This invention relates to combustible structural composites and to methods of forming combustible structural composites.
In certain applications, primarily military, vehicles are used to carry a payload to a location of interest. The vehicles might be of land, sea, or air, or some combination thereof and may be manned or unmanned. The payload might be personnel and/or equipment. In some instances, the payload/personnel/cargo is unloaded or used at a location of interest with the vehicle left behind after serving its primary purpose of delivering the payload to such location. An enemy or undesired persons may thereby have access to, or use of, the vehicle.
Furthermore, in some applications, it might be desirable to transport structures and/or equipment to a desired location in an assembled or unassembled condition. Upon serving its purposes, the structure(s) or equipment might need to be left behind, and to which an enemy or others might undesirably have access. It would be desirable to enable vehicles, structures, and/or equipment to be readily disposed of after such have served their useful purpose and/or to preclude such from being accessed by undesirable entities.
While the invention was motivated in addressing the above-identified issues, it is in no way so limited. The invention is only limited by the accompanying claims as literally worded, without interpretative or other limiting reference to the specification, and in accordance with the doctrine of equivalents.
Preferred embodiments of the invention are described below with reference to the following accompanying drawings.
This disclosure of the invention is submitted in furtherance of the constitutional purposes of the U.S. Patent Laws “to promote the progress of science and useful arts” (Article 1, Section 8).
Aspects of the invention encompass combustible structural composites and methods of forming combustible structural composites. Such composites might be used in any number of existing, or yet-to-be developed, manners. For example, and by way of example only, such might be used as structural load-bearing components of a vehicle. For example, a combustible structural composite might be used as a structural supporting component of an aircraft wing or fuselage (including the skins thereof), and/or sub-structural components of a wing or fuselage. Alternately by way of example, combustible structural composites as described herein might be used as load-bearing structure for land, sea, and/or amphibious vehicles. Further by way of example only, combustible structural composites as described herein might be utilized as structural load-bearing components of a building, equipment, or articles of manufacture other than vehicles. Examples include planar and non-planar sheets that might be used as a surface or an internal structural component of an article of manufacture, of course, including vehicles. Regardless, such load-bearing structural composites will be capable of partial or complete destruction by self-sustaining combustion as described herein. Thereby, a user can selectively choose to destroy wholly or partially a structure or piece of equipment by choosing to selectively cause the structural load-bearing composite to burn.
Several embodiments are described below that might be used in the fabrication of structural load-bearing components of vehicles, buildings, other structures and/or equipments, and by way of example only. Referring initially to
Combustible structural composite 10 is depicted as comprising combustible material 12 and structural-reinforcing fibers 14. The combustible material 12 comprises a fuel metal and a metal oxide. The fuel metal might be in an elemental form, including a plurality of different metal elements in an elemental form. Alternately by way of example, the fuel metal might be an alloy of elemental metals. Specific examples include aluminum, titanium, zirconium, and magnesium, whether used either alone or in any combination, or as an alloy. In one embodiment, the fuel metal comprises aluminum in alloy form, for example, magnalium.
A variety of metal oxides might be used. Specific preferred examples are shown in the TABLE below with respect to example fuel metals.
The fuel metal is present in the combustible material at a weight ratio from 1:9 to 1:1 of the fuel metal to the metal oxide. In one preferred embodiment, the fuel metal is present in the combustible material at a weight ratio from 1:4 to 3:7 of the fuel metal to the metal oxide. The fuel metal and the metal oxide are provided to be capable of exothermically reacting upon application of energy at or above a threshold value to support self-sustaining combustion of the combustible material within the combustible structural composite 10.
A plurality of structural-reinforcing fibers 14 are present in the combustible structural composite 10 at a weight ratio of from 1:20 to 10:1 of structural-reinforcing fibers 14 to combustible material 12. In one preferred embodiment, structural-reinforcing fibers 14 are present in the combustible structural composite 10 at a weight ratio from 1:2 to 2:1 of the structural-reinforcing fibers 14 to the combustible material 12. The structural-reinforcing fibers 14 may or may not be combustible or consumed upon self-sustaining combustion of the combustible material 12 within the combustible structural composite 10, and typically will not be inherently capable of supporting self-sustaining combustion. Fuel metal and metal oxide combustible materials typically contain a ceramic phase that makes such too brittle for use as structural supporting members, in place of metals such as aluminum or steel. Such brittle nature makes such combustible materials unable to carry any meaningful tensile load that is essential in most structural applications. Addition of reinforcing material such as structural-reinforcing fibers may result in a composite effectively capable of carrying significant structural design loads in addition to providing increased fracture toughness in comparison to the combustible material alone. Exemplary structural-reinforcing fibers include one or more of glass fibers (i.e., fiberglass), carbon fibers, and aramid fibers (i.e., KEVLAR®). In another example, the fibers may be of a composition comprising the fuel metal, including fibers of a composition consisting essentially of the fuel metal. Regardless, the fibers may be of uniform length and diameter or of variable lengths and/or diameters. Regardless, an example diameter range for structural-reinforcing fibers 14 is from 4×10−5 inch to 0.1 inch, and an example length range is from 0.050 inch to 12 inches. Other diameters and/or lengths may be used.
