IT201900007710A1 - ARC TYPE LAUNCHING TOOL - Google Patents

Description

ARC TYPE LAUNCHING TOOL.

DESCRIPTION

The invention relates to a bow-type throwing tool.

Generally an arch includes:

- two limbs, or 'limbs', which represent the elastically deformable parts;

- two terminals, or 'tips', to which one end of a load rope is tied,

- a loading rope, through which the arrow is loaded and the bow is flexed, - a central part, or 'riser', typically rigid, which joins the limbs. On the central part there is typically a handle and an arrow rest.

Nowadays a type of bow is known and widespread, known in jargon as a 'compound bow', which has an eccentric type pulley system which allows to accumulate a greater amount of muscle energy in the limb system and to reduce by a percentage which normally ranges from 40% to 90% of the effort when the bow is drawn.

The term 'let-off' indicates that effect, generated by the mechanism, which allows you to pull the wire or string of a compound bow or similar, reaching the complete opening of the bow with a visibly reduced muscular effort compared to to the traditional bow, as well as allowing the shooter to remain with reduced effort in an open bow aiming position.

The let-off is measured with a percentage that represents the reduction value of the effort necessary to keep the arc completely open; giving an example, to keep open a bow loaded at 60 pounds with a let-off of 70%, we must exert an effort equal to only the remaining 30% of 70 pounds or 18 pounds.

The let-off, obtainable with the first compound bows with percentages from 35% to 50%, has significantly increased over the years and it is currently normal to find bows with 80% let-off percentages.

The compound bow therefore allows to transmit to the arrow a greater amount of energy, therefore greater speed, compared to a bow, with the same load, traditional, or recurve or longbow, and to be more accurate in the aiming phase.

Such compound bows, although widespread and popular, have some limitations.

A first limitation of such known bows consists in the fact that in order to vary the load capacity of a bow beyond a certain range it is necessary to replace the limbs, where possible, and to adjust the preload of the limbs themselves.

These operations are often cumbersome and therefore difficult to carry out in a short time and without suitable equipment; above all, the replacement of the limbs requires having other different and adequate limbs and specific equipment available for the set-up of the bow with the new limbs.

A second limit of known bows is the let-off, which, although it has reached good levels nowadays, still determines an important physical effort to the shooter who needs time and stability to aim in the best possible way.

A third limit of known bows is the structural complexity of known compound bows, including pulleys, cams or other eccentric elements in addition to the central part and limbs, double wires placed side by side with the need to adopt a special wire separator, as well as components for assembling and regulating these components.

The aim of the present invention is to provide an arc-type throwing tool capable of obviating the aforementioned drawbacks and limitations of the known art.

In particular, an aim of the invention is to develop an arc-type throwing tool that is simpler and quicker to calibrate and adjust.

Another purpose of the invention is to develop a throwing tool with which a better 'let-off' than known bows can be achieved.

Another object of the invention is to develop a structurally simpler and easier to use bow-type throwing tool.

The above mentioned aim and objects are achieved by an arc-type throwing tool according to claim 1.

Further characteristics of the arc-type throwing tool according to claim 1 are described in the dependent claims. The aim and the aforementioned purposes, together with the advantages that will be mentioned below, are highlighted by the description of an embodiment of the invention, which is given, by way of indication but not of limitation, with reference to the attached drawing tables, where:

- Figure 1 represents a side view of a throwing tool according to the invention;

- figure 2 represents a rear view of the throwing tool of figure 1 according to the invention;

- figure 3 represents a sectional side view of a detail of the throwing tool of figure 1;

- Figure 4 represents a side view of the throwing tool according to the invention in an intermediate extension arrangement;

figure 5 represents a side view of a detail of figure 4;

figure 6 represents a detail of figure 5;

- Figure 7 represents a side view of the throwing tool according to the invention in a position of maximum extension;

figure 8 represents a side view of a detail of figure 7;

figure 9 represents a detail of figure 8;

- Figure 10 represents a first variant of the tool according to the invention;

