The present invention generally relates to pyrotechnic delay compositions that burn slowly to allow for a time lapse before ignition of a primary charge and, more particularly, to novel non-toxic pyrotechnic delay compositions in which no ingredients pose any environmental hazard.
A delay fuse is a known pyrotechnic device designed to give a delay before ignition of a primary charge, or between ignitions of successive charges in an explosive train. Pyrotechnic delay fuses are widely employed in fireworks exhibitions, mining, quarrying and other blasting operations in order to permit sequential initiation of the explosive charges in a pattern. They are also commonly used in artillery applications to afford a number of seconds for the operator to retire from the artillery before it functions, or to time the explosion of an artillery shell.
Existing delay detonator cartridges comprise a metallic shell closed at both ends and containing in sequence a percussion cap, pyrotechnic delay composition, and igniter. The delay composition imposes an ignition delay between the percussion cap and igniter.
A large number of burning pyrotechnic delay compositions are known in the art, and generally include mixtures of fuels and oxidizers. There are certain requirements for these compositions. They must burn without creating large amounts of gaseous by-products which would interfere with the functioning of the delay detonator. Moreover, pyrotechnic delay compositions should be safe to handle, from both an explosive and health perspective, and they must be resistant to moisture and degradation over periods of time. They are also subject to volume constraints as they must operate in a wide range of delay detonators within the confines of space available inside existing detonator shells.
A large number of delay compositions consisting of mixtures of fuel and oxidizers are known, e.g. Manganese Delay (MIL-M-21383: Mn—PbCra4—BaCrO4), Tungsten Delay (MIL-T-23132: W—BaCrO4—KClO4—SiO2), T-10 (B—BaCrO4,), etc. See, e.g., M. E. Brown, S. J. Tylor, and M. J. Tribelhorn, Fuel-Oxidant Particle Contact in Binary Pyrotechnic Reactions, Propellants, Explosives, Pyrotechnics 23, 320-327 (1998). Unfortunately, these existing ignition delay mixtures are not environmentally friendly due to the toxicity of individual components. For example, Manganese Delay (MIL-M-21383) or Tungsten Delay (MIL-T-23132) and other similar pyrotechnic delay compositions contain carcinogenic hexavalent chromates. Silicon and barium sulphate delay compositions include a proportion of red lead oxide, also carcinogenic. There is a significant desire in the explosives industry to eliminate all use of lead or other toxins and carcinogenics as compounds in delay compositions.
Recently it was found that Si—Al—Fe3O4 could be considered as a potential replacement for commercial formulations. This mixture appears to be very safe when tested by impact or friction and it is rather insensitive to electrostatic discharge. Ignition temperatures are close to 1000° C. The advantages of Si—Al—Fe3O4 are its insolubility in water and resistance to moisture and that it is environmentally benign. Thus, it would be greatly advantageous to provide a non-toxic pyrotechnic delay composition based principally on Si—Al—Fe3O4 that burns substantially gas-free, is safe to handle, is resistant to moisture and degradation over time, can be incorporated within the confines of existing detonator shells, and that poses no environmental hazard.
An aspect of the invention is to provide a non-toxic environmentally-friendly pyrotechnic delay composition blended principally from Si—Al—Fe3O4 that burns substantially gas-free, is safe to handle, resistant to moisture and degradation over time, can be incorporated within the confines of existing fuse explosive trains, and that poses no environmental hazards.
In accordance with the stated aspects, a novel pyrotechnic delay composition is provided for use in conventional metal delay fuse cartridges, each including a burnable delay composition for providing a progressive burning zone. The burnable delay composition includes as its primary constituent Si—Al—Fe3O4. More specifically, the pyrotechnic delay composition includes Si—Al—Fe3O4 in a range of from about 15 wt % Si and about 85 wt % Fe3O4 to about 35 wt % Si and about 65 wt % Fe3O4, and more particularly at least about 1 wt % Al, about 29 wt % Si and about 70 wt % Fe2O3.
The composition burns substantially gas-free, is safe to handle, resistant to moisture and degradation over time, can be incorporated within the confines of existing detonator shells, and poses no environmental hazards.
The present invention includes s a non-toxic pyrotechnic delay composition based principally on a silicon-aluminum-iron oxides mixture and, more specifically, a blend comprising powdered or acicular powdered Silicon, Ferric Oxide powder and Fine Grain Aluminum. The pyrotechnic delay composition of the present invention generally includes powdered or acicular powdered Silicon, Ferric Oxide powder or Ferrosoferric Oxide powder, and Fine Grain Aluminum and, more particularly, Si—Al—Fe3O4. The blend is formulated to provide an ignition delay system with an average inverse burn rate in the range of 0.0046182-0.005644 m/s. The blend described herein has a consistent burn rate in the range between 0.005 and 0.02 m/s, an activation energy of approximately 227 kJ/mol, is nontoxic and none of the ingredients pose an environmental hazard. This makes an excellent candidate for replacement of conventional pyrotechnic delay compositions. Experimental and modeling studies confirm their performance as herein described. For purposes of description, the following nomenclature will be used.
