JP5374725B2 - Bullet for toy gun - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To provide a bullet for a toy gun capable of improving straight-ahead moving property and accuracy in hitting of a spherical bullet made of synthetic resin used as the bullet of toy guns such as an air gun and a gas gun. <P>SOLUTION: A diameter of the resin spherical bullet 1 used in the toy gun is at least 7 mm, a plurality of recessed grooves 2 are formed on an outer periphery of the spherical bullet, and the diameter of the spherical bullet is ideally 8 mm. The recessed grooves formed on the outer periphery of the BB bullet are a plurality of linear recessed grooves or a plurality of dimples formed on the outer periphery of the BB bullet. <P>COPYRIGHT: (C)2009,JPO&amp;INPIT

Description

  The present invention relates to a resin toy gun bullet used as a bullet for a toy gun such as an air gun or a gas gun.

  An air gun or a gas gun is a type of toy gun that mimics a firearm (a gun, a rifle, a machine gun, or the like) that fires a bullet made of synthetic resin with low air pressure or low pressure gas. A spherical synthetic resin bullet used for such an air gun or a gas gun is generally called a BB bullet.

  By the way, the bullet conventionally used in the air gun or the gas gun is generally a BB bullet having a diameter of 6 mm (abbreviated as “6 mmBB bullet”). This 6mm BB bullet has a spherical outer diameter, so when the bullet is fired, if it jumps out of the muzzle with no rotation (actually gentle rotation) or irregular rotation state, not only the direction of travel but also the top, bottom, left and right As a result of the irregular air resistance, the direction of bullet movement is not fixed, and the accuracy of hitting is significantly deteriorated.

  There are two possible methods for solving this problem. The first method is to rectify the air resistance received from the front of the bullet by applying a backspin perpendicular to the direction of travel when the BB bullet is fired, and using this rectified air resistance as lift. is there.

  As a second method, the BB bullet is not spun at all, and the initial flight distance (bullet) of the bullet is adjusted by adjusting the gun potential, that is, the gun power and the clearance between the barrel and the BB bullet. For example, a certain distance (for example, a fixed distance of 5 meters) from the launch position. However, this method has a drawback that it is limited to a close range to the last because it receives a large amount of air resistance from the front of the bullet in the traveling direction.

  Moreover, as a prior art regarding the straight advanceability of the BB bullet as described above, there is a barrel structure of a toy gun as disclosed in Patent Document 1. The barrel structure of this document provides a slight gap between the inner circumference of the barrel and the outer circumference of the bullet to be fired, and a plurality of spiral grooves that spirally rotate the compressed gas passing through the gap are provided on the inner circumference of the barrel. The rotational force is forcibly applied to the bullet passing through the.

  In addition, the structure described in Patent Document 2 includes a pair of symmetrical rail portions along the axial direction on the upper inner surface of the barrel, and spherical bullets fired with an upward rotation from the launch device. By making contact with the pair of rail portions at two points, the lateral displacement is restricted, so that straightness is improved and the accuracy of hitting is improved.

However, any of the above-mentioned documents relate to the improvement of the gun, and it is currently impossible to find a technique that improves the straightness and accuracy by the structure of the bullet itself from the conventional documents. . This is because the conventional 6 mm BB bullet has a small diameter and is difficult to process, but a remarkable effect cannot be expected by the processing.
No. 7-3192 JP-A-9-280793

  The present invention has been made in view of the above circumstances, and for a toy gun that improves the straightness and accuracy of a spherical bullet made of synthetic resin used as a bullet of a toy gun such as an air gun or a gas gun. The purpose is to provide bullets.

  In order to achieve the above object, a bullet for a toy gun according to claim 1 of the present invention has a diameter of a resin spherical bullet used for a toy gun of at least 7 mm, and a plurality of concave grooves are formed on the outer periphery of the spherical bullet. It is characterized by that.

  According to the above bullet for a toy gun according to the present invention, the diameter of the resin spherical bullet used for the toy gun is at least 7 mm, and a plurality of concave grooves are formed on the outer periphery of the spherical bullet. The bullet groove acts as a gas vent, and the gas pressure from the back of the spherical bullet passes forward through the spherical bullet groove, pulling the spherical bullet forward by pushing away the air in front of the spherical bullet The power of gas pressure can be effectively exhibited.

  Also, after a spherical bullet is fired from the barrel, the lift acting on the spherical bullet hits multiple grooves and raises the lift, resulting in a far greater than conventional spherical bullets without grooves on the outer periphery As a result, a great lift force is exhibited, the deceleration of the spherical bullet is suppressed, the stability of the trajectory is increased, and the effect can be exhibited in terms of flight distance and accuracy.

