WO2003081161A1

WO2003081161A1 - Slingshot with mechanism

Info

Publication number: WO2003081161A1
Application number: PCT/FR2003/000938
Authority: WO
Inventors: Serge Allain
Original assignee: Serge Allain
Priority date: 2002-03-26
Filing date: 2003-03-25
Publication date: 2003-10-02
Also published as: FR2837918A1; AU2003244711A1

Abstract

The invention concerns a slingshot comprising a handle (1) extended by two branches with a globally fork-type shape, and a flexible cable (2) extending between the free ends of the fork and enabling production of a drive force. The invention is characterized in that it is further provided with a mechanism actuated by said flexible cable (2) comprising first means for downshifting the drive force (4, 4') linked to second means for storing and releasing energy (7, 7', 13, 14).

Description

FRONDE A MECANISME

The present invention relates to a sling-type spray gun or slingshot, with a _mechanism, particularly energy storage giving it superior performance, especially in the comfort and firepower by compared to a classic slingshot. The sling mechanism according to 1 / invention is intended to be used in particular, but not exclusively, by sports shooting enthusiasts using this type of throwing weapon or even by fishermen using slings to project bait from a distance.

As is well known, a conventional slingshot or slingshot consists of a handle extended upwards from a support with two branches and having a general fork configuration, provided with a pocket made of flexible and solid material such as leather and two elastic cables to connect the two branches of the fork to the pocket to which they are tied.

The pocket is designed to contain for example a stone or any other type of suitable projectile to which a motive force will be transmitted by means of the two elastic cables when the latter, after they have undergone a more or less significant tension force exerted by the user of the sling, are suddenly released.

The energy necessary for projection is therefore first of all stored. at the elastic cables when

I the user exerts a tension force on them by pulling towards him the pouch containing the projectile to which they are connected, then it is released by these cables when the user releases them. Energy is thus coupled to the projectile by means of elastic cables.

However, a major drawback of these throwing weapons of the prior art type slingshot or slingshot as they have just been described, is that they do not offer sufficient comfort of use to allow good shot accuracy.

Indeed, to project a projectile using a conventional slingshot, the user must exert a substantial tension force on each of the two elastic cables. However, this tension force exerted to tension the two elastic cables and thus provide the desired energy making it possible to launch the projectile with the expected power must be maintained by the user on the elastic cables while he is aiming at the target to be reached . The prolonged maintenance of this tension effort and the repetition of this operation with each different shot makes the use uncomfortable and causes rapid fatigue of the user. Conventionally, the user then tries to compensate for this fatigue by slightly tilting the slingshot and, consequently, the accuracy of the shot suffers. Indeed, a tiny tilting of the slingshot fork when firing is enough to cause a significant deviation from the target.

In addition, for the majority of users, the power of shooting with a slingshot or slingshot is limited. Indeed, even if elastic cables have the potential, by their intrinsic characteristics, to send a given projectile at a substantial distance, an average user will not be able to use all the power potential because he will not have not enough force to stretch the elastic cables far enough back.

It is therefore an object of the present invention to overcome the drawbacks of the aforementioned prior art by proposing a sling provided with a particular mechanism providing it with superior performance, in particular in the comfort of use and the power of shoot.

To this end, the invention proposes to replace the elastic cables allowing the manifestation of the driving force in a conventional sling with cables made of a material which is both flexible and solid, for example nylon (registered trademark), provided for actuating a mechanism internal to the fork or disposed in front of it (the user being behind) in a support structure provided for this purpose.

The mechanism implemented in the sling according to the invention consists of a first assembly having a function of reduction of the driving force, connected to a second assembly having a function of energy storage on the one hand and release energy on the other hand. The energy is then coupled to the projectile via the reduction gear assembly and the flexible cable, for increased firing power.

