RU2152578C1 - Arbalest - Google Patents

Abstract

FIELD: missile weapon. SUBSTANCE: the arbalest has a casing, string tensioning mechanism in the form of a rotary spring-loaded fork engageable with the trigger mechanism. The arbalest is provided with a shooting simulation mechanism, having a change lever with two recesses linked by a tracer surface, and a spring-loaded pin with a roller engageable with the recesses and change lever tracer surface. The pin rests against the stem of the rotary fork and is tightened to it by a spring with an adjusting nut providing for a moment from the force of pin action on the fork equal to the moment from action of the tensioned string on the fork. EFFECT: provision of simulated shooting without loading of the bow and drawing of the string, enhanced durability. 3 cl, 5 dwg

Description

 The invention relates to throwing weapons, namely to crossbows.

 Known crossbow according to US patent N 4,877,008 NCI 124/25, having a trigger for holding and lowering the bowstring, comprising a fork holding the bow of the crossbow mounted on its axles between the lateral planes of the trigger housing, a trigger holding the fork in cocked position, a safety lever, excluding rotation of the trigger in the protection position and having the ability to rotate with switching from the protection position to the firing mode.

 However, the well-known crossbow does not provide for the possibility of conducting simulation shooting without loading the bow and pulling the bowstring. A single descent of a bowstring without an arrow leads to premature destruction and breakage of the bow.

 The objective of the invention is the creation of a crossbow with a simulation of firing.

 To solve this problem, the crossbow contains a housing, a bowstring retention mechanism in the form of a spring-loaded swivel fork in contact with the trigger, and a firing simulation mechanism made in the form of a translational translator equipped with two recesses connected by a copy surface and a roller in contact with them installed in a spring-loaded finger interacting with the rotary fork of the bowstring retention mechanism. The swivel fork is equipped with a manual cocking lever in firing simulation mode. The firing simulation mechanism is equipped with an adjusting nut in contact with the spring of the finger and pressing the finger to the protrusion of the fork with a force that provides a moment equal to the moment from the impact on the fork of a stretched bowstring.

 The proposed design will improve the durability, safety and ease of use of the crossbow during training shooting.

 When using the firing simulation mechanism, the force exerted by the shooter on the trigger remains the same as during combat shooting, maximally approximating the conditions of simulation shooting to combat.

The invention is illustrated by drawings, which depict:
figure 1 - crossbow in the position of live shooting;
figure 2 - cross section AA in figure 1;
figure 3 - crossbow in the position of simulating shooting;
figure 4 is a section BB in figure 3;
figure 5 - components of a crossbow with a simulation of firing.

 On the body 1 of the crossbow (Fig. 1) there is a guide 2 for the arrow, the body 3 of the mechanism for holding the bowstring, in which the fork 5 is located on the axis 4, the elastic shock absorber 6 of the fork. In the opening of the housing 3 of the bowstring retention mechanism, there is a spring 7, a pressure 8, pressing the plug 5. To limit the output of the pressure 8, an axis 9 is installed in the body 3. A finger 10 with a roller 11, a spring 12 of the finger and a regulating spring force are located in the opening of the crossbow 1 12 nut 13. In the crossbow housing 1 there is a translator 14 mounted with the possibility of axial translational movement, imparting translational movement to the finger 10 and providing its fixation in extreme positions. To do this, the translator 14 has a copy surface 15 with two recesses 16 and 17, with which the roller 11 interacts. The end surfaces 18 and 19 of the translator 14 are used to turn on or off the simulated crossbow firing mechanism. Fork 5 is equipped with a lever 20 in the upper part for cocking by hand in firing simulation mode, a shank 21 in the lower part for placing the fork 5 on the cock, and hooks 22 in the front for holding the cocked bowstack 23 in combat shooting mode. a trigger 24 is installed, in which the trigger 25 and the fork fixing element 26 interacting with the fork 5 are located.