Figure 11 represents a sectional side view of the first embodiment variant of Figure 10;

- Figure 12 represents a phase of use of the first variant of the launching tool according to the invention;

- Figure 13 represents a side view of a second variant embodiment of a launching tool according to the invention;

- figure 14 represents a phase of use of the tool of figure 13;

- Figure 15 represents a variant of a detail of a throwing tool according to the invention;

- figure 16 is a section view of the detail of figure 15;

- Figure 17 represents a side view of a throwing tool according to the invention in one of its embodiments in a rest position;

- figure 18 represents the same view of figure 17 in section; - Figure 19 represents a side view of a throwing tool according to the invention in the variant embodiment of Figure 17, in a position of maximum extension.

With reference to the aforementioned figures, an arc-type throwing tool according to the invention is indicated as a whole with the number 10. Said arc-type launching tool 10 comprises a central body 11, a nocking cord 12 for a arrow, and elastic energy accumulation means 13 activated by the traction of the string 12.

The peculiarity of the arc throwing tool 10 according to the invention lies in the fact that the elastic energy storage means 13 include:

- two opposite primary levers 14 and 15 connected with hinging means 16 to the central body 11; the nocking cord 12 is bound by its opposite ends 12a and 12b to opposite free ends 17 and 18 of the primary levers 14 and 15,

- two opposed axial action thrust accumulators 19 and 20 respectively, defined on the central body 11,

- loading means 21 of said axial action thrust accumulators 19 and 20, which loading means 21 are configured to induce a compression in the thrust accumulators 19 and 20 following a traction of the nock string 12.

The central body 11 comprises a predominantly longitudinal part 22.

The predominantly longitudinal part 22 is configured so as to define a handle 23 and an arrow rest area 24. The central body 11 also comprises two opposite frames 25 and 26 each defining a window, inside each of which windows are placed a corresponding thrust accumulator 19 and 20. The 'front side' is defined as the side of the launching tool 10 facing the direction of the exit of a shot arrow, and the opposite side of the same launching tool 10 is defined as the 'rear side' .

The central body 11 comprises hinging appendages 27 and 28 respectively.

These hinging appendages 27 and 28 extend from the rear side of the central body 11.

These hinging appendages 27 and 28 extend from the central body 11 in correspondence with the frames 25 and 26.

In the present embodiment, obviously not limiting the invention, these hinging appendages 27 and 28 have a trilateral shape.

The nocking string 12 for an arrow can be constituted by a single thread or alternatively by a braid of threads, and in any case it is to be understood as a known type of string.

In the form of the invention described here, to be understood as an example and not a limitation of the invention itself, each of the two opposing primary levers 14 and 15 comprises an 'L' body.

Each primary lever 14 and 15 comprises a free end 17 and 18 respectively and an opposite pivot portion 29 and 30. Each pivot portion 29 and 30 is designed to connect, by means of the hinging means 16, to a corresponding hinging appendage 27 and 28 of the central body 11.

Each primary lever 14 and 15 has a transmission appendage 17a and 18a respectively, equipped with a support element for the nocking rope 12 when the launching tool 10 is in the rest position, as shown in figures 1, 2 and 3.

Said support element 17b and 18b can be constituted, for example, by a bearing, or by a simple pin, or other cylindrical or disc-shaped element, fixed or rotatable around its main axis. The hinging means 16 comprise a pin 31, clearly visible in particular in Figure 6; this pin 31 is connected to the central body 11, and in particular to the respective hinging appendix 27 or 28, by means of friction reduction means of a known type, such as two rolling bearings.

In the variant embodiment of the invention described here by way of non-limiting example of the invention itself, each of the thrust accumulators with axial action 19 and 20 respectively, includes at least one compression load spring.

In particular, in the present embodiment, an axial action thrust accumulator 19 and 20 comprises a plurality of cup springs 40, arranged in series with each other, as clearly visible in Figure 3.

