DE2642962A1 - Arrow head for competitive archery - has spring loaded tip preventing rebound on hitting wire in target - Google Patents

Abstract

The arrow accommodates the impact forces when the arrow e.g. meets one of the wires which demarcate the target areas. This prevents the rebound of the arrow on the wire and ensures that all arrows contribute to the score. The arrow head is a long slender body with coaxial bore. The arrow tip is held in this bore and it can move between two limiting positions against a spring force. This spring supports the arrow tip on impact. The tip displacement is pref. 10-15 mm. The arrow tip can carry out in the bore also radial movements.

Description

Password: arrow

Dart Game The dart game is usually played with a set of three Played arrows designed to be shot into a target and although to achieve a certain number of points. The goal is generally of the form a circular arrow disk, which is divided into 20 segments, which in one numbered from 1 to 20 in the specific order. Around the perimeter of the disc two wires are provided relatively close to each other which are cut by wires will in turn define the aforementioned 20 segments. The part of the target which of the circumferential wires and two adjacent and intersecting them Wires is formed, represents twice the number> that determined Part is assigned; if, for example, the segment in question has the value 20, so an arrow in this part would mean 40 points. Similarly, are two more wires in tightly spaced circles on smaller radii, i.e.

arranged within the peripheral wires. Define these additional wires together with the cutting (radial) wires areas in which the number, allocated to a particular segment is tripled. A field of the disc, which surrounds the center of the circle is given the value 50, while another The field that surrounds the middle field is assigned the value 25.

The wires that define different target areas of the target, are relatively thin and flexible, but they are still an obstacle for the Arrow that is to be shot into one of the fields. It happens enough that an arrow brushes against a wire, causing the arrow to rebound. This leads to, that sometimes not all the arrows fired contribute to increasing the score, and that this puts the shooter at a disadvantage compared to his competitors.

The highest number of points that can be achieved with the arrow disc described is 180 when three arrows are used. This number is achieved by you place three arrows in the triple field of the segment that has the value 20. A such a field is of course relatively small, and the wings of such a field placed arrows can shield the field so that it can no longer be seen can. In addition, the wings represent an arrow placed in the field mentioned represent an obstacle for any further arrow shot on this field and can even cause each subsequent arrow to be deflected.

The invention is based on the object of designing arrows in such a way that that the aforementioned disadvantages are avoided or at least largely avoided will.

This object is achieved according to the invention in that his head is designed as an elongated body with a bore coaxial therewith, that the arrowhead is stored in this hole and between two limit positions is movable, and that a spring is provided against which the arrowhead supported on impact. The spring is expediently designed as a helical spring and wrapped around the arrowhead.

The spring has the effect that it absorbs all the recoil forces then act on the arrowhead when the tip hits an obstacle, for example on one of the wires that mark the target fields.

The elongated arrow head expediently consists of two halves, which are either screwed together or joined together in some other suitable manner can be.

In a further embodiment of the invention, the bore in the two Head halves extended at one point over a certain length of the longitudinal extension, so that it forms a chamber receiving the spring. Furthermore, that part the arrowhead protruding into or through this chamber one Be provided which the axial movement of the tip limited relative to the head.

Appropriately, the tip and bore are dimensioned such that the Tip sits with play in the hole and thus a certain amount in the radial direction Measure can move.

Further features of the invention can be found in the subclaims. It should be mentioned here that the arrow shaft is also in the above-mentioned Hole of the arrow head can sit. In this case, the arrangement can be made in this way be that this shaft when the arrow hits the target in the associated rebound of the arrowhead is thrown out. The arrowhead then gets stuck in the target; the head (i.e. the elongated body) lay on this point. The arrow shaft with the wings that may be near has since fallen off, so that the shooter can see the Target and thus completely releases the most favorable target area.

The invention is explained in more detail with reference to the drawing. Show in it: Fig. 1 shows a detail of a view of the arrow according to the invention, unwar its Head area in which the major part is cut away in longitudinal section; and Fig. 2 shows the arrow shown in Fig. 1 in cross section, according to the Section line A-B shown in Fig. 1.

