EP0229763B1

EP0229763B1 - Tracer ammunition

Info

Publication number: EP0229763B1
Application number: EP86900682A
Authority: EP
Inventors: Thomas E. De Phillipo; James F. Kowalick
Original assignee: LSI Technologies Inc
Current assignee: LSI Technologies Inc
Priority date: 1985-07-10
Filing date: 1985-07-10
Publication date: 1992-10-28
Also published as: EP0229763A4; WO1987000263A1; IN164215B; EP0229763A1; ATE81905T1; DE3586786D1

Abstract

An improved tracer ammunition round and method of manufacturing the tracer ammunition. Each round is fabricated by first providing an elongated hole (38) in a cord (36) of soft metal, filling the hole with a special pyrotechnic composition (40) and then reducing the diameter of the cord to a desired size. The cord is then cropped into round size lengths (42) and each length is treated to provide a shaped slug (44') with a pyrotechnic column throughout its length. The shaped slugs are then inserted into the interior cavities of shaped metallic jackets (52) and are secured therein by crimping (32). The pyrotechnic column (46) is formed of zirconium powder, potassium perchlorate and a suitable binder. The ratio of the length of the column to its diameter is between five and two hundred, the diameter of the pyrotechnic column is between .030 inches and .055 inches and the quantity of pyrotechnic composition in the pyrotechnic column is between 12 grains and 24 grains per linear foot of column.

Description

BACKGROUND OF THE INVENTION

1. Field of the Invention

This invention relates generally to the field of small arms and cannon caliber ammunition, and more particularly, is directed to improved tracer ammunition including an improved method of manufacture of the tracer ammunition.

