JP3139388U - Darts barrel - Google Patents

Abstract

An object of the present invention is to change the position of the center of gravity of a barrel during flight to bring the flight trajectory of the dart closer to a straight line.
A metallic cylindrical barrel body 11 having a partition wall 12 that separates the in-cylinder space forward and backward, a metal sphere 17 that slides in a bottomed cylindrical space 15 on the rear end side of the partition wall, and a coil spring 18. And a spring retainer 19 that is screwed into a female screw 14 provided on the inner wall of the inlet portion of the bottomed cylindrical space and moves forward and backward. After the sphere and coil spring are inserted in order into the cylindrical space of the barrel body, the spring retainer is screwed forward, and the coil spring presses and presses the sphere against the partition wall at the bottom of the bottomed cylindrical space. It is set as the structure stopped by.
[Selection] Figure 1

Description

  The present invention relates to a barrel that is a main component of a dart used in a dart game or a dart competition in which a dart (arrow) is applied to a wall or the like to compete for scores.

  Darts is a British-born sport that is prepared on the walls, etc., and uses arrows to compete for scores. At the same time, the word dart means the arrow itself used in this sport. Hereinafter, in this specification, darts will be described as indicating this arrow itself.

  FIG. 6 is a longitudinal sectional view showing a configuration of a general dart 1. The dart 1 is composed of four parts: a tip (point) 2, a barrel 3, a shaft 4, and a flight 5 from the tip side. The tip 2 is a pierced part and is made of metal or plastic. Flight 5 is a blade and contributes to flight stability. The shaft 4 is a part for attaching the flight 5 and is made of plastic.

  The barrel 3 is the main part of the dart 1 and is the most important part. The competitor throws dart 1 with this part in his hand. The barrel 3 has a cylindrical shape, and a female screw 7 for screwing and attaching the tip 2 is formed on the front end side, and a female screw 8 for screwing and attaching the shaft 4 is formed on the rear end side. The flight stability and straight flight performance of the dart 1 are delicately related to the overall weight of the dart 1, the position of the center of gravity, the length of the shaft 4, the size of the flight 5, and the like.

For the barrel 3, the weight and the position of the center of gravity are emphasized. Generally thin and heavy are preferred, so they are made of tungsten or nickel with high specific gravity. The position of the center of gravity can be adjusted by changing the depth of the holes of the female screws 7 and 8 at the front and rear ends. However, this method cannot adjust the position of the center of gravity after fabrication. In order to make it possible to adjust the position of the center of gravity even after manufacture, a barrel is formed in a cylindrical shape, and a weight has been proposed so that it can be detachably loaded at an arbitrary position inside (see Patent Document 1). None of these conventional barrels change their center of gravity during flight.
JP 2007-202893 A

  The inventor of the present application repeatedly studied the effects of the position of the center of gravity of the barrel on flight stability and flight straightness through repeated trials and experiments. He discovered that changing the position of the center of gravity of the barrel during flight could improve the flight stability and straightness of flight. The present invention is to provide a barrel capable of changing the position of the center of gravity during the flight as a result of such research.

  The invention described in claim 1 for solving the above-mentioned problem is a barrel for darts which is used in a cylindrical appearance with a tip at the front end and a shaft with a flight screwed at the rear end. Provided on the inner wall of the inlet portion of the bottomed cylindrical space, a metal cylindrical barrel body having a partitioning wall, a metal sphere that slides in the bottomed cylindrical space on the rear end side of the bulkhead, a coil spring, and the like. It consists of a spring retainer that is screwed into a female screw and moves forward and backward.After inserting a sphere and a coil spring in this order into the bottomed cylindrical space, the spring retainer is screwed forward and the coil spring moves the sphere into the bottomed cylindrical space. It is a barrel for darts, characterized in that it has a structure that is stopped at a position where it is pressed against and urged against a partition wall that is a bottom.