The arrow shown here shows a head 1 which, as you can see, has an elongated shape. The head 1 in turn consists essentially of the two halves 2 and 5. A bore 4 extends through the entire head 1 through. In the head half 2, the bore 4 is widened to form a chamber 5.

A needle 7 is inserted into the bore 4 and thus also runs through it the chamber 5 through. The needle 7 is in the area of the chamber 5 with a shoulder 8 provided. This lies in the assembled state of the arrow with one of them Contact surface on a helical spring 10. This spring can absorb recoil forces, which in the axial direction on the arrowhead (in the direction of the wings of the arrow) act as will be described in more detail below. The ones not shown Wings have a shaft 11, part of which is shown. The depicted ending of the shaft 11 is firmly embedded in one end of the head half 2.

The needle 7 is continuous. At one end she is with one Tip 14 fitted; its other end 12 forms an ejector pin in one Distance a from the end 15 of the arrow shaft 11 ends. The distance between the two opposite ends of the shaft 11 and the ejector pin 12 is dimensioned such that the needle 7 can penetrate sufficiently far into the target, whereby due to the relative axial movement of the head 1 with the needle 7 of the shaft 11 the bore 4 is ejected. As soon as the needle 7 hits the target, the speed becomes of head 1 delayed. This delay is negligible, so that the head is his Movement towards the target will continue. Once the head 1 the distance a has traveled relative to the needle 7, the ejector pin 12 of the needle 7 rebounds against the shaft 11, whereupon a further relative movement between the head 1 and the needle 7 ejects the shaft 11.

It goes without saying that the part of the needle that goes over the end edge the head half 5 protrudes, must be long enough to allow penetration of the needle 7 to allow the target and also an ejection of the wings as a result of the relative speed between the head part 1 and the needle 7 to allow.

If the hole 4 in the example shown is also completely through If the head 1 is stretched backwards, it only needs to go through part of the head; the rest of the head can be massive. Just take precautions on one end of Head to receive the flight shaft 11 hit aseVin. ~% Ei in such an embodiment there are no provisions for ejecting the shaft met. The needle 7 extends partially into the chamber 5, and the Part of the shaft located inside the chamber is from the spring 10 surrounded concentrically. Another possibility is to use the chamber 5 for the To omit the spring 10 in the head. In such a case the spring of the bore 4 are added. Means are then also to be provided for the axial To limit movement of the needle 7 between the aforementioned limit positions.

The wings of an arrow will generally be made of plastic. If it is an arrow with the second predetermined position through the shaft end embedded in the head is defined, the shaft could as a result be damaged or destroyed upon impact with a plunger.

To prevent this, this shaft end can be made with an insert hard material, which is able to withstand repeated impacts to resist. In the example shown, the shaft 11 has one Insert 15a made of hard material (see Fig. 1).

Regarding the rebound frequency of a designed according to the invention The following arrow was found: An arrow with the tip relative to the Head is axially movable against the force of a spring, rebounds less often, as an arrow with a fixed point, i.e. as an arrow whose point is not axially is freely movable.

While there is no exhaustive explanation for this, it could but the reason lies in the following: The speed of a shot arrow can be broken down into three components, namely one. Component in Z-direction, in a component in the X direction that is vertically between the 20 and the 5 of a normal Target acts, and a component Y that is at right angles to the X component works.

The wires of an arrow disc are relatively thin and somewhat elastic, and the disc itself on which the wires are arranged comprises a material which is soft compared to the wires and arrowhead. So persevere the wires do not rest when they are hit by an arrow, but move easily move in the direction of at least one of the three components of speed. The energy required for this movement is derived from the kinetic energy of the Arrow derived, whereby this energy is dissipated. Whether the direction in which the arrow moves, is changed or not, and how large the extent of one such change, if any, depends on the angle at which the arrow is taken hits the wire. If an arrow with a solid arrowhead is the middle area of a wire hits (seen in relation to the longitudinal axis of the wire), so loses the arrow takes up a large part of its kinetic energy and its direction of movement is essentially reversed. The arrow then moves off the target away and falls to the ground so that it does not score. If such an arrow hits zones of the wire, which are located adjacent to the first central zone of the wire, so he loses less kinetic energy than if he were in the central zone of the arrow meets. In addition, the change in the three components of speed is substantial. The speed of the arrow after impact is not of such magnitude and direction that this would enable the arrow into the target to penetrate. If an arrow with a fixed tip crosses the edge of a When it hits the wire, the arrow loses little energy as a result of the Impact on the wire; the main velocity component is then the X or Y component. This causes the arrowhead to slide slightly around the wire and penetrate the target. Generally speaking, the energy transfer depends from a body in motion to that of a body at rest on the speed of the moving body and the weight of the both bodies. If the arrowhead is rigidly attached, the energy transfer is suspended on the weight of the arrow and on the elasticity of the wire. If, however on the other hand, the arrowhead is movably attached, so according to the invention, so depends the transfer of energy from the weight of the arrowhead as well as from the elasticity of the wire, unless the spring is on impact of the arrow on the wire is completely compressed.