2. Discussion of the Prior Art

Tracer ammunition, that is, ammunition including pyrotechnic compositions, has long been employed by the military and other organizations to provide a visible "trace" of a projectile's trajectory after the projectile has been fired from a weapon. Such tracer ammunition provides visual assurance that all rounds or slugs are being delivered to the exact area wherein it is desired to direct the fire. Accordingly, for small arms, it is important that the tracer rounds be similar in size, weight and configuration to the other non-tracer rounds so that all ammunition will exhibit similar trajectories and flight patterns. For cannon caliber rounds, all types of ammunition (e.g., armor-piercing, high-explosive, target-practice, etc.) will contain a tracer.
Such prior art pyrotechnic compositions have conventionally been loaded into a hole drilled in the base of the projectile to a predetermined depth wherein the depth of the hole is related to the total visible burning time required. The visible burning time for a pyrotechnic tracer projectile is usually defined as the "trace" of the projectile. This hole in the base of the projectile is filled during the manufacturing process with a pyrotechnic powdered composition, which composition must be consolidated under extremely high compression forces, usually by employing a hydraulic or pneumatic press. This consolidation process may require several consolidation steps and may require the addition of a separate igniter composition in order to assure ignition after firing. The extremely high tamping pressures previously required in the tracer ammunition manufacturing process proved to be extremely cumbersome and difficult when encountering small cavity projectiles to thereby greatly increase production costs while at the same time decreasing reliability and predictability.
The consolidation process presently necessary to produce the currently available tracer ammunition has rendered the manufacture of such ammunition unadaptable to fast production by employment of the usual automatic ammunition manufacturing equipment. This results in the requirement to utilize special, slow functioning machines, thus considerably slowing down the production of tracer ammunition and causing increased production costs. The consolidation process also contributes to the relatively unreliable performance of currently available military tracer ammunition. Military specifications usually set forth the common "trace" requirement that ninety to ninety-five percent of the tracer projectiles actually trace at a reliability level of ninety percent. Ammunition manufacturers have experienced difficulties in meeting such standards. The presently employed consolidation process and the use of standard metal-oxidizer chemical formulation has led to various ammunition malfunctions such as "blinds" (wherein there is no tracing at all), short traces, dim traces or even the ejection of all or part of the pyrotechnic composition during flight (usually called "popout"). Further difficulties have been experienced by prior workers in the art because the proper functioning of many tracer compositions exhibited an undesirable dependence on the ambient temperatures.
Additionally, inasmuch as present small-arms tracer projectiles often do not or can not have the same exterior ballistics as the companion (non-tracer) projectiles such as ball projectiles or HE projectiles, which they must simulate in flight trajectory, it will be appreciated that other design and manufacturing problems exist which have not been fully mastered by those skilled in the art of tracer ammunition production.
It has been found by prior workers in the field that the reliability of ignition and the burning time of a tracer is a sensitive function of several manufacturing and environmental variables. The tracer assembly takes up critical space in the round as a whole and is not readily compatible with other ammunition types. Further, the tracer functioning can perturb the exterior ballistics, and because of this, tracer sub-caliber rounds for large caliber systems or the same caliber tracer rounds for small caliber systems can experience ballistic mismatches as compared with the main or non-tracer round when in flight.
Additionally, the presently available tracer ammunition usually exhibits poor visibility at long ranges from the gunner's location. The relatively large pyrotechnic display of the presently available tracer ammunition provides a close range of visibility which may serve as a locater and thus permit enemy detection of the firing source. Accordingly, many gunners have been faced with the choice of discarding tracer ammunition entirely and thus losing the accuracy and locating affect of the tracer rounds or else, employing the tracer ammunition for accuracy purposes, they might then find themselves unduely attracting return fire because of the locater effect of the tracers. Further, it has been found that in many instances, certain chlorinated ingredients of current tracer compositions have histories of manifesting carcinogenic effects during manufacturing, thereby possibly creating a considerable job hazard. Additionally, as above set forth, automated tracer manufacturing procedures have not heretofore been available and accordingly, the cost of tracer ammunition manufacturing is considerably greater than that of the main, non-tracer rounds.
US-A-3 401 636 relates to a clad pyrotechnic device for use in small projectiles like flechettes. It discloses a tracer ammunition round according to the preamble of claim 1 and having a propellant charge and comprising a hollow jacket defining a shaped interior cavity, a pyrotechnic composition within the cavity and completely filing the central cavity, the pyrotechnic composition being capable of being ignited by the propellant charge to provide a visible trace of the trajectory of the round upon firing, said pyrotechnic composition being included in a thin metallic sheat. But, this document does not disclose means to sink the heat and the device fails to provide a long burn because lack of means for heat absorbtion.
US-A-2 425 148 discloses an incendiary bullet in which the incendiary charge is included in the nose of the bullet. Obviously, the incendiary charge is intended to operate on or in the target and not during the displacement of the round. On the other hand, the incendiary material is not in contact with the propellant charge and a closure is provided in the rearward end of a column usable to load the nose.
