CH636695A5 - Ballistic projectile - Google Patents

Description

The invention relates to a ballistic projectile according to the 53 body with a diameter of up to 1.15 cm. Preamble of patent claim 1, which is shot down with sub-shell To ensure a clean, effective and limited penetration into speed and is particularly suitable for the one-animal with a subsonic speed expulsion in living carcasses. Ensuring a projectile of low density has been an issue

There are many floors, e.g. Shots for shooting on showed that the nose had a conical shape and a parting-head animal, which means that these should be made defenseless or killed, should have an angle of more than 45 ° and up to 75 °, with a len. Typically, such projectiles have an average angle of 60 ° is preferred. The crown, or the density of approx. 10 g / cm3. They are intended for deep penetration into the tip of the lap, a curve with a radius in the size animal tissue must be determined and should have a large shock-effect range of 0.04 to 0.05. Trigger projectiles from clotting, which causes maximum trauma in the animal. low density with hemispherical or parabolic rounded Na

Ballistic-projectiles that are biologically active 65 tend to contain holes in an animal's skin for implantation into living animal bodies are punched into which they are driven at subsonic speed to the U.S. 3,948,263 and 3,982,536. This is why they can get part of the skin into the wound

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sweep away, which becomes a source of infection there. In addition, such projectiles cause considerable trauma with the resultant hematoma when they penetrate the meat of an animal, so that a thickened bead is formed around the entry point immediately after the projectile has penetrated the animal. Low-density bullets with a conical nose that have an apex angle in the specified range, but have a pointed apex instead of the rounded one, tend to get stuck in the skin of an animal, i.e. do not penetrate the animal if they are subsonic 10 speed can be shot down. The penetration of a projectile designed according to the invention only causes a slit in the skin at the point at which the projectile penetrates.

This entry slit is shorter than the diameter of the projectile and little, if any, 15 bleeding occurs through the slit. The bullet does not drag any part of the animal's skin into the wound. In addition, the projectile moves through the meat without causing any significant trauma with the resulting hematoma, so that only a slight swelling occurs in the area in which the projectile penetrates. In addition, such a projectile appears to penetrate the meat only to a limited extent, e.g. 5 to 12.7 cm, depending on the type of animal, regardless of the distance from which the projectile is shot at the animal in the range between approx. 18 m and 18 m. 25th

The projectile preferably has an indentation at the end opposite the nose, which indentation can be formed either on the body itself or on a medicament or a device inserted into the cylindrical cavity. The indentation contributes to achieving a better flight accuracy of the projectile. The indentation is particularly useful for achieving flight accuracy with bullets made of solid material.

Bullets of the type according to the invention can be provided with essentially cylindrical bodies as well as with bodies 35, the shape of which corresponds to a non-round, helical, helical profile.

Advantageous shooting results are achieved when projectiles with helically wound profile bodies 40 are driven out of a barrel with a likewise helically profiled bore of the same shape and dimension as said profile body.

Bullet-shaped projectile bodies with a polygonal, preferably regular-polygonal cross-section 45 have a surface which has a multiplicity of curved surfaces which are twisted around the longitudinal axis of the body.

If the cross-section has the shape of an ellipse, a projectile results, the helically curved surface of which looks like a twist drill.

The term “non-round” profiled used above is understood to mean that the outline does not form a perfect circle. This includes preferably oval and polygonal, preferably triangular and rectangular cross sections, as well as those from combinations of curved and straight side boundaries.

The invention is explained in more detail below with the aid of schematic drawings of various exemplary embodiments. It shows:

1 shows a side view, partly in section, of a first embodiment of a projectile according to the invention with a medicament in a chamber formed in the projectile;

FIG. 2 shows a rear view of the projectile according to FIG. 1;

3 shows a side view of a second exemplary embodiment of a projectile according to the invention with an electronic device fastened in a chamber in the projectile;

FIG. 4 shows a rear view of the projectile according to FIG. 3;

5 shows a side view of a projectile according to the invention with dashed, optionally provided cavities and ballast or an identification device;

Fig. 6 is a rear view of the projectile shown in Fig. 5;

7 shows a longitudinal section through a barrel mounted in a holder with a helically wound polygonal bore, which is designed to be complementary to the body profile of the projectile according to FIG. 5;

8 shows the cross section along the line 8-8 through the barrel according to FIG. 7;

9 shows a perspective view of a further exemplary embodiment of a projectile with cavities and ballast, optionally provided, which are shown partly in broken lines, or with an identification device;

FIG. 10 shows a rear view of the projectile according to FIG. 9;

11 shows a cross section similar to FIG. 8 through a barrel which has a smooth bore which is designed to be complementary to the body profile of the projectile according to FIG. 9.