The energy storage and release assembly is advantageously in the form of springs or alternatively in the form of a compressed fluid such as air or gas. As for the reduction gear assembly, it consists of a fixed pulley-mobile pulley system. It is possible to multiply at will the number of fixed pulley-mobile pulley couples in order to overcome the resistance of the energy storage means. The mechanism thus implemented makes it possible to very clearly increase the shooting power of the sling in which it is installed, while ensuring great comfort of use for the shooter. The invention therefore relates to a sling comprising an extended handle of two branches having a general fork configuration, and a flexible cable extending between the free ends of the fork and allowing the manifestation of a motive force, characterized in that it is provided in addition with a mechanism actuated by said flexible cable comprising first means of reduction of the driving force connected to second means of storage and release of energy. Other characteristics and advantages of the present invention will appear more clearly on reading the description which follows given by way of illustrative and nonlimiting example and made with reference to the appended figures in which: - Figures 1A, 1B and 1C illustrate a first embodiment of the invention using traction springs; FIGS. 2A and 2B illustrate a second embodiment of the invention using compression springs; FIG. 3 illustrates a third embodiment of the invention implementing compressed air systems; FIG. 4 illustrates a particular embodiment where the energy storage means are combined in a single block; FIG. 5 illustrates a particular embodiment where the mechanism as a whole is arranged inside the fork; FIG. 6 illustrates an additional embodiment where the fixed pulley-movable pulley assembly has an assembly in two alignment; - Figures 7A and 7B illustrate a last embodiment of the invention combining the fixed pulleys-movable pulleys system with that of the lever. The elements common to the different figures keep the same references.

In Figures 1A, 1B and 1C is therefore described a first embodiment of a sling according to the present invention. It is formed at the base of a handle 1 extended upwards by two branches and having a general fork configuration. Each of the two branches of the fork comprises in its upper end an orifice 10 allowing the passage of a cable 2 of flexible and solid material allowing the manifestation of a driving force when it is pulled backwards by the user. The cable 2 is preferably made of nylon (registered trademark).

A support structure 3 is fixed respectively in front of each of the two branches of the fork so as to support a mechanism intended to be actuated by the cable 2 when the latter is stretched by the user. Each of the support structures 3 has a general inverted "L" shape.

The mechanism thus integrated into the sling through the support structures 3 comprises, symmetrically for each support structure 3 associated respectively with each of the two branches of the fork, first reduction means connected to second storage means and of energy release. The reduction means, advantageously arranged in the upper part of the support structure 3, comprise a set of at least one fixed pulley 4 assembled to a set of at least one movable pulley 4 ', among which the cable 2 circulates. In this example, the fixed pulleys 4- mobile pulleys 4 ′ assembly consists of three fixed pulley-mobile pulley pairs assembled in a block. Thus, the set of fixed pulleys 4 and the set of movable pulleys 4 'each have a common axis, respectively 5 and 5', the set of movable pulleys being further supported by a yoke 6. However, it is possible to decrease or increase at will the number of couples fixed pulley-movable pulley without departing from the scope of the present invention.

As for the energy storage and release means, advantageously arranged in the lower part of the support structure 3, they are constituted in this first embodiment of the invention by at least one tension spring 7. In the example, of FIG. 1A, only one spring is used. It should however be understood that a plurality of springs can be used without departing from the scope of the present invention. One end of the tension spring 7 is fixed to the lower end 9 of the support structure 3 and the other end of the spring is fixed to a fixing point 8 secured to the yoke of movable pulleys 6.

In FIG. 1B, it is shown that the support structure of the mechanism placed in front of each of the arms of the fork can be a tubular structure 3B so as to protect the mechanism. The support structure can also be an open structure 3C, as shown in FIG. 1C. In this first embodiment of the invention, when the user pulls the cable 2 backwards to fire a projectile, the yoke of movable pulleys 6 rises towards the upper part of the structure 3, thus making an effort of significant traction at the spring 7. However, this effort is largely assumed by the fixed pulley-movable pulley assemblies as a result of the reduction ratio resulting from their assembly. The user then has to provide a moderate effort to keep the cable in tension when aiming and therefore experiences less fatigue. The mechanism according to the invention therefore allows better comfort in using the sling.

The energy is then stored by the springs 7 and will be released suddenly under the effect of the return of the springs when the user releases the cable 2 to pull.