Again in particular, in the present embodiment, the thrust accumulator 19 and 20 comprises at least two groups of load springs 40 and 41, for example three groups of load springs 40, 41 and 42.

Advantageously, these groups of load springs 40, 41, 42 have differentiated stiffnesses.

A thrust accumulator with axial action 19 and 20 comprises a fixed head 43 at one end and a movable head 44 at the opposite end.

The thrust accumulator with axial action 19 and 20 includes a rod 45, translatable in the direction of its own X axis, to which the movable head 44 is constrained.

The above indicated at least one compression load spring is centrally crossed by a stem; for example, the groups of load springs 40, 41 and 42, are centrally crossed by the rod 45. The rod 45 has a maneuvering end 45a, available for connection with the loading means 21.

The loading means 21, configured to induce a compression in the thrust accumulators 19 and 20 following a traction of the nocking cord 12, are described below as an example of implementation in any way limiting the invention.

Such loading means 21 comprise:

- a load wire 47, which is fixed at one end to the central body 11 and at the opposite second end to a corresponding primary lever 14 or 15;

- a system of pulleys configured to cause a translation of the rod 45, out of the frame 25 or 26, following a traction of the load wire 47.

This pulley system includes, for example, two pulleys, a first pulley 48 pivoted to the maneuvering end 45a of the rod 45, and a second pulley 49 pivoted to the central body 11.

In particular, the loading wire 47 is fixed at one end to a fixed pin 50, integral with the central body 11, and at the second end to a movable pin 51, which is instead rotatably constrained to a corresponding primary lever 14 or 15.

The traction of the nocking cord 12 by a user determines the simultaneous rotation in a load direction of the primary levers 14 and 15.

The rotation of the primary levers 14 and 15 in the respective load direction causes the rotation of the movable pins 51, each integral with a primary lever 14 and 15, according to a trajectory away from the corresponding fixed pin 50.

This movement of the movable pins 51 causes the traction of the load wires 47 and, by means of the pulleys 48 and 49, the translation of the stems 45 out of the respective frames 25 and 26.

The translation of the stems 45 causes the moving heads 44 to approach the respective fixed heads 43 of the thrust accumulators 19 and 20 and therefore the loading of the thrust accumulators 19 and 20.

The thrust accumulators 19 and 20 are said to have axial action since once brought into compression they operate a thrust in the direction of their own main axis X.

In particular, in the present embodiment, the thrust accumulators with axial action 19 and 20 are advantageously coaxial with each other.

The thrust accumulators 19 and 20 each have only one degree of freedom in one direction, which is a vertical direction in the exemplary figures, indicated by the X axis, of the crushing of the pack of Belleville washers placed in series with each other.

Also each of the primary levers 14 and 15, with respect to the central body 11, has only one degree of freedom or can only rotate around the axis identified by the cylindrical seat where the rolling bearings are housed.

The thrust force exerted by each of the thrust accumulators 19 and 20, or by the compressed cup springs described in the present embodiment, is transmitted from the central body 11 to the primary levers 14 and 15 through the load wire 47.

This force tends to rotate the primary levers 14 and 15 towards the front side of the launching tool 10, opposing any rotation of the same primary levers 14 and 15 in the opposite direction.

The rotation of the primary levers 14 and 15 in the direction indicated below as 'discharge direction', that is towards the front side of the throwing tool 10, ends when the rope 12 resting on the support elements 17b and 18b reaches the rest position, as shown in figures 1 to 3.

The nocking cord 12 is fixed at its ends to corresponding locking pins 60, which are free to rotate around their own axis with respect to the primary lever 14 or 15 which carries them.

The primary levers 14 and 15 rotate until the nocking string 12 is fully extended as exemplified in Figure 7.

The load of the springs, partially or completely compressed, creates a tension both on the loading wire 47 and on the nocking cord 12. Figure 3 shows a first variable lever arm A of the loading wire 47 and a second lever arm variable B of the nocking string 12.

