RU2066038C1 - Arbalest - Google Patents

Abstract

FIELD: weapons for sports and hunting. SUBSTANCE: arbalest has frame with grip 13 on which frontal part there are anchored bow 11 with bow-string 22 and axle 17 which carries lever 3 and trigger mechanism 7. Arbalest is also fitted with tie-rod 6 and crank 2. Trigger mechanism is manufactured for reciprocating motion along frame 1 and is hinged to one end of tie-rod 6 which second end is hinged to one end of crank 2. Its second end is attached to axle 17 on end of frame 1 and lever 3 is kinematically coupled to midpart of crank 2. Trigger mechanism 7 has several modifications. EFFECT: improved shooting efficiency. 6 cl, 6 dwg

Description

 The invention relates to sports equipment and hunting equipment and is intended for aimed shooting with shortened arrows at a distance of up to 50 m

 Convenience and safety of handling a crossbow, the rate of fire of the latter, range and aiming fire to a large extent depend on the construction of the trigger mechanism, on how and with what means the crossbow is cocked, the bow is held and released.

 In a number of known designs, charging a crossbow, i.e. the bowstring is pulled by the handle, the crossbow body being held by the second hand or foot of the shooter, and the bowstring is captured by the movable trigger assembly (see US patent 4662345, F 41 B 5/00, 1987 or US patent 4926834, F 41 B 5/00, 1990).

 However, cocking a crossbow with one hand, especially at shoulder level, is quite difficult. If you hold the crossbow with your foot, safety is largely determined by the position of the parts of the trigger relative to each other, and with their mutual movement it is impossible to ensure the stability of this position.

 Crossbows are known in which cocking is performed by turning one part of the body (usually this is the butt) with the trigger assembly (see UK patent 1553387, F 41 B 5/00, 1979 or French application 2373772, F 41 B 5/00, 1978).

 The disadvantages of this design are the same: inconvenience of use, the possibility of unauthorized shots, low accuracy. This is because only a small part of the length of the body is used as a lever for bow deformation, and parts of the trigger, as in the case described above, are moved relative to each other.

 In the crossbow described in the application of the UK 2157579, F 41 B 5/00, 1985, cocking is done with a brush by pressing the trigger lever, and the body consists of two parts connected by a smooth movable rod.

 In this design, accuracy is limited due to the deformation of the rod, and cocking a crossbow is even more difficult.

 The problem of facilitating a cocking of a crossbow and increasing the rate of fire is partially solved in US patent 4,594,994, F 41 B 5/00, 1986, which describes a crossbow with a vertical bow arrangement. The latter is placed on a smooth pipe with the ability to move relative to the crossbow body under the action of a lever moving in a horizontal plane.

 However, with the vertical arrangement of the bow, the sight should be shifted, which is not always convenient. In addition, with a movable bow, it is not possible to provide the necessary accuracy of the relative position of the bow and sight, which affects the accuracy of the shooting. And finally, when pulling the bow with the lever located on the side, there is no emphasis.

 Closest to the proposed is a crossbow according to US patent 4942861, F 41 B 5/00, 1990. It contains a body with a butt and a frame on which a bow is attached. The frame is made with guide grooves in which the movable trigger assembly moves, capturing the bow string and connected to the lever by a link system and a flexible gear located on movable and fixed blocks.

 In this crossbow, bow deformation is carried out without significant effort, with emphasis and quickly enough. However, this is achieved due to a significant complication of the kinematic transmission located between the lever and the movable trigger assembly, which captures and holds the bowstring.

 In addition, the presence of flexible connections and numerous intermediate links in the cocking mechanism, as well as the very presence of a movable and fixed nodes of the trigger mechanism, lead to a decrease in safety and accuracy of shooting for the above reasons.

 The disadvantages of the known design include the fact that the bowstring is located in the slot of the frame, and the bow of the bow at its end, which makes it difficult to assemble and disassemble the crossbow. In addition, as the tests and calculations showed, with a similar relative arrangement and fastening of the bow, bowstring and the movable element holding it, it is practically impossible to ensure the stability of the position of this element, and hence the constancy of the force applied to the arrow in size and direction, which also negatively affects on firing accuracy.

 And, finally, the trigger of the known crossbow is not equipped with a system of protection against unauthorized shots, and with the indicated arrangement of flexible connections and the bowstring, the shooter's hands may be in the movement zone of the bowed bowstring.

 Thus, the technical result expected from the use of the invention is to increase the accuracy of shooting, safety and rate of fire of the crossbow, while simplifying and reducing the weight of the structure.

 This result is achieved by the fact that in a known crossbow containing a body with a handle, in front of which a bow with a bowstring and an axis of the lever are fixed, as well as a trigger mechanism, is equipped with a pull and crank, while the trigger mechanism is arranged to reciprocate along the body and pivotally connected to one end of the rod, the second end of which is pivotally connected to one end of the crank, the second end of which is fixed on an axis at the end of the housing, and the lever is kinematically connected to the middle part of the crank.

 In addition, the body is made with a trapezoidal groove, and the bow is made with a central bracket having a wedge bearing surface located in the trapezoidal groove of the body.