FIGS. 2A and 2B illustrate a second embodiment of the invention which differs from that of FIG. 1A by the use of at least one compression spring 7 'for the energy storage and release means.

The implementation of compression springs requires a modification of the structures supporting the mechanism integrated into the sling. Thus, a rigid piece 12 is securely attached to the uprights of the support structure 3, as shown in detail in Figure 2B. One end of the compression spring 7 'is provided to be fixed to this part 12. The other end of the spring 7' is then fixed to an additional structure 11 contained in the support structure 3, advantageously composed of two rigid rods passing on either side of room 12 as shown in Figure 2A, and connected to the yoke of movable pulleys 6, thus allowing the communication of the driving force.

Only one compression spring is used in the example of FIG. 2A, but it is possible to use more.

FIG. 3 shows a third embodiment of the invention in which the energy storage and release means comprise at least one air compression system. Energy is therefore no longer stored by springs but in the form of a compressed fluid such as gas or air. The only structural difference with FIG. 2A is that the compression springs 7 ′ associated with each of the two branches of the fork are replaced by the air compression system or any other suitable gas.

The air compression system conventionally comprises an air compression tube 13 in which a piston for compressing the air is slid

14. The piston 14 comprises on the one hand, a disc 15 for compressing the air in the tube and, on the other hand, a rod

16 sliding in the tube through a through hole.

In the same way as in FIG. 2B, a rigid piece 12 is securely fixed to the upright of the support structure 3 of the mechanism. To this part is fixed the upper end of the air compression tube 13, while the lower end of the rod 16 of the piston to compress the air 14 is fixed to the structure 11 composed of two rigid rods passing through and other of the rigid part 12 and connected to the yoke of movable pulleys 6.

Thus, following the action of the user pulling the cable 2 backwards to prepare a shot, the movable pulley yoke 6 moves towards the upper part of the support structure 3 and makes perform a compression stroke with the air piston 14. The energy stored in the form of compressed air is then suddenly released by the air compression system when the user releases the cable 2 to fire.

The assembly of air compression tube and piston to compress the air therefore fulfills exactly the same function as the compression spring 7 ′ in the context of FIG. 2A. The simple difference is that energy is stored as compressed air instead of compression springs.

Figure 4 shows a particular embodiment where a support structure 3 ', modified with respect to the support structure 3 already seen, is implemented so that the energy storage and release means are combined in one and the same block. Thus, we no longer have, as with reference to the preceding figures, separate and differentiated storage means, dedicated respectively to the two branches of the fork with a support structure 3 corresponding to each.

In the particular embodiment of FIG. 4, the support structure 3 ′ is fixed in its upper part to each of the two branches of the fork and comprises, respectively for each of the two branches, the means for reducing the driving force already described with reference in the previous figures. The lower part of the support structure 3 'is designed to accommodate a set of five traction springs 7A to 7E joined in a single block (the number of springs used is simply given for information and must be interpreted as being at least equal has a) . A rigid part 17 allows the assembly of all of the springs in a single block and two cables 18 are provided to connect this block to the two yokes 6 of movable pulleys. It is possible, instead of using these two cables 18, to directly fix the two yokes 6 to the rigid part 17 joining the springs.

It should be noted that this particular embodiment described with reference to FIG. 4 can also be implemented with energy storage and release means using compression springs or even a compressed air system.

One advantage of this particular embodiment where all the energy storage and release means are combined in a single block is that the possible failure of at least one of these means (possibly being tension springs, compression or compressed air systems) can be compensated by the others in the same block and therefore does not prevent the operation of the sling.

FIG. 5 describes a particular embodiment of the sling mechanism where the mechanism as a whole, that is to say the reduction means and the storage means, is contained inside the handle 1 having a general fork configuration.

The reduction means constituted by the fixed pulley 4-movable pulley 4 'assembly assembled in a block are arranged respectively inside each of the two branches of the fork. The energy storage and release means constituted by a tension spring in the example of FIG. 5 are, for their part, arranged in the lower part of the handle forming the fork handle. The end of the traction spring 7 is fixed to the base of the handle, while the other end of the spring is connected to the movable pulley yokes 6 by means of two cables 20 and 21 and four fixed pulleys, 19 _x to 19 ₄ , allowing orientation inside the fork of the cables 20, 21 used for the transmission of the driving force.