A projectile 10 according to a first exemplary embodiment of the invention is shown in FIGS. 1 and 2. It has an elongated body 12 with a central axis and a cylindrical outer surface which has a diameter of e.g. Has 0.64 cm. The body 12 fits closely into the bore of a barrel, from which the projectile is expelled in the barrel, for example by deformation in trains. The projectile 10 also has a conical nose 14 which is arranged coaxially on the body 12. The base of the nose 14 corresponds overall to the cross-sectional area of the body 12. The conical nose 14 has an apex angle 16 of 60 ° and a radius of 0.04 cm at its tip 18, the center of the curvature being on the axis of the nose 14 lies. The projectile 10 has a cavity 20 which is opened by the end face 22 of the projectile opposite the nose 14 and is delimited by a cylindrical inner surface 24 which smoothly merges into a hemispherical surface 26 at its end opposite the end face 22, so that within the projectile 10 there are no places where tensions or stresses can concentrate. As can be seen from the drawing, the cavity 20 is filled with a medication 28 which e.g. is in the form of a compressed or freeze-dried powder and is shaped such that it has a recess 29 on the end face 22 of the projectile 10. The edge of the recess 29 is shown here on the end face 22 of the projectile, but could also be set back within the cavity 20.

Figures 3 and 4 show another embodiment of a projectile 30 according to the invention. Like the projectile 10 according to FIGS. 1 and 2, the projectile 30 also has a conical nose 31, the base of which overall corresponds in cross section to the cross section of the elongated body 34. This projectile also has a rounded tip 32 and a cavity 33 in the shape of the projectile 10. However, the body 34 of the projectile 30 is not cylindrical and smooth on its outer surface, but instead has ten flattened surface areas 36 of the same width, which are around its circumference is distributed and wound evenly around the axis of the projectile 30. These flattened surface areas 36 fit tightly into correspondingly curved wall parts in the bore of a barrel from which the projectile 30 is to be fired, so that the projectile has a desired rotation during flight

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movement. Instead of a medicament, the cavity 33 here contains a device 37 which is fixed in place with an epoxy resin 38 and e.g. can be electronically activated to locate an animal that carries this projectile. The epoxy resin 38 with which the device is fastened in the cavity forms a concave end surface 39 on the projectile 30.

5 shows a projectile 110 with an elongated body 112 and a slightly rounded, tapered nose 114. The body 112 has a surface which is delimited by ten intersecting planes which form surface regions 116 of the body which are helical around the axis a of the floor 110 are arranged around.

As already mentioned, the body 112 of the projectile 110 has a shape which is delimited by the helically wound surface areas 116, the surface contour being formed by continuously uniform movement of a regular decagonal planar figure along a helix running around the axis a. Thus, the projectile has a twisted outer surface which is designed to be complementary to the wall of the bore hole in FIG. 8 and which has a helical course. As a result, the projectile is given a rotational movement in its longitudinal axis on its way through the barrel, so that the projectile emerges from the barrel with a twist. The speed of rotation can be controlled by the slope of the helically wound surface of the projectile body and the correspondingly shaped barrel bore.

The floor 110 is shown here with ten sides, which result in a body cross section that has the shape of a regular decagon. However, the body surface can have any number of pages from three to twenty or more. As a practical limit, the maximum number of sides of a bullet with a diameter of approx. 0.6 cm is a maximum of twenty pages, because the outline of the cross-section of the body would too close to a circle and the bullet could have the tendency to slip over the sides inside the barrel without getting the desired rotation. The minimum number of pages on the floor is determined by stability considerations. A bullet with wide sides is more likely to be affected by air currents on its flight. The width of the pages is therefore preferably kept in the range from approximately 0.1 cm to approximately 0.4 cm, and the pages preferably have the same width. This corresponds to a range of approximately five to approximately twenty pages for a floor with a nominal maximum diameter of approximately 0.6 cm. For a body with sides of the same width, the ratio is expediently determined by standardized design formulas. If the body has sides of non-uniform width, the width of all sides should preferably be within the range mentioned above, i.e. the width should be between 0.1 and 0.4 cm.

