TITLE: Insensitive high energetic explosive formulations United States Patent 5061330 ABSTRACT: A cast cured propellant and explosive with a higher volume percentage of ymer resulting in improved mechanical and safety properties is made from glycidyl azide polymer, an energetic plasticizer and HMX or RDX. Aluminum powder can also be added. INVENTORS: Reed Jr., Russell (Ridgecrest, CA) Chan, May L. (Ridgecrest, CA) APPLICATION NUMBER: 06/440678 PUBLICATION DATE: 10/29/1991 FILING DATE: 11/01/1982 ASSIGNEE: The United States of America as represented by the Secretary of the Navy (Washington, DC) PRIMARY CLASS: 149/19.6 OTHER CLASSES: 149/19.4 INTERNATIONAL CLASSES: C06B25/34; C06B45/10; (IPC1-7): C06B45/10 FIELD OF SEARCH: 149/19.4, 149/19.6, 149/19.1, 149/92 US PATENT REFERENCES: 4379903 Propellant binders cure catalyst April, 1983 Reed et al. 528/55 4288262 Gun propellants containing polyglycidyl azide polymer September, 1981 Flanagan et al. 149/19.6 4269637 High-performance MHD solid gas generator May, 1981 Flanagan 149/19.91 4168191 Thermally stable, plastic-bonded explosives September, 1979 Benziger 149/92 4163681 Desensitized explosives and castable thermally stable high energy explosive compositions therefrom August, 1979 Rothenstein et al. 149/92 4141910 Azido compounds February, 1979 Flanagan et al. 149/88 4098625 Explosive compositions bonded with fluorocarbon polymers July, 1978 French et al. 149/92 4011117 Method for curing poly(glycidyl 2,2-dinitro-2-ethoxide) March, 1977 Lo et al. 149/88 3907907 2-Fluoro-2,2-dinitroethyl substituted polyethers September, 1975 Frankel et al. 149/88 PRIMARY EXAMINER: Miller, Edward A. Attorney, Agent or Firm: Sliwka, Melvin J. Sheinbein, Sol Parent Case Data: This is a continuation of application Ser. No. 07/241,189 filed Sept. 7, 1988, now U.S. Pat. No. 4,968,441. CLAIMS: What is claimed is: 1. An explosive composition comprising: glycidyl azide polymer as an energetic binder; bis(2,2-dinitro-2-fluoroethyl) formal as a plasticizer; and an explosive compound selected from the group consisting of cyclotetramethylenetetranitramine and cyclotrimethylenetrinitramine. 2. An explosive composition according to claim 1 further comprising aluminum powder. 3. An explosive composition according to claim 1 comprising on a weight percent basis: 7.0 to 12.6 percent glycidyl azide polymer, 20.0 to 50.4 percent bis(2,2-dinitro-2-fluoroethyl) formal and 37 to 65 percent explosive compound. 4. An explosive composition according to claim 2 comprising on a weight percent basis: 10.0 percent glycidyl azide polymer, 20.0 percent bis(2,2-dinitro-2-fluoroethyl) formal, 57 percent explosive compound and 13 percent aluminum powder. DESCRIPTION: BACKGROUND OF THE INVENTION 1. Field of the Invention This invention relates to propellants and explosives. More particularly, this invention relates to cast cured propellants and explosives containing energetic polymeric binders. 2. Description of the Prior Art Conventional plastic-bonded explosives (PBXs) contain inert polymers as desensitizing binders. One commonly used inert binder is polyethylene glycol. Pressed PBX compositions can have relatively low levels of polymer or wax. Cast-cured PBXs contain higher levels or rubbery polymers to improve the processing. High levels of polymer make these compositions less hazardous, but also less energetic. Some studies have suggested that the hazard properties in detonable propellants and explosives become more benign as propellant toughness is increased. Propellant toughness is a combination of tensile strength and elongation properties. These properties are known to be improved by an increase in the percent volume of polymer in the composition. A reduction in the amount of crystalline explosive filler such as cyclotetramethylene tetranitramine tetranitramine (HMX) and cyclotrimethylenetrinitramine (RDX) will improve the safety properties. Energetic plasticizers have been substituted for a portion of the solid fillers with varied success. Previously, the use of high levels of plasticizers has been associated with the problem of plasticizer exudation. SUMMARY OF THE INVENTION The present invention is a cast-cured propellant and explosive composition. The composition comprises glycidyl azide polymer as an energetic binder, a plasticizer selected from the group consisting of bis(2,2-dinitro-2-fluoroethyl) formal, a eutectic mixture of bis(2,2-dinitropropyl) formal/acetal, trimethylolethane trinitrate, triethyleneglycol dinitrate, and HMX. Additionally, aluminum can be added to the composition. OBJECTS OF THE INVENTION Accordingly, it is an object of this invention to provide a cast-cured propellant and explosive composition having a high content of polymeric binder and energetic plasticizer with a reduced HMX or RDX content. Another object of this invention is to provide a cast-cured propellant and explosive using the energetic binder glycidyl azide polymer in place of the inert polymer binder. Still another object of the invention is to provide a propellant and explosive with improved mechanical properties to give greater safety. Yet another object of the invention is to provide a propellant and explosive having a high tensile strength and better elongation properties. These and other objects of the invention will become apparent from the following specification. DETAILED DESCRIPTION OF THE INVENTION The energetic azido-polymer glycidyl azide polymer (GAP) is used as