The publication entitled " Development of tracer for XM216 Cartridge" (Report R-2033),Dept. of The Army, published Feb.1972, Perkins et al, as disclosed for exemple at page 34, involves a process for producing tracer elements having a pyrotechnic element with a core diameter of 0.058" and a sheating wall thickness of 0.001". The developments discussed in this publication are the same developments which are the subject of the US-A-3 401 636. In this publication the pyrotechnic composition is included in a thin sheat and do not have means to sink the heat.
US-A-2-958-277 (SNELLING) also concerns an incendiary device rather than a tracer. This incendiary device is packaged such that when it is exposed to dry conditions ( i.e., when the conditions are optimum for exploding), the casing material surrounding a self-igniting incendiary composition shrink, break or otherwise permit the entry of air needed for self-ignition. The central cavity is not the primary combustible material, but rather is a combustion accelerator which assists in the ignition of the inflammable material which does not really self-ignite, surrounding the central cavity. Although this document includes a central axial cavity whose diameter is a fraction od the diameter of the device as a whole, the incendiary load substantially fills the jacket.
The present invention relates generally to the field of tracer ammunition, and more particularly, is directed to tracer ammunition featuring a logitudinally extending pyrotechnic core having an extremely small cross sectional diameter.
According to the present invention, the tracer ammunition round having a propellant charge and comprising a hollow jacket having a generally pointed front end and a generally blunt rear end , the jacket defining a shaped interior cavity; a pyrotechnic composition within a central opening and completely filing the central opening, the pyrotechnic composition being capable of being ignited by the propellant charge to provide a visible trace of the trajectory of the round upon firing, is characterized in that a shaped slug is inserted into the jacket cavity, the slug comprising a metallic body, said body having a forward end and a rearward end and a central opening , the central opening forming a column extending longitudinally trough the entire lenght of the body, from the forward end to the rearward end, the rearward end being exposed to the propellant charge, the ratio of the lenght of the central opening column to diameter of the central opening column being at least five, and the pyrotechnic composition defining an elongated pyrotechnic column, the diameter of which is comprised between 0,76 and 1,44 mm. (0.030 to 0.055 inch) the ratio of the mass of slug to the mass of the pyrotechnic column being sufficiently large to cause the slug to act as a heat sink to slow down the speed of combustion of the pyrotechnic composition.
The present invention relates also to a method of fabricating a tracer ammunition round as above.
A continuous pyrotechnic composition filled cord is formed by employing a continuous reel lead, or lead antimony alloy wire or any other soft metal such as aluminium, copper,etc. and then drilling or otherwise providing a continuous, concentric hole theretrough. The concentric central opening is then filled with a suitable pyrotechnic formulation and the two ends of the cord are closed with lead or antimony-lead stoppers. The continuous cord with the filled pyrotechnic composition is then swaged down in size to the desired final diameter, which diameter usually is the inside diameter of the projectile jacket. Preferably, this size will be the same size as the lead cord material usually employed in the conventional manufacture of ball-type ammunition and accordingly, the same manufacturing techniques and equipment usually employed with ball-type ammunition can be utilized when manufacturing the tracer ammunition of the present invention.
In the manufacturing process, the continuous cord is swaged or drawn down to the desired outside diameter and the cord is cropped or cut into slug size segments. Each slug sized segment contains an outer lead or lead-antimony slug with a concentric, small diameter, pyrotechnic column therewithin. The pyrotechnic column extends throughout the length of the slug. After cropping, the slug is then shaped in known manner to provide a generally pointed front end and generally cylindrical rear end of suitable size to allow loading into a brass jacket using conventional ammunition manufacturing equipment.
It is therefore an object of the present invention to provide an improved tracer ammunition of the type set forth.
It is another object of the present invention to provide a novel tracer ammunition featuring pyrotechnic columns including means to produce long burning times with highly intense displays visible over long ranges.
It is another object of the present invention to provide a novel small arms tracer ammunition which can be manufactured utilizing the same equipment and the same manufacturing techniques which are employed when manufacturing the non-tracing rounds.
It is another object of the present invention to provide a novel tracer ammunition featuring a pyrotechnic column characterized by a length-to-diameter ratio which exceeds the value of five.
It is another object of the present invention to provide a novel tracer ammunition including a pyrotechnic column of small diameter and means to slow the burning rate of the pyrotechnic column.
It is another object of the present invention to provide a novel method of manufacturing an improved tracer ammunition wherein the need for a drilled hole to receive a pyrotechnic composition in the base of the projectile can be eliminated.
It is a further object of the present invention to provide a metal encased tracer element for use in cannon caliber ammunition.
It is another object of the present invention to provide a novel tracer ammunition and an improved method of manufacturing the same.
Other objects and a fuller understanding of the invention will be had by referring to the following description and claims of a preferred embodiment thereof, taken in conjunction with the accompanying drawings, wherein like reference characters refer to similar parts throughout the several views and in which:

BRIEF DESCRIPTION OF THE DRAWINGS

Fig. 1 is a cross sectional view, partly in elevation, showing a conventional, prior art type of tracer round.
Fig. 2 is an enlarged, partial, side elevational view of continuous cord containing a continuous, small diameter pyrotechnic column, and partially broken away to expose interior construction details.
Fig. 3 is a side elevational view of a segment of the cord of Fig. 2, cut to the desired length, and partially broken away to expose interior construction details.
Fig. 4 is an enlarged, cross sectional via taken along line 4-4 on Fig. 3, looking in the direction of the arrows.
Fig. 5 is a side elevational view of the segment of Fig. 3, partially broken away, showing a preformed, tracer charged lead slug.
Fig. 6 is a cross sectional view showing the preformed slug of Fig. 5 inserted within a bullet jacket, and partly in elevation to illustrate the jacket crimp.
Fig. 7 is a cross sectional view taken along line 7-7 on Fig. 6, looking in the direction of the arrows.

DESCRIPTION OF THE PREFERRED EMBODIMENT OF THE INVENTION

Although specific terms are used in the following description for the sake of clarity, these terms are intended to refer only to the particular structure of the invention selected for illustration in the drawings, and are not intended to define or limit the scope of the invention.
Referring now to the drawings, there is illustrated in Fig. 1 a prior art type of tracer bullet 10 which includes generally a brass or other metal jacket 12 which is shaped to the desired configuration for the desired path of flight. A point filler 14 completely fills the forward portion of the jacket 12 and preferably, the filler material can be formed of lead in the known manner.
The forward end 16 of the jacket 12 is generally pointed in configuration and the rearward end 18 of the jacket is blunt and is provided with a rear opening 20. The rearward portion of the lead filler 14 is usually drilled or otherwise treated to define a concentric opening 24. Through the rear opening 20 is inserted under pressure a pyrotechnic composition or tracer 22 to fill the slug opening 24. In the illustrated embodiment, the pyrotechnic composition is inserted into the lead. In other configurations, a pyrotechnic composition can be loaded through the jacket rear opening 20 to abut directly the rear end of a shortened lead slug 14 in face to face contact. When required, the rearward end of the tracer composition 22 can be drilled or otherwise worked to provide an opening for receipt therein of an igniter composition 26. In some types of tracers, if necessary, a sub-igniter composition 28 can also be provided to assure ignition of the pyrotechnic composition 22. A closure disc 30 is provided rearwardly of the pyrotechnic composition 22, the igniter 25 and sub-igniter 28 in a manner to close the rear jacket opening 20 and to facilitate the manufacturing process. Preferably, a peripheral crimp 32 is impressed in the jacket 12 to secure the jacket to the lead slug 14. In known manner, the peripheral crimp may be provided with a knurled cannelure 34 to aid in the mechanical bonding of the parts.
Referring now to Figs. 2-5, a series of operations for forming a preformed tracer charged lead slug in accordance with the present invention can bow be described. A continuous pyrotechnic composition filled cord 36 is formed by employing a continuous reel lead, or lead-antimony alloy wire or any other soft metal such as aluminum, copper, etc. and then drilling or otherwise providing a continuous, concentric hole 38 therethrough. Optionally, a tube of lead, lead-antimony alloy or aluminum, etc. with relatively thick side walls and with a relatively small diameter longitudinal opening can be employed. The concentric, central opening 38 is then filled with a suitable pyrotechnic formulation and the two ends of the cord can be closed with lead or antimony-lead stoppers. The continuous cord 36 with the filled pyrotechnic composition is then swaged down in size to the desired final diameter, which diameter usually is the inside diameter of the projectile jacket. Preferably, this size will be the same size as the lead cord material usually employed in the conventional manufacture of ball-type ammunition and accordingly, the same manufacturing techniques usually employed with ball-type ammunition can be utilized when manufacturing tracers. It is noteworthy that there is no need to individually drill a rear opening in each round, nor to insert a suitable pyrotechnic composition into that hole under considerable pressure in the manner previously required when producing tracer ammunition. Thus, the manufacture of tracers will take no longer than the manufacture of non-tracer ammunition when using the method of the present invention.
In the manufacturing process, after the continuous cord 36 is swaged or drawn down to the desired outside diameter, the cord is cropped or cut into slug size segments 42 as illustrated in Fig. 3. As shown in Figs. 3 and 4, each segment 42 contains an outer lead or lead-antimony slug 44 with a concentric, pyrotechnic column 46 therewithin. In ball type ammunition as illustrated, the pyrotechnic column 46 extends throughout the length of the slug 44. As best seen in Fig. 5, after cropping, the slug 44 can be shaped in known manner to provide a generally pointed front end 48 and generally cylindrical rear end 50 of size to allow loading into a brass jacket 12 using conventional ammunition manufacturing equipment. See Fig. 6.
In the preferred embodiment, the pyrotechnic column 46 illustrated in Fig. 5, after swagging or drawing down the cord 36 to the required size, preferable measures between 0.76 and 1.44 mm (0.030 inches to 0.055 inches) in diameter and the core loading density of pyrotechnic material is between approximately twelve grains per linear foot and twenty-four grains per linear foot. A core size of approximately .044 inches in diameter has provided improved results with better ignition reliability over smaller core diameters due to the larger core area that is exposed, while sacrificing only a minor amount of trace distance. The relatively small diameter of the pyrotechnic column surprisingly produces an improved tracer capable of yielding a highly intense, yet distinct line of light along the trajectory which is visible over a range 140% that of conventional tracers. The tracer of the present invention is visible to the gunner within a ^± 20° angle from the trajectory, but due to its small diameter, is not visible to the enemy.
It has been found that with larger pyrotechnic core diameters, that is, core sizes of 1.52 mm (0.060 inches in diameter and larger, the trace distance falls off dramatically with a corresonding loss in trace quality. The term "trace quality" as used herein is defined to mean the evenness and continuity of the trace output, where a bright, thin, straight line is preferable. The larger core sizes 1,52 mm or (0,060 inches and larger) display a larger, unacceptable amount of what is usually termed "frazzle", that is, a widely dispersed sparkling effect in the trail of the tracer.

