the introduction of a new cartridge when the latter reaches the bottom of its barrel. reception room (4).

  The diaphragm elasticity of the bi-lip seal tending to a perfect centering of the piston in its chamber under the pressure of the gases, it will advantageously mounted floating. This floating, very light considering the piston / chamber tolerances which are of the order of a few hundredths of a millimeter, will be included in the game of the slide of the weapon or the guides of the breech.

  Any axial offset of the piston is automatically overtaken by the rotulance of the outer lip of the bi-lip seal ensuring the perfect contact of a generator with the wall of the chamber.

  Embodiment: Those skilled in the art will adapt the dimensions, materials and thicknesses of the lips of the bi-lip joint to the pressures involved (several thousand bars) in order to advantageously combine the intrinsic elasticities of variation of their curvature and their angle. of convergence. The seal (17) bi-lip can be set up (in force) at the factory in its housing (18) of the ring (7) removable piston chamber inlet neck, in the manner of mounting a ball bearing by playing on its intrinsic elasticity. The assembly and replacement are then simple on the ground and correspond perfectly to a use of the armed forces.

  In order to guarantee a long life to the bi-lip joints, these will be realized (machining in the mass ...) in an elastic material (UE9P bronze, steel, cast iron ...) able to resist the efforts of temperature and friction. A self-lubricating treatment (titanium nitride, Diamond Like Carbon, amorphous carbon, molybdenum, graphite ...) can also be applied.

  Note: the three aforementioned modes are compatible with most breech / barrel securing devices known to those skilled in the art, among them: rotary locking, tenons.

  Applications: The three aforementioned modes may find application in the fields of high pressure fluid cylinders and temperature and combustion engines. This type of "segment" can naturally be applied in the engine two or four times being placed as described, including room base following the second mode. The dimensions and in particular the thickness and the curvature of the lips will be adapted to the lower compression pressure of the engines. With no opening, such a segment should substantially increase the compression efficiency by producing additional sealing to the gas pressure.

  PISTON / CHAMBER SOLIDARIZATION DEVICES (boards 4/8 & 5/8, FIGS. 5 to 8) 40 In order to increase the delay in the opening of the cylinder head, several modes of securing the piston to the chamber, causing a breech / barrel joining, can be introduced. Thus, in addition to the possibility of combining the principle of diaphragm-diaphragm sealing with coupling formulas gun / cylinder head tenons driven by gas borrowing as described in the PCT application FR / 03/01220 of the same author, a method of fastening by clamping can be introduced.

  First mode (Plate 4/8, Figs 5, 6 & 7) In a first embodiment of the securing of the piston with the chamber, the latter is obtained by the presence of a ring (21) of the bayonet segment type disposed in a housing accommodated in the piston chamber on the inner face of the inlet cone ring (7). This housing is characterized in that it has a cone (22) clamping a slope ((3) adapted to ensure the contraction of the ring during a movement of the latter to the chamber inlet under the action of the gas pressure.

  The return of the ring (21) clamping can be facilitated by the presence in the bottom of its housing a spring (23) annular peak-to-peak type (see Smalley trademark rings) or an elastic washer flat corrugated wire .

  Operating principle: At the start of the stroke the propellant gases take the volumes relative to the mechanical clearance between the piston and the chamber, or better the lights or crenellations (10) periphery of the firing bowl of the piston head and immediately exert a uniformly distributed pressure on the inner wall of the lip (15) producing a diaphragmatic contraction reinforcing its uniform contact with the wall of the piston (5) for a perfect seal against the peripheral gases which are blocked by the contact of a generator of the lip with the piston wall. Simultaneously the ring (21) moves under the pressure of the gas to the inlet chamber of the piston and contracts under the action of the cone (22) tightening. This contraction causes an immediate blocking of the piston and therefore a securing with the cylinder head.

  As soon as the bullet comes out of the barrel the pressure drops instantly and the ring (21) returns to its nominal bore under the effect of its own elasticity and possibly the return spring, immediately releasing the piston for the recoil of the cylinder head.

  Note: the bayonet segment type open ring may be replaced by a closed and leaktight ring (24) with peripheral slots, the section of which is illustrated in Figure (7) and whose geometry is designed to ensure uniform contraction. over the entire contact and clamping range for locking the piston. This ring ensures a contact seal with both the piston and the clamping cone and is characterized in that its section has notches (1/10 of a millimeter) symmetrically and alternately distributed on its front and rear faces as shown hatched on the sectional view of the figure. The role of the notches is of course to allow a uniform contraction of the ring under the action of the clamping cone.