Observing the system from this point of view, the primary levers 14 and 15 rotate in the unloading or loading direction according to whether the torque exerted by the thrust accumulators 19 and 20 exceeds or is lower than the torque exerted by the nock string 12.

Figures 4 to 6 show an intermediate set-up of use of the launching tool 10 according to the invention.

In this intermediate position, the nocking string 12 is pulled with a force applied to the nocking point P, which is to be understood as positioned in the middle of the nocking string 12.

The torque exerted by the nocking cord 12, pulled at point P by the hand of a user, possibly by means of special tools of the known type referred to in the sector with the term 'releases', on each of the primary levers 14 and 15, is greater than the torque achieved by the thrust accumulators 19 and 20, whereby the primary levers 14 and 15 rotate in the load direction, favoring the removal of the nock point P from the central body 11.

The stems 45 of the thrust accumulators 19 and 20 tend to be extracted from the respective frames 25 and 26, moving towards the respective maximum extraction position. Consequently, the disc springs, stacked in series on these stems 45, tend to flatten more and more, increasing the quantity of elastic energy accumulated more and more. The variable lever arms A and B vary according to the rotation of the corresponding primary lever 14 or 15; in particular, the first lever arm A, of the loading wire 47, tends to decrease while the second variable lever arm B, of the nocking cord 12, tends to increase, as can be clearly seen by comparing Figures 3, 4 and 6, with a multiplier effect that allows to accumulate a high level of elastic energy when compared to the pulling force at point P of the nocking string 12.

Figures 7 to 9 show the launching tool 10 according to the invention in its position of maximum extension.

In this setting, the primary levers 14 and 15 have reached their respective final maximum load position; in fact, each lever 14 and 15 rests against an abutment portion 11a of the central body 11 so that it cannot rotate further in the load direction, regardless of the force created on the nocking cord 12. The stem 45 of each accumulator 19 and 20 has reached the maximum design extraction position and the relative springs 40, 41 and 42 reach their maximum design nominal compression and, consequently, exert their maximum design force.

The variable lever arms, first arm A of the load wire 47, clearly visible in figure 9, and second arm B of the nocking cord 12, indicated in figure 7, reach their final size upon completion of the design extension.

In particular, the distance of the axis of the loading wire 47 with that of the rotation axis of the pin 31 approaches zero, while remaining greater than zero to allow rotation in the unloading direction once the force which it generates the extension, i.e. at the moment of the release of the rope 12 by the user.

This situation is determined thanks to an outlet 31a made on the rotation pin 31 of each lever 14 and 15, and clearly visible in Figures 6 and 9, so that, when a primary lever 14 and 15 is in the position of maximum extension of the launching tool 10, the axis of the loading wire 47 almost intersects the axis of rotation of the pin 31. The discharge 31a is also made in such a way that the distance of the axis of the loading wire 47 with respect to the axis rotation of the pin 31 is always greater than zero. In fact, the loading wire 47 rests on the cusp of the unloading 31a which is, from the center of rotation, a distance less than the radius of the loading wire 47 itself, thus ensuring that the distances between the axes are always greater than zero.

Once the draw force is zeroed, at the release of the arrow nocked to the string 12, the torque created by the nocking string 12 is equal to zero while the force of the thrust accumulators with axial action 19 and 20 is greater than zero and therefore the levers 14 and 15 move in the unloading direction, reaching the rest position of figures 1, 2 and 3.

The combination of the variable lever arms A and B during the loading phase is such that, depending on the extension, the force necessary to achieve this extension has a trend represented by the graph below, where the abscissa is indicated extension in millimeters, and in ordinate the force to achieve this extension expressed in Newton.

This trend is an example, as there are many possible variations of the trend of the graph below.

This trend shows how the let-off at maximum extension is very low and the reduction of the load effort is reduced by over 90%.