It is obvious that the surface of a bullet with a larger diameter can have a greater number of sides than a bullet with a smaller diameter in order to maintain the minimum side width of 0.1 cm.

The pitch of the helix can also be chosen over a wide range, but it should be such that the projectile receives an appropriate swirl that stabilizes the flight. The slope must be constant over the entire length of the floor. The pitch of the helix is the distance between two turns of the screw along the longitudinal axis of the body. This means that the slope is the distance over which one of the spiral sides of the body makes a full turn around the body. The slope is preferably between 18 and 40 cm and is best at about 20 to 25 cm in order to achieve a projectile which has a twist of «1 to 20» to «1 to 25».

If the screw pitch of the projectile is greatly extended, the projectile does not achieve a sufficiently large swirl to be properly stabilized in its trajectory. If the slope is excessively short, the projectile experiences greater resistance as it moves along the inside of the barrel. Stronger driving forces are therefore necessary in order to achieve the desired outlet exit speed. This in turn can lead to increased frictional forces in the barrel, which leads to undesired wear and contamination.

The projectile 110 shown in FIG. 5 contains a cavity 118 which is delimited by a wall 15 which is annular in cross section and which is open towards the rear of the projectile. The cavity 118 is optionally provided and can accommodate different payloads, as explained in detail below. A mass 120 is also embedded in the floor 110. This can be ballast, which stabilizes the projectile in its trajectory. However, it can also be an active or passive detection or labeling element, e.g. a passive responder in the form of a tuned resonant circuit.

25 The nose 114 is slightly rounded as described in order to achieve the desired flight and penetration properties. The nose shape corresponds in principle to that according to FIGS. 1 to 4.

FIG. 6 is a rear view of the projectile 110 according to FIG. 5 and shows a cavity 118 delimited by a wall with a circular cross section inside the body 112. Ten surface areas 116 wound in a spiral shape form the surface of the body 112.

FIG. 7 shows a longitudinal section of a barrel 130, which is shown mounted in a holder 132. The barrel 130 has an inlet cone 134 and a barrel wall 136. The running wall 136 has no trains. Instead, it has ten wall strips 138, which are arranged helically around the longitudinal axis b of the barrel bore. “Diameter” and pitch 40 of the helically wound barrel bore are selected according to the body surface of the projectile 110 according to FIG. 5. The running wall 136 therefore has a structure which is formed by continuously uniformly rotating a regular decagonal planar figure along a helix running around the axis b 45, as described in connection with the projectile 110.

When the projectile 110 is expelled through the barrel 130, the surface regions 116 of the projectile 110 come into contact with and follow correspondingly shaped regions 138 of the barrel wall 50 136, so that the projectile 110 is forced to turn on its way through the barrel 130 to rotate its longitudinal axis a and to leave the muzzle of the barrel with twist.

55 FIG. 8 shows a cross section along the line 8-8 through the barrel 130. The barrel wall 136 is shown with a decagonal contour which is formed by the wall regions 138.

9 shows a perspective view of another exemplary embodiment of a projectile 140 which has a body 60 142 and a beveled nose 144. The cross section of the body 142 is elliptical, as the rear view of the projectile 140 according to FIG. 10 shows. The body 142 has a curved surface that is helically wound around the longitudinal axis c. Optionally, a cavity 146 is provided, which is delimited by an elliptical-65-ring-shaped wall and is open towards the rear of the floor 140. This cavity can be used to accommodate and release various payloads, if desired. In addition, a

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Further mass shown in dashed lines in the form of a cube 148 in the example of polymers which are found in animal bodies, e.g. can be accommodated on Rin floor 140, which can also be solved with the same advantage, are cellulose derivatives such as hydroxypropylcel, as it already does in connection with the floor gelulose, which are marketed under the name “Klucel” by Hercules Pow 5 has been described. the Company are commercially available.