  In addition, mold molding for forming a plurality of concave grooves on the outer periphery of a spherical bullet was impossible with the conventional 6 mm BB bullet, whereas in the present invention, it is a spherical bullet having a diameter of at least 7 mm. Is possible. Furthermore, regarding the visibility of the trajectory, the spherical bullet of the present invention looks much larger than the conventional 6 mm BB bullet, and the trajectory when used as a bullet such as an air gun or a gas gun is more visible than the conventional one. It becomes easy to reproduce the strength and force of a large caliber gun. Further, since it is a spherical bullet having a diameter of at least 7 mm compared to the conventional 6 mm BB bullet, the area of collision when hitting is enlarged and the impact force is reduced, so that the cardboard is penetrated as in the conventional case. It is possible to improve the safety when hitting a human without exerting such pressure.

  Embodiments of the present invention will be described below with reference to the drawings.

  The bullet for a toy gun according to the present invention has a resin spherical bullet 1 used for a toy gun having a diameter of at least 7 mm and a plurality of concave grooves 2 formed on the outer periphery thereof. As the concave groove 2 provided on the outer periphery of the spherical bullet 1, the one shown in FIG. 1 has three linear grooves (drawing a curve along the outer periphery of the spherical bullet 1) concave groove 2 (2 a 2b, 2c). In such a spherical bullet 1, each concave groove 2 is an outer peripheral position that draws the maximum outer diameter of the spherical bullet 1, and each concave groove 2 is formed at a position facing the three-dimensional direction.

  When the spherical bullet 1 is loaded into the toy gun chamber, it cannot be specified which direction the concave groove 2 of the spherical bullet 1 is directed, but the three concave grooves 2 (2a, 2b) as described above. 2c) is formed at a position facing the three-dimensional direction, so that any one of the three grooves 2 exhibits the following effects even when the spherical bullet 1 rotates in any direction. Become.

  The first effect is that any one of the grooves 2 (2a, 2b, 2c) acts as a gas vent in the barrel. That is, since the conventional spherical bullet 1 does not have the concave groove 2 on the outer periphery, it moves in the barrel with almost no clearance in the barrel, so the air in the barrel is compressed in front of the spherical bullet 1. This acts as a resistance force that prevents the bullet from advancing, resulting in a decrease in the power of the gas pressure acting from behind the spherical bullet 1.

  On the other hand, in the spherical bullet 1 of the present embodiment, the gas pressure from the rear in the barrel passes through the concave groove 2 of the spherical bullet 1 to escape forward, and pushes away the air in front of the spherical bullet 1. Since the spherical bullet 1 is pulled forward, the power of gas pressure can be efficiently exhibited.

  Further, as a second effect of the concave groove 2 formed on the outer periphery of the spherical bullet 1, after the spherical bullet 1 is fired from the barrel, lift acting on the spherical bullet 1 hits the concave groove 2, and the spherical bullet This is to enhance the backspin of 1.

  That is, as shown in FIG. 7, when the spherical bullet 1 flies to the left, the spherical bullet 1 is rotated clockwise by the back spin applied in the barrel, and the air pressure from the front of the spherical bullet 1 is It acts from the left to the right in the figure. At this time, the phenomenon “air velocity α> air velocity β” occurs above the spherical bullet 1 and “air velocity α <air velocity θ” occurs below the spherical bullet 1, and the difference in air velocity between the upper and lower sides of the spherical bullet 1 occurs. Generates lift (-G). As a result of the lifting force generated in this way scooping up the concave groove 2 on the outer periphery of the spherical bullet 1, the back of the spherical bullet 1 is exerted because the lift is much larger than that of the conventional spherical bullet 1 having no concave groove 2 on the outer periphery. Spinning is promoted, ballistic stability is improved, and it is possible to exert effects in terms of flight distance and accuracy.

  In this embodiment, the groove width and groove depth of the concave groove 2 provided on the outer periphery of the spherical bullet 1 are also related to how many concave grooves 2 are formed on the outer periphery of one spherical bullet 1. As a result of an experiment in consideration of processing for a small sphere having a diameter of at least 7 mm, when three concave grooves 2 are formed on the outer periphery of a spherical bullet 1 having a diameter of 8 mm, 0.5 mm to It was confirmed that it was most effective to set the groove depth and groove width to 1 mm.

  Further, as described above, the number of the concave grooves 2 formed on the outer circumference of the spherical bullet 1 is set to three as shown in FIG. Therefore, the spherical bullet 1 according to the present invention is ideally formed with three concave grooves 2 (2a, 2b, 2c) on the outer periphery thereof in a three-dimensional direction, but a larger number of concave grooves 2 are formed. It is also possible to do. Therefore, as shown in FIG. 3, when six concave grooves 2, 2,... Are formed on the outer periphery of the spherical bullet 1, the grooves of the three concave grooves 2 (2a, 2b, 2c) described above are used. Effective lift can be obtained with a depth smaller than the depth and the groove width.

