Portable selfcontained explosives system

The present invention relates to a system for forming an explosive and more particularly to a system that is portable, self-contained and is capable of mixing essentially non-explosive ingredients from separate containers to form an explosive. The system is particularly adaptable for military or tactical appli­cations.

Common uses for explosives in military or tactical applica­tions are for demolition work, barrier creation, concrete breaching, concertina wire removal, etc. It often is necessary for infantry to carry explosives on their persons for such purposes. This creates a hazard for the person carrying the explosive as well as for those in the person's vicinity, because the explosive, which necessarily must be relatively sensitive to initiation in small quantity applications, may be susceptible to initiation by rifle bullet or other projectile or munition. A need therefore exists for a tactical explosive that can be carried by infantry in a non-explosive state and then rendered detonable at the desired time. This need is satisfied by the system and unit of the present invention which houses segregated non-explosive ingredients that can be readily mixed together at the intended time of usage to form a sensitive, detonable explosive.

In addition, a tactical explosive for infantry use must be capable of being transported in a backpack, must be able to be used with minimal preparation time and must be capable of use in varied weather and battle conditions. The system and unit of the present invention satisfy these requirements in that the unit can be sized to fit in a backpack; the self-contained unit readily can form an explosive within, for example, one minute; the mixing operation can be accomplished manually without any direct contact with the ingredients or the final explosive; the containers protect the ingredients from the environment; an inner container is housed within an outer container and thus the handling of separate containers is not required; the unit can be operated under water and the explosive composition itself can be designed to be flowable and waterproof thereby making it adaptable for a variety of applications.

Finally, a tactical explosive must be capable of producing sufficient energy and brisance to accomplish its intended purpose. Heretofore, a relatively powerful compound explosive has been used such as TNT (trinitrotoluene), Composition B, pressed RDX and C4. As explained more fully hereafter, the system of the present invention is capable of forming an explosive of equal or greater energy and brisance than such compound explosives but which is formed from non-detonable ingredients that can be transported safely.

The system comprises an outer or first container for holding one or more ingredients of the explosive, an inner or second container disposed within or contiguous to the outer or first container for holding one or more ingredients of the explosive and a mixing element for mixing together the ingredients from the two containers to form an explosive. Preferably, the second container is rupturable by engagement of the mixing element, which can be manually operated in a reciprocal or other fashion to mix the ingredients uniformly together. The invention also relates to a unit comprising the containers and mixing element. Preferably, one container holds an inorganic oxidizer salt solution and the other a fuel. When these ingredients are mixed together an explosive is formed from preferably non-explosive ingredients.

Referring to the FIGURE, there is shown one illustrative embodiment of a portable, self-contained explosives mixing unit 1 constructed in accordance with the present invention and includ­ing a first or outer container 2 for holding one or more ingredi­ents of the explosive. This outer container preferably is rigid or semi-rigid and can be formed from any material compatible with the contained ingredients, such as plastic. Housed or disposed within or contiguous to the outer container 2 is an inner or second container 3 for holding one or more additional ingredients of the explosive which when mixed with the ingredient(s) in the outer container 2 will form an explosive. The inner container 3 has at its open end a flange 4 that abutts or sets upon a corresponding surface at the top of the outer container 1. The flange 4 is secured against the outer container 2 by means of a cap 5 that is threadibly engaged with outer container 1 by threads 6. The flange 4 is sealed with respect to the cap 5 by means of an o-ring 7. (A similar o-ring seal could be placed between the flange and the adjacent surface of the outer container or the flange could be glued to such surface.) In this fashion, the ingredients within the inner container are segregated from the ingredients in the outer container.

The inner container 3 is composed of a material that is rupturable or frangible to allow mixing of the ingredients in the inner container with those in the outer container at the desired time. Such frangible materials include polystyrene or other plastics. The cap 5 also could function as an inner container if, for example, inner container 3 were an integral part of cap 5 or if cap 5 otherwise were modified to hold ingredients that were separated from the ingredients in the outer container by means of a rupturable membrane. Thus the language "disposed within or contiguous to" includes configurations in which the inner or second container is adjacent to the outer or first container and separated therefrom by a rupturable membrane.