 It is also advisable to perform a trigger with a fork, providing the ability to capture and hold the bowstring from above when the trigger is moving.

In particular, the trigger mechanism can be made in the form of a housing with a guide placed in the housing of a spring-loaded trigger and a fuse in the form of a spring-loaded stopper and lever, as well as a spring-loaded fork mounted on an axis in the upper part of the housing so that it interacts in one extreme position with a spring-loaded trigger and in the other
with a safety lock or trigger housing.

 It is also recommended to carry out the trigger with a fuse kinematically connected to the plug.

 So, the trigger mechanism can be made in the form of a housing with a guide placed in the fuse housing in the form of a spring-loaded stopper and lever, two kinematically connected intermediate links, a spring-loaded hook on the axis and a spring-loaded fork mounted in the upper part of the housing so that in one extreme position it interacts with a spring-loaded hook kinematically connected with the trigger, and in another with a safety stop, kinematically connected with the free end of the first intermediate link, Therefore, the free end of the second intermediate link is kinematically connected with the back of the fork.

 In the proposed crossbow, the lever through the crank and traction moves the entire trigger mechanism as a whole, so that parts of the latter do not move relative to each other. This allows not only to simplify the design of the crossbow and increase the accuracy of shooting, but also to set the boom before cocking.

 Another important feature of the crossbow is that the bow is fixed in a prismatic groove with a trapezoidal cross section, with the smaller base of the trapezoid being at the bottom, and the bow string is caught and held by the trigger trigger from above. This, as the tests showed, provides the optimal, from the point of view of range and aiming of firing, as well as safety when firing, the distribution of forces when cocking a bow.

 And finally, the difference of the proposed crossbow is the implementation of a movable trigger mechanism, which provides a convenient, quick and safe cocking of the bow, setting the crossbow on the fuse and aimed shooting.

 In Fig.1,2 and 3 shows a General view of the proposed crossbow (front, side and top, respectively). FIG. 4 illustrates the process of cocking a crossbow, and FIGS. 5,6 show embodiments of a trigger mechanism.

 Shown in figures 1-3 crossbow, contains a housing 1, a crank 2, levers 3,4 (lever 3 is made with a slot in which the crank is located), an arm 5 of the bow, rod 6, the trigger 7, the bracket 8 of the sight 9, the axis 10, the shoulders 11 of the bow, the guide 12 of the arrow, the handle 13, the namushnik 14, the front sight 15, the strap 16, the axis 17, the washer 18, the latch 19, the plate 20, the handle 21, the bowstring 22, the pins 23-28, the screws 29-38, ball and cone washers 39.40, thrust spring washer 41, spring 42 and pin 43.

 The mechanism 7, shown in figure 5, contains a housing 44, a stopper 45, a fork 46, a hook 47, a lever 48, a spring 49-52, pins 53-55 and a screw 56.

 The mechanism 7 shown in FIG. 6 comprises a housing 57, a link 58, a stopper 59, a plug 60, a sleeve 61, a spring 62, a screw 63, a hook 64, a spring 65, a link 66, a spring 67, 68, a handle 69 of the stopper 59, and spring 70. The trigger in Fig.6 is not shown, but its location is apparent from the following description.

 The housing 1 (Fig. 1-4) is made of steel and has a box shape. Inside the housing 1, a T-shaped groove and a dovetail groove are made. In the front of the housing 1 there are two holes for the axes 17 and a trapezoidal groove with holes for the screws 36, in which the bracket 5 is placed (Fig. 4).

 The shoulders 11 of the bow are mounted in the rectangular slots of the bracket 5 and are drawn by the screws 37. In order to evenly distribute the forces along the plane of the shoulder 11, a ball 39 and a conical 40 washer are installed under the screw 37. The trapezoidal groove of the housing 1 is conventionally shown in Fig.4.

 The crank 2 at one end is mounted on the axis 17. The other end of the crank 2 through the pin 23 and the centering washers 18 is connected to the rod 6, which through the pin 24 is connected with the trigger mechanism. The latter is made with rectangular protrusions extending into the T-shaped groove of the housing 1, allowing movement of the mechanism 7.

 The nylon guide 12 moves in the housing 1 along the dovetail groove and is connected to the mechanism 7 by a pin 43. Using screws 29, a spring plate 20 is mounted on top of the mechanism 7 to secure the arrow in the guide 12. The bracket 8 is mounted so that its triangular protrusions entered the dovetail groove and were secured with pin 25 and screws 32.

 In the hole of the bracket 8, through the pins 26, an axis 10 is installed, on which a handle 13 is mounted, drawn by a screw 38. The lever 3 enters the crank 2 and is connected to the housing 1 by the axis 17. A latch 19 with a spring 42 is installed using the pins 28 in the lever 3. The lever 3 is connected to the lever 4 by three pins 27. At the end of the lever 4, using the screw 35, for ease of charging, a handle 21 of caprolon is installed. The axes 17 are fixed with spring stop washers 41. On the upper parts of the brackets 5 and 8, screws 30 fasten the slats 16 with the edges under the dovetail groove. The headpiece 14 and sight 9 are moved along them. Due to the elastic deformation of the walls of the groove and the pressure against the strips 16, they are fixed in the desired position. Fixation is carried out by screws 34 and 31. Front sight 15 is fixed in the rectangular groove of the nozzle 14 with a screw 33.