The thrust accumulators 19 and 20 of the invention have the following advantages:

- thanks to the coaxial and opposite position, at the end of the return stroke the blocking forces of the two accumulators 19 and 20 are opposite and cancel each other; in this way the perturbation on the system, when the limit switch is reached, is very low;

- in bows with known types of limbs, the load on the bow can be varied either by replacing the limbs, thus passing from one predefined level to another, or by adjusting the preload of the same; thanks to the launching tool 10 according to the invention by varying the type and size of the load springs that make up the accumulators 19 and 20 it is possible to vary the load gradually, and by varying the quantity of the springs it is possible to obtain a more customized;

- the eventual breakage of a spring still allows the operation of the launching tool 10, contrary to the known type of limb arches;

- the preload, or the load on the load wire 47 in the rest configuration, can be easily varied by acting on a nut 80 which closes the springs on the stem 45.

As mentioned above, the first variable lever arm A of the load wire 47 is determined by the distance between the axis of the load wire 47 itself and the axis of the unloaded pin 31 of the corresponding primary lever 14 or 15.

In the example described and illustrated here, the unloaded pin 31 rotates integrally with the primary lever 14 or 15, but alternatively the pin 31 can be integral with the central body 11. In this case the lever 14 and 15, equipped with suitable bearings, would rotate around to its pin 31.

The variable lever arm A of the loading wire 47 is reduced to almost zero when the lever 14 and 15, by rotating, reaches the position of maximum extension. This occurs because the loading wire 47 is fixed to a movable pin 51 which is integral with the lever 14 and 15 itself.

When the lever 14 and 15 is rotated, the mobile pin 51 rotates around the center of rotation of the pin 31 of the lever 14 and 15, moving into a position such that the axis of the load wire 47 almost coincides with the axis of rotation.

The unloading 31a of the pin 31, in addition to allowing the lever arm to be almost zeroed, ensures that this is always greater than zero. In fact, the mechanical processing of the unloaded surface of the unloading 31a is done in such a way that the distance between the cusp and the axis of rotation is less than the radius of the loading wire 47 itself.

This configuration allows to achieve final load reductions, or the 'Let-Off ratio' values, which are higher than those of the systems on the market.

As mentioned above, each of the primary levers 14 and 15 is connected to the central body 11 by means of the unloaded pin 31, which rotates rigidly with the respective lever 14 and 15, and by means of two rolling bearings which allow the rotation of the lever with friction close to zero. .

The rolling bearings are connected on one side to the lever 14 or 15 while on the other side they are connected to a seat defined on the central body 11, for simplicity not shown. A rubber body is interposed between the seat on the central body 11 and the bearing, for example one or more O-rings, for example in NBR plastic material; the presence of such rubber bodies has the following advantages:

- reduces the vibrations generated by the nocking string 12 when this is released and returns to the rest configuration after the loading phase,

- reduces the cost of machining the bearing seat because the tight coupling tolerances typical of bearing seats are not required.

With 'total extension' or 'Draw Length' we mean the distance between the handle and the nocking point of an arrow.

The final position of the primary levers 14 and 15 is defined by the design, since the central body 11 has, as mentioned, an abutment portion 11a which blocks the rotation of the levers 14 and 15 themselves.

From this point, by selecting the length of the nocking string 12, the desired length is obtained.

In current systems, the definition of the draw length is achieved through a cam device with discrete adjustments which allows, for the same components, to obtain a limited range of adjustment of the draw.

Sometimes this adjustment requires the use of a dedicated tool, known as a 'bow press' to change the attachment position of the nocking string.

With the present invention, by simply modifying the length of the nocking string 12 it is possible to obtain an almost continuous variation of the draw length from a maximum to a minimum value (these values are related to the size of the primary levers 14 and 15). Furthermore, by using the same nocking string 12 we can obtain discretized extension variations.

This is achieved, as exemplified in the variant embodiment of Figures 10, 11 and 12, by means of a discretization insert of the extension 90. This discretization insert of the extension 90 is fixed in a hole 91x chosen from a plurality of aligned holes 91 defined on each of the primary levers 14 and 15.