  Achievement: Those skilled in the art will adapt the dimensions, materials and thicknesses of the clamping rings and their angular reach. For example, an angle of the order of 20 may be adopted for the cone (3) of clamping arranged inside the inlet ring-cone.To ensure a long life to the rings, those - will be made of an elastic material (UE9P bronze, steel, cast iron ...) capable of withstanding the temperature and friction forces Self-lubricating treatment (titanium nitride, Diamond Like Carbon, amorphous carbon, molybdenum, graphite ...) can also be applied.

  Second Mode (Plate 5/8, Fig. 8) According to a third embodiment of the breech / barrel connection, this is achieved by sealing and simultaneously jamming the piston in its chamber. For this purpose, a clamp-type ring (25) is placed in a receiving housing arranged in the chamber (4) of the piston on the inner face of the inlet cone ring (7). This ring comprises a clamping cone (26) mounted to bear on the end of the diaphragm lip (15) sealing which comprises a symmetrical conical shoulder (27) intended to cooperate with the clamping cone.

  Operating principle: At the start of the stroke the propellant gases take the volumes relative to the mechanical clearance between the piston and the chamber, or better the lights or crenellations (10) periphery of the firing bowl of the piston head and immediately exert a pressure uniformly distributed on the inner wall of the chamber inlet lip (15) producing a diaphragmic contraction reinforcing its uniform contact with the wall of the piston (5) for a perfect seal against the peripheral gas. Simultaneously the ring (25) moves under the pressure of the gases to the chamber inlet of the piston and exerts via its clamping cone (26) an increased clamping effect on the diaphragm lip (15) which contracts around the piston the solidarity of the room by jamming.

  The return of the closed ring (25) can be facilitated by the presence at the bottom of its housing of a spring (23) annular peak-to-peak type (see Smalley trademark rings) or a spring washer with corrugated flat wire.

  It should be noted that in this mode of operation the closed ring (25) is at no time in contact with the piston.

  Note: those skilled in the art will advantageously combine some of the provisions of the two modes without departing from the scope of the invention.

  PISTON EXPANSION SEALING SYSTEM (Plates 6/8 to 8/8) First mode (Plate 6/8, Figs 9 & 10): In a first embodiment, the piston expansion seal can to be obtained by the uniform radial expansion at the pressure of the gas of a sealing ring surrounding the head of said piston.For this purpose, the piston (5) of the cylinder head comprises a groove (28) peripheral housing of a ring (29). ) elastic, said groove lined on each side of a circular bevelled groove (30) intended to receive the symmetrically beveled edge of the cylindrical ring (31) This groove further comprises a circular groove (32) concentric for the circulation of gases, in which open orifices (33) arranged in the central body of the piston (5) in a radial direction and communicating with channels (34) parallel to the central axis of the piston and opening only into the firing bowl. For example, two gas borrowing channels located at 18 0 to one another (FIG 6/8) or three to 120 around the igniter / ejector (35) in the bowl (9) firing would be enough to supply gas uniformly the annular housing of the sealing ring.

  This cylindrical ring placed around the piston acts as a seal under the action of the pressure of propellant gases which, from the start of the stroke, take the ducts (34) which open on the inner face of said ring (29). in order to cause its radial expansion and flatten it uniformly against the wall of the chamber (4).

  The elastic force of the ring is applied radially and mainly in its larger diameter. Its shape and its assembly are thus studied so that its deformation under the pressure of the gases ensures the tightness in spite of any lack of alignment or centering of the piston and prevents any risk of irreversible accidental deformation as of leakage at the level of its lateral lips.

  For this purpose, the sealing ring (29) has a swiveling outer face inside the piston chamber, its section is trapezoidal, thin (a few tenths of a millimeter), its edges (31) being supported or beveled so as to respectively take place in the reception housing (30) to the symmetrically beveled profile of the piston and its skirt.

  In order to reinforce the sealing phenomenon, the relative tolerances for piston / chamber machining are arranged so that a peripheral generatrix of the ring is advantageously in contact with the wall of the chamber before the piston is at the end of the stroke. For this purpose, the chamber has a slight taper from its entrance to the firing chamber and its bore at the end-of-stroke zone of the piston is such that its wall is in contact with the swiveling portion of the ring.