The body of this projectile has a shape that is 5 For certain applications, metallic projectiles can be used by continuously moving an elliptical se. Magnesium results in light projectiles and a flat figure along a screw line running around the axis c - can be dissolved by body fluids, so that genius is formed. The elliptical cross section should be clearly unscrewed from magnesium or combinations of magnesium of different diameters on the major and minor axes and an organic polymer, which should be to be out of round, so that the bullet with its OK magnesium either Existing on the outside or inside of the floor from a correspondingly shaped barrel is a twist. Lead is not one of the preferred substances, it can be conveyed around the longitudinal axis c. The difference between, however, as a ballast or also as a covering on the floor of the main and secondary axes should not be so great that it should be. Because of its toxicity, however, lead is generally a projectile that is flown by air currents for implantation in an animal body, e.g. as surface contamination is unduly impaired. The length of the diameter on the minor axis is preferably about 50 to the length of a coating or inside a carrier that can be dissolved in the animal body. In addition, bullets point to 90% of the length of the diameter on the main axis. The lead lead coating has the tendency to smear the barrel. Demands on bullets with a curved surface are dirty. As a result, bullets are drawn before cross-sections similar to those already described, the surface of which is free of metallic lead. with polygonal outlines, as in connection with 20 The most diverse inorganic fillers, such as Calium-Fig. 5 described. carbonate, magnesium carbonate, ferrooxides, iron powder and

11 shows a cross section through a barrel similar to that shown in FIG. 8 - can be used to remove the solubility properties - the barrel 130 shown in FIG. 8, but with a screw shadow and / or the density or other physical intrinsic winding bore 152 to change with smooth shafts of the projectiles.

Wall is provided, which delimits an elliptical outline. For certain applications it may be desirable that the outline of the barrel bore 152 is designed in accordance with the body of the projectile-projectile upon impact with or without any noticeable penetration 140 according to FIG. 9, so that the target bursts into the target, for example, a dye or shot 140 as it is driven through barrel 150 to rotate medicament such as an antiseptic or sedative longitudinal axis c and to swirl the muzzle of the barrel.

leaves. 30 Certain waxes or breakable polymeric substances can

As with the polygonal outlines shown in Figs. 5 through 8, to achieve these results, the elliptical outline of the floor and barrel can also detect neither the Sanze floor nor only a part thereof, e.g. the inner according to FIGS. 9 to 11 of a large number of imaginary nose from which the bursting material can be made. Outline lines are formed that are tangent to the outline. Lubricants can also be incorporated into the storeys.

Be prepared for the 35 already mentioned for the polygonal structures> that the shaping and shooting down of the projectile reasons, these lines must not be easier within the generation. Calden slicing is advantageously suitable for this purpose if it is intended to fall under the inventive structure stearate, glycerol monostearate, pulverized “Teflon” and ren. d§l-

The projectiles can be made of any material. The projectiles according to the invention can be placed on the inside, which is suitable for this purpose with cavities in which the various purposes are used and can be absorbed from the payload at subsonic speed. The cavity can be fired from the barrel of a rifle barrel without either staying open or breaking with a removable, detachable one. In addition, the finished projectile, or porous stopper, must be sealed so that the payload, including a payload if necessary, can spread out after the planting in the animal. The density of the volume must be guaranteed. 45 different types of payloads and different devices can be used, which reduce the release of the payload. A wide variety of materials can be used for the production, see e.g. U.S. Patents 3 948 263 and 3 982 536. of the different projectiles used in accordance with the invention. Of particular interest is the manufacture to be completely detachable. Fabrics with a specific gravity below - bullets made of hydroxypropyl cellulose or another one of that of heavy metals, such as lead, are preferred to polymer soluble in the body. The payload can be achieved in a hollow to achieve the desired inertial properties. Generally, there is space in the body of the projectile, or organic substances are preferred to the solid body, although certain metals, such as magnesium, are admixed and dispersed easily in the projectile. Weighted metals, such as magnesium, are advantageously used that can. The preferred organic substances are completely polymeric and release their contents into the animal. The projectiles that can be used as “solid cans” are also made of materials such as the various thermoplastic and heat-curing interests. are drawn, in which the projectile has a weight of up to approx. 95%. If the projectiles according to the invention have a percentage by weight of active ingredient on animals during which the projectiles are to be and are to be planted in, the rest is a biologically acceptable binder. It is therefore preferred that a biomedically acceptable organic substance is used, which uses 90 to 95% penicillin and 5 to 10% hydroxy. These substances can also contain propyleneellulose as a binding agent from the point of view of being selected in such a way that they are formed in the target animal body according to the invention and used after the ballistic implantation of the projectile or become detachable.