The Pyrotechnic Delay Composition
An embodiment of the composition is about 1 wt % Al, 29 wt % Si and 70 wt % Fe3O4, within a range from 15 wt % Si and 85 wt % Fe3O4 to 35 wt % Si and 65 wt % Fe3O4. When 15 wt % Si and 85 wt % Fe3O4 are used propagation starts in Si—Fe3O4 system at 70 degrees F., however Aluminum is used to increase propagation. Below the value of that composition there is no propagation. Propagation continued in Si—Fe3O4 system up to 35 wt % Si and 65 wt % Fe3O4. Beyond that range there is no propagation. To prepare the blend, wet mixing of the two reactants takes place in acetone. After mixing for 2 hours, the mixture is sieved three times using a 140-size mesh. The reactant mixture is loaded into aluminum capsules having a diameter of 0.204 inches at a predetermined pressure (for example, 30,000 psi).
All the foregoing reactants are obtained in powder form from commercial suppliers: Silicon (Elkem Metals Company, mean particle diameter 3.6 micron); Fe3O4 (Columbian Chemicals Company, mean particle diameter 2.9 micron, Aluminum (Valimet, Inc. Grade H-2 aluminum weight average particle diameter about 2-3 microns).
Composition Variables that Effect Burn Rate
Combustion front velocity measurements in a metal cavity (see
1. Gas Pressure Gradients
In an actual close column cartridge, pressure is rapidly built up in the ignition cavity, which causes hot gases to flow through the porous reactant mixture. These hot gases preheat reactants causing faster combustion front propagation. The source of the pressure may be gas output from the ignition source, temperature increase, or desorption of volatile species. In an attempt to better understand the effect of pressure on the burning time, experiments were conducted under uni-axial gas pressure gradients in an Al—Si—Fe3O4 system. Propagation velocities under uni-axial gas pressure gradients were measured using the experimental setup shown in
2. Composition
Composition has an effect on the burning time, and the weight percent of Silicon in the Al—Si—Fe3O4 system was varied to optimize the burn rate at approximately 4.5 sec/inch. It was found that the lowest limit for Si—Fe3O4 at 70° F. was 15 wt % of Si. The upper limit was 35 wt % Si. This data resulted in an embodiment of the composition of 30 wt % Si and 70 wt % Fe3O4, within a range of from 15 wt % Si and 85 wt % Fe3O4 to 35 wt % Si and 65 wt % Fe3O4. Addition of aluminum is required in order to increase the velocity of propagation and to ensure propagation of that system at low temperatures as indicated by the test data. More aluminum may be added to the mixture to yield a higher propagation velocity.
3. Loading Pressure
One of the factors to be considered in the performance of ignition delay devices is the loading pressure of the delay mixture. Thus, for comparative testing it is essential to keep loading conditions the same for all samples.
4. Activation Energy
To determine activation energy, a test reactor shown in
5. Capsule Design
Apparent burn rates can be affected by geometrical factors specific for the cartridge design. Compositions loaded into a small diameter tube burn slower than the same material placed in a cavity with larger diameter. In addition, the heat loss to the wall of the container is less significant for a wide bore tube, relative the heat retained by the composition. The inverse burn rates were measured at room temperature in 0.20 inch and 0.26 inch diameter aluminum capsules are shown in Table 1 (Si—Fe3O4) and in 0.26 inch diameter aluminum capsules in Table 2 (Al—Si—Fe3O4). The reactant mixture and loading conditions were the same for all samples.
The present inventors have also experimented with igniter 4 (AlA), packing it on one side of the delay composition 2 as well as on both sides. It was found that the inverse burn rates are almost same in both cases.
6. Simulations
In addition to the empirical results obtained above, the present inventors have employed mathematical modeling to simulate the combustion wave propagation in condensed reacting systems, both with and without the presence of uni-axial gas pressure gradient. The models (described below) assume that the pressure drop along a cylindrical specimen can be described by the Ergun equation as stated by H. S. Fogler, Elements of Chemical Engineering, 3rd, (1999). The models also assume gasless and elementary character of the combustion process. This reaction can be represented as:
A(solid)+B(solid)→P(solid)
The governing equations describing the condensed-phase reacting system under adiabatic conditions for the semi-finite cylindrical body are:
Mass Balance
Where, φ(ηp,T) is heat released function and it is defined as:
Energy Balance
Where
Cpg=a+bT+cT2. (6)
Continuity Equation
Ideal Gas Law
Ergun Equation
The superficial mass velocity, G, in Equation 9 is defined as
Substituting Equation 10 into Equation 9 gives:
The initial and boundary conditions for semi-finite cylindrical specimen can be written as
t=0 0<z<L:T=To,p=po,η=0,vg=0 (12)
t>0z=0:T=Tc,p=ph (13)
It is convenient from the numerical analysis point of view to rewrite the governing equations 2 through 14 into dimensionless forms. The exponential function in the reaction rate expression, Equation 3, may be approximated using the Frank-Kamenetskii approximation written as follows [15]:
Equation 15 was simplified into
Where:
Thus, the governing equations in dimensionless form are:
Mass Balance
Energy Equation
Where:
Continuity Equation
Where:
Ideal Gas Law
Where:
Ergun Equation
Where:
The initial and boundary conditions can be rewritten as;
The dimensionless variables and parameters used in Equations 15 through 31 are well-defined in the related art nomenclature. For simulation purposes, the first and second order spatial derivates were approximated by an upwind and a central finite different scheme, respectively [11, 12].