Slidably engaged with the cap 5 is a mixing element or plunger 8 in the form of a rod and piston assembly having a handle 9, a shaft 10, a baffle plate 11 at the end of the shaft opposite the handle and a base 12 disposed on the shaft 10 between the baffle plate 11 and the closed end 13 of the inner container 3. The shaft 10 extends through the axis of the inner container 3 and protrudes through its closed end 13.

Also shown is a port 14, through which ingredients may be loaded into the inner container 3 or through which a blasting cap may be inserted, and plug 15. A lid 16 is adapted to be removably engaged with the cap 5 to cover and prevent premature movement of the plunger 8.

Once the unit 1 is assembled as shown in the FIGURE with the separate explosive ingredients present in both the inner and outer containers, the unit can be operated to mix the ingredients together and produce an explosive as follows. The lid 16 first is removed and then the handle 9 of the plunger 8 manually is pulled or forced upward or away from the cap 5 and outer container 1. This causes the base 12 of the plunger to put a compressive force on the closed end 13 of the frangible inner container 3, and as the plunger 8 is continued to be pulled toward the top or opening of the outer container 1, the frangible inner container ruptures or breaks and the ingredients thereof are allowed to mix with those ingredients in the outer container. The closed end 13 of the inner container can have grooves or convolutions 17 as shown to ease or enhance the rupturing of the inner container. As the plunger then is forced to reciprocate within the confines of the outer container 1, the baffle plate 11 moves up and down (or back and forth) along the axis of the outer container 1, much like a piston within a cylinder, to mix uniformly the ingredients in the ruptured inner container with those in the outer container. The orifices 18 in the baffle plate 11 enhance this mixing action as the ingredients are forced to flow through the orifices. The ruptured or broken inner container 3 may break apart into several or more separate pieces which also enhance the mixing action, and it has been found that the presence of separate pieces of inner container 3 does not adversely affect the detonation results of the final mixed explosive.

The present invention can be further illustrated by refer­ence to the examples given below.

In a unit similar in construction to that shown in the FIG­URE, explosive compositions were formed under various conditions and were test detonated as follows:

Formulation (parts by weight of the final composition):

Oxidizer Solution (outer container)

Fuel (inner container)

Sodium perchlorate

40.5

Atomized aluminum

18.0

Water

31.0

Paint grade aluminum

2.0

Ethylene glycol

8.0

Xanthan gum

.5

80.0

20.0

Testing Results:

Mix

1

2

3

4

5

Mixing Temp (°C)

25

25

25

25

-10

Mixing Strokes

20

150

50

50

50

Density (g/cc)

1.365

1.356

1.360

-

-

Detonation Temp (°C)

25

25

-10

25

-10

D-150 mm (km/sec)¹

4.54

-125

4.54

-100

4.38

-75

4.23

4.10

4.38

4.23

4.23

-63

-

-

-

3.97

-

-50

-

-

-

3.74

-

-38

-

-

-

3.34

-

-32

-

-

-

3.43

-

-25

-

-

-

3.26

-

-19

-

-

-

2.20

-

-12

-

-

-

Fail

-

MB-det/fail (cap#)²

I2/I1

I3/I2

I3/I2

I1/-

I4/I3

1 Cloth Wrap*

2 50 grain Cord Wraps

-

-

Det³

-

-

1 Cloth Wrap*

1 50 gr. Cord Wrap

-

-

Det

-

-

3 Cloth Wraps*

1 50 gr. Cord Wrap

-

-

Det

-

-

Bullet Impact @ 25°C (22/.250) with Steel backing plate

-

-

Fail⁴

-

-

*A plastic bottle (4.5 inches in diameter) was filled with the mixed explosive. A heavy canvas cloth was wrapped around bottle, and detonating cord was wrapped around the cloth.

¹ Detonation velocity in the given charge diameter at the given temperature.

² Minimum booster in a 75mm charge at the given temperature. The left number indicates that a detonation occurred with the designated cap and the right number indicates a failure. I1 is a blasting cap having 1 grain of loose PETN; I2, I3 and I4 have 2, 3 and 4 grains, respectively.

³ Charge detonated.

⁴ Charge failed to detonate.