A compression spring or an air compression system as previously described can also be implemented in the configuration of FIG. 5.

FIG. 6A shows another embodiment of the invention where the assembly of at least one fixed pulley 4 and the assembly of at least one movable pulley 4 'forming the means for reducing the motive force has an assembly in two alignments, one for the fixed assembly, the other for the mobile assembly.

A set of fixed pulleys 4 is thus fixed directly respectively on the front of each of the branches of the fork (the user being behind), while a set of corresponding movable pulleys is fixed on a board 22 located opposite each respectively branches of the fork.

In such an assembly, the alignments of fixed and movable pulleys are parallel to the branches of the fork. Each of the pulleys has its own axis and these axes are perpendicular to each respective alignment.

FIGS. 6A and 6B show an exemplary embodiment where the energy storage and release means comprise a plurality of compression springs 7 ′. Each of the compression springs 7 'used has one of its ends fixed to one of the branches of the fork and the other end fixed on the board opposite said branch.

Air compression systems as previously described can also be used in place of compression springs. In this case, the end of the air compression tube opposite the piston rod is fixed to one of the legs of the fork and the end of the piston rod is fixed to the board opposite said branch. FIG. 6C shows a profile view of the mechanism sling according to the present invention having an assembly of pulleys in two alignment identical to that of FIGS. 6A and 6B, but where a plurality of tension springs 7 are used as storage means and of energy release.

A rigid structure 23 is additionally fixed respectively to each of the branches of the fork so as to completely surround the assembly of pulleys in two alignments. Each of the tension springs 7 used then has one of its ends fixed to the rigid structure 23 and its other end fixed to the face of the board 22 opposite the face supporting the alignment of movable pulleys 4 '.

Whether it is the embodiment of FIG. 6B or that of FIG. 6C, it is possible to decrease or increase the number of springs used as long as the proper functioning of the sling is not disturbed.

FIGS. 7A and 7B illustrate a final embodiment of the present invention consisting in combining the set of fixed pulleys-movable pulleys with a lever system serving as energy storage and release means. The set of fixed pulleys 4 and mobile pulleys 4 'here has an assembly in two alignments as already described with reference to Figures 6A to 6C. However, another type of assembly such as the muffle assembly already described with reference to FIG. 1A could also be implemented. Thus, a lever 26 having a general fork configuration similar to that of the sling, as shown in FIG. 7B, supports a set of movable pulleys 4 'on each of its two branches respectively. The two branches of the fork acting as a lever 26 are advantageously arranged in front of and opposite the branches of the fork forming the handle 1 of the sling itself, which branches each support respectively a set of fixed pulleys 4. The cable 2 then circulates through this assembly in two alignments of the fixed pulley-mobile pulley system.

Daτrs une- pxemiè-re variant, the lever 26 is fixed to the foot of the handle 1 of the sling via a rigid projection 24. The projection 24 and the lever 26 are then connected by a torsion spring 25 The torsion spring 25 can be fixed directly to the foot of the handle 1, in which case the projection 24 and the lever 26 are integral. The advance can also be itself composed of a torsion spring.

According to another variant, the projection 24 and the lever 26 consist of a single piece advantageously fixed to the foot of the handle 1 and composed of a flexible material to avoid the use of the torsion spring.

Finally, many other variants in the fixing of the lever to the handle of the sling can be envisaged as long as they do not put back in question the proper functioning of the present invention.

Thus, for example, the lever 26 can be fixed at the intersection of the fork.

It can also be fixed respectively to the foot of each branch of the fork or to the top of each branch of the fork. In this case, there are two levers per sling.

Claims

1. Sling comprising a handle (1) extended by two branches having a general fork configuration, and a flexible cable (2) extending between the free ends of the fork and allowing the manifestation of a motive force, characterized in that that in addition it has a mechanism actuated by said flexible cable (2) comprising first means for reducing the driving force (4, 4 ′). connected to second means for storing and releasing energy (7 , 7 ', 13, 14).

