Firing system in a precharged pneumatic (PCP) rifle

Abstract

A firing system using a gas piston instead of a trigger spring provides firing by air that is released after contacting an air outlet valve needle in pre-charged pneumatic (PCP) rifles. This system results in a high outlet speed as well as rapid fire by use of a lever that limits the single release of air into the tube.

Claims

1. A firing system in pre-charged pneumatic (PCP) rifle comprising: at least one gas piston; at least one hammer; and at least one lever having at least one kicking surface and at least one needle contact surface, wherein the at least one kicking surface and the at least one needle contact surface are parallel to one another.

2. The firing system of claim 1, wherein the at least one lever has on its upper end, a lever limiting notch.

3. The firing system of claim 1, wherein the at least one lever has on its lower end, a needle limiting notch.

4. The firing system of claim 1, wherein the at least one lever at a lower part of the at least one kicking surface has a pushing surface.

5. The firing system of claim 1, wherein the at least one lever has at least one centering hole.

6. The firing system of claim 4, wherein the at least one kicking surface and the pushing surface face the hammer and the at least one needle contact surface faces the needle.

Description

DETAILED DESCRIPTION OF THE INVENTION

(1) Gas piston and lever developed in order to achieve the purpose of the invention are shown in the figures.

(2) The figures are as follows:

(3) FIG. 1: General view of parts forming firing system of PCP rifle

(4) FIG. 2: Detailed view of parts forming firing system of PCP rifle

(5) FIG. 3: Detailed view of air outlet valve needle

(6) FIG. 4: Detailed view of air outlet valve body

(7) FIG. 5: Detailed view of lever

(8) FIG. 6: Detailed view of hammer

(9) FIG. 7: Detailed view of setting arm

(10) FIG. 8: Detailed view of mechanism body

(11) FIG. 9: Detailed view of gas piston

(12) FIG. 10: Detailed view of lever fixing pin

(13) Numbers are put on the figures in order to better understand the parts and their functions. Accordingly: 1—Air outlet valve needle 2—Air outlet valve body 3—Lever 4—Hammer 5—Set lever 6—Mechanism body 7—Gas piston 8—Fixing pin 9—Preventive surface 10—Body centering 11—Lever hitting surface 12—Needle housing 13—Valve body centering surface 14—Needle contact surface 15—Centering hole 16—Pushing surface 17—Kicking surface 18—Hitting surface 19—Hammer centering surface 20—Hammer rest surface 21—Lever fixing hole 22—Gas piston fixing chamber 23—Hammer housing 24—Valve body fixing body 25—Mechanism body fixing chamber 26—Gas piston rest surface 27—Fixing pin surface 28—Lever limiting notch 29—Needle limiting notch

(14) A general view of a pre-charged pneumatic (PCP) rifle comprising a gas piston (7), a hammer (4) and a lever (3) is disclosed in the invention as shown in FIG. 1. FIG. 2 shows detailed view of the gas piston (7), the hammer (4) and the lever (3) of the invention. After the set lever (5) shown in FIG. 7 is pulled back, the hammer (4) connected to the set lever (5) contacts the gas piston (7) at a hammer rest surface (20) and pushes the gas piston (7) spindle inside and air inside the gas piston (7) is compressed. When a trigger is pressed, compressed air in the gas piston (7) moves forward the gas piston (7) spindle (FIG. 9). Gas piston rest surface (26) which is the end part of the gas piston (7) spindle pushes the hammer (4) from the back by means of the rest surface (20) of hammer. Centering surface (19) of hammer moves linearly in a hammer housing (23) located on the mechanism body (6) such that the hammer's (4) hit surface (18) first makes contact with a pushing surface (16) in the lower part of the lever (3) (FIG. 5).

(15) Gas piston fixing chamber (22) and mechanism body fixing chamber (25) sit onto each other. The mechanism body (6) and gas piston (7) are also connected. Lever fixing hole (21) located on mechanism body (6) and centering hole (15) located in an end part of an upper section of the lever (3) are overlapped by help of a fixing pin (8) shown in FIG. 10 and interconnected by means of fixing pin (8). Lever fixing hole (21) and centering hole (15) conduct rotating action on fixing pin surface (27). By effect of this action, lever (3) is fixed to a valve body connection chamber (24) located on the mechanism body (6) shown in FIG. 8 by air outlet valve body (2) centering surface (13) (FIG. 4). Air outlet valve needle (1) located in a needle housing (12) is centered in the air outlet valve body (2) which moves in the plane of the body centering (10). With this pushing motion, needle contact surface (14) on the lever (3) pushes the lever hit surface (11) shown in FIG. 3 and such that the air outlet valve needle (1) and the surface (9) moves away from the lever (3) which provides a passage for air to pass through the air outlet valve body (2); thus, releasing air from the tube.

(16) The pushing movement of the hammer (4) on the lever (3) continues until the lever (3) contacts the kicking surface (17) which is on the upper surface. The needle limiting notch (29) limits the counterclockwise pushing movement of the lever (3), thus limiting movement of the needle contact surface (14) with the air outlet valve needle (1). Hit surface (18) contacts the kicking surface (17) such that the backward force of the air outlet valve needle (1) is adequate to push back the hammer (4). If the hit surface (18) shown in FIG. 6 presses only on the push surface (16), the backward force of the air outlet valve needle (1) will not be adequate to push the hammer (4) back and therefore the air in the tube is released only once. In such a case, the system does not allow a second shooting and air re-loading is required. The lever limiting notch (28) limits clockwise movement of the lever (3), thus, preventing excessive movement of the hitting surface (18) when coming into contact with the kicking surface (17) of the lever (3).