RU2574871C2 - Spiral resilient elements for firing device - Google Patents

Abstract

FIELD: weapons and ammunition.

SUBSTANCE: invention relates to firing means, particularly, to resilient firing means. Claimed device consists of one spiral resilient element (1) arranged at the body (4) of firing device (S). Said resilient element (1) is secured by one end to the firing device (S). The opposite end of said resilient element is connected with the string (3) that changes from the idle position to stretched position at twisting and contracting of the spiral resilient element (1). Every element consists of the spiral plate, its first central end (1b) being secured relative to the body (4) of the firing device (S) while the opposite end (1d) includes the string (3) fasteners (1e).

EFFECT: decreased force to be applied at resilient element contraction, higher rate of fire.

21 cl, 11 dwg

Description

The present invention relates to an elastic device consisting of an elastic element of a spiral shape mounted on shooting devices and mechanisms, for example, such as crossbows, bows, spearguns for sports, recreation or hunting practice.

It should be noted that the principle of constructing a crossbow or bow remained unchanged for many centuries.

The principle of operation of crossbows or bows is based primarily on the use of a linear bending elastic element, fixed on one side or in the middle and made up of one or two parts.

The arcuate profile geometry of the deformable shoulder or shoulders that make up the linear elastic element of bows or crossbows, determines their significant drawbacks, which is primarily the mismatch of the bowstring tension vector relative to the arrow or missile body.

In fact, the force created by the movement of the free end of the elastic element is oriented tangentially to the crossbow’s shoulder, describing the curve around it, and consists of two parts: one is progressive and the other is perpendicular to the arrow’s acceleration direction, which coincides with the longitudinal axis of the crossbow.

Figures 1-3, for example, show a schematic representation of the principle of operation of a known crossbow. Thus, in the resulting changing parallelogram of forces, the bowstring’s speed in the direction of the crossbow’s axis is always lower than its speed at the attachment points, with the transverse component prevailing as the arc straightens.

Accordingly, the translational speed of the bowstring and the force exerted by the bowstring will decrease to zero in proportion to the cosine of the angle formed by the bowstring and crossbow guide, in accordance with the following formula:

Vprogressive = V × cos ABC or Fprogressive = F × cos ABC.

This proportional decrease in progressive speed and progressive force increases depending on the size of the crossbow arc, which cannot exceed 900 mm.

In fact, under these conditions, it should be noted that the bowstring accelerates the arrow at a distance of DF of only 250 mm, i.e. half way, and then its speed decreases and the bowstring lags behind the moving arrow.

Known from previous patents US 4879987 and US 7743760 elastic device for crossbows, consisting of linear elastic elements installed in the opposite direction to the usual, i.e. the inner side of the arcs is oriented across the tension of the bowstring, on the one hand, and blocks that convert the tensile force on the other hand are installed on the outer ends of the linear elastic elements.

However, it should be noted that the improvements described and illustrated in the documents of the prior art do not eliminate the main disadvantages associated with the elastic linear elements, as previously explained.

The present invention addresses the above drawbacks by replacing deformable shoulders (arcs) of a curved profile constituting a linear elastic element of a bow or crossbow or speargun with one or more elastic elements in the form of a spiral placed on the body of the firing device.

The elastic firing device according to this invention is composed of at least one spiral elastic element located on the base of the firing device, the specified elastic element is fixed at one of its ends on the firing device, while the other end is connected to the bowstring, which moves from the idle position to the tensioned position when twisting and compressing the spiral elastic element.

The elastic firing device according to this invention consists, for each elastic element, of an elastic plate twisted in the form of a spiral so that the central end allows the specified element to be fixed relative to the body of the firing device, while the second opposite end includes means for attaching the bowstring.

The elastic firing device according to this invention includes, for each spiral arc, a central groove (groove) on the surface of the outer turn, profiled to receive the bowstring.

The elastic device for firing according to this invention consists of at least two spiral elastic elements, which are attached at one horizontal end to a firing device having a crossbow profile.

The elastic firing device according to this invention consists of a spiral elastic element, which is attached at one end in a vertical plane to a firing device having a crossbow profile.

The elastic firing device according to this invention is composed of at least two spiral elastic elements, which are attached at one end in a vertical plane to the firing device having a bow profile.