By keeping the same nocking string 12 of predetermined length, and simply by choosing a 91x hole and fixing the string 12 to the insert 90 and then the insert to the hole 91x, it is possible to modify the performance of the throwing tool 10 in numerous ways according to the needs and technical requirements of the user. In an embodiment variant of the throwing tool according to the invention, not illustrated for simplicity, the loading wire and the nocking rope are both of a single wire or a single rope.

The launching tool 10 according to the invention allows for a very wide and refined variation of the load curve.

In particular, while the current technology allows a percentage of lightening of the shot in the final position (Let Off) in the range 70 ÷ 90%, the throwing tool 10 according to the invention allows to easily reach a Let-Off higher than 90% , thus guaranteeing the archer greater relaxation during the aiming phase before shooting the arrow.

Furthermore, the ratio between accumulated elastic energy and maximum shooting force is about double that currently declared by current technology, which allows to increase performance with the same effort for the archer or reduce the effort for the archer for the same. of performance, facilitating, for example, endurance in shooting competitions.

A further advantage achieved by the launching tool 10 according to the invention is given by the fact that the configuration of the same launching tool 10 allows to eliminate the connection cables of the pulleys thus allowing greater visibility and better maneuverability for the archer.

Furthermore, it does not require the use of dedicated systems, such as adjustment benches - bow press, for the adjustment of the archery and its extension.

Further, with the launching tool 10 according to the invention, the configuration of the load chart can be easily adapted to the needs of the archer by acting, as already mentioned, on the configuration of the accumulators 19 and 20, or the packs of cup springs.

Furthermore, by acting on the pulleys 48 and 49 and on the other mechanical members of the loading wire mechanism 47, the desired Let-Off can be obtained.

The same let-off variation can be obtained by varying the final end-of-stroke position of the levers 14 and 15.

As mentioned above, the variation of the extension of the throwing tool 10 can be achieved in two ways:

- varying the length of the nocking string 12, choosing a string 12 having the preferred length,

- using the extension discretization insert 90; by varying the position of this insert 90 in the holes 91, with the same length of the wire, the elongation is varied in a discretized manner.

In a variant embodiment of the invention, the thrust accumulators with axial action 119, thus indicated in figures 15 and 16, are of the magnet type.

These magnet thrust accumulators 119 have two magnets or electromagnets 140 and 141, one of which is fixed to a fixed head 143 and the other mobile and supported by a movable head 144; the movable head 144 is fixed to the rod 145 which is in turn translated by the loading means 21 as described above.

By placing the magnetic poles in opposition and bringing them closer to each other, it is possible to achieve the same dynamic action done by the springs.

In a further variant embodiment of the invention, exemplified in Figures 13 and 14, each of the ends of the nock string 12 is fixed to an intermediate rod 99, which in turn is pivoted to a corresponding locking pin 60 as described above. .

This intermediate rod 99 is of such length as to rest on the support element 17b and 18b of the respective primary lever 14 and 15 in the rest position.

This intermediate auction 99 is rigid.

The application of this intermediate rod 99 allows the adoption of a shorter nocking cord 12, therefore less expensive, and also reduces the vibrations of the nocking cord 12 itself.

In a further embodiment of the invention, also not illustrated for the sake of simplicity, the bow-type throwing tool comprises a leaf spring structure, i.e. also comprising a grip shaft and loading and release mechanisms for a body to be thrown .

Figures 17 to 19 show a different variant of the launching tool according to the invention, indicated therein as a whole with the number 110.

In this variant embodiment, which is also obviously exemplary and non-limiting of the invention itself, each of the two opposing primary levers 114 comprises a shaped body with a circular sector. Each primary lever 114 includes a pivot portion 129 defined at the axis of the profile of the body shaped in a circular sector.

Each pivot portion 129 is designed to connect, by means of the hinging means 16 as described above, to a corresponding hinging appendage 27 of the central body 11, also similarly to what has already been described for the previous variant embodiment of figures 1 to 16.

Each primary lever 114 has a curved perimeter edge 117a, equipped with a support groove 117b for the nocking cord 12 when the throwing tool 110 is in the rest position, as shown in figures 17 and 18.