 In the firing position (Fig. 1), the end face 18 of the translator 14 is recessed in the housing 1 with the aim of switching the crossbow to the firing mode, the plug 5 rests against the elastic shock absorber 6 under the action of the spring loaded weight 8 and is in the position when the employees hold the bowstring 23, the hooks 22 are raised above the guide 2 and do not prevent the bowstring 23 from cocking. The translator 14 is in the extreme right position, in which the roller 11 of the finger 10 abuts the recess 16 of the translator 14, while the spring-loaded finger 10 occupies the extreme rear fixed p position (figure 2) and does not interfere with the positioning of the plug 5 on the cock by fixing the shank 21 of the plug 5 element 26 of the trigger 24. Thus, the crossbow is ready for combat shooting.

 When cocking the bowstring 23 is retracted along the guide 2 and interacts with the fork 5, the latter rotates around the axis 4 and stands on the combat cock by fixing the shank 21 of the fork 5 by the element 26 of the trigger 24. The bowstring 23 is held in the cocked position by the hooks 22 of the fork 5. When pressed on the trigger 25 of the trigger 24 of the crossbow, the shank 21 of the fork 5 is disengaged with the element 26 for fixing it in the trigger 24. The fork 5 is rotated around the axis 4 by the action of the bowstring 23 and the spring spring 8, the hooks 22 of the forks and 5 release the bowstring 23, thereby lowering it, after which the fork 5 returns to its original position, interacting with the elastic shock absorber 6. A shot is fired in live shooting mode.

 The translation of the crossbow to the firing position (Fig. 3) is carried out by pressing the end face 19 of the translator 14. When moving the translator 14 in the crossbow housing 1, the roller 11 of the finger 10, resting on the copy surface 15 of the translator 14, becomes in the recess 17 of the translator 14, while the finger 10 under the action of the spring 12 occupies an extreme forward position (figure 4).

 When acting on the rear lever for cocking the fork 5, the latter, turning clockwise (Fig. 3) on the axis 4, depresses the spring loaded inlet 8, passes the element 26 for fixing the fork 5 in the trigger 24 and retracts the spring finger 10 to the stop. After termination impact on the lever 20 cocking the plug 5 finger 10 under the action of the spring 12 compresses the shank 21 of the plug 5 to the element 26 of the trigger 24, fixing the plug 5 in the cocked position. In this case, the moment from the force of action of the finger 10 on the plug 5 should be equal to the moment created by the string 23 when it is tensioned.

 When the trigger 25 of the trigger 24 is pressed, the shank 21 of the fork 5 is disengaged with the fork fixing element 26 in the trigger 24. The fork 5, under the action of the spring pin 10 and the spring spring 8, rotates around axis 4 and returns to its original position, interacting with the elastic shock absorber 6. A shot is fired in simulated shooting mode. In this case, the force that the shooter exerts when pulling the trigger remains the same as in combat shooting.

 The translation of the crossbow from the firing simulation position (Fig. 3) to the live firing position (Fig. 1) is carried out by clicking on the protrusion 18 of the translator 14.

Claims (3)

 1. A crossbow containing a housing, a mechanism for holding the stretched bowstring, having a spring-loaded swivel fork in contact with the trigger mechanism, characterized in that it is equipped with a firing simulation mounted with the possibility of contacting with the swivel fork.  2. The crossbow according to claim 1, characterized in that the shooting simulation mechanism consists of a translator with two recesses connected by a copy surface, and a spring-loaded finger with a roller mounted to interact with recesses and a copy surface of the translator, while the finger is installed with the possibility of interaction with a rotary fork, and the latter is equipped with a cocking lever in firing simulation mode.  3. The crossbow according to claim 2, characterized in that the firing simulation mechanism is equipped with an adjusting nut in contact with the finger spring, providing a moment from the force of the impact of the finger on the fork, equal to the moment from the impact on the fork of a stretched bowstring.

Images