Patent Document

CROSS-REFERENCE TO RELATED APPLICATION 
     This application claims priority from applicants&#39; prior Provisional Application Ser. No. 60/331,881, filed Nov. 21, 2001, entitled “METHOD AND APPARATUS FOR TREATING AIRCRAFT FUEL TO REDUCE ITS COMBUSTIBILITY IN FLIGHT”. 
    
    
     BACKGROUND OF THE INVENTION 
     The present invention relates to a method and apparatus for treating liquid fuel to temporarily reduce its combustibility. In a preferred embodiment, the present invention relates to a system for treating fuel on board an aircraft, to improve the margin of safety in the event of an aircraft accident. 
     Aircraft accidents are very difficult to survive. Not only does such an accident result in a rapid deceleration at the moment of impact, but, subsequent to impact, loss of life occurs due to smoke inhalation and burning, because of the fire which almost inevitably follows. 
     Following an aircraft accident, it is imperative that any crew or passengers which remain conscious immediately exit the craft. The time available for such an emergency evacuation varies, but usually only a few minutes, if any, are available before the fuel carried on board the aircraft commences burning and in some cases, explodes. 
     SUMMARY OF THE INVENTION 
     It is a principal object of the present invention to provide a method and apparatus for treating liquid fuel to substantially reduce its combustibility, for example when the fuel is to be stored, and to thereafter restore its combustibility. 
     It is a subsidiary object of the present invention to increase the time available for survivors of an aircraft accident to exit the aircraft, before the craft is enveloped in flames, and to decrease the likelihood that an uncontrolled (or uncontrollable) fire will occur. 
     This object, as well as other objects which will become apparent from the discussion that follows, are achieved, in accordance with the present invention, by treating the fuel in such a way as to substantially reduce its combustibility in the fuel tank and/or in open air. The combustibility of a small portion of the treated fuel is later restored (at least to some degree) to its pretreatment value, as such fuel is needed. For example, in the case of aircraft, this higher (i.e., normal) combustibility fuel is supplied to the aircraft engine(s). 
     Since the preponderance of the fuel on board an aircraft is maintained with a low combustibility, the time for evacuation and escape from a crashed aircraft is markedly increased and the likelihood of fire is decreased. 
     In a preferred embodiment of the invention, the combustibility of the aircraft engine fuel is reduced, by cooling the fuel as a liquid to within about 40° C., and preferably to about 25° C. or even about 10° C., above its freezing point. Experiments have shown that liquid fuel which is cooled to within this range of temperatures has its combustibility remarkably reduced. 
     In another preferred embodiment of the present invention, the combustibility of the fuel is reduced by freezing it and maintaining the fuel, on board the aircraft, at a temperature at or below its freezing point. The fuel may be cooled to a temperature much lower than its freezing point; i.e., to 15° C. or even 25° C. or more below the freezing point. 
     Once the fuel is cooled as a liquid to near freezing temperature, or cooled to a temperature at or below freezing, a portion of the fuel must be warmed, as needed by the aircraft engine(s). 
     The freezing point of aviation jet fuel lies in the range of about −40° C. to about −65° C. This range was determined by an “Aviation Turbine Fuel Freezing Point Survey” conducted by Francis Davidson and Dr. Gordon Chiu of Phase Technology, 11168 Hammersmith Gate, Richmond, BC, V7A 5H8, Canada. 
     Techniques for refrigerating and freezing liquids, having freezing points in the range of −40° C. to −65° C. are well known. For example, liquid nitrogen, which is stored under pressure at about −200° C. and is commercially available in large quantities, at a cost of about $50 per ton, may be used as a heat exchange fluid. Other cryogenic fluids or solids, such as carbon dioxide, may also be used. 
     Also known are various techniques for determining the phase transition point and phase transition temperature of fuel. See, e.g., U.S. Pat. No. 4,804,274 to Green. 
     In still another embodiment of the present invention, the combustibility of the fuel is reduced by adding to it a first chemical composition. Thereafter, just before the fuel is used, a portion of this fuel is treated by either removing the first chemical composition or by adding a second chemical composition thereto. The combustibility of this portion of the fuel is thereby restored, or at least increased, before the fuel is converted into energy, for example by the aircraft engine. 