Similarly to what has been described above, the loading wire 47 is fixed at one end to a fixed pin 50, integral with the central body 11, and at the second end to a movable pin 151, which is instead rotatably constrained to a corresponding primary lever 114 .

Also in this embodiment variant the launching tool 110 includes a discretization insert of the elongation 190.

This discretization insert of the elongation 190 is fixed in a hole 191x chosen from a plurality of aligned holes 191 defined on the curved perimeter edge 117a of each of the primary levers 114.

The operation of this embodiment variant is similar to the operation of the variants described above.

In practice it has been found that the invention achieves the intended aim and purposes.

In particular, the invention has provided a throwing tool of the bow type which is simpler and quicker to calibrate and adjust than known bows.

Furthermore, with the invention a throwing tool has been developed with which a better 'let-off' is achieved than with known bows.

In addition, with the invention a structurally simpler and easier to use bow-type throwing tool has been developed.

The invention thus conceived is susceptible of numerous modifications and variations, all falling within the scope of the inventive concept; moreover, all the details can be replaced by other technically equivalent elements.

In practice, the components and materials used, as long as they are compatible with the specific use, as well as the contingent shapes and sizes, may be any according to the needs and the state of the art.

Where the characteristics and techniques mentioned in any claim are followed by reference signs, these reference signs are to be understood as affixed for the sole purpose of increasing the intelligibility of the claims and consequently such reference signs have no limiting effect on the interpretation. of each element identified by way of example by such reference signs.

Claims (10)

CLAIMS 1) Bow-type throwing tool (10), comprising a central body (11), a nocking string (12) for an arrow, and elastic energy storage means (13) activated by the traction of said string (12) ), characterized by the fact that said elastic energy storage means (13) comprise: - two opposite primary levers (14, 15) connected with hinging means (16) to said central body (11), said nocking cord (12) being constrained by its opposite ends (12a, 12b) to opposite free ends ( 17, 18) of said primary levers (14, 15), - two opposed thrust accumulators with axial action (19, 20), defined on said central body (11), - loading means (21) of said thrust accumulators with axial action (19, 20) configured to induce a compression in said thrust accumulators (19, 20) following a traction of said nock cord (12). 2) Launching tool according to claim 1, characterized in that said central body (11) comprises two opposite frames (25, 26) each defining a window, inside each of which windows there is a corresponding thrust accumulator ( 19, 20). 3) Launching tool according to one or more of the preceding claims, characterized in that said central body (11) comprises hinging appendages (27, 28). 4) Launching tool according to one or more of the preceding claims, characterized in that each primary lever (14, 15) comprises a free end (17, 18) and an opposite pivot portion (29, 30). 5) Launching tool according to one or more of the preceding claims, characterized in that said hinging means (16) comprise a pin (31). 6) Launching tool according to one or more of the preceding claims, characterized in that each of said thrust accumulators with axial action (19, 20) comprises at least one compression load spring. 7) Launching tool according to one or more of the preceding claims, characterized in that a said thrust accumulator with axial action (19, 20) comprises a plurality of cup springs (40), arranged in series with each other. 8) Launching tool according to one or more of the preceding claims, characterized in that said thrust accumulator with axial action (19, 20) comprises at one end a fixed head (43) and at the opposite end a movable head (44 ), a said thrust accumulator with axial action (19, 20) comprising a stem (45), translatable in the direction of its own axis (X), to which said movable head (44) is constrained. 9) Launching tool according to one or more of the preceding claims, characterized by the fact that said stem (45) has a maneuvering end (45a), available for connection with the loading means (21). 10) Launching tool according to one or more of the preceding claims, characterized in that said loading means (21) comprise: - a load wire (47), which is fixed at one end to the central body (11) and at the opposite second end to a corresponding primary lever (14, 15); - a pulley system configured to cause a translation of said stem (45), out of the frame (25, 26), following a traction of the load wire (47).