If a movable arrowhead hits the wire, it is that of the Arrow lost energy overall small compared to the energy loss, which occurs at a rigid arrowhead. So there is enough energy left to enable the arrow to penetrate the target and thus to contribute to increasing the number of points.

If an arrow designed according to the invention hits the central one Zone of a wire, the speed of the arrow body remains on impact the arrowhead almost unchanged in size. However, the direction of movement of the tip will vice versa. During the initial impact, the spring slows down of the arrowhead to a lesser extent, while the speed of the arrowhead increases very much reduced. Thus, the spring itself or the spring returns with it the internal impact of the tip against the body determines the direction of movement of the tip around. Whether there is an internal impact between the arrowhead body and the arrowhead, depends on the spring force and the weight of the arrowhead body and tip. In such a case the tip becomes the surface of the wire in the same place meet, as it did the first time, or in a place that is very dense is at the first place. After two or more hits, possibly with internal tip impact, the body's speed is lost and the arrow does not enter the target.

If an arrow designed according to the invention hits the wire in areas which are adjacent to the said central zone, then the course of events is whole similar to the one when the arrow hits the said central zone. Because of the angle between the velocity component in the Z direction and the surface however, the wire does the speed transmission and arrowhead impact etc. to the fact that the main speed of the arrow towards the X or Y component be changed. The point at which the arrowhead meets the wire is from farther away from the central zone than the point at which the arrowhead touches the wire first met. The angle between the Z component and the surface the wire will be bigger than it was when the tip of the wire the first time met, and the components of the velocity in the X or Y direction become larger as the component in the Z direction. Because the loss of kinetic energy after each impact is small, enough energy remains to push the tip into the Stand to penetrate the target, provided that they are on the Wire comes by. Because the arrowhead is adjacent to each other, and therefore different Points hits the wire, there is a possibility and probability that that the arrowhead slides along or around the wire. This tendency will increased when the point of impact can move in the radial direction.

Experiments have shown that the rebound frequency of a shaped arrow from the weight of the elongated arrow head, the weight the arrowhead, the greatest axial relative movement between the tip and the rest Head, the rate of fire of the arrow and the design of the spring depend. Although no general limits are given with regard to the conveyor characteristics the spring should be able to absorb the rebound energy of the arrowhead to save before the tip touches its rear, movement-limiting surface. However, the spring should not be able to slide into the elongated head body to slow down its speed so far that the remaining speed of the arrow is too small for the arrow to penetrate the target. It it was found that the design of the spring is expediently between 100 N / m and 1000 N / m, with arrow weights of between 24 and 50 grams.

The spring expediently has a design of between 200 and 600 N / m.

Tests have also shown that the axial movement of the tip should be between 4.5 and 20 mm in the elongated head body, preferably between 10 and 15 mm. The radial movement of the tip can be between 0.1 and 1 mm are, preferably between 0.2 and 0.7 mm.

A number of attempts have been made with arrows of various weights executed. The results of these tests are given in the table below shown. Each arrow was run 500 times at a calculated average speed shot down at 5 m / s.

The test target here comprised a base body made of fiber material and a plurality of wires arranged in a net-like manner on the base body. The vertical wires of the mesh were spaced 4 mm apart and had a length of 16 cm and a diameter of 1.65 mm. The cross wires of the net had a mutual distance of 5mm and a diameter of 1.5 mm. The wires covered approximately 55 [deg.] Of the total area of the test target. The arrows were dropped or shot against the test disc from a Distance of 1.5 m at the previously mentioned calculated average speed of 5 m / s.