     There are a number of chemical compositions which may serve to reduce the combustibility of fuel. These may be classified as an anti-detonative agent, a polymer agent, a gelling agent, a “soap” and, finally, a bonding agent. 
     The anti-detonative (“anti-knocking”) agents may be lead based, such as tetra-alkyl lead, tetra-ethyl lead, tetra-methyl lead; tin-based, such as tetra-ethyl tin; iron-based, such as iron carbonyl; iodine-based, such as elemental iodine; carbon-based, such as aniline; aluminum-based; silicon-based; germanium-based; nitrogen-based, such as an amine; phosphorus-based; arsenic-based; sulfur-based; selenium-based; tellurium-based; bromine-based; chromium-based; molybdenum-based; tungsten-based; manganese-based; osmium-based; organic-based; nickel-based; palladium-based or platinum-based. 
     Where the first chemical composition is a polymer, the polymer may be polystyrene; made from a monomer which is an alkene, such as a heptene (e.g. 1-heptene), an octene (e.g. 1-octene), a nonene (e.g. 1-nonene), a decene (e.g. 1-decene); or an alkene which has more than ten carbon atoms. 
     In the case where the first chemical composition is a gelling agent, the chemical composition may form a colloid with the fuel, or form a gel. In the case of the gelling agent, the gel may be silicon-based, such as treated silica. The gel may be a silica aerogel which has been subject to derivitization or which has been organically modified. The aerogel is preferably a hydrophobic silica aerogel. Where the aerogel has been subject to derivitization, this derivitization may consist of linking trialkylsilyl groups to the surface hydroxyl groups. The trialkylsilyl groups may be trimethylsilyl groups. In the case where the silica aerogel has been organically modified, the modification may consist of replacing the surface hydroxyl groups with alkoxy groups or consist of linking an organometallic compound to the surface hydroxyl groups. 
     In the case where the first composition is a “soap”, the composition may be a salt of an organic acid, such as an aluminum salt of an organic acid. The chemical composition may also be a salt of a long chain organic acid, such as an organic acid with five to ten carbon atoms, ten to fifteen carbon atoms, fifteen to twenty carbon atoms or more than twenty carbon atoms. The chemical composition may be a salt of an aromatic organic acid such as naphthenic acid. Also the chemical composition may be a mixture of two or more salts of organic acids. 
     In the case where the first chemical composition is a bonding agent, it may consist of a polymer bonded to inner surfaces of the fuel tank, including the inner walls of the tank and/or additional surfaces on plates and the like which have been incorporated into the fuel tank. Alternatively, the polymer may be bonded to small beads, such as beads which are less than one centimeter in diameter, less than one millimeter in diameter or even less than one micron in diameter. 
     In the case where the first chemical composition is a gel, the gel may be bonded to inner surfaces of the fuel tank, including the inner walls of the tank and/or the surfaces of plates or the like which have been incorporated into the fuel tank. Alternatively, the gel may be bonded to small beads, such as beads having a diameter of less than one centimeter, less than one millimeter or even less than one micron. 
     In the case where the first composition is a polymer or a gel, the combustibility of the fuel may be restored by filtration, to eliminate the effects of this polymer or gel. 
     In the case where the polymer or gel is bonded to small beads, the beads themselves, with their bonding agent, may be removed by filtration. 
     Finally, the first composition may also be removed by electrodeposition, electrostatic deposition and/or electroprecipitation. 
     Finally, the combustibility of the fuel may be restored by adding a second chemical composition to a portion of the treated fuel as an “antidote” to the first composition. 
    
    
     
       BRIEF DESCRIPTION OF THE DRAWINGS 
         FIG. 1  is a block diagram of a system, according to a preferred embodiment of the present invention, for providing frozen fuel on board an aircraft, loaded on to the aircraft in frozen form. 
         FIG. 2  is a block diagram of a system, according to a preferred embodiment of the present invention, for providing frozen fuel on board an aircraft, loaded on to the aircraft in liquid form. 
         FIG. 3  is a block diagram of a system, according to another preferred embodiment of the present invention, for providing chilled liquid fuel on board an aircraft. 
         FIG. 4  is a block diagram of a system, according to still another preferred embodiment of the present invention, for providing a chemical additive to the fuel on board an aircraft to reduce the combustibility of the fuel. 
