KR20050028865A - Device for correcting the trajectory of projectiles in a weapon replica - Google Patents

Abstract

A trajectory correcting device of a projectile for an arm replica is provided to compensate the trajectory of the plastic projectile vertically or horizontally by arranging two rubber pins symmetrically at both sides of a vertical shaft passing a center of a cannon, and to improve accuracy by adjusting height of a boss of the cannon. A trajectory correcting device of a projectile discharged from a cannon of an arm replica is composed of a first pin(3d) with a first boss(6d) for containing the projectile of the cannon and a second pin(3g) with a second boss(6g) for containing the projectile of the cannon. The first pin and the second pin are placed over a horizontal axis passing a center of the cannon, and symmetrically arranged at both sides of a vertical axis. Height of the first boss or the second boss of the cannon is adjusted, and the first and second pins are composed of adjusting knobs(5d,5g) and screws(4d,4g).

Description

DEVICE FOR CORRECTING THE TRAJECTORY OF PROJECTILES IN A WEAPON REPLICA}

The present invention uses an "air soft gun" to fire a very light plastic ball with a diameter of about 6 millimeters. Or "soft air ??" A device for correcting the trajectory of a projectile of a type weapon replicator. More specifically, the present invention relates to a device for correcting the trajectory of a plastic projectile exiting a cannon of an inorganic replicator. The ballistic correction of the projectile can be done equally vertically or horizontally on an elongated weapon or short arm replicator.

The invention is applicable to the field of spring loaded or electric long arms, in particular long arm replicators such as electric rifle.

The invention applies in particular to inorganic replicators in which the projectile is a ball of plastic material. The invention is also applicable to small arm replicators.

In the field of weapon replicators, various models of firearms are being replicated for the purpose of producing toys for adults and / or children. These weapons referees are weapons that fire plastic projectiles, such as plastic balls, instead of real weapon balls or lead bullets. In this case, the inorganic replicator has the drawback resulting from the manufacture of the replicator itself. This flaw, located in the shooting system or cannon, causes the projectile to deflect during discharge from the weapon. For example, exiting the weapon, the projectile may be deflected left or right, or even singly or downwardly. In practice this drawback is inevitable and is simply due to manufacturing tolerances. In particular, these shortcomings are acute in long weapon replicators of long rifle type. In fact, the general public understands that the farther the projectile covers, the more significant the projectile trajectory deflection is.

Currently, in the longest weapon replicators, no corrections are made to the projectile trajectory.

However, a system exists for vertically correcting the trajectory of the projectile exiting the cannon of the weapon replicator. HOP UP? This system consists of rubber pins disposed inside the inorganic replicator at the vertical entrance of the center of the canon. More specifically, the rubber pin is located at the top of the canon on a vertical axis that intersects with the center of the inorganic canon. This rubber pin has the function of holding and orienting the projectile. Indeed, this rubber pin holds some of the projectiles projecting by the shooting system before being ejected from the weapon cannon. The action of holding the projectile while exiting the canon provides a rotational effect on the projectile's exit trajectory. This rotation effect consequently raises the projectile, i.e., changes the projectile trajectory upward. However, the weight of the projectile itself offsets the planned rise in projectile trajectory, which generates a horizontal trajectory of the projectile in a short time after being discharged from the canon.

As can be seen from the above description, the HOP UP system allows only vertical correction of the projectile trajectory. In this case, as mentioned above, a manufacturing defect of the inorganic replicator can cause ballistic defects both vertically and horizontally.

It is an object of the present invention to solve the above disadvantages of the system. For this purpose, the present invention proposes a device for correcting the trajectory of a projectile exiting a cannon of an electric long arm, which correction can be both vertical or vertical and horizontal. To this end, the device of the present invention places two rubber pins located symmetrically on either side of the vertical axis passing through the center of the canon.

More specifically, the invention relates to an apparatus for correcting the trajectory of a projectile exiting a cannon of a referrer, comprising a first pin forming a first boss holding a projectile at a canon.

And a second pin forming a second boss to hold the projectile at the canon, wherein the first and second pins are symmetrically positioned on both sides of the vertical axis passing through the center of the canon.

Preferably, the heights of the first and second bosses of the canon are adjustable so that all adjustments to the effect given to the ball can be made to optimize shooting accuracy.

1 is a front view showing a cross section of a canon of an electric long arm replicator, such as a rifle replicator. Such electric long arm replicators are more simply called arm or arm replicators and are equipped with the ballistic correction device of the present invention. In Fig. 1, reference numeral 1 denotes an arm cannon. The canon includes an inner side 1i and an outer side 1e. The canon joint 2 is attached to this canon along its inner surface 1i. The canon joint 2 is usually comprised with elastic materials, such as rubber | gum.

The point C shown in the center of the canon represents the geometric center of the canon through which the vertical axis XX and the horizontal axis HH pass.