Using the foregoing models, the reaction between the delay composition powders can be considered using the kinetic and physico-chemical data taken from the above empirical results. Numerically calculated dynamic profiles of dimensionless velocity, temperature, pressure, density, and conversion profiles were derived, and a good qualitative agreement between the experimental results and numerical calculations was found regarding the effect of gas pressure gradient on the propagation velocity. It was observed that as gas pressure increases the propagation becomes faster.
Actual Experimental Testing Data
Experimental (actual) data was collected on combustion front propagation characteristics in Si—Al—Fe3O4 delay columns. These propagation characteristics were investigated at 70° F., −65° F., and 200° F. The major measurement effort was on the following compositions (70 wt % Fe3O4—this composition was kept constant, Si (20−30 wt %), and Al (0−10 wt %).
Silicon burns well with Fe3O4 in a wide range of concentrations as specified above. However, when the temperature was significantly lower e.g. −65F the range of concentration was significantly narrowed and the Si—Fe3O4 mixture without the addition of aluminum had the tendency not to propagate or propagate in so called oscillatory regime (unstable). The addition of small amount aluminum significantly widened the concentration range for propagation at very low temperatures, which were as important as room or elevated conditions. Therefore, aluminum was used as an additional fuel to allow tunability of combustion front propagation characteristics, especially propagation velocity. The capability of tuning the propagation velocity was very important for design of different delay columns. In studies, aluminum content was varied from 0 to 10 wt %. At higher aluminum concentrations (above 10%) the propagation velocity was much higher than that desired for delay columns. In addition, the combustion temperature increased significantly causing some additional product gasification and therefore possibilities of disintegration of a column prior to the completion of the combustion process. Accordingly, this behavior would be catastrophic from the point of view of the performance of such delay columns. Therefore, the use of aluminum concentrations above 10 wt % is ineffective.
An extra benefit of the addition of Al was the improvement of a structural strength and column pressability and integrity when exposed to vibration or during the combustion process. Based on the tests as indicated below, the use of aluminum in an exemplary range between 0 to about 10 wt % is feasible, and in another exemplary embodiment, aluminum in a range of about 1-about 7 wt % may be used to produce a stable combustion front propagation, and in another exemplary embodiment, aluminum in a range between about 1- about 5 wt % may be used to obtain a more effective tunability range for Si—Al—Fe3O4 delay columns, and in a further exemplary embodiment, aluminum in a range between about 1- about 2.5 wt % may be used for meeting propagation velocities of specific applications.
Specifically, in Tables 3-10 and
Below in Tables 3—X are selected data for multiple measurements of inverse burn rate as the function of Al composition in the mixture consisting of 70 wt % Fe3O4 and the balance of silicon.
It should now be apparent that the present pyrotechnic delay compositions provide non-toxic, environment-friendly delay compositions that replace toxic alternatives such as Manganese Delay (MIL-M-21383), Tungsten Delay (MIL-T-23132) and other pyrotechnic delays containing carcinogenic hexavalent chromates. The present blends burn substantially gas-free, are safe to handle, are resistant to moisture and degradation over time, can be incorporated within the confines of existing fuze explosive trains, and that pose no environmental hazards.
Having now fully set forth the exemplary embodiments and certain modifications of the concept underlying the present invention, various other embodiments as well as certain variations and modifications of the embodiments herein shown and described will obviously occur to those skilled in the art upon becoming familiar with said underlying concept. It is to be understood, therefore, that the invention may be practiced otherwise than as specifically set forth in the following claims.
Finally, any numerical parameters set forth in the specification and attached claims are approximations (for example, by using the term “about”) that may vary depending upon the desired properties sought to be obtained by the present invention. At the very least, and not as an attempt to limit the application of the doctrine of equivalents to the scope of the claims, each numerical parameter should at least be construed in light of the number of significant digits and by applying ordinary rounding.
This application is a continuation-in-part application of application Ser. No. 11/650,758 filed Dec. 15, 2006, now abandoned.
The invention described herein may be manufactured and used by or for the Government of the United States of America for governmental purposes without the payment of any royalties thereon or therefore.
Number | Name | Date | Kind |
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2232745 | Udy | Feb 1941 | A |
3837940 | Spenadel et al. | Sep 1974 | A |
3890168 | Shumway | Jun 1975 | A |
5326732 | Ogawa | Jul 1994 | A |
5356732 | Terasaka et al. | Oct 1994 | A |
5700974 | Taylor | Dec 1997 | A |
Number | Date | Country | |
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Parent | 11650758 | Dec 2006 | US |
Child | 12315488 | US |