     
    
    
     DESCRIPTION OF THE PREFERRED EMBODIMENTS 
     The preferred embodiments of the present invention will now be described with reference to  FIGS. 1-4  of the drawings. 
     Identical elements in the various figures are designated with the same reference numerals. 
       FIG. 1  shows an embodiment of the invention in which frozen fuel is loaded onto the aircraft. Frozen fuel  2  enters the frozen fuel supply chamber  4  through inlet  6 . A refrigeration system  8  maintains the proper temperature in frozen fuel supply chamber  4  via cooling ports  10 . The frozen fuel supply chamber is insulated with insulating material  12 . Temperature and fuel phase, as well as other characteristics such as viscosity, are monitored within the frozen fuel chamber  4  by monitoring elements  14  which, in the case of temperature may be thermistor-based, thermocouple-based, or other technology, and in the case of phase monitoring may consist of optical density/turbidity monitoring, ultrasound monitoring to look for liquid/solid boundaries, or other monitoring apparatus and associated transducers. Pre-flight, during aircraft fuel loading, frozen fuel intake port  16  is maintained in the open position. At all other times it is sealed. During flight, frozen fuel outlet port  18  is open, unless a threat of crash or accident exists, in which case it may be sealed. Port  20  allows for the supply of refrigerant. The position of each of ports  16 ,  18 , and  20  is monitored and controlled by fuel monitoring and control system  22 . The fuel monitoring and control system  22  also monitors the temperature and phase information from monitoring elements  14 , and uses this information to control refrigeration system  8  to maintain the proper temperature in frozen fuel supply chamber  4 . Most of the fuel carried by the aircraft is maintained in the frozen state. The amount of liquid fuel is maintained at a minimum which, nevertheless, is sufficient to meet the demands of each segment of the flight. 
     Frozen fuel leaves the supply chamber  4  and passes through a cutting/shaping apparatus  24 . This may shave slices off of a bar of fuel, shave a ribbon off of a cylinder of fuel, or create pellets, blocks, strips or spheres of frozen fuel. The cut/shaped fuel is moved by frozen fuel transport system  26  which is controlled by control system  22 . The rate of transport is determined by throttle position, pilot settings and other variables. 
     Frozen fuel then passes to warming chamber  28 , where it is melted by warming system  30 . The warming system has access to the warming chamber via ports  31 . Warm gases or liquid may be supplied to the warming system via port  32 . Alternatively, the system may provide electrical warming via current passing through a resistive element or heating by electromagnetic energy. If necessary, the warming chamber may be sealed by closing inlet door  34  and outlet valve  36 . This chamber is insulated by insulating material  38 . The temperature and phase (and possibly other characteristics) within the chamber are monitored by elements  40 , which are analogous to but not necessarily the same type as elements  14  in the frozen fuel supply chamber  4 . The relative degree of opening of each of ports  32  and  34  and valve  36  is monitored and controlled by fuel monitoring and control system  22 . The fuel monitoring and control system  22  also monitors the temperature and phase information from monitoring elements  40 , and uses this information to control warming system  30 . 
     Liquified fuel leaves the warming chamber and passes successively through valve  36  and through fuel line  42  to fuel pump  44 . Pressure and flow upstream and downstream from the fuel pump are monitored by sensors  46  and  48 , Information from these sensors is monitored by fuel monitoring and control system  22 , which also controls the fuel pump  44 . 
     The fuel then passes through fuel line  49  to the fuel filter  50 . To prevent clogging by ice or remaining frozen fuel, the filter is equipped with a warming system  52 , which is controlled by fuel monitoring and control system  22 . The warming system has access to the filter via ports  54 . Warm gases or liquid may be supplied to the filter warming system  52  via port  56 . Alternatively, this warming system may be electrically powered by an electric current passing through a resistive element or by electromagnetic energy. The position of port  56  is monitored and controlled by fuel monitoring and control system  22 . 