Application of energy sufficient to support self-sustaining combustion of the combustible material 12 within the combustible structural composite 10 might occur by any existing or yet-to-be developed manner. Further, selection of the fuel metal and metal oxide compositions and weight ratio relative to one another will impact the threshold energy required to support self-sustaining combustion. Accordingly, the quantity and manner of applying energy may vary upon composition and concentration of materials. For example, compositions may be fabricated such that self-sustaining combustion can be initiated by a conventional match. Further and by way of example only, higher or lower energy application for a given material might occur by application of electrical impulse, or microwave or other radiation exposure. Furthermore, some sort of an initiator might be provided as part of the combustible structural composite 10, or separately from the combustible structural composite 10 to enable initiation of self-sustaining combustion. For example, a suitable incendiary composition might be provided that can be caused to ignite by a lower energy input (i.e., by a match) to initiate burning thereof at a higher temperature that initiates self-sustaining combustion of combustible material 12 at the higher temperature.
As a specific example, a combustible structural composite 10 comprising combustible material 12 of 25.3% by weight aluminum and 74.7% by weight iron oxide will burn once heated to approximately 800° C. The products are alumina, iron and 4 KJ/g of heat. The adiabatic flame temperature for the reaction is greater than 2000° C.
Dimensions and thickness of combustible structural composite 10 can be selected by a person of ordinary skill in the art depending upon resultant strength of the combustible structural composite 10 and the load carrying configuration desired for a structural supporting member of which the combustible structural composite 10 would be a part. Further, additional material might be present within, or in addition to, combustible material 12 and structural-reinforcing fibers 14.
For example,
The above-mentioned
Embodiments of the invention also encompass combustible structural composites 10 comprising the above-described combustible material 12 in combination with a structural load-bearing sheet that is bonded thereto, with the structural load-bearing sheet being present in the combustible structural composite 10 at a weight ratio from 1:20 to 10:1 of the structural load-bearing sheet to the combustible material. For example,
An alternate embodiment of combustible structural composite 40 is shown in
An alternate embodiment of combustible structural composite 40b is shown in
Another alternate embodiment of combustible structural composite 50 is shown in
Foam-comprising core 56 comprises a plurality of combustible material masses 52, as shown by dashed lines in
An alternate embodiment of combustible structural composite 50a is shown in
The above combustible structural composites might be manufactured by any existing, or yet-to-be developed, manner, and in any shapes or configurations. In one example, a tape casting-like process might be utilized. For example, a suitable mixing container is used within which suitable binders and solvents are mixed. Powders of the fuel metal and the metal oxide are added thereto. Further, another oxidizer for the binder might also be added, such as potassium perchlorate. In one embodiment where structural-reinforcing fibers 14 are present throughout the combustible structural composite, such structural-reinforcing fibers 14 may also be added, and the mixture stirred until homogeneity is obtained.
A suitable surface which is ideally chemically inert to the solvent, for example, MYLAR™, is provided. A suitable mold shape may be provided over the surface, and the mixture poured or otherwise spread over such surface within the mold or in the absence of a mold. The resultant composition is then allowed to dry either at room temperature or at an elevated temperature to evaporate the solvent, with the binder or binders holding the resultant combustible structural composite together. The process may of course be repeated to form multiple layers and a larger combustible structural composite. The binder will likely not be combustible, and thereby may compromise the exothermic output of the combustible material 12 wherein some of the energy stored by the combustible material 12 will be utilized to decompose the binder upon burning the combustible material 12. Regardless, combustible structural composites containing binders may be subjected to further treatments, such as hot-pressing to increase their density and toughness. In such an event, much of the binder might be eliminated by exposure to the high temperatures associated with such treatments.