  According to such a configuration, when the barrel is separated from the player's hand, the coil spring is compressed and contracted by the inertia of the sphere, so that the sphere is located at the rear end of the cylindrical body. When moving to the flight state, the sphere is pushed out by the coil spring and slides to the front end side. As the sphere moves forward, the center of gravity of the dart moves forward. The sphere that has moved forward eventually collides with the bulkhead and stops. Upon impact, the sphere gives the barrel its momentum and raises the barrel speed slightly. By such a slight increase in the speed due to the movement of the center of gravity and the collision of the sphere, the flight trajectory of the dart is more linear than the conventional center-of-gravity fixed dart, and it is easy to hit the target location.

The invention described in claim 2 is a dart barrel having a cylindrical appearance, tip at the front end, and a shaft with a flight at the rear end, which is screwed and used. A cylindrical barrel main body, a bottomed cylindrical body that has a male screw threadedly engaged with the female screw on an outer peripheral wall surface in the barrel main body and moves forward and backward in the barrel main body with the bottom as a front end side, and the bottomed It consists of a metal sphere that slides in a cylindrical body, a coil spring, and a spring presser that moves forward and backward by screwing into a female screw provided on the inner wall of the barrel body,
A position where a spherical body and a coil spring are sequentially inserted into the bottomed cylindrical body, and then the spring retainer is screwed forward from the rear end side so that the coil spring presses and presses the spherical body against the bottom of the bottomed cylindrical body. It is the barrel for darts characterized by having the composition stopped by.

  In addition to the same effects as the barrel described in claim 1, the barrel having such a configuration can adjust the position of the center of gravity of the dart in a stationary state by changing the stop position of the bottomed cylindrical body. Has the advantage of being able to.

Hereinafter, the structural example of the barrel for darts which concerns on this invention is divided into embodiment, and is demonstrated.
(First embodiment)
FIG. 1 is a cross-sectional view of a barrel 10 according to the present embodiment. The barrel 10 is composed of four parts: a main body 11, a sphere 17, a coil spring 18, and a spring retainer 19. The main body 11 is formed in a cylindrical shape using a metal material such as tungsten or nickel. However, the inside of the cylinder is not a through-hole, and a partition wall 12 is provided in the cylinder to separate the cylinder space in the front-rear direction. On the inner wall of the bottomed cylindrical space from the front end side (flying direction side) to the partition wall 12, a female screw 13 for screwing and attaching the tip is formed.

  A female screw 14 for screwing and attaching the shaft is formed on the inner wall of the inlet portion of the cylindrical space on the rear end side, and a cylindrical space 15 is formed between the female screw hole and the partition wall 12. That is, the cylindrical space 15 has a bottomed cylindrical shape with the partition wall 12 as a bottom. A spherical body 17 that can slide back and forth in the space and a coil spring 18 that urges the spherical body 17 toward the partition wall 12 are inserted into the cylindrical space 15.

  The reaction force acting on the coil spring 18 is received by the spring retainer 19. The spring retainer 19 has a male screw shape, and moves forward and backward by being screwed into the female screw 14 for attaching the shaft. A driver groove 20 is formed on the head of the spring retainer 19 to be rotated using a screwdriver. In the state where the spring retainer 19 is advanced to the innermost part, the length of the coil spring 18 is adjusted so that the coil spring 18 presses the spherical body 17 against the partition wall 12 with a weak force.

  Next, the operation of the barrel 10 having such a configuration will be described. In use, a tip is screwed and attached to the front end side of the barrel 10, and a shaft to which a flight is attached is screwed and attached to the rear end side to form a dart. Then, hold the barrel 10 part in your hand and throw it toward you. FIG. 2 shows the state in the barrel 10 over time from the moment the barrel 10 leaves the hand. (1) in FIG. 2 is a state at the moment when the barrel 10 leaves the hand, and (2) and (3) are states in flight.

  When throwing a dart, the competitor releases the dart from a state where the dart is pulled backwards and then rapidly moves forward. The barrel 10 receives a large force directed forward by the movement of the hand. This force causes the barrel 10 to gain a large acceleration, increase the speed, and move away from the hand. If the air resistance is ignored after leaving the hand, the aircraft will fly in the horizontal direction with the initial horizontal velocity at the moment of releasing the hand.