  Operating principle: At the start of the stroke the propellant gases take the ducts (34) arranged at the bottom of the firing basin and open into the throat (32) for the circulation of gases where they exert immediately a uniformly distributed pressure on the rear face of the ring simultaneously driving: É a valve seal by peripheral contact of the beveled edges (31) with the conical shoulders (30 & 30 bis) of the respective receiving grooves preventing any leakage of gas, É a piston / chamber seal by contact a generatrix of the ring (29) rotulante with the chamber 40 of the piston.

  The piston (5) and the chamber (4) are adjusted (some 1/100 of a millimeter) so as to minimize play that could lead to leakage risks. When shooting the resulting effect is similar to that of a conventional case of ammunition: the ring ensures the sealing of the chamber by eliminating any clearance between piston and chamber.

  In the absence of any breech / barrel joining system, the ring remains in contact, under the pressure of the gases, during the recoil of the piston with the wall of the chamber while accompanying, thanks to its radial centrifugal elasticity, the increase of diameter due to its conicity. Note that this elasticity also plays, in expansion as in compression, the role of wear compensator to ensure always perfect contact of the ring with the chamber.

  As soon as the bullet comes out of the barrel the pressure drops instantly and the ring returns to its nominal bore in order to ensure a next contact with the piston at the bottom of the chamber after the introduction of a new cartridge.

  Embodiment Those skilled in the art will appreciate the architecture of the piston by positioning, for example, one of the two bevelled grooves (30) retaining the ring on the same body (5) central piston to promote the introduction from below and the other (30 bis) at the top of the skirt (36) in the form of a conical shoulder intended to cooperate with the corresponding edge (31) beveled of the ring to ensure the joining and sealing.

  The taper angle of the piston chamber (a few tenths of a millimeter) will be adapted so that the ring is always in contact with its wall when the piston is at the end of the race, so as to ensure a seal before any climb in gas pressure. The elasticity in compression as in radial expansion of the ring will promote this contact.

  The uniform radial expansion of the ring tending to produce perfect centering of the piston in its chamber, the latter will advantageously mounted floating. This floating, very light considering the piston / chamber tolerances which are of the order of a few hundredths of a millimeter, will naturally be included in the game of the slide of the weapon or the guides of the breech.

  This sealing formula has the advantage of being able to be coupled with conventional bolt / barrel securing devices known to those skilled in the art, such as rotary locking with tenons integral with the cylinder head (FIG.), For example.

  In order to guarantee a long service life to the weapon, the ring will be made of an elastic material (steel, bronze, brass ...) capable of withstanding the temperature forces. An appropriate surface treatment (titanium nitride ...) may also be adopted.

  Second mode (Plate 7/8, Figs 11 & 12): In a second embodiment, the seal can be obtained by the uniform radial expansion of the rotulance zone (37) of the wall of the skirt (36). ) of the sealing piston (5) used as a radially self-expanding gas pressure seal. For this purpose, the skirt comprises a rotulante portion (37) corresponding to the cylindrical elastic wall of an internal expansion chamber (38) whose thickness (a few tenths of a millimeter) of the material (USP bronze, elastic steel). .) promotes, under the pressure of the gases, a radial expansion or "swelling" to ensure contact of a peripheral generatrix of said swiveling zone with the wall of the piston chamber. This chamber (38) internal communicates with the bowl (9) firing via the device channels (33, 34) borrowing gas described above. The pressures (of the order of 5000 bars) brought into play are particularly favorable for this type of sealing device.

  In order to ensure a seal before any increase in pressure of the gases, the chamber of the piston may have a slight taper (a few tenths of a millimeter) in order to be in contact with a generatrix of the swiveling part of the piston wall when it is at the end of the race. The elasticity in compression as in radial expansion of the wall will promote this contact.

  The simplicity of the formula will meet all the specifications in terms of cost of production and implementation. Operating principle: At the start of the stroke the propellant gases take the ducts (33, 34) arranged at the bottom of the firing bowl and 45 open into the chamber (38) internally where they exert immediately a uniformly distributed pressure on the rear face of the swiveling wall causing its expansion against the piston chamber.