Tests A1 and A2 were marked with arrows (with a weight of 24 g) executed in which no spring was provided, but in which the tip is could move radially in a range of 0.7 mm.

The rebound frequency of these arrows was in each case 9.8 ß and 8.6 ffi indicated. Tests A3 to A6 were carried out with arrows in which the individual arrowheads were able to move radially against the force of a To move the spring, the design of which was 600 N / m. A clear one emerged here Improvement in rebound frequency. The best results were found in the arrow used in test A6, the tip of which has a maximum Axial movement of 14.5 mm could perform.

Test A7 was carried out with an arrow with no spring was present, but its tip axially displaceable by a distance of 6 mm was. The rebound frequency was measured to be 9.0%, despite the tip's ability to move axially.

The tests show that the rebound frequency of an arrow is very important is reduced when the tip moves axially against the force of a spring can perform. A lower rebound frequency is also achieved if the Arrowhead a radial Movement in the hole can run. A favorable amount of such a radial movement is in the range of 0.2 to 0.8 mm.

Table test arrow- radial dimension of the axial spring rebound no. weight movement movement of the tip hardness frequency against the force of a spring g mm mm N / m A1 24 0.7 0+ OO + 9.8 A2 24 0.7 0+ 00+ 8.6 A3 24 0.65 4.5 600 5.6 A4 24 0.7 8.5 600 5.2 A5 24 0.7 9.5 600 5.4 A6 24 0.7 14.5 600 2.8 A7 28 0.3 6.0 0 9.0 A8 30 0.1 8.5 600 9.4 A9 30 0.3 10.0 600 1.9 A10 50 0.3 7.5 600 0.6 The weight the arrowhead was approximately 1.5 g in each case.

Claims (1)

Keyword: PLeia "Patent Claims 1 arrow for use with an arrow and bow game with an arrow head, arrowhead and arrow shaft, thereby gekeanzeichg that the arrow head as an elongated body of a coaxial to this Bore is designed that the arrowhead is supported in this bore and between two limit positions is movable and that a spring is provided against the the arrowhead is supported on impact. 2 Arrow according to claim 1, characterized in that that the coaxial bore penetrates the arrow head completely and that the arrow shaft at the end of the bore facing away from the arrowhead is inserted into this 5 arrow according to claim 1 or 2s, characterized in that the design of the spring between 100 N / m and 1000 N / m, preferably between 200 and 600 N / m5 moves you the 4th arrow according to / claims to 3, characterized in that the arrowhead can move relative to the arrow head in the axial direction by an amount that is between 4n5 and 20 mm, preferably between 10 and 15 mm. 5. Arrow according to one of claims 1 to 4, characterized in that that the arrowhead can also move radially in the hole 6o Arrow according to claim 52, characterized in that the amount of radial movement based on the central axis of the bore, between OS1 and 1 mm, preferably between 0.2 and 0.7 mm. 7. Arrow according to one of claims 1 to 6, characterized in that that the arrow head consists of two halves which are designed such that they are joined together can be. o. Arrow according to claim 7, characterized in that one half is wetert to form a receiving chamber for the spring. 9. Arrow according to one of claims 1 to 8, characterized in that that the part of the arrowhead protruding into the receiving chamber becomes the limit the relative movement between arrowhead and arrowhead in at least one direction is provided with a collar. 10. Arrow according to one of claims 8 and 9, characterized in that that the rammer has a first wall defining said first predetermined ones Position, and a second wall for defining said second P predetermined Position has 11. Arrow according to one of claims 1 to 10, characterized in that that the arrangement is made so that the arrow shaft or the associated here Arrow wing with axial movement of the arrowhead against the arrow shaft as a result the impact of the arrow in the direction of the arrow head. 12. Arrow according to claim 11, characterized) that the ejection of the arrow shaft takes place by direct action of the arrowhead. 15. Arrow according to one of claims 11 or 12, characterized in that that the arrow shaft in the area of its introduction into the bore of the head made of shockproof Material exists or is provided with one.