RU2162995C1 - Ejector gun of sporting gun - Google Patents

Abstract

FIELD: extraction of extracted cartridges or cartridge cases from weapon. SUBSTANCE: ejector mechanism has spring-loaded extractor 1, cam 7 with plate spring 9, the cam is made with cantilever 8, which can be engaged with rod 15 of mainspring 16, shaped undercutting 17 for the cam cantilever is made on the rod. Groove 12 engageable with cam angle boss 11 is made on the cam plate spring 9. For accuracy of location of cam in a definite position the cam angle boss is shifted relative to axis of rotation 6 towards the mainspring rod. EFFECT: enhanced reliability of ejector mechanism and simplified design. 3 cl, 4 dwg

Description

 The invention relates to weapons technology and is an ejector mechanism for ejecting spent cartridges from trunks of a hunting rifle.

 Known ejector mechanism by AS N 268206, IPC F 41 C., containing a spring-loaded extractor with a pin, shepialo swinging on the axis and a spring-loaded latch. The design involves a one-time manual shutdown of the ejector with its subsequent inclusion in the subsequent fracture of the trunks.

The disadvantage of this ejector mechanism is the inconvenience in operation due to the fact that
- the design involves the constant operation of the ejector, while the ejection of a non-fired cartridge occurs,
- the design requires a special one-time manual shutdown.

 Known ejector mechanism of a sports-hunting double-barreled gun according to a. from. N 1230270, MKI F 41 C 15/06, taken as a prototype. The mechanism contains a spring-loaded extractor with platoons, a hinge with a leaf spring and a cam with a control and controllable protrusions and an eccentric interacting with the leaf spring, as well as a cock. The control protrusion is made in the form of a console, and the eccentric is made with the rear and upper stops interacting with the hinge and angular protrusions.

 The disadvantages of the described ejector mechanism are the unreliability and complexity of the mechanism due to the placement of the cock between the cam and the rod with the mainspring. This arrangement leads to loss of energy during the shot, contributing to the occurrence of misfires. There is a fuzzy fixation of the cam in the intermediate position, when the action of the leaf spring is directed to the axis of the cam and to the sides of this position by the value of the angle of friction.

 The objective of the invention is to eliminate these disadvantages, namely increasing the reliability of the structure while simplifying it.

 The problem is solved due to the fact that in the well-known ejector mechanism of a hunting rifle containing a spring-loaded extractor, a cam with a leaf spring mounted on an axis in a hinge, a cam made with a console controlled, controlling and angled protrusions, the cam console is designed to interact with rod of the mainspring, while the rod has a profile undercut under the cam console. A groove is made on the leaf spring of the cam, having the ability to interact with the angular protrusion of the cam. For clarity of fixation of a certain position of the cam, the angular protrusion of the cam is shifted relative to the axis of rotation towards the shaft of the mainspring.

 The implementation of the cam console with the possibility of direct interaction with the rod of the mainspring increases the reliability of the mechanism, because eliminates energy losses due to the operation of mechanisms during firing, and, consequently, misfires.

 The implementation of the profile undercut on the rod of the mainspring eliminates the spacer between the controlled cam tab and the rod during a forced rotation of the cam cam at the end of the barrel rotation.

 The execution on the leaf spring of the groove interacting with the angular protrusion of the cam also helps to increase the reliability of the mechanism, because increases the clarity of the cam fixation, excluding its inertial stall, for example, when fired from another barrel.

 The shift of the angular protrusion of the cam relative to the axis of rotation increases the turning moment, which increases the clarity of tracking the cam over the position of its protrusions, i.e. cocked or not.

The invention is illustrated by drawings, where
in FIG. 1 shows a General view of the ejector mechanism of a double-barreled gun, the position of the parts after the shot,
in FIG. 2 - the same, the trunks are open,
in FIG. 3 is a view A in FIG. 2 (forend and trunks not shown),
in FIG. 4 - cam.

 The ejector mechanism contains two mirror-reflected mechanisms, including an extractor 1 with a spring 2, mounted in the hole 3 of the barrel coupler 4. In the assembled hinge 5, a cam 7 is pivotally mounted on the axis 6 with a console 8 and a leaf two-leaf spring 9. The cam has a controllable protrusion 10 and an angular the protrusion 11 located behind the groove 12, made on a leaf spring. A hole 14 is made in the box 13, in which an assembly rod 15 with a service spring 16 is installed. On the rod 15, a profile undercut 17 is made under the cam console 8.

 The ejector mechanism works as follows: to fire the shot, it is necessary to cock the trigger 18 by turning the cock 19 located outside clockwise. In this case, the rod 16 with the mainspring 16 moves back through the trigger 18, compressing the mainspring 16. The front of the rod releases part of the hole for the rod. The cam 7 rotates due to the leaf spring counterclockwise and the console 8 enters the hole 14 under the spring.

 When firing a trigger, the trigger 18 rotates counterclockwise and the rod 15 with the mainspring 16, moving forward, has a limit in the front of the hinge, strikes the console 8, turning it clockwise. The interaction of the rod with the console occurs before it is limited to the hinge. The console inertially moves until the angular protrusion 11 snaps into the groove 12 on the leaf spring 9.

 After the shot, when opening the gun, the extractor moves under the action of its spring until it is placed on the control ledge 20.

 With further opening, when the sleeve has the ability to pass over the box forehead 21, the controlled protrusion 10 interacts with the tooth of the feeder 22, the cam 7 rotates counterclockwise, the control protrusion 20 is released and the extractor 1 is disrupted and the spent sleeve is ejected. The angled protrusion 11 exits the groove, and the cam console 8 enters the profile undercut 17 of the rod.

 When closing the barrel, the cam console runs around the front end of the stem and rotates the cam clockwise without the angled protrusion popping into the groove under the spring. The protruding protrusion 20 does not engage the extractor.

 If there was no shot, when opening the trunks, the cam console rolls around the rod and enters the recess of the rod 17, the control protrusion 20 does not interact with the extractor 1 and the latter simply extends when opening the trunks.

 Thus, the proposed ejector mechanism allows it to be used on trigger guns and on shotguns with external cocking, excluding the release of an unshooted cartridge (when opening the gun), which further increases reliability, since cocking is carried out immediately before firing, which increases safety during handling with a gun. In addition, in this design there is no replanting of the mainspring during prolonged use of a gun with cocked triggers.

Claims (3)

 1. The ejector mechanism of a hunting rifle with an external cocking of a trigger, comprising a spring-loaded extractor, a cam with a leaf spring mounted on an axis in a hinge, made with a console controlling, controlled and angled protrusions, a rod with a combat spring located in the opening of the box, characterized in that the cam console is configured to interact with the stem of the mainspring, while the latter has a profile undercut under the cam console.  2. The ejector mechanism according to claim 1, characterized in that a groove is made on the leaf spring of the cam, having the ability to interact with the angular protrusion of the cam.  3. The ejector mechanism according to claim 1, characterized in that the angular protrusion of the cam is displaced relative to its axis of rotation towards the mainspring rod.

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