     The liquid fuel then passes successively through fuel line  58 , and intake valve  60  into the liquid fuel reservoir  62 . Pressure and flow within fuel line  58  are monitored by sensor  64  which sends information to fuel monitoring and control system  22 . The liquid fuel reservoir  62  is insulated by insulating material  64 . Temperature and phase (or other characteristics) within this reservoir are monitored by elements  66  which are analogous but not necessarily the same as elements  14 . These elements send their information to fuel monitoring and control system  22 . Access to this reservoir is controlled by inlet valve  60  and outlet valve  74 . In the event of emergency such as impending crash, this chamber may be sealed by closing these valves. The positions of these valves are monitored and controlled by fuel monitoring and control system  22 . Also, in the event of impending crash, the liquid fuel in reservoir  62  may be rapidly cooled or frozen by emergency refrigeration system  68 , which has access to the liquid fuel reservoir  62  by ports  72 . Port  70  allows for the supply of refrigerant to emergency refrigeration system  68 . The emergency refrigeration system  68  is controlled and monitored by fuel monitoring and control system  22 . 
     Liquid fuel passes out of reservoir  62  through valve  74  into fuel line  76 , and flows through the fuel supply system that is in common use for the aircraft. 
       FIG. 2  shows an embodiment of the invention in which liquid fuel is loaded onto the aircraft. The liquid fuel is then frozen. Liquid fuel enters the fuel freezing and supply chamber  3  after passing successively through intake pipe  5  and intake valve  15 . Pre-flight, during aircraft fuel loading, intake valve  15  is maintained in the open position. At all other times it is closed. The position of intake valve  15  is monitored and controlled by fuel monitoring and control system  22 . After entering the fuel freezing and supply chamber  3  in liquid form, the fuel is frozen in this chamber by refrigeration system  8 . Thereafter, chamber  3  serves as a frozen fuel supply chamber, analogous in function to the frozen fuel supply chamber  4 , described in  FIG. 1 . All other components and operations of  FIG. 2  are the same as those shown in  FIG. 1 . 
     Although  FIG. 1  and  FIG. 2  show a single fuel pump and filter, clearly multiple fuel pumps and/or fuel filters may be provided. 
       FIG. 3  shows an embodiment of the invention in which liquid fuel is loaded onto the aircraft. The liquid fuel is then chilled but not frozen. Liquid fuel enters the chilled fuel reservoir  7  after passing successively through intake pipe  5  and intake valve  15 . A refrigeration system  8  maintains the proper temperature in the chilled fuel reservoir  7  via cooling ports  10 . Pre-flight, during aircraft fuel loading, intake valve  15  is maintained in the open position. At all other times it is closed. During flight, chilled fuel reservoir outlet valve  17  is open, unless a threat of crash or accident exists, in which case it may be closed. The position of each of valves  15  and  17  is monitored and controlled by fuel monitoring and control system  22 . 
     Chilled, but not frozen fuel leaves the reservoir  7  and passes through valve  17  into fuel supply line  25 . It then is pumped by fuel pump  45 , after which it passes through another segment of fuel supply line  25 . Pressure and flow may be monitored within each of supply lines  25 , and this information is supplied to fuel monitor and control system  22 . Fuel then passes through warming chamber intake valve  33  and enters the warming chamber. It leaves this chamber through warming chamber outlet valve  36 . If necessary, this chamber may be sealed by closing valves  33  and  36 . The position of valves  33  and  36  is monitored and controlled by fuel monitoring and control system  22 . 
     After passing through fuel line  42 , fuel pump  44 , fuel line  49 , fuel filter  50  and intake valve  60 , the warmed fuel enters warmed fuel reservoir  61 . All other components and operations of  FIG. 3  are the same as those shown in  FIG. 1 . 
     Whereas  FIG. 3  shows two fuel pumps and one filter, clearly a greater (or lower) number of pumps and/or a greater number of filters may be provided. 
       FIG. 4  shows an embodiment of the invention in which a first composition is added to the fuel in order to decrease its combustibility and, thereafter, a second composition is added to a portion of the fuel, as needed by the aircraft engine, to at least substantially restore it to its original combustibility. 