  In the absence of any breech / barrel joining system, the wall (5) of the piston remains, during recoil, in contact with the wall of the chamber (4) while accompanying, thanks to its radial centrifugal elasticity, I ' diameter increase due to the taper of said chamber. The elasticity of the wall also plays, in expansion as in compression, the role of wear compensator in order to guarantee an always perfect contact with the chamber.

  As soon as the bullet comes out of the barrel the pressure drops instantly and the elastic wall of the piston returns to its nominal bore to ensure a next contact with the chamber at the end of the race after the introduction of a new cartridge.

  Achievement: One skilled in the art will appreciate the particularly simple architecture of the piston promoting the introduction of the skirt from below, the assembly being, for example, secured to the cylinder head by one and the same pin (8).

  For this purpose, the skirt (36) is hollowed on its inner face with a groove (38) of depth adapted to the best elasticity of its wall which advantageously has at this level on its outer surface a rotulante portion (37). This groove cooperates with that (39) hollowed on the central part of the piston and into which open the channels (34) for sampling the gas at the bottom of the firing bowl. The assembly forms an internal chamber (38) such that the thickness of the material (USP bronze, elastic steel, etc.) of its cylindrical wall promotes a radial expansion or "swelling" under the pressure of the gases.

  The uniform radial expansion of the wall tending to produce perfect centering of the piston in its chamber, the latter will advantageously mounted floating. This floating, very light considering the piston / chamber tolerances which are of the order of a few hundredths of a millimeter, will naturally be included in the game of the slide of the weapon or the guides of the breech.

  This sealing formula has the advantage of being able to be coupled with conventional bolt / barrel securing devices known to those skilled in the art, such as the rotary locking with integral tenons of the cylinder head, for example.

  In order to guarantee a long service life to the weapon, the skirt will be made of an elastic material (steel, inconel ...) capable of withstanding the temperature stresses. An appropriate surface treatment (titanium nitride ...) may also be adopted.

  Third mode (Plate 8/8, Figs 13 & 14): In a third embodiment, the seal can be obtained by the uniform radial expansion of the wall of the skirt (Fig.13, 36) of the piston or a cylindrical crown (FIG 14, 40) obtained by core drilling along the central axis of the piston at the inner periphery of the firing bowl, the said skirt and crown used as a radially self-expanding seal gas pressure. For this purpose, the skirt or the crown, whose crown advantageously provides the role of edge of the bowl (9) firing, have on their outer cylindrical face one or two zones (s) rotulante (s) (41) of which thickness (a few tenths of a millimeter) of the material (bronze USP, inconel ...) favors, under the pressure of the gases circulating in the annular chambers (42) which they delimit, a radial expansion suitable to ensure the contact of a generator peripheral of at least one swiveling zone with the wall of the sealing chamber.

  In order to ensure a tightness before any increase in gas pressure, the chamber (4) of the piston may have a slight taper (a few tenths of a millimeter) in order to be in contact (Figures 13 & 14, 41). with a generatrix of the swiveling head part of the wall of the piston when it is at the end of the race. For this purpose, said swiveling portion (FIGS 13, 41) may advantageously be positioned at the top of the skirt or piston ring. The elasticity in compression as in radial expansion of the wall of the skirt (36) as the ring (40) cylindrical promote this contact.

  Principle of operation: At the start of the stroke, the propellant gases immediately occupy the volumes of the chambers (42) annular arranged behind the skirt (36) or the ring (40) and exert a uniformly distributed pressure on their rear face causing their expansion against the wall of the chamber of the piston. The generatrix of at least one swiveling zone (41) of the outer cylindrical wall of the piston then provides a peripheral contact of perfect sealing.

  In the absence of any breech / barrel joining system, the wall of the piston remains, during the recoil, in contact with the wall of the chamber while accompanying, thanks to its radial centrifugal elasticity, the increase in diameter due to the taper of said chamber. The elasticity of the skirt or the crown also plays, in expansion and radial compression, the role of wear compensator in order to guarantee an always perfect contact with the chamber.

  As soon as the bullet comes out of the barrel the pressure drops instantly and the piston returns to its nominal bore to ensure a next contact with the chamber at the end of the race after the introduction of a new cartridge.

  Embodiment: The person skilled in the art will appreciate the particularly simple architecture of the piston comprising either a skirted mounting or an easy-to-machine core for the production of the gas expansion chamber (42), the assembly being secured to the breech by one and the same pin (8).