  On the other hand, the sphere 17 receives a forward force from the spring retainer 19 via the coil spring 18 when throwing. Since the sphere 17 has a mass, an inertial force (inertial resistance) as a reaction force acts on the coil spring 18. Since the spring constant of the coil spring 18 is small, the coil spring 18 is contracted by this inertial force, and the sphere 17 is retracted to the last part as shown in FIG. The horizontal acceleration acting on the barrel 10 from the moment the barrel 10 leaves the hand becomes zero, and the forward force applied to the spring retainer 19 via the main body 11 of the barrel 10 also becomes zero. The inertia force (inertial resistance) generated in the sphere 17 due to the forward acceleration of the spring retainer 19 is also zero.

  The coil spring 18 is in a compressed state as shown in FIG. The compressed coil spring 18 applies a force of a value obtained by multiplying the amount of displacement from the uncompressed state by a spring constant to the sphere 17 and the spring retainer 19. The force acting on the spring retainer 19 acts in a direction to reduce the forward speed of the barrel 10. However, since the mass of the main body 11 connected to the barrel 10 is larger than the mass of the sphere 17, the speed reduction is slight.

  Since the sphere 17 has a small mass, the acceleration received by the force received from the coil spring 18 increases the forward speed. That is, the forward speed of the sphere 17 is higher than the forward speed of the barrel 10. Thereby, the spherical body 17 slides in the cylindrical space 15 in the front end direction as shown in (2) and (3) of FIG.

  Such forward movement of the sphere 17 in the cylindrical space 15 has the following effects. First, the barrel 10, and thus the center of gravity of the dart, is moved toward the front end during flight. Secondly, the sphere 17 that has moved forward collides with the partition wall 12 as shown in FIG. When the collision occurs, the forward speed of the sphere 17 coincides with the speed of the barrel 10. At that time, the sphere 17 gives the barrel 10 a momentum of a speed difference from the barrel 10. Given the momentum, the forward speed of the barrel 10 is slightly increased.

  The inventor of the present application verified through experiments the effects of a slight increase in the forward speed of the barrel 10 due to the forward movement of the center of gravity of the barrel 10 during the flight and the collision of the sphere 17 on the flight characteristics. As shown in FIG. 3, the experiment was performed by comparing the trajectories from the point A until the dart thrown at the same initial speed pierces the center B point of the target 30. As a result, the dart with the sphere 17 fixed at the position shown in FIG. 2 (1) flies in a mountain-like arc as shown by the curve 31, whereas the sphere 17 moves during the flight. In the darts, it was confirmed that the arc trajectory was gentle as the flight trajectory was curve 32, and the flight trajectory was more linear. For this reason, it has been found that the dart according to the present embodiment is easier to hit at the target location than the conventional center-of-gravity dart.

The reason why the flight trajectory of the dart of this embodiment approaches a straight line in this way is not clear, but it can be considered as follows. As a first reason, the forward movement of the center of gravity by the advancement of the sphere 17 has the same effect as the length of the shaft attached to the rear end side of the barrel 10 becomes longer during the flight. As a second reason, the kinetic energy and momentum of the barrel 10 and the sphere 17 at the moment when the dart is removed from the hand are the same for the conventional type and the present embodiment type. However, in the dart of the present embodiment type, the coil spring 18 is compressed at the moment when it is separated from the hand, and the position of only (1/2) Kx ² where K is the spring constant of the spring and x is the amount of displacement. Excess energy is stored in the coil spring 18. When the potential energy is released during flight, the sphere 17 slides to the front end side, and at the moment when it collides with the partition wall 12, the kinetic energy and the momentum of the speed difference from the barrel 10 are given to the barrel 10. As a result, the speed of the barrel 10 slightly increases during the flight. As a result, even if the dart of this embodiment type is thrown at the same initial speed as the conventional type, the average speed until reaching the target is slightly increased. It is thought that these two effects combine to make the dart's flight trajectory closer to a straight line.

(Second Embodiment)
FIG. 4 is a cross-sectional view of the barrel 10a according to the second embodiment. In the barrel 10 according to the first embodiment shown in FIG. 1, the position of the partition wall 12 is fixed. The barrel 10a of the present embodiment is configured such that the position of the partition wall 12 can be moved and the position of the center of gravity when the barrel 10a is stationary can be adjusted.

