The present invention relates to a hydraulically locked breech mechanism for high power firearms of all classes.
A typical firearm has a barrel with a chamber for a cartridge and a bolt or breech block to lock the cartridge in the chamber for firing and until the pressure in the chamber has dropped, after firing, to a level at which it is safe to unlock the breech mechanism. For safe and reliable operation it is essential that the bolt or breech block and barrel are locked together to support the cartridge during firing. Failure of the cartridge case can occur if the bolt or breech block and barrel are not rigidly locked together. Typically a mechanical interlock or abutment is used to achieve this locking.
A major disadvantage is the complexity of form of these locking members and the need to manufacture such complex forms to close tolerances.
Another disadvantage is that the complex forms of the moving parts make sealing the mechanism against the ingress of foreign matter, such as sand or mud, extremely difficult and any such matter can render the locking mechanism inoperable.
According to the present invention there is provided a hydraulic breech mechanism comprising a low pressure reservoir for fluid having communication with a high pressure reservoir for fluid and a sealing means moveable between a sealed position isolating the two reservoirs to allow the fluid sealed in the high pressure reservoir to rigidly lock the bolt or breech block in relation to the barrel and an open position permitting communication between the two reservoirs thus allowing the bolt or breech block to travel in relation to the barrel.
By using fluid in this way the number and complexity of parts is significantly reduced.
Another advantage is the cylindrical form of the parts means sealing against ingress of foreign matter simple
A further advantage due to the combination of in line hydraulics and floating piston assembly is a significant reduction in recoil transmitted to the operator.
In one embodiement the sealing means seperating the high and low pressure reservoirs is a sleeve valve, concentric with the high pressure reservoir and secured to the outer casing. Recoil forces move the assembly comprising the high pressure cylinder, bolt, barrel extension and barrel through the sleeve valve to open the ports communicating between high and low pressure reservoirs. A floating piston assembly, forming one end of the low pressure reservoir allows for the displacement of fluid caused by this travel and by the travel of the bolt subsequent to this, the spring in the floating piston assembly provides the force to return the bolt and seal the high pressure reservoir.
In a second embodiement the sleeve valve is permited limited travel enabling it to function as a floating piston. As the high pressure cylinder, bolt, barrel extension and barrel move rearward during recoil the sleeve valve moves forward compressing a return spring against the barrel extension.
In a third embodiement direct or indirect action of gas pressure generated by discharge of the cartridge moves the sleeve valve to open the ports. The present invention is applicable to a wide range of weapons from rifles to artillery.
The present invention will now be described by way of example with reference to the accompanying drawings in which:
A hydraulic breech mechanism according to the present invention is shown in
On discharge of a cartridge in chamber 3 gas pressure generated by the combustion of propellant in the cartridge will exert a force on bolt 6. The barrel 2, barrel extension 4, bolt 6 and high pressure cylinder 7 are locked in a fixed relationship to each other. The force on the bolt 6 caused by discharge of a cartridge in chamber 3 will move the assembly comprising barrel 2, barrel extension 4, bolt 6 and high pressure cylinder 7 toward the floating piston 12, displacing fluid in low pressure reservoir 11 and compressing spring 13. After a delay to allow the gas pressure in chamber 3 to drop to safe levels the ports 10 will clear the sleeve valve 8, allowing communication between the high pressure reservoir and the low pressure reservoir to be established. The delay to allow the gas pressure in chamber 3 to drop to safe levels is caused by the travel of the high pressure cylinder 7 through the sleeve valve 8 before the ports 10 clear the sleeve valve 8. When the ports 10 have cleared the sleeve valve 8 a catch 21 engages the barrel 2 and holds the barrel 2, barrel extension 4 and high pressure cylinder 7 against the load of spring 13. With the high pressure reservoir 9 and the low pressure reservoir 11 in communication via ports 10 the bolt 6 is no longer locked in relation to the barrel 2 a combination of inertia and residual gas pressure in chamber 3 will cause the bolt 6 to move toward the low pressure reservoir 11 and reach the position shown in
The position shown in
Number | Date | Country | Kind |
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0503716.3 | Feb 2005 | GB | national |
Number | Name | Date | Kind |
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2720820 | Dixon et al. | Oct 1955 | A |
3336838 | Wilson | Aug 1967 | A |
Number | Date | Country | |
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20060185507 A1 | Aug 2006 | US |