The resilient firing device according to this invention includes a helical resilient member that is made of a plastic material, including fiberglass and carbon.

The elastic device for firing according to this invention includes spiral elastic elements, which are respectively mounted on horizontal brackets located on both sides of the crossbow guide body, by means of fastening axes interacting, on the one hand, with complementary shaped holes formed at the first central end, and , on the other hand, fixing said spiral arms axially relative to said barrel guide and blocking their rotation relative to about the indicated axes of fastening.

The elastic firing device according to this invention includes spiral elastic elements that are axially mounted on respective horizontal brackets, so that each second end is located close to the other and in a direction parallel to the longitudinal axis of the crossbow guide body.

An elastic firing device in accordance with the present invention consists of a spiral elastic element mounted on a first bracket, the second end of which is connected to the first loop of the bowstring, while the second end of the other spiral arm mounted on the second bracket is attached to the second loop of the bowstring.

An elastic firing device according to this invention includes a bowstring with two end loops and a fastening area for placement and temporary holding of the boom or projectile.

The resilient firing device according to this invention includes helical resilient elements that are individually fenced with a protective cover.

The elastic firing device according to this invention includes an elastic element in the form of a spiral, which is fixed between the extensions of the two halves of the flanges attached to the crossbow body, by mounting on the axis of the non-cylindrical profile, interacting, on the one hand, with a complementary shaped hole formed at the first central end, and, on the other hand, fixing said spiral arc with respect to said guide and blocking its rotation with respect to said fixing axis.

The elastic firing device according to this invention includes an elastic plate in the form of a spiral, which is located in the axial direction between the extensions of the two halves of the flanges so that the second end is on the extension of the longitudinal axis of the crossbow guide.

The resilient firing device according to this invention includes a spiral plate, the second end of which is attached to one end of a single stranded string forming a bowstring, while the other end of said single thread is connected to an arrow-pushing device.

The elastic device for firing according to this invention includes a pushing device having in plan two guiding protrusions interacting with slots respectively formed in the half flanges so as to guide and guide said pushing device along a guide formed in the barrel of the crossbow to simultaneously bring the bowstring out state of rest to a stretched position and a spiral arc from an unloaded position to a compressed position.

An elastic firing device according to this invention includes a pushing device having a protrusion perpendicular to the guide and vertically protruding above it, which is the fulcrum of the boom and transmits the driving force when the boom or projectile is in contact with it.

The elastic firing device according to this invention includes spiral elastic elements, which are respectively attached to each end of the bow body brackets by means of fixing axes with a non-cylindrical profile, interacting, on the one hand, with holes formed in the first central end, and, on the other hand, fixing each spiral in the axial direction and blocking their rotation relative to the indicated axes of attachment.

The elastic firing device according to this invention includes elastic spiral elements fixed in the axial direction so as to wrap the bowstring in plan from above and parallel to the frontal projection, with each second end connected to the bowstring being substantially oriented towards the trigger device formed on said case

The following description, in the light of the accompanying drawings, which are given as non-limiting examples, will help to better understand the invention, its functions and the advantages that it can create.

Figures 1-3 show views illustrating the movement and forces of a bowstring on an arrow when using linear elastic elements, such as bent shoulders of a bow or crossbow, known per se.

Figures 4-6 are perspective views showing a crossbow type firing device with two spiral elastic elements mounted, twisted in a horizontal plane according to this invention.

Figures 7, 8A and 8B are perspective views illustrating a crossbow type firing device including a spiral elastic element twisted in a vertical plane according to this invention.

Figures 9 and 10 are perspective views illustrating a firing device such as a bow containing two spiral elastic elements twisted in a vertical plane according to this invention.

Fig. 11 is a schematic view showing a comparison of the forces and speeds of a crossbow, known per se, and a crossbow in accordance with the present invention.

Figures 4-6 show a type S crossbow firing device including a housing 4 on which spiral elastic elements 1 connected to a bowstring 3 are located at one of its ends, which can move from an unloaded to a tense position.

The body 4, for example, contains a handle 4a for holding the crossbow, continues with the support of the barrel 4b, which has a guide 4c in the upper horizontal part for guiding the boom or projectile.