According to the present invention, the cannonball 1 is equipped with a projectile trajectory correction device. The device comprises a first pin 3d (right pin) and a second pin 3g (left pin), which respectively form a first boss 6d and a second boss 6g inside the canon 1. do. These pins 3d, 3g are arranged symmetrically on both sides of the vertical axis XX, on the horizontal axis HH. In the embodiment of Figure 1, the pins 3d, 3g are arranged at an angle of about 40 ° with respect to the vertical axis XX.

The screws of the pins 3d and 3g cross the canon 1 and are introduced into the canon. The screw may also be introduced across the support of the canon and the canon itself. In the latter case, the adjustment knob may be placed near the target of the weapon replicator. This allows the launcher to easily adjust the height of the bosses while continuously aiming at the target.

In the embodiment of Fig. 1, each pin 3d, 3g comprises screws 4d, 4g which enter the joint 2 of the canon and form bosses 6d, 6g by pressure on the joint. In this embodiment, knobs 5d and 5g are formed at the top of each of the screws 4d and 4g to adjust the height of the screw entering the joint 2. Thus, when each screw is tightened to the canon 1 for some time, it enters the joint 2 for some time to form a boss that can be of any size.

Thus, the height adjustment system of the boss is rotary.

Moreover, the height of each boss is adjusted by height adjustment to the joint 2 of each screw. Thus, the bosses 6d and 6g can have the same height or vice versa.

The function of each boss is to hold the projectile to some extent when the projectile exits the cannon. This holding allows the trajectory of the projectile exiting the canon to be changed. Different boss heights allow you to change trajectory horizontally. In addition, the boss can change the projectile vertically. By varying the height of the boss, the trajectory of the projectile can be changed horizontally, ie right or left. Indeed, when the boss has a low height, the effect on the projectile is reduced during the passage of the projectile, and conversely, when the boss is high, the effect on the projectile during its passage is increased.

If the bosses 6d and 6g have the same height, that is, when the knob of the pin 3d and the knob of the pin 3g are equally adjusted, the trajectory of the projectile does not change horizontally; Compensation only in the vertical plane. On the other hand, if the bosses 6d and 6g have different heights, this will affect the trajectory of the projectile in the horizontal and vertical planes.

In particular, if the left boss 6g is higher than the right boss 6d, the shooting is oriented leftward. Conversely, if the right boss 6d is higher than the left boss 6g, the shooting is directed to the right.

An example of a firing orientation is shown in FIG. More specifically, Fig. 2 shows a target in which three projectile shots were executed.

The result of the first shot T1 indicates that the projectile was corrected only vertically. Therefore, the right boss 6d and the left boss 6g are the same case.

The result of the second shot T2 is oriented to the right of the vertical axis XX. This indicates that the height of the right boss 6d was higher than the left boss 6g.

In contrast, the result of the third shot T3 is located to the left of the vertical axis XX. This indicates that the height of the left boss 6g was higher than the right boss 6d.

2 shows that the trajectory of the projectile can be changed in the horizontal and vertical planes by changing the heights of the bosses 6d and 6g. By correcting the projectile trajectory in the whole space, it can be seen that the defects in the trajectory of the weapons referrers can actually be corrected.

3A is a side view showing a second embodiment of the apparatus of the present invention. In this embodiment, reference numeral 8 is an adjustment pin. The adjusting pin 8 is made of a plastic material such as rubber and comprises a lug 9 mounted on an elastic strip 10 of metal, for example. The lug 9 is fixed to one of the extremes of the elastic strip 10 by any fastening means, such as sticking or drilling. The elastic strip 10 is fixed to a control rod 11 of a certain length, for example half of the length, of metal or the like.

An orifice 13 is formed in the canon 1 to allow passage of the lug 9. The lug 9 is retained at the position of the orifice 13, selected by the launcher. Thus, the lug 9 forms a boss inside the cannon of the weapon. The height of this boss is controlled by the control rod 11 associated with the elastic strip 10. More specifically, the elastic strip 10 holds the lug 9 completely in the orifice 13 to some extent. For this purpose, the elastic strip 10 extends from the control rod 11 on which the strip is fixed. Thus, as the control rod is pulled further towards the launcher, the elastic strip 10 extends further and the lug 9 is introduced less fully into the orifice 13, thereby shortening the boss. Conversely, if the control rod is pushed further towards the canon support 7, the elastic strip 10 is loosened and the lugs 9 more fully enter the orifice 13 to make the boss larger. Thus, when the control rod 11 is pushed to the maximum towards the canon 1, the elastic strip 10 is located on the outer side of the canon 1 and consequently the lug 9 to the inside of the canon 1. With the protruding entry and being able to be fired by the flexibility of the elastic strip, the boss has a maximum height without any risk of blocking a slightly larger ball. On the other hand, when the control rod 11 is pulled up towards the launcher, the elastic strip 10 is stretched to the maximum (as shown in FIG. 3A), thereby causing the lug to rise to the maximum at the orifice 13, The boss is not formed.