     Fuel enters the first composition mixing chamber and reservoir  1  through supply line  5  and inlet valve  15 . First composition enters chamber  1  through first composition supply lines  11 . The first composition is stored in reservoir  9  which is filled through inlet port  21 . The properties of the mixture of fuel and the first composition, including temperature, infrared, optical and ultraviolet spectroscopy and ultrasound reflection and transmission may be monitored by sensors and transducers  19 . Pre-flight, during aircraft fuel loading, valve  15  is maintained in the open position. At all other times, it is closed. During flight, valve  13  is open, unless a threat of crash or accident exists, in which case it may be closed. Supply port  21  allows for loading first composition into its reservoir  9 . The position of each of valves  13  and  15  and supply port  21  is monitored and controlled by fuel monitoring and control system  22 . The fuel monitoring and control system  22  also monitors the information from sensors  19  and uses this information to control the amount of first composition to be released from reservoir  9  through supply lines  11  into first composition mixing chamber and reservoir  1 . Most of the fuel carried by the aircraft is maintained as a mixture with the first composition. 
     Chemically stabilized fuel leaves chamber  1  passes through outlet valve  13  and through fuel line  23 . It is then pumped by fuel pump  35 , into fuel line  27 , through valve  37  into second composition mixing chamber  43 . Pressure and flow may be monitored in each of supply lines  23  and  27 , and this information is supplied to fuel monitoring and control system  22 . Pump  35  is controlled by control system  22 . The flow rate is determined by throttle position, pilot settings and other variables. 
     Stabilized fuel is mixed with second composition to reverse the stabilizing effect of first composition. The mixing with second composition occurs in second composition mixing chamber  43 . Second composition is stored in reservoir  39  which is filled through supply port  33 . Second composition enters the second composition mixing chamber  43 , through inlet ports  29 . The properties and composition of the mixture in chamber  43  are monitored by sensors and transducers  41 , which operate in a manner analogous to sensors and transducers  19 . Fuel monitoring and control system  22  monitors the information from these sensors  41  and uses the information to control the amount of second composition which is added. The positions of valves  37  and  36  are monitored and controlled by fuel monitoring and control system  22 . 
     Treated fuel leaves second composition mixing chamber  43 , passes through valve  36  and supply line  42 , is pumped by fuel pump  44 , enters fuel line  49 , and passes through the fuel filter  50 . The filter is linked to a filter cleaning system  53 , which either continuously and/or intermittently cleans and/or resupplies the filtering material. The filter cleaning system has access to the filter through ports  55 . Filtering and cleaning agents may be supplied and removed through supply port  57 . 
     An alternative to the addition of second composition to reverse the effect of first composition is to filter out the first composition. In such an embodiment, the second composition reservoir, mixing chamber and associated ports and valves would be eliminated, as would fuel pump  35  and its associated supply line. In this embodiment, treated fuel would pass directly from valve  13  and fuel line  23  to the fuel line  42 . In this embodiment, the first composition would be removed by fuel filter  50 . 
     The pressure and flow rate within the fuel supply lines is monitored by sensors  46 ,  48 , and  64 , which send information to the fuel monitoring and control system  22 . 
     Fuel leaves the filter  50  and passes through supply line  58 , through valve  60  into the fuel reservoir  63 . The temperature, composition and other properties of the fuel in this chamber are monitored by sensors and transducers  67  which are linked to fuel monitoring and control system  22 . At any time, only a minority of the fuel is maintained in fuel reservoir  63 , since the combustibility of this fuel is greater than that in first composition mixing chamber and reservoir  1 . 
     Fuel leaves reservoir  63  passes through valve  74  into fuel line  76  and flows through the fuel supply system that is in common use for the aircraft. 
     Whereas  FIG. 4  shows two fuel pumps and one filter, clearly a greater (or lower) number of pumps and/or a greater number of filters may be provided. 
     In the event of anticipated crash, an additional supply of first composition is situated in reservoir  69 . It could be rapidly added to the fuel in reservoir  63  to stabilize it, through inlet ports  73 . First composition is supplied to reservoir  69  through supply port  71 . 
     Examples of both the first and the second chemical compositions are discussed above in the “Summary of the Invention”. Such compositions are well known as evidenced by the various U.S. patents and publications, the following of which are incorporated herein by reference:
         U.S. Pat. Nos. 6,319,855   6,319,852   6,318,124   6,315,971   6,208,014   6,174,926   6,172,120   6,171,645   6,159,540   6,159,295   6,140,254   6,132,837   6,131,305   6,130,152   6,107,350   6,099,749   6,090,448   6,090,439   6,063,714   6,048,804   6,037,277   6,037,275   6,022,812   6,010,762   5,972,826   5,955,140   5,807,494   5,928,723   5,877,100   5,847,443   5,807,607   5,804,508   5,795,556   5,789,819   5,788,950   5,753,305   5,750,415   5,744,118   5,736,425   5,723,368   5,680,713   5,561,318   5,523,615   5,504,042   5,494,858   5,470,802       

       Silica Aerogels , Ernest Orlando, Lawrence Berkeley National Laboratory (web site). 