are not solvable. Examples of relatively insoluble substances In the cross section of round deviating floors according to synthetic organic polymers such as polyolefins, e.g. 6J of the invention, polyethylene and polypropylene, polysiloxanes; Polyamides, such as being shot down without losing the barrels even after long nylon; fluorinated hydrocarbon resins; Acrylonitrile buta use of e.g. several hundred kills in un-diene styrene polymers and the like. soiling. In contrast, show up

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in the case of projectiles made from similar materials, the fact that it was exposed to ethylene oxide corrugated. The projectile had the cross-sectional shape and a density of approx. 2.5 g / cm3 to achieve the twist stability.

Shot from conventional barrels with swirl grooves. These floors could be

will be shot after a hundred kills or less, with a cross-section decagonal barrel,

Traces of contamination. As a result, these runs 5 must be made without undesirable contamination. After the periodic cleaning, in order to ensure maximum accuracy when planting in cattle, the implantation sites showed no guarantee. - harmful tissue reaction against the implant. The

The invention is explained in more detail below by means of a few examples of planted responders by means of removed electronic ones. Perception devices are found.

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Example 1 Example 3

Projectiles similar to that shown in FIG. 5 were injected into a projectile similar to that shown in FIG.

Injection molding process made. For this purpose, an intimate casting process was made from hydroxypropyl cellulose, which was mixed or dissolvable with 50 parts of hydroxypropyl cellulose and 50 parts of Cal in animal tissue. It

cium carbonate by dissolving the hydroxypropyl cellulose in 15 held a cavity. This triangular cross-section

To shoot 250 parts of methanol and stirring in the calcium carbonate was sterilized with ethylene oxide. Prepared a thick paste in the cavity. The solvent was removed using a tablet of a dry vaccine (Clostridium Hae

Air drying removed and the resulting cake crushed mermolyticum bacterin). The loaded load

shrunk and for injection molding of bullets under a dead floor had a density of approx. 2 g / cm3.

Forming a ten-cornered shape in cross-section with a 25 cm 20 These bullets could be used from a correspondingly shaped screw pitch. The storeys had a room, the cross section of a decagonal barrel was shot down,

weight of approx. 2 g / cm3. ne that after hundreds of kills

These bullets were entered with subsonic mud soiling of the barrel. After the ballistic implantation

cadence from a correspondingly designed zen in cattle showed that the floor after about 24 hours

Shot down. After several hundred kills, 25 showed that the body had dissolved.

there was no undesirable contamination in the form of precipitation in the run, and there was also no significant loss of speed. As a conventional projectile with a projectile similar to that shown in FIG. 5, round bodies made of the same materials were used to produce a mixture which contained a high proportion of penis and 30 riiiin through a conventional round barrel with swirl grooves. Ten parts of hydroxypropyl cellulose were shot down, the barrel showed traces of fouling - five hundred parts of methanol dissolved. Ninety parts of potassium tongue and had to be cleaned after prolonged use. Penicillin G was stirred into the liquid to obtain a homogeneous slurry. After the pulp had been air-dried, for example 2 the solvent had been removed, the cake-like mixture was finely ground in a mixture suitable for long-term implantation in cattle. The resulting powder was then given in rounds of caliber 0.25 (6.35 mm) with a helical shape - a helical wound, cross-sectionally shaped, cross-sectionally decagonal body * with a 25 cm slope to projectiles The exemplary embodiment according to FIG. 5 was injection molded using polyethylene, which had a density of about 2 g / cm 3. In the middle These floors could be shot through a complementarily provided chamber in the floor, a small passive 40 shaped, cross-sectionally decagonal barrel was used. The rest of the cavity, or that without the undesired pollution. After the chamber was filled with epoxy resin, which dissolved in place and planted in cattle, the bullet was hardened in the animal body. Then the bullet opened more rigidly after about 24 hours.