To facilitate this pushing or pulling operation of the control rod 11, the control rod may comprise a lever 12 which can be an extension of the control rod, for example folded along a 90 ° angle with respect to the horizontal axis HH. In this case, as shown in FIG. 3B, the lever 12 intersects the elliptical orifice 15 formed in the frame 14 of the weapon.

By pushing or pulling the lever 12 for some time, the launcher acts directly at the height of the boss formed by the lug 9. In this embodiment a linear height adjustment system of the boss is obtained. This linear adjustment has the advantage of making the measurement by the launcher easier. In fact, the lever 12 can be seen at the elliptical orifice 15 so that the launcher can visually know the level of the boss, i.e. the boss can perceive all levels of zero, low, average, high, maximum and middle of the boss. Can be.

3A and 3B show a single boss and a single height adjustment system of the boss. Of course, like the first embodiment (shown in Figure 2), the ballistic correction device according to the second embodiment also includes two symmetrical bosses, the height of each boss being a separate control system (control rod, elastic strip, etc.) Is adjusted by.

Whichever embodiment is selected, the ballistic correction device is disposed immediately after the position at which the projectile protrudes outward from the entrance of the cannon. In the first embodiment, the boss adjustment system is actually located outside of the weapon in the position where the projectile projects. In a second embodiment, the boss adjustment system can be placed at a selected position of the weapon, which is advantageous in that it can be transferred, ie close to the launcher.

In a variant of the invention, the ballistic correction device may become unadjustable. This makes it possible to equip weapon replicators economically. In this case, two bosses are located on the upper side of the canon on both sides of the axis XX. The two bosses 6d and 6g are identical to those shown in Fig. 1 except that their height is not adjustable. The boss is made of a hemispherical shape of a rubber material formed on the inner side of the canon 1. In this variant, during efficient rotation, the single boss retains the ball and better retains the ball than is known which can slightly move to the left or right of the shooting axis. Thus, the device reduces scattering of the shots, providing a better group of shots during a series of shots.

In another variant, the position of the bosses 6d and 6g on the inner side of the canon 1 is adjustable. This variant is shown in FIG. In this variant, the bosses are the same as those of the previous variant, and the correction device comprises a knob 16 fixed to the canon 1 at the same distance from the two bosses 6d and 6g. The canon (or part of the canon including two bosses) is free to rotate, and the knob 16 can pivot the canon 1 on the canon support 7, resulting in the bosses 6d and 6g being axial XX. You can move about.

It is possible to shoot to the left or the right side of the axis XX to be corrected by the rotation of all or part of the cannon to the left or the right side of the axis XX. That is, the ballistics of the ball can be horizontally corrected by the rotation of the canon.

1 is a cross-sectional view showing an embodiment of a ballistics correction device according to the present invention;

2 is a front view showing a second embodiment of the ballistic correction device of the present invention;

3a and 3b are side views of a target showing the impact of a projectile obtained for further adjustment of the apparatus of the present invention, and

4 is a cross-sectional view showing a modification of the trajectory correction device of the present invention.

Claims (11)

In the ballistic correcting device for a projectile discharged from a cannon of an inorganic replicator, comprising a first pin (3d) forming a first boss (6d) to hold a projectile of the canon, A second pin 3g forming a second boss 6g to hold the projectile of the canon, the first and second pins passing vertically through the center C of the canon, on a horizontal axis HH through the center of the canon; A ballistics compensator, which is located symmetrically on both sides of the axis XX. The ballistic correction device according to claim 1, wherein the heights of the first and second bosses of the canon are adjustable. The ballistic correction device according to claim 1 or 2, characterized in that the first and second pins comprise screws (4d, 4g) with adjustment knobs (5d, 5g), respectively. 4. The ballistic correction device according to claim 3, wherein each screw of the pin is pushed onto a joint made of an elastic material of the canon to form a boss. The ballistic correction device according to claim 1 or 2, characterized in that the first and second pins each comprise a lug (9) fixed on the elastic strip (10). 7. The ballistic correction device according to claim 5, wherein the canon includes an orifice (13) for each lug, which forms a passage of the lug. Ballistic correction device according to claim 5 or 6, characterized in that the elastic strip (10) is deformed by the control rod (11). The ballistic correction device according to any one of claims 5 to 7, wherein the lug is made of an elastic material. The ballistic correction device according to any one of claims 5 to 8, wherein the elastic strip is metal. 2. The ballistic correction device according to claim 1, wherein the position of the boss in the canon is adjustable. 11. The ballistic correction device of claim 10, comprising an adjustment knob fixed on the canon at the same distance from the two bosses.