 In the case 44 of the mechanism 7 (Fig. 5), the plug 46 and the trigger 47 are mounted on the pins 55. The coil spring 50 provides the fork 46 an open position for gripping the bowstring 22. The hook 47 is spring-loaded with a spring 51, and its position is adjusted by a screw 56.

 A stopper 45 is mounted in front of the housing 44, coupled to the housing 44 by a spring 49 mounted on a pin 53 mounted in the housing 44 and a stopper pin 45. The lever 48 is mounted on an axis 54 and is spring loaded 52.

 The crossbow is used as follows. The initial position of the details of the crossbow is shown in figures 1-3. Holding it by the handle 13 with his right hand, with the left of the handle 21, the lever 3 is disengaged (down and forward). The latter, rotating around the axis 17, presses on the crank 2, which moves the mechanism 7 through the rod 6 until it contacts the bow 22. The bow 22 presses on one side of the fork 46 and moves it until it engages with the hook 47.

 With the reverse movement of the lever 3, the mechanism 7 moves in the opposite direction. The other side of the fork 46 captures the bowstring, pulling the shoulders 11 of the bow of the crossbow. The lever 3 is returned to its original position with force.

 Before installing the boom lower the lever 48 down. In this case, the stopper 45 rises in front of the hook of the fork 46. After that, on the guide 12, under the plate 20, an arrow is installed all the way into the bowstring 22. Then, the lever 48 is raised. Under this action, the stopper 45 is lowered into the lever 48 until it stops. The crossbow is ready for shooting.

 The difference between the mechanism shown in Fig.6, is that, when cocking the trigger mechanism 7 is automatically installed on the fuse. When installing the boom on the guide 12, there is a danger that during spontaneous descent the fingers of the arrow will be in the plane of action of the bowstring. To eliminate this danger, in the mechanism 7 shown in FIG. 6. The stopper 59 is automatically released in front of the fork 60 when cocking. It’s impossible to fire a shot.

 In the charging process, with the approach of mechanism 7 to the string 22 and its further movement forward, the string 22 presses the protrusion of the fork 60 with the force F1, turning the fork, and with it the links 58, 66. Link 58 stops holding the stopper 59, which, under the action of the spring 70, moves up to the stop with its pin into the handle 69. The fork 60 is rotated to interact with the hook 64. After that, the lever 3 is turned in the opposite direction, pulling the string 22 and deforming the shoulders 11 of the bow.

 To fire a shot, the handle 69 is lowered until it clicks. The cam part of the handle 69 through the pin in the stopper 59 lowers the latter, releasing the fork 60. The hook 64 is kinematically connected to the trigger (not shown in Fig. 6), which presses on the hook 64 with a force F2. In this case, the fork 60, released from the hook 64 releases the string 22.

 The link 58 under the action of the spring 68 enters the groove of the stopper 59. The handle 69, returning to its original position, is held in it by the spring 67, releasing the stopper 59, which is now obstructed by the link 58. The crossbow is ready for re-charging.

 Thus, the proposed crossbow is easy to use, structurally simple and provides high firing accuracy. YYY2 YYY4

Claims (6)

 1. A crossbow containing a body with a handle, in front of which a bow with a bowstring and an axis on which the lever is mounted, as well as a trigger mechanism, characterized in that it is equipped with a pull and crank, the trigger mechanism is made with the possibility of reciprocating moving along the body and pivotally connected to one end of the rod, the second end of which is pivotally connected to one end of the crank, the second end of which is fixed on an axis at the end of the body, and the lever is kinematically connected to the middle part of the crank.  2. A crossbow according to claim, characterized in that the body is made with a trapezoidal groove, and the bow is made with a central bracket having a wedge bearing surface placed in the trapezoidal groove of the body.  3. The crossbow according to claim 1 or 2, characterized in that the trigger is made with a fork, providing the ability to capture and hold the bowstring from above when the trigger is moving.  4. The crossbow according to claim 3, characterized in that the trigger mechanism is made in the form of a housing with a guide placed in the housing of the spring-loaded trigger, and a safety device in the form of a spring-loaded stopper and lever, as well as a spring-loaded fork mounted on an axis in the upper part of the housing that in one extreme position it interacts with a spring-loaded trigger, and in the other with a safety lock.  5. Crossbow according to claim 3, characterized in that the trigger mechanism is made with a fuse kinematically connected to the plug.  6. The crossbow according to claim 5, characterized in that the trigger mechanism is made in the form of a housing with a guide placed in the fuse body in the form of a spring-loaded stopper and lever, two kinematically connected intermediate links, a spring-loaded hook on the axis and a spring-loaded fork installed in the upper part the housing so that in one extreme position it interacts with a spring-loaded hook kinematically connected to the trigger, and in the other with a safety lock kinematically connected to the free end of the first intermediate link, and the free end of the second intermediate link is kinematically connected with the back of the plug.

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