If using sheets of structural-reinforcing fibers, metal or other composition, or metal wire, such might be laid over a chemically inert surface with or without a mold, and the above liquid composition spread thereover. Upon cure, the process could be repeated with the solvent composition bearing the combustible material 12 with or without provision of additional structural-reinforcing sheets and/or metal wire.
An alternate example process includes hot-pressing that may use no binder. For example, structural-reinforcing fibers 14 in combination with combustible material 12 as described above may be placed into a graphite mold. Such mixture is then ideally brought to near the melting temperature of the fuel metal, and placed under high pressure. Ideally, the temperature is maintained below the melting temperature of the fuel metal, but at or above its plastic transition temperature. The combustible material 12 plastically flows together and around the reinforcing material and densifies. Pressing would occur, for example, at 10,000 psi for 15 minutes, whereupon a solidified composite of a desired shape is formed. Subsequent machining thereof may or may not be conducted.
Another example technique is a thermal spray coating process to deposit the combustible material onto structural-reinforcing material 12 with or without using a mold. Such an example process includes introducing fuel metal and metal oxide in combination or separately into a hot gas jet stream that is generated by either electric arc discharge (plasma) or oxygen-fuel combustion. The particles are heated and accelerated by the gas jet to be deposited onto a structural-reinforcing substrate (i.e., a fibrous or metal sheet, or metal wire) to form a coating thereon. An iterative approach is ideally implemented with additional combustible material 12 being deposited. Furthermore, additional reinforcing material may be laid down at desired thickness intervals.
With such a thermal spray process, the powder particles essentially melt in-flight and impact upon the surface onto which the powder particles are sprayed. Such forms a strong bond with one another and the reinforcing material. Upon completion, the combustible structural composite may or may not be densified to reduce void volume that may occur during the thermal spray process. Densification, by way of example only, might be conducted by hot press and/or hot isostatic press.
An aspect of the invention encompasses methods of forming a combustible structural composite. In one embodiment, a liquid mixture is sprayed onto and through a screen mesh. The screen mesh may comprise metal and/or other material. The screen mesh may be planar, cylindrical, or of any other desired shape or configuration. The screen mesh may rest upon a substrate or be elevated above a substrate or other surface during the spraying.
The sprayed liquid is solidified into combustible material 12 that covers a plurality of opposing surfaces of the screen mesh, with the combustible material 12 comprising a fuel metal and a metal oxide as described in the above embodiments with respect to combustible material 12. In one example of a preferred embodiment, the liquid mixture is molten and at a temperature above that of the screen mesh during the spraying. In one example of a preferred embodiment where the screen mesh comprises a cylinder, the screen mesh cylinder is rotated about its longitudinal axis during the spraying, with the solidifying forming the combustible material 12 to line an internal surface and an external surface of the cylinder. For example, the combustible structural composite 40b of
In one specific example, a tubular combustible structural composite was formed using a plasma spray process by first forming an aluminum screen substrate into a desired tubular shape. For example, an aluminum wire mesh was formed into a tubular structure of 12.7 mm in diameter by 125 mm long. The tube was rotated while a plasma torch was translated across the tube longitudinally while spraying a mixture of molten fuel metal and metal oxide with the plasma torch. The exit of the plasma torch was positioned between 25 mm and 200 mm from the rotating tubular structure. The process was repeated multiple times until a desired coating was provided internally and externally on the wire mesh. The process further may be repeated to provide a thicker external coating on the tubular structure than internally within the tubular structure upon complete covering of the openings in the wire mesh.
The plasma torch was operated using 10 standard liters per minute (slm) to 60 slm of argon and from 0 slm to 20 slm of helium. Torch current was adjusted between 400 amps and 1,000 amps. The result was a free-standing tubular structure approximately 13.7 mm in diameter with an internal and external wall thickness greater than 1 mm. Not including the wire mesh substrate, the tubular structure was composed of approximately 32% by weight fuel metal, 65% by weight combustible material, and 3% porosity.
The combustible structural composites 50 described above in connection with
An aspect of the invention also encompasses forming a combustible structural composite 50a, for example, as described in connection with
Referring to
Referring to
In compliance with the statute, the invention has been described in language more or less specific as to structural and methodical features. It is to be understood, however, that the invention is not limited to the specific features shown and described, since the means herein disclosed comprise preferred forms of putting the invention into effect. The invention is, therefore, claimed in any of its forms or modifications within the proper scope of the appended claims appropriately interpreted in accordance with the doctrine of equivalents.
This invention was made with government support under Contract Number DE-AC07-05ID14517 awarded by the United States Department of Energy. The government has certain rights in the invention.
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