Sol-gel manufactured energetic materials

Abstract

Sol-gel chemistry is used for the preparation of energetic materials (explosives, propellants and pyrotechnics) with improved homogeneity, and/or which can be cast to near-net shape, and/or made into precision molding powders. The sol-gel method is a synthetic chemical process where reactive monomers are mixed into a solution, polymerization occurs leading to a highly cross-linked three dimensional solid network resulting in a gel. The energetic materials can be incorporated during the formation of the solution or during the gel stage of the process. The composition, pore, and primary particle sizes, gel time, surface areas, and density may be tailored and controlled by the solution chemistry. The gel is then dried using supercritical extraction to produce a highly porous low density aerogel or by controlled slow evaporation to produce a xerogel. Applying stress during the extraction phase can result in high density materials. Thus, the sol-gel method can be used for precision detonator explosive manufacturing as well as producing precision explosives, propellants, and pyrotechnics, along with high power composite energetic materials.

Description

RELATED APPLICATIONS [0001] This application is a Divisional of Ser. No. 08 / 926,357 filed Sep. 9, 1997 and claims priority to this Non-Provisional Application entitled “Sol-Gel Manufactured Energetic Materials” by inventor(s) Randall L. Simpson, Ronald S. Lee, Thomas M. Tillotson, Lawrence W. Hrubesh, Rosalind W. Swansiger, Glenn A. Fox.[0002] The United States Government has rights in this invention pursuant to Contract No. W-7405-ENG-48 between the United States Department of Energy and the University of California for the operation of Lawrence Livermore National Laboratory.BACKGROUND OF THE INVENTION [0003] The present invention relates to energetic materials, particularly to the manufacture of energetic materials, and more particularly to the manufacture of energetic materials using sol-gel chemistry. [0004] Energetic materials are herein defined as any material which stores chemical energy in a fixed volume. Explosives, propellants, and pyrotechnics are examples of energetic ma...

AI Technical Summary

Benefits of technology

[0025] Functionalized Solid Network: Use of reactive monomers which have functionalized sites dangling throughout the solid network after gelation. Dissolution of the energetic material constituent in mutually compatible solvents and diffusing into the gel allows the energetic material constituent to react and bind to the functionalized site. Thus, the amount of energetic material constituent may be controlled by the number of functionalized sites while ensuring homogeneity at the molecular level.

Problems solved by technology

Reproducibility in performance is adversely affected by the difficulties of synthesizing and processing materials with the same particle morphology.

Manufacturing these granular substances into complex shapes is often difficult due to limitations in processing highly solid filled materials.

An example of an existing limitation of processing granular solids is in manufacturing energetic materials for detonators.

Handling fine grain powders is very difficult.

Dimensional and mechanical tolerances may be very poor as the pellets may contain no binder.

Manufacturing rates are also low as the process is usually done one at a time.

Certification of material is typically done by expensive, end-use detonation performance testing and not solely by chemical and physical characterization of the explosive powder.

As these detonators or initiating explosives are sensitive, machining to shape pressed pellets is typically not done.

Another current limitation is producing precise intimate mixtures of fuels and oxidizers.

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