In view of the extremely small diameter of the pyrotechnic column 46, the pyrotechnic composition 40 must be of a type that will burn brightly at a controlled rate, that will burn for a sufficient length of time to permit visual observation over the entire range and that will not be subject to burn-outs or misfiring. In order to produce a satisfactory pyrotechnic composition capable of meeting this criteria, numerous tests have been conducted and the compositions employed in each test are set forth below. In each test, various composition by weight of zirconium powder, potassium perchlorate and a polyester binder have been employed. In each instance, the zirconium powder employed was finely divided through a forty micron sieve, granular type one, meeting the requirements of Mil-399, class 3. The potassium perchlorate utilized was "primer grade", sieved through a sixty mesh sieve size, meeting the requirements of Mil-P-217, grade A, class 3. The polyester binder was type B, high strength. An alternate binder comprising vinyl alcohol acetate resin (VAAR) as manufactured by Union Carbide Company, company specification US-MA-28-18, 28% solids was also tested in the first three compositions. The following compositions expressed in percentage by weight were tested:

INGREDIENT	TEST NUMBER
	1	2	3	4	5	6	7	8
zirconium powder	69.3	69.0	68.7	58	38	77.5	65	62.5
potassium perchlorate	29.6	29.4	29.3	38	58	17.5	25	22.5
VAAR or polyester binder	1.1*	1.6*	2.0*	4.0	4.0	5.0	10	15

*Compositions tested with VAAR binder

Of the above tested compositions, it has been determined that the compositions of Tests 1, 2 and 3, using the VAAR binder and the compositions of Tests 7 and 8 using the polyester binder have proved to be most satisfactory for the purpose and test compositions have been designated by the applicants as LSI-PT-44, LSI-PT-45, LSI-PT-46, LSI-PT-47 and LSI-PT-48.
Referring now to Fig. 6, utilizing the formed and shaped slug 44' of Fig. 5, the slug can be loaded into the open rear 54 of the brass jacket 52 by employing the usual equipment utilized to load lead rounds (not shown) in substantially the same manner and in substantially the same amount of time. After the interior of the brass jacket 52 is loaded with the slug 44', the medial crimp 32 can be applied about the periphery of the jacket to secure the parts together. At the same time, in the manner previously described, a knurled cannelure 34 can also be formed. Additionally, if desired, the rear end 58 of the jacket 52 can be pressed, molded or otherwise formed to provide conventional boattail 56. Thus it is seen that a finished tracer round 60 can be provided having a pyrotechnic column 46 of relatively thin diameter extending the entire length of the tracer round 60.
Also, it will be noted that during the formation of the tracer round 60, there was no requirement for any drilling or filling operations. Accordingly, after the production of the formed slug 44' of Fig. 5, conventional ammunition manufacturing equipment can be utilized in the usual manner to form the tracer ammunition of the present invention. Additionally, it will be noted that the pyrotechnic column 46 extends the entire length of the jacket 52 and that the diameter of the pyrotechnic column 46 is relatively small in comparison to the diameter of the lead or lead-antimony slug. Additionally, in view of the fact that the pyrotechnic column 46 extends the entire length of the slug, there is no tendency or possibility of the pyrotechnic material separating from the lead or lead-antimony slug. By employing the peripheral crimp 32 to secure the slug within the jacket, assurance can then be made that the pyrotechnic column will also be secured to the jacket.
It will be noted that the lead slug 44' completely surrounds the pyrotechnic column 46 for its entire length and fills the entire interior cavity of the jacket. The lead slug 44' then acts as a heat sink in a manner to control and slow the rate of burning of the pyrotechnic column 46. As heat is generated upon ignition of the pyrotechnic column, a significant portion of the heat will be absorbed into the surrounding heat sink material, thereby slowing the rate of combustion of the pyrotechnic material to assure tracer burn over the entire range.
As above set forth, in accordance with the teachings of the present invention, the ratio of the length of the pyrotechnic column to the diameter of the column is greater than five. This results in an elongated pyrotechnic column of very small diameter. For example, for 22 cal. ammunition, a pyrotechnic column having a diameter of approximately 0,76 mm (0.030 inches has been satisfactorially tested.
In view of the small diameter of the pyrotechnic column, the applicants' compositions LSI-PT 44, LSI-PT-45, LSI-PT-46, LSI-PT-47 and LSI-PT-48, have been selected for their reliability in ignition and their burning rate. Because of the relatively large mass to pyrotechnic ratio, upon ignition, the unit thermal characteristics of the tracer ammunition comes into effect, even for small caliber rounds, and the heat of the reaction is driven off into the surrounding lead, lead-antimony, aluminum or other soft metal sidewalls. The sidewalls function as a heat sink to thereby slow down the speed of reaction to assure trace over the entire flight path.