  Note that this chamber is located at the inner periphery of the firing bowl so that the skirt or the crown of the piston also provides the role of edge of the firing bowl as the function of the cartridge introduction nozzle. The gas supply is immediate.

  The uniform radial expansion of the skirt (36) or crown (40) tending to produce perfect centering of the piston in its chamber, the latter will advantageously mounted floating. This floating, very light considering the piston / chamber tolerances which are of the order of a few hundredths of a millimeter, will naturally be included in the game of the slide of the weapon or the guides of the breech.

  This sealing formula has the advantage of being able to be coupled with conventional bolt / barrel securing devices known to those skilled in the art, such as the rotary locking with integral tenons of the cylinder head, for example.

  To ensure a long service life to the weapon, the skirt or the piston will be made of an elastic material (steel, inconel ...) capable of withstanding the temperature forces. An appropriate surface treatment (titanium nitride ...) may also be adopted.

Claims (5)

REVENDICATIOffl IO 1 - System of firing mutinions ms case composed of m barrel provided with room rmmifion c tiguë a = chan = (4) home of a piston (5) & sealing solidarity of a breech t steel, = steel in that a contact suhmt a "an = = suede piriplalàpte mit established be Lem clamMe (4) and lek piston (5) by tm elastic alma = that the ratasse is in position km & and that it also allows the cylinder head / barrel will be solidified: mn = with effect of gas under pressure, 2 - System of the system in the form of the elastic element of one or more Ieweele (15) 16) mimed in series to fie (Meut of amber sealing and présratant = omet = mye = dl = the erétatrice can be pare * to raw of the camn will say to adopt adopt angle of ttehsi of the coast (Il) entry & amine in order to reach May even swam lofa cone.   3 -. The method according to claims 1 to 2, which is camérterized in that the Pmrt (5) is compatible. will be able to shrink with the elastic wall (13) dela. amide or amide (a) -chafergme (15 & 16) which it comprises.   4- itandréité system according to retmakation 1 characterized in that the élémart elastic consists of & rai rai rai bi bi bi bi section section section section section section section section section section section et et et et et et et et et et et et et et et et et et et et et et et et et et of the diantre (4) of the pistm and of which and the lem agreement (19) is = blade Mn let Ingement (20) and the lip Mime (Xi) convex is in guiche of the pis = to peotkrire = Mut & sealing peripheral e and centripetal by elastic défasmeon ra 'd = Mette Ièwes.   5 - .Systene étantrhéeselon reverikatice I characterized in that the ring of soli atisafim breech / tenon effect e ttteion. either of the fixed type ("24) or t.a ba8imaete. (21) and mate in support = m Life (22) must be in the same position as in the bagm-c = (7) (slit to roam around.   M. piton et xoduire = arisera càarenepis = t = d'Ira randomly to 'c Peritrer entambre mus spe the pressure spi 6 -% agnat étandeé stems claim 1 omet: keg in that the atmaau des. lidarsera culmt * anra effect of contractitr 'n be closed and of type clamp (25), arranged in usa tomme host brings = the inner end of the cremated ring-cone (7), and oampute tut cone & sage C26) ground resting on the shouldered = conical (27) sytne * ique & the dull & aphte = (15) in order to puduire a solidification ehmbieipiston lots of a displacement of erdtie & room under the pees "pz.   7-y yMetne detached according to tevenrlieation 1 ca = téiisé what the elastnpt'é eldnpt 'e is composed of a bag 50 (29) = tom = the sealing piston and whose tear ente = is Mea = to: zntétitsr de the chamber (4) of the piston and such = = lords (31) = ent shouldered or bevelled material n take tespecthement place in the Iogmets home (30) to symmetrical profile beveled of the groove (28) peripheral housing - de said bagm This station (32) = mimic with the cm = (9) firing via a tspositif cana = (33, 34) dlettrptuatdom. 55 1O - Sealing system according to any one of the preceding claims e mounted slightly eottira at. breech and has a slight taper from the base to its so or that the chamber has a slight taper since its entry vars the firing chamber so as to promote a contact gener gener l peripheral said piston with rte chamber when the allasse is in closed position.   9 - Sealing system (36) or crown edge of the bowl (41) whose thickness promotes, under challenge melt the own radial expansion to mainteè oontact a rotulante with the wall of the sealing chamber.