  Specifically, the bottomed cylindrical body 33 having the partition wall 12 as a bottom is formed by integrating the partition wall 12 and the peripheral wall portion of the cylindrical space 15 in which the sphere 17 slides. And the external thread 34 is formed in the outer peripheral wall part of the bottomed cylindrical body 33, the internal thread 35 is formed in the inner wall of the through-hole 36 of the main-body part 11 of the barrel 10a, both are screwed together, and the bottomed cylindrical body 33 is formed. Can be stopped at an arbitrary position in the through hole 36. A driver groove 38 is formed on the bottom side of the bottomed cylindrical body 33 to be rotated using a screwdriver. The spherical body 17 and the coil spring 18 are inserted into the bottomed cylindrical body 33 and the spring retainer 19 is attached in the same manner as the barrel 10 according to the first embodiment.

  (1) in FIG. 5 is a state at the moment when the barrel 10a leaves the player's hand, and (2) and (3) are in flight. The sphere 17 slides in the same manner as the barrel 10 of the first embodiment. Therefore, it acts in the same manner as the barrel 10 of the first embodiment, and the same effect is obtained. The advantage over the barrel 10 of the first embodiment is that the bottomed cylindrical body 33 can be stopped at an arbitrary position in the through hole 36 of the barrel 10a, whereby the position of the center of gravity of the barrel 10a in a stationary state. The effect that can be adjusted arbitrarily is obtained.

It is sectional drawing of the barrel 10 which concerns on 1st Embodiment. It is sectional drawing explaining the movement of the spherical body 17 in the barrel 10 in flight. It is a comparative example of the flight locus of the dart according to the present invention and the conventional dart. It is sectional drawing of the barrel 10a which concerns on 2nd Embodiment. It is sectional drawing explaining the movement of the spherical body 17 in the barrel 10a in flight. It is sectional drawing which shows the structure of the conventional dart 1.

Explanation of symbols

  In the drawings, 1 is a dart, 2 is a tip, 3, 10, 10a is a barrel, 4 is a shaft, 5 is a flight, 11 is a barrel body, 12 is a partition wall, 15 is a cylindrical space, 17 is a sphere, 18 coil springs, Reference numeral 19 denotes a spring retainer, 33 denotes a bottomed cylindrical body, and 35 denotes a screw thread.

Claims (2)

It is a barrel for darts that uses a cylindrical appearance with a tip at the front end and a shaft with a flight screwed at the rear end,
A metal cylindrical barrel body having a partition wall that separates the in-cylinder space in the front and back, a metal sphere that slides in a bottomed cylindrical space on the rear end side of the partition wall, a coil spring, and the bottomed cylindrical space It consists of a spring retainer that moves forward and backward by screwing into a female screw provided on the inner wall of the inlet,
After the spherical body and the coil spring are sequentially inserted into the bottomed cylindrical space, the spring presser is screwed forward and the coil spring presses and biases the spherical body against the partition wall which is the bottom of the bottomed cylindrical space. A dart barrel characterized in that it has a structure that is stopped at a position where it enters a state. It is a barrel for darts that uses a cylindrical appearance with a tip at the front end and a shaft with a flight screwed at the rear end,
A cylindrical barrel body made of metal having a female thread on the inner wall of the cylinder, and a male thread that is screwed to the female thread on the outer peripheral wall surface in the barrel body, and moves forward and backward in the barrel body with the bottom at the front end side. A bottomed cylindrical body, a metal sphere that slides within the bottomed cylindrical body, a coil spring, and a spring retainer that is screwed into a female screw provided on the inner wall of the barrel main body and moves forward and backward.
After inserting a spherical body and a coil spring in order into the bottomed cylindrical body, the spring presser is screwed forward from the rear end side, and the coil spring presses the spherical body against the bottom of the bottomed cylindrical body and urges it. A barrel for darts, characterized in that it has a configuration in which it is stopped at a position where it is in a finished state.