Claims

A tracer ammunition round having a propellant charge and comprising a hollow jacket (60) having a generally pointed front end and a generally blunt rear end (56) the jacket defining a shaped interior cavity; a pyrotechnic composition within a central opening and completely filing the central opening, the pyrotechnic composition being capable of being ignited by the propellant charge to provide a visible trace of the trajectory of the round upon firing, characterized in that,

a shaped slug (44') is inserted into the jacket cavity, the slug (44') comprising a metallic body, said body having a forward end (48) and a rearward end (50) and a central opening (46), the central opening (46) forming a column extending longitudinally trough the entire lenght of the body, from the forward end (48) to the rearward end (50), the rearward end (50) being exposed to the propellant charge, the ratio of the lenght of the central opening column to diameter of the central opening column being at least five, and the pyrotechnic composition defining an elongated pyrotechnic column, the diameter of which is comprised between 0,76 and 1,44 mm. (0.030 to 0.055 inch) the ratio of the mass of slug to the mass of the pyrotechnic column being sufficiently large to cause the slug (44') to act as a heat sink to slow down the speed of combustion of the pyrotechnic composition.
The tracer round of claim 1 characterized in that the pyrotechnic column (46) has a diameter of 0.76 to 1.1 mm (0,030 to 0.044 inch).
The tracer round of claim 1 characterized in that the ratio of length to diameter of the central opening is between five and two hundred.
The tracer round of claim 1 characterized in that the quantity of pyrotechnic composition is between 2,56 to 5,13 mg per linear millimeter (12 to 24 grains per linear foot of column).
The tracer round of claim 3 characterized in that the ratio of the diameter of the slug to the diameter of the column is about 6.
The tracer round of claim 1 characterized in that the jacket is cannon caliber in size, between 20 mm and 40mm.
The tracer round of claim 1 characterized in that the jacket is 22 caliber or larger in size.
The method of fabricating a tracer ammunition round comprising the step of forming a hollow metallic jacket to a shaped configuration and defining a shaped interior cavity of complementary configuration to a slug-shaped configuration characterized in that it comprises further
- providing a 0,76 to 1,1 mm (0.0030 to 0.044 inches) diameter elongated hole in a cylindrical cord of lead or other soft metal containing material, the elongated hole extending continuously along the entire length of the cylindrical cord;

- filling the elongated hole with a fast burning pyrotechnic compound;

- reducing the diameter of the cylindrical cord and the elongated opening;

- cropping the cord into round-size length and shaping the configurations of the cropped lengths into shaped configurations to form shaped slugs, wherein the pyrotechnic compound extends continuously along the entire length of the slug between its front and rear ends;

- inserting a shaped slug into the shaped interior cavity and securing the slug therewithin, the ratio of the mass of the slug to the mass of the pyrotechnic column being sufficiently large to cause the slug to act as a heat sink to slow down the speed of reaction of the pyrotechnic composition.
The method of claim 8 characterized in that the filling comprises inserting between 2,56 to 5,13 mg of pyrotechnic composition per 1 mm of elongated hole (12 to 24 grains per linear foot of elongated hole).
The method of claim 8 characterized in that the reducing is by swaging or drawing.
The method of claim 8 characterized in that the providing comprises forming the elongated hole of approximately 1,1 millimeter (.044 inches) in cross sectional diameter.
The method of claim 11 characterized in that the filling comprises utilizing a core loading weight of pyrotechnic material of between approximately 2,56 to 5,13 mg/mm.