a binder in plastic-bonded explosive compositions. Basically, the energetic binder GAP comprises hydroxyterminated aliphatic polyether having pendent alkyl azide groups. The GAP energetic binder is more fully described in U.S. Pat. No. 4,268,450. PBXs with this binder have enhanced properties in the areas of performance and safety. Formulations with the relatively high content of the energetic polymer GAP significantly increase the volumetric fraction of polymers, but do not reduce performance. The level of crystalline explosive HMX or RDX is reduced as the energetic binder content is increased. This transfer of energy releasing groups from the solid phase to the soft polymeric binder phase results in a high performance propellant or explosive with reduced hazard potential. A further enhancement of the safety properties of a cast-cured PBX is achieved by replacing additional HMX or RDX, the solid crystalline filler, with an energetic plasticizer. Improved safety results from reduced sensitivity to initiation by impact shock and deflagration to detonation transition during processing, transportation, and combat use. High levels of plasticizers previously caused problems having a tendency to suffer plasticizer exudation. Explosives and propellants have stringent requirements which allow no exudation during temperature cycling and the aging of plasticized compositions. The need for more energetic rocket propellants led to the development of various compositions containing high levels of energetic plasticizers which exhibit no exudation. GAP has been found to retain high levels of plasticizers without exudation (plasticizer/polymer, Pl/Po=6.0). Earlier compositions with the inert binder polyethylene glycol contained up to only 3 parts plasticizer per 1 part polymeric binder. The plasticizers used with the GAP binder in these formulations include bis(2,2-dinitro-2-fluoroethyl) formal (FEFO), a eutectic mixture of bis(2,2-dinitropropyl) formal/acetal (BDNPF/A), trimethylolethane trinitrate (TMETN), and triethyleneglycol dinitrate. FEFO is the most desirable PBX plasticizer because of its high energy contribution and least loss of mechanical properties. BNDPF/A is lower in energy contribution but has favorable effects on PBX mechanical and hazard properties. A number of 70 g propellant formulations were prepared under vacuum in high shear vertical mixers according to standard procedure known to those in the art. Triphenyl bismuth (0.02 wt percent) and dibutyltin dilaurate (0.005 wt. percent) were used as catalysts, while the biuret trimer of hexamethylene diisocyanate was used as the curative for these compositions. Curatives such as 4,4'-Diisocyanatodicyclohexylmethane or hexamethylene diisocyanate can be used to replace a portion of the biuret trimer. Both the ethylene glycol initiated GAP and the glycerol initiated GAP were used. The mechanical properties were best with the ethylene glycol initiated GAP. The characteristics of the ethylene glycol GAP which was made by Rocketdyne Division of Rockwell International were: Mn-1869, Mw 2139, pd-1.14, eg. wt. 1122, ΔHf cal/g 189, and density 1.3. The following examples illustrate specific embodiments of the invention: Example I summarizes the formulations of GAP alone and with the various plasticizers. EXAMPLE I ______________________________________ Ingredient, % Wt A B C D ______________________________________ GAP 16.26 16.26 16.26 30.7 FEFO 13.74 -- -- -- TMETN -- 13.74 -- -- BDNPF/A -- -- 13.74 -- HMX (10 μm) 60.0 60.0 60.0 56.25 Al (18 μm) 10.0 10.0 10.0 13.04 Impact sensitivity (cm 28 31 36 48 2.5 Kg, 50%) ______________________________________ EXAMPLE II ______________________________________ Ingredient, % Wt A B C D ______________________________________ GAP 6 16.26 21.72 11.28 BDNPF/A 24 13.74 18.32 19.43 Al 13 10 -- 13.04 HMX 57 60 60 56.25 Sensitivity 29 36 39 22 Impact (2.5 Kg, 50%) Friction (ABL, 1000 lb) 9/10 NF -- NF NF Electrostatic (0.25 J) 10/10 NF -- -- 10/10 NF Vacuum Thermal -- -- -- 0.22 Stability (100° C., 48 hrs, ml/g) Elongation (max. stress, %) -- -- -- 41 (rupture, %) -- -- -- 124 Stress (max, psi) -- -- -- 40 Modulus (PSI/PSI) -- -- -- 265 ______________________________________ A formulation made similar to composition A in Example II, only with polyethylene glycol (PEG) rather than GAP had plasticizer exudation. The formulation with GAP produced satisfactory results. Detonation pressures of various compositions containing GAP were calculated using the Kamlet method. The compositions contain varied amounts of the GAP binder and FEFO plasticizer to reduce the amount of HMX or RDX. The mechanical properties such as toughness are related to the volume percent of polymer. As toughness increases the hazard sensitivity properties are improved. EXAMPLE III ______________________________________ Prior art comp (1) (2) (3) (4) (5) (6) ______________________________________ PEG 6.4 -- -- -- -- -- GAP -- 25.0 12.6 11.0 7.0 10.0 FEFO 18.61 -- 50.4 44.0 28.0 20.0 HMX -- 75.0 37.0 -- 65.0 57.0 + 13.0 Al RDX 75.-- -- -- 45.0 -- -- Polymer, vol % 8.9 32.8 16.0 13.9 9.2 14.8 det. press 266 278 267 267 311 295 (Kj, Kbar) ______________________________________ Obviously, many modification and variations of the present invention are possible in light of the above teachings. It is therefore to be understood, that within the scope of the appended claims, the invention may be practiced otherwise that specifically described.