The guide 4c includes, at one of its ends, a travel stop 4d of the bowstring 3 when the latter is in an unstretched position, and there is a trigger lock 4e opposite the said stop to hold said bowstring in a stretched position.

Said lock 4e is connected with a trigger 4f placed below the guide 4c between the barrel 4b and the handle 4a.

Two lateral brackets 4g, 4h are mounted to the free end of the barrel support 4b of the crossbow body 4, arranged in a horizontal plane and connected to the mounting axles 4i with a non-cylindrical external profile extending in the vertical direction.

Each elastic element 1 is composed of a plate 1a twisted in a spiral, for example, made of plastic material, including fiberglass and carbon.

Each elastic element 1 is composed of a plate 1a, coiled into a spiral, including the first so-called central end 1b with a through hole 1c.

The hole 1c of each spiral plate 1a has an internal profile complementary in shape to the axis of attachment 4i, which allows the spiral plate 1a to be mounted axially relative to the longitudinal axis of the barrel 4b when mounted on the respective brackets 4g, 4h, and locked from rotation around the specified mounting axis 4i, on the other hand.

Each spiral plate 1a is vertically fixed on the axis of fastening 4i by means of a latch 4j, for example, screwed inside the specified axis.

Each spiral plate 1a includes, opposite the first or so-called central end 1b, a second end 1d, for example, with a hole 1e, to form a means for attaching the bowstring 3.

The elastic spiral elements 1a are mounted on the respective brackets 4g, 4h so that each second end 1d is located close to the other and in a direction parallel to the longitudinal axis of the barrel 4b of the crossbow body 4,

The bowstring 3 includes a first loop 3a that is attached to the second end 1d of the spiral plate 1a mounted on the bracket 4g, while the second loop 3b is attached to the second end 1d of the other spiral plate 1a mounted on the bracket 4h attached to the crossbow body 4.

The bowstring 3 includes, between its two loops 3a and 3b, a fastening area 3c for placement and temporary connection with an arrow or projectile.

Each spiral plate 1a has an axial groove 1f on its outer profile, which internally corresponds to the loops of turns 3a, 3b of the string 3, when the latter is in standby mode.

The bowstring 3 goes from the idle position from the stops of the travel stop 4d to the tensioned position until it is locked in the fastening area 3c when placed inside the trigger lock 4e using a tensioner (not shown) to cock the crossbow or manually by an arrow.

The movement of the string 3 allows you to compress, respectively, when twisting, each spiral plate 1a around the vertical axis 4i and move the crossbow to the cocked position.

A protective cover 4k can be installed around each spiral plate 1a, avoiding deformations of the outer surface of the spiral supporting the string 3 when the latter returns to its uncompressed idle position.

The cover 4k also protects the shooter in case of damage to both the bowstring 3 and the spiral plate 1a.

The lid 4k can slow down the deformation of each spiral plate 1a during an idle shot, that is, without a projectile.

Figures 7, 8A and 8B show a crossbow type shooting device S including a housing 4, on which, at one of its ends, the spiral elastic element 1 is mounted connected to a bowstring 3, which can move from an idle position to a stretched position.

The firing device S differs from those described above only in that it includes a single elastic member 1 consisting of a spiral plate 1a folded in a vertical plane.

The housing 4 is fastened along its barrel 4b with two half flanges 4l, 4m extending beyond the specified barrel and covering the guide 4c.

Each half-flange 4l, 4m has an extension 4n, 4p with a horizontal hole 4q, through which the locking axis 4i passes to secure the spiral plate 1a.

Thus, the spiral plate 1a is blocked from rotation between the extensions 4n, 4p of the half flanges 4l, 4m by the corresponding profile of the hole 1c in the specified plate, which interacts with the axis of attachment 4i with the non-cylindrical profile and the retainer 4j.

A helical plate 1a is axially placed between the extensions 4n, 4p of the half flanges 4l, 4m, so that the second end 1d is placed in the longitudinal axis of the barrel 4b of the crossbow body 4 having the guide 4c, so as to be able to attach a single branch 3d forming string 3 to the specified second end.

Thus, one end of the single branch 3d of the string 3 is attached to the second end 1d of the spiral plate 1a, while the other end is connected to the pushing device 5.