2. Slingshot according to claim 1, characterized in that a support structure (3) is fixed respectively in front of each of the two branches of the fork, so as to receive there, in its upper part, the means for reducing the force drive and, in its lower part, the means of storage and release of energy.

3. Slingshot according to claim 2, characterized in that the support structure (3) is generally of inverted "L" shape and has a tubular or open structure.

4. Slingshot according to claim 1, characterized in that the means for reducing the driving force and the means for storing and releasing energy are internal to the handle (1) having a general fork configuration, said reduction means being arranged inside the two branches of the fork and said energy storage and release means being arranged in the lower part of the handle (1) forming the handle of the fork.

5. Slingshot according to one of claims l to 4, characterized in that the energy storage and release means comprise at least one tension spring (7).

6. Slingshot according to one of claims 1 to 4, characterized in that the energy storage and release means comprise at least one compression spring (1 ').

7. Slingshot according to one of claims l to 4, characterized in that the energy storage and release means comprise at least one air compression system, said air compression system consisting of a air compression tube (13) in which slides a piston to compress the air (14).

8. Slingshot according to one of the preceding claims, characterized in that the means for reducing the driving force comprise a set of at least one fixed pulley (4) e a set of at least one movable pulley (4 ') assembled in muffle, a yoke (6) supporting the set of movable pulleys (4 ').

9. Slingshot according to claim 1, characterized in that the means of reduction of the driving force comprise a set of at least one fixed pulley (4) intended to be fixed directly respectively on the front of each of the two branches of the fork and a set of at least one corresponding movable pulley (4 '), said sets being assembled in two alignments parallel to said legs of the fork, respectively one alignment for said set of fixed pulleys (4) and the other for said set movable pulleys (4 '), each of the pulleys having its own axis perpendicular to each respective alignment.

10. Slingshot ^• according to claim 9, characterized in that the set of movable pulleys (4 ') is fixed on a board (22) respectively facing each of the two branches of the fork and in that the storage means and of energy release comprise a plurality of compression springs (7 '), each of the compression springs has one of its ends fixed to one of the legs of the fork and the other end fixed to the board opposite said branch .

11. Slingshot according to claim 9, characterized in that the set of movable pulleys (4 ′) is fixed on a board (22) respectively facing each of the two branches of the fork and in that the storage means and of energy release comprise a plurality of air compression systems consisting of an air compression tube (13) in which slides an air compression piston (14), each of the air compression systems at the end of said air compression tube (13) opposite the piston rod (16) fixed to one of the legs of the fork and the end of the piston rod (16) fixed on the board opposite said branch.

12. Slingshot according to claim 9, characterized in that the set of movable pulleys (4 ') is fixed on a board (22) respectively facing each of the two branches of the fork and in that the storage means and of energy release comprise a plurality of tension springs (7), a rigid structure (23) then being additionally fixed respectively to each of the legs of the fork so as to completely surround the assembly of pulleys in two alignment, each said tension springs having one of its ends fixed to said structure rigid (23) and the other end fixed to the face of the board (22) opposite to the face of said board supporting the alignment of movable pulleys (4 ').

13. Slingshot according to claim 9, characterized in that the energy storage and release means comprise a lever (26) having a general fork configuration similar to that of the handle (1) of said slingshot, said lever ( 26) supporting the set of movable pulleys (4 ') on each of its branches arranged in front of and opposite the branches of the fork forming said handle (1).

14. Slingshot according to claim 13, characterized in that the lever (26) is fixed to the handle (1) of said slingshot by means of a rigid projection (24), said lever and said rigid projection being connected by a torsion spring (25).

15. Slingshot according to claim 13, characterized in that the lever (26) is fixed to the handle (1) of said slingshot by means of a torsion spring.

16. Slingshot according to claim 13, characterized in that the lever (26) is made of flexible material.

17. Slingshot according to one of claims 14 to 16, characterized in that the lever (26) is fixed to the foot of the handle (1).

18. Slingshot according to one of claims 14 to 16, characterized in that the lever (26) is fixed at the intersection of the fork.