  As another embodiment, as shown in FIG. 4, a curved concave groove 3 like a seam formed on a baseball ball may be formed on the outer periphery of the spherical bullet 1. Further, as another embodiment, a plurality of short concave grooves 4, 4,... May be formed as shown in FIG. Moreover, you may form the cross-shaped ditch | groove 4a which crossed such a short ditch | groove.

  Furthermore, as shown in FIG. 6, even when a plurality of dimples 5 (concave depressions) are formed on the outer periphery of the spherical bullet 1, it is possible to obtain the effect of improving the lift during flight as described above. Become.

  In any of the above forms, when a plurality of concave grooves 2 are formed on the outer periphery of the spherical bullet 1, the flying distance and the accuracy of hitting are much improved as compared with the conventional spherical bullet in which the concave grooves 2 are not formed. It is possible to obtain an improvement result of In addition, as a ditch | groove formed in the outer periphery of the spherical bullet 1, either or all of said linear ditch | groove 2, curved ditch | groove 3, short ditch | groove 4, cross-shaped ditch | groove 4a, and dimple 5 are mentioned. It may be combined.

  Next, referring to FIG. 2 regarding the diameter of the spherical bullet 1 of the present embodiment, a conventional spherical bullet 6 mm in diameter (referred to as 6 mmBB bullet) 6 is shown on the left side, and a 7 mm diameter spherical bullet (7 mmBB bullet) is shown in the center. 1), and a spherical bullet (8mm BB bullet) 1 having a diameter of 8 mm is shown on the right side. As shown in this figure, the spherical bullet 1 of 7mmBB bullet and 8mmBB bullet looks much larger than the conventional 6mmBB bullet, and the trajectory when used as a bullet for air gun or gas gun is much less than conventional This makes it easier to see the image and reproduces the strength and force of a large caliber gun.

  Further, the 8 mm BB bullet is enlarged by 2.37 times in volume ratio compared to the 6 mm BB bullet 2, and the impact area is reduced when the target hits, so the impact force is reduced. For this reason, the pressure which penetrates corrugated cardboard is not exhibited unlike the past, and the safety at the time of this BB bullet hitting a human can be improved.

  If the spherical bullet 1 has a diameter of 8 mm or more, the distance from the impression as a bullet is increased, and the diameter of the air gun or gas gun is enlarged, resulting in a design problem. Although 8 mm BB bullets are ideal, the present invention does not prohibit larger diameters.

  Next, the spherical bullet 1 according to the present embodiment can be manufactured by using a mold by injection molding as in the conventional method. However, the concave groove 2 formed on the outer periphery of the spherical bullet 1 can be manufactured. Drawing from multiple directions according to the number and shape is required.

  In the case of a conventional spherical bullet (6 mm BB bullet) having a diameter of 6 mm, a concave groove 2 as in the present embodiment is formed on a small diameter sphere having a diameter of 6 mm when manufactured as a molded product using a mold. However, since it is very difficult to manufacture a mold and the diameter is small, a remarkable improvement result cannot be obtained in terms of flight distance and accuracy. However, if the spherical bullet 1 has a diameter of 7 mm or more, it is possible to manufacture a mold that forms a plurality of concave grooves 2, and the flying distance and accuracy of hitting are significantly improved compared to the spherical bullet 1 having a diameter of 6 mm. The result can be obtained.

  The bullet for the toy gun of the present invention improves the flight distance, straightness, and accuracy by forming a plurality of concave grooves on the outer periphery of a synthetic resin spherical bullet used as a bullet for a toy gun such as an air gun or a gas gun. It can be used as a bullet for toy guns.

In the Example of this invention, it is an external view of the spherical bullet which formed three concave grooves in the outer periphery. In the Example of this invention, it is a figure at the time of comparing with the spherical bullet with a diameter of 7 mm and a diameter of 8 mm with the conventional product with a diameter of 6 mm. In the Example of this invention, it is an external view of the spherical bullet which formed six recessed grooves in the outer periphery. It is sectional drawing. In the Example of this invention, it is an external view of the spherical bullet which formed the curved concave groove in the outer periphery. In the Example of this invention, it is an external view of the spherical bullet which formed the short ditch | groove and the cross-shaped ditch | groove in the outer periphery. In the Example of this invention, it is an external view of the spherical bullet which formed several dimples in the outer periphery. In the Example of this invention, it is explanatory drawing which shows the air characteristic of a spherical bullet.

Explanation of symbols

DESCRIPTION OF SYMBOLS 1 Spherical bullet 2 Grooves 2a, 2b, 2c Each of the three grooves 3 Curved groove 4 Short groove 4a Cross-shaped groove 5 Dimple 6 6mmBB bullet

Claims (1)

A bullet for a toy gun, wherein the groove formed on the outer periphery of a resin bullet used in a toy gun is a plurality of cross-shaped grooves.