The pushing device 5 in plan has two transversely directed protrusions 5a, 5b interacting with slots 4r, 4c respectively formed in the half flanges 4l, 4m to guide and guide the pushing device over the guide 4c, and at the same time move the bowstring 3 from the idle position to the tensioned position and a spiral plate 1a from a free position to a compressed position.

The pushing device 5 has a support 5c perpendicular to the guide projections 5a, 5b and vertically directed protruding above the half flanges 4l, 4m, transmitting force to the boom or projectile when they are in contact with it.

The pushing device 5 is locked in the platoon position in the specified locks 4e of the guide 4c, when the only branch 3d of the bowstring 3 is brought into the tensioned position (figures 7 and 8B), the previously mentioned locks 4e are connected to the trigger 4f in order to be able to release the pushing device 5 when shots with an arrow or projectile (Figure 8A).

The pushing device 5 can be moved either manually by the shooter or using a tensioner (not shown) to cock the crossbow.

The crossbow body 4, and more particularly the barrel 4b, may include a brake device 6, which consists of a brake pad 6a controlled by pressing the forearm 6b, sliding on the bottom of the specified barrel. The brake shoe 6a is actuated by pressing the forearm 6b against the outer periphery of the spiral plate 1a so as to inhibit the discharge of said plate.

It should be noted that in this arrangement, the force created by the spiral plate 1a coincides with the direction of acceleration of the boom as reported by the pushing device 5. Thus, the direction of deformation of the spiral plate 1a compensates for the overturning impulse during the shot, which occurs due to the excess of the firing line relative to the line butt 4a.

Figures 9 and 10 show a bow-type shooting device S including a body 4, on which a spiral elastic element 1 is located at each end, said spiral elastic element is connected to a bowstring 3, which can go from an idle position to a stretched position.

The base 4 is composed of a frame 4t, the profile of which, for example, can be triangular, equipped on one of its sides with a handle for gripping 4u passing into an elongated window 4v, for the fingers to pass the arrow.

The frame 4t has on one of its sides 4w at its farthest ends two mounting axles 4i, which have a non-cylindrical profile, are arranged in the perpendicular direction relative to the front side 4w of the frame 4t containing them.

The upper edge of the handle 4u, located in the front plane 4w, is equipped with a supporting support 4x, which allows you to support the firing boom or projectile.

On each axis of the attachment 4i, the elastic member 1 consists of a spiral plate 1a twisted in a vertical plane parallel to the surface 4w of the frame 4t and fixed by the fixing means 4j.

Thus, each elastic element 1a is blocked from axial rotation by the interaction of the complementary profile of the hole 1c of the specified spiral with the axis of attachment 4i with a non-cylindrical profile and fixing means 4j.

The axial position of each spiral elastic element 1a is maintained when the second end 1d associated with one of the ends of the bowstring 3 is substantially oriented towards the handle 4u of the frame 4t, so that the specified bowstring 3 is located in the axial recess 1f and connects these spirals 1a , is located in a plane parallel to the plane of the larger side of the frame 4t.

Principle of operation

It will be understood from the above description that the firing device S, equipped with at least one spiral elastic element (1), allows you to completely solve the above disadvantages.

In fact, the tension of the string 3 corresponds to the deformation of the spiral plate (s) 1a, which makes (s) approximately one 360 ° rotation relative to the fixed point embodied by the attachment axis 4i, by untwisting the said string 3. However, the movement of the string 3 is equal to the circumference formed by the spiral 1a in a free state.

Thus, in order to obtain the optimal distance for the acceleration of the arrow, that is, along the entire length L of the guide 4c, the maximum diameter D of the elastic element 1, which determines the minimum frontal projection of the crossbow, can be defined as D = L / tm, where L is the path of the bowstring 3 .

In addition, it can be noted that the spiral elastic element 1 according to the invention does not produce recoil and the speed of the boom is equal to the speed of the free end of the spiral elastic element 1 and increases during the deformation of the spiral along the entire length of the path.

In addition, it should be noted that the speed of the boom increases as a function of the deformation of each spiral elastic element 1 and the increase in the outer diameter of the specified spiral.

It can be noted that the advantages of the firing device S containing at least one spiral elastic element 1 can be as follows:

a) The force acting on the arrow is proportional to the cosine of the angle ABC between the direction of movement of the arrow and the attachment points of bowstring 3 on the elastic element 1, that is, F × cosABC, where F is the bow tension force.