C.

2 sheets of drawings

Claims (12)

636 695 1. Ballistic projectile with an elongated body and weight and enable a precisely controlled ballistic im-with a conical nose that is arranged coaxially on the body, plantation within a target, e.g. of an animal body. All and one end of it protrudes and the basis of which, however, the cross-sectional area used in these ballistic projectiles can correspond to a total of the neighboring cross-sectional areas of low density to the body's pollution problems, characterized in that if they lead from rifle barrels with conventional swirl bullets has a density of at most 5 g / cm3, and that trains are shot. the nose (14; 31) has an apex angle of 45 ° to 75 °. The object of the invention is not only to point out the different ones and to avoid rounding with a disadvantage of known projectiles at the tip (18; 32), but also a Has a radius of 0.04 to 0.05 cm in order to create the bullet that is shot with a subsonic ball, which is a favorable combination velocity and represents the limited penetration of body shape and density, so that bullets are directed towards an animal to allow minimal damage to the skin and of this type without difficulty over a long period of time with the smooth meat of the animal. Chen launcher can be shot while doing so 2. Projectile according to claim 1, characterized in that gently hit the target. the opposite end of the nose (29; 39) of the body (12; 15 The solution to this problem is concave by claim 1 34). featured. Embodiments of this are based on the 2nd PATENT CLAIMS These floors have a low specific nature 3. Projectile according to claim 1, characterized in that pending claims emerge. the apex angle is approx. 60 ° and the radius of the curve. The elongated body of the bullet is 0.04 cm at the tip of the nose. Engagement with the inner surface of a barrel from which the Projectile according to claim 1, characterized in that 20 projectiles are fired, e.g. in adaptation to the barrel the body has a diameter between 0.45 and 0.76 cm. a device operated with compressed gas. If bullets 5. Projectile according to claim 1, characterized in that the type according to the invention with subsonic speed, the body (12, 34) has a central cavity (20; 33), they penetrate cleanly into the tissue of one of the cylindrical sections coaxial to the projectile axis Animal without containing any appreciable damage to the skin and on the end of the animal's body or flesh opposite the nose. The projectile is open and has a hemispherical section on the end adjacent to the nose (14; 31) at a point within the tissue of the animal, the hemisphere being only a short distance from the entry point , gel-shaped section at the base of the same diameter no matter from which distance the projectile is within the same as the cylindrical section. A range of approx. 'A to 18 m was shot down. Should Projectile according to claim 5, characterized in that the projectile contains a biologically active substance on a bone or a semi-rigid body in the cavity (20). meet part within the animal, so it is stopped or 7. Projectile according to claim 1, characterized in that deflected, without the bone or the relevant part of the body, the body (34, 112, 142) has a shape whose surface is worth damaging. configuration by constant movement of a non-run- The medication, e.g. a vaccine, the cross-sectional area is generated along a helix, 35 an antibiotic or a worming agent, or a device, the cross-sectional area having an outline shape in which, like an electronic locating or marking device, all intersection points of the outline tangent on the product tend to be in the meat of the animal. Body and that of the projectile body and in the largest ra nose of the projectile can lie completely from a uniform dial distance from the axis of the helix. Mixture of a drug and a binder 8. Projectile according to claim 7, characterized in that 40 places. On the other hand, the floor can also have a polygonal outline from one of the flat figures. removable or non-removable solid material of low density 9. Projectile according to claim 8, characterized in that it is shaped and provided with a cavity in the middle, the polygonal outline is decagonal (Fig. 7). the end of the body opposite the nose 10. Projectile according to claim 7, characterized, opens and into which a medicament or a device-that the flat figure an essentially elliptical outline 45 can be placed. has (Fig. 10). The body provided with such a cavity must 11. Projectile according to claim 7, characterized in that it has a sufficiently large diameter so that it contains a biologically active substance. Dose of a medicament or device of considerable 12. Projectile according to claim 7, characterized in that it can accommodate size. On the other hand, it must be as small as possible in the fluids and cells of a living animal body in order to make the wound caused by the projectile soluble to a small extent. hold. Projectile body with a diameter of 0.45 to 0.76 cm is most suitable, with the preferred size of the body diameter being 0.64 cm. For limited Applications of superficial implantation can also