In the above example, the inner container was a rigid polystyrene plastic which was ruptured and broken into several pieces upon engagement of the mixing element (plunger comprising a handle, shaft and baffle plate). The outer container was poly­ethylene, the plunger assembly or mixing element was comprised of a polycarbonate shaft and base, and the baffle plate was a high density polyethylene. The cap element, similar in configuration to cap (5) shown in the FIGURE, was comprised of high density polyethylene, and the lid (16) was medium density polyethylene. The inner container contained 1000 grams of the atomized and paint grade aluminum mixture and the outer container contained 3545 grams of the sodium perchlorate solution, which occupied about 2.36 liters of the 3.79 liter capacity of the outer container. The mixing strokes were done manually and each stroke occurred in less than 1 second. Thus all mixes except Mix 2 were formed in less than 1 minute. As indicated in the detonation results, all of the mixes were relatively sensitive to detonation even at a temperature of -10^oC.

The mixing was accomplished by an individual who held the outer container on the ground with one hand while he reciprocated the plunger assembly with the other hand. Following completion of the indicated number of strokes, the resulting mixed explosive was poured into the various charge diameters and plastic bottles for detonation testing.

As shown in the preceding example, explosive compositions for use with the system and in the unit preferably are formed from a binary system of oxidizer and fuel, with the oxidizer in one container and the fuel in the other. The oxidizer component preferably is a solution of inorganic oxidizer salt selected from the group consisting of ammonium, alkali and alkaline earth metal nitrates, chlorates and perchlorates or mixtures thereof. Perchlorates are particularly preferred because they increase density and enhance sensitivity in explosive compositions of this type.

The fuel component can be a liquid, a solid or combinations thereof. The fuel used in the above example was a mixture of aluminum particles, with the paint grade aluminum acting as both a fuel and a sensitizer. Other solid fuels include finely divided carbonaceous materials such as gilsonite, finely divided vegetable grains such as wheat and potato starch, and sulfur. Liquid fuels include water-immiscible organic liquids such as mineral oil, waxes, paraffin oils, benzene, toluene, xylenes and petroleum distillates. Water-miscible organic liquids that can be used as fuels include alcohols such as methyl alcohol, glycols such as ethylene glycol, amides such as formamide, and analogous nitrogen-containing liquids. As shown in the example, a portion of the fuel (ethylene glycol) was contained in the oxidizer solution component, because ethylene glycol is a solvent for the oxidizer and as a liquid was easier to handle in the solution rather than in the dry (aluminum) component.

Water preferably is present in sufficient quantity to keep the oxidizer salt in solution at intended temperatures of use to allow for a fluid mixing medium. The xanthan gum thickening agent in the oxidizer solution renders the solution more viscous which aids in suspending the aluminum particles uniformly throughout the composition following mixing. Various thickening agents are well-known in the art. A density reducing agent, such as hollow glass or plastic spheres, may be included in either the oxidizer or fuel component to increase sensitivity.

The theoretically available energy of the formulation of the example is 1384 kcal/kg, which compares favorably with that for TNT of 1235 kcal/kg.

Although in the above example the oxidizer solution was in the outer container, and the aluminum fuel was in the inner container, this arrangement could have been reversed; however, it was easier to mix the solids into the liquid.

A preferred size of the unit of the present invention is as follows: An outer container capable of holding 4545 grams of mixed explosive and comprising a cylindrical container approxi­mately 15 centimeters in diameter and 20 centimeters in height. The inner container would be about one-fourth of this size (if holding the fuel component). The size of the unit and its various components, however, can be varied as desired.

The explosive should be fluid at the mixing temperature for ease of mixing and to allow ease of removal from the outer con­tainer into a separate receptacle, if desired. Further, a fluid explosive can be used advantageously in a variety of applica­tions.

The positioning of the second container within or contiguous to the first container is not critical; however, if the second container is axially positioned within or contiguous to the first container, then uniformity of the final mixture is somewhat easier to obtain. The concept of housing an inner container within or contiguous to an outer container is advantageous in that it dispenses with the need to handle separate containers. This prevents the possibility of separation or misplacement of one of the containers, does not require the handling of separate containers (which is time consuming and difficult if not impossible to accomplish under water) and prevents potential errors in attempting to combine ingredients from separate containers.

While the present invention has been described with reference to certain illustrative embodiments, various modifications will be apparent to those skilled in the art and any such modifications are intended to be within the scope of the invention.