- In the traditional crossbow configuration, the ABC angle during arc straightening increases from 45 ° to 90 °, the strength of the elastic element is partially transmitted to the arrow in the initial part of the trajectory with a factor of 1 / √2 (because 45 °), that is, only 70%, and falls to zero when the arc is straightened (Figure 3).

- In the configuration according to the invention of the shooting device S containing at least one spiral elastic element 1, it should be noted that the angle ABC is actually constant and allows the arrow to receive at least 99% of the force from the deformation of the spiral elastic element 1.

As a result, in order to obtain equal values of the boom speed, it is necessary to have a force arising from the compression of the spiral elastic element 1, half that of the linear element (Figure 11).

b) Newton’s second law states that with a constant strength F of the bowstring 3 and mass m of the arrow, its final velocity value or speed will be directly proportional to the duration of the use of force in accordance with F × T = m × (V-V0).

It can be noted that, having multiplied the advantage in the force applied to the arrow (point a) by the time of its operation, we conclude that the speed level or arrow speed for the firing device S containing one or more spiral elastic elements 1 increases to 3 time.

You must also understand that the previous description was given solely as an example and in no way limits the scope of the invention and will not be outside this area of replacement of the details of the described embodiment of the invention by any equivalent means.

Claims (21)

1. An elastic device for firing, characterized in that it consists of at least one spiral elastic element (1) mounted on the housing (4) of the firing device (S), said elastic element (1) is fixed at one of its ends in said shooting device (S), while the other end is connected to the bowstring (3), which, when moving from the idle position to the tensioned position, twists and compresses the spiral elastic element (1), each of which consists of a plate rolled up into a spiral (spiral plate) (1a) so about at the same time that its first central end (1b) allows you to fix the specified element relative to the body (4) of the firing device (S), while the second opposite end of the spiral (1d) includes fastening means (1e) for attaching the bowstring (3) . 2. The device according to claim 1, characterized in that the outer profile of the spiral elastic element (1a) has a central groove (1f) perceiving the profile of the bowstring (3). 3. The device according to claim 1 or 2, characterized in that at least two spiral elastic elements (1a) are arranged rolled in a horizontal plane at one of the ends of the firing device (S), the body (4) of which has a crossbow profile. 4. The device according to claim 1 or 2, characterized in that the spiral elastic element (1a) is positioned twisted in a vertical plane at one end of the firing device (S), the body of which (4) has a crossbow profile. 5. The device according to claim 1 or 2, characterized in that at least two spiral elastic elements (1a) are located and twisted in a vertical plane at each end of the firing device (S), the body of which (4) has a bow profile. 6. The device according to claim 1, characterized in that each spiral elastic element (1a) is made of a plastic material, for example fiberglass or carbon. 7. The device according to claim 1, characterized in that the spiral plates (1a) are respectively mounted on horizontal brackets (4g, 4h) attached to both sides of the barrel (4b) of the crossbow housing (4) by means of mounting axles (4i) with a non-cylindrical a profile that interacts, on the one hand, with a complementary hole (1c) formed at the first central end (1b), and, on the other hand, with fastening means (4j) that enable axial positioning of these spiral elastic elements relative to the longitudinal axis of the specified about the barrel (4b) and the rotation lock of these spirals (1a) around the indicated axes of attachment (4i). 8. The device according to claim 3, characterized in that the spiral plates (1a) are respectively mounted on horizontal brackets (4g, 4h) attached to both sides of the barrel (4b) of the crossbow housing (4) by means of mounting axles (4i) with a non-cylindrical a profile that interacts, on the one hand, with a complementary hole (1c) formed at the first central end (1b), and, on the other hand, with fastening means (4j) that enable axial positioning of these spiral elastic elements relative to the longitudinal axis of the specified about the barrel (4b) and the rotation lock of these spirals (1a) around the indicated axes of attachment (4i). 9. The device according to p. 7 or 8, characterized in that the spiral elastic elements (1a) are located in the axial direction on the respective horizontal brackets (4g, 4h) so that each second end (1d) is adjacent and in a direction parallel to the longitudinal axis of the barrel (4b) of the crossbow body (4). 10. The device according to p. 9, characterized in that the second end (1d) of the spiral elastic element (1a), mounted on the bracket (4g), is attached with one loop (3a) to the bowstring (3), and the second end (1d) of the other a spiral elastic element (1a) mounted on an arm (4h) is also attached by a second loop (3b) to said string. 11. The device according to p. 10, characterized in that the bowstring (3) includes, between its two loops (3a, 3b), a fastening area (3c) for accommodating and temporarily holding the boom or projectile. 12. The device according to claim 7 or 8, characterized in that each spiral elastic element (1a) can be closed with a protective cover (4k). 13. The device according to claim 1, characterized in that the spiral elastic element (1a) is fixed between the extensions (4n, 4p) of the two half flanges (4l, 4m) attached to the barrel (4b) of the crossbow body (4) via the mounting axis (4i ) with a non-cylindrical profile, interacting, on the one hand, with a hole (1c) of a complementary shape formed at the first central end (1b), and, on the other hand, with fixing means (4j), which makes it possible to fix the spiral in the axial position elastic element relative to the longitudinal axis of the specified barrel (4b) and block the rotation of the specified elastic element (1A) around the specified axis of attachment (4i). 14. The device according to claim 4, characterized in that the spiral elastic element (1a) is fixed between the extensions (4n, 4p) of the two half flanges (4l, 4m) attached to the barrel (4b) of the crossbow body (4) via the mounting axis (4i ) with a non-cylindrical profile, interacting, on the one hand, with a hole (1c) of a complementary shape formed at the first central end (1b), and, on the other hand, with fixing means (4j), which makes it possible to fix the spiral in the axial position elastic element relative to the longitudinal axis of the specified barrel (4b) and block the rotation of the specified elastic element (1A) around the specified axis of attachment (4i). 15. The device according to p. 13 or 14, characterized in that the spiral elastic element (1a) is placed in the axial direction between the extensions (4n, 4p) of the two half flanges (4l, 4m) so that the second end (1d) is placed in the longitudinal axis of the barrel (4b) of the crossbow body (4). 16. The device according to p. 15, characterized in that the second end (1d) of the spiral elastic element (1a) is attached to one of the ends of a single multicore thread (3rd), forming a bowstring (3), while the other end of the specified a single (3rd) thread is connected to the pushing device (5). 17. The device according to p. 16, characterized in that the pushing device (5) in the transverse direction has two guide protrusions (5a, 5b) interacting with the slots (4r, 4s), respectively formed in the half flanges (4l, 4m), so that guide and direct the indicated pushing device over the guide (4c) formed in the barrel (4b) of the crossbow body (4b) to simultaneously move the bowstring (3) from the idle position to the tensioned position and the spiral elastic element (1a) from the idle position to the compressed position . 18. The device according to claim 17, characterized in that the pushing device (5) has an emphasis (5c) perpendicular to the guides (5a, 5b) and protruding above the half flanges (4l, 4m), transmitting the driving force when the arrow or the shell is in contact with it. 19. The device according to claim 1, characterized in that the spiral elastic elements (1a) are respectively attached to each end of the frame (4t) of the base (4) of the bow by means of fixing axes (4i) with a non-cylindrical profile, interacting, on the one hand, with the hole (1c) a complementary shape formed at the first central end (1b), and, on the other hand, with fixing means (4j), which makes it possible to axially position each spiral elastic element and to block rotation of said spiral elastic elements (1a) around said axis th mounts (4i). 20. The device according to claim 5, characterized in that the spiral elastic elements (1a) are respectively attached to each end of the frame (4t) of the base (4) of the bow by means of fixing axes (4i) with a non-cylindrical profile, interacting, on the one hand, with the hole (1c) a complementary shape formed at the first central end (1b), and, on the other hand, with fixing means (4j), which makes it possible to axially position each spiral elastic element and to block rotation of said spiral elastic elements (1a) around said axis th mounts (4i). 21. The device according to p. 19 or 20, characterized in that the spiral elastic elements (1a) are located in the axial direction so as to fold in a vertical plane parallel to the front side (4w) of the frame (4t) so that every second end ( 1d) connected to the bowstring (3) was substantially oriented towards the gripping handle (4u) formed on the said frame (4t).

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