       Charles F. Kettering and the  1921  Discovery of Tetraethyl Lead , by Bill Kovarik (web site). 
       Columbia Encyclopedia , 6 th  Ed. (2001): “Tetraethyl Lead”. 
       Separation Methods in Biochemistry , by C. J. Morris and P. Morris; John Wiley &amp; Sons, New York; pp 188-193; 207-211; 236-237; 380-382. 
       Aerogel Materials and Tungsten Engineered Materials , by Marketech International, Inc. (web site). 
     Options for cooling or freezing the fuel include refrigeration systems as are known in the art. Other options include the use of a liquified inert gas such as nitrogen, helium or other noble element. Yet another option is the use of carbon dioxide in either liquid form (under pressure) or solidified. The inert gases and carbon dioxide also have the advantages of fire retardation properties. They could, in the event of impending crash, be placed in close proximity to, or in direct contact with the fuel, as an additional combustion retardant. 
     Options for warming the fuel include a number of methods of exposure to a warm surface. The surface may be warmed by ambient air, by hot engine gases, or by hot engine oil. Alternatively, an electric current may be passed through a resistive element as a source of heat or the fuel may be warmed by electromagnetic energy. 
     Multiple options exist for distributing frozen fuel: 
     I) The entire quantity of fuel is stored as one (or a small number of) large block(s) of fuel: 
     A) Methods in which small pieces are not cut off of the large block: 
     i) An extrusion process: The frozen fuel is a waxy substance, which can be forced to change shape by pressure applied from the outside of its container. Pressure may be applied by a screw-type mechanism which forces waxy fuel from the larger end to the smaller end of a funnel-shaped segment. Such a mechanism would control the movement of frozen fuel from the supply chamber to the frozen fuel transport system. In addition, the funnel shaped segment could be warmed to facilitate passage of the fuel through the funnel segment. 
     ii) A length of fuel element is situated so that most of it is frozen. It may be shaped like a stick of butter. One end of the stick passes through a warming region (where warm is defined as a temperature above the freezing point of the fuel). Drops of liquid fuel fall from the melting fuel stick into a collector. The liquid fuel then moves through a fuel line to a liquid fuel reservoir. 
     iii) The fuel is frozen in large sheets, which are then rolled up like a roll of carpet. It could be loaded onto the aircraft as a roll, or could conceivably be unrolled from one container, passed into the aircraft as a wide ribbon of frozen fuel, and re-rolled as it is taken into the aircraft. During the flight, as fuel is needed, the roll is gradually unrolled, and a continuous ribbon of frozen fuel is supplied. It could be transported by a conveyor belt-like apparatus to a “distant” melting chamber, or melted nearer to the roll. 
     iv) The fuel is frozen into a string-like shape and rolled up like a ball of twine. There would be a similar unrolling process as in I(A)(iii), above. 
     B) Methods in which small pieces are cut off of the large block. 
     i) A guillotine-like apparatus cuts small slices of solid fuel off of a rectangular, margarine-stick shaped block of fuel. The slices fall onto a conveyor belt which transports the fuel to a melting chamber. The advantage of situating the melting chamber distant from the guillotine is the greater separation of the far more combustible liquid fuel from the less combustible solid fuel. Alternatively, rather than transporting the slices to a distant location, they could be melted near the cutting apparatus. 
     ii) Same concept as I(B)(i) but the frozen fuel element is cylindrical, rather than rectangular. Slicing is carried out perpendicularly to the central axis of symmetry of the cylinder. 
     C) Method in which one continuous piece is cut. 
     i) The fuel is cylindrical in shape. It rotates continuously about its central axis of symmetry. A cutting blade (like a cheese knife) is applied to the surface which cuts off a continuous ribbon of fuel. The fuel is processed as in I(A)(iii), above. 
     II) The fuel is stored as a large number of small pieces, to be used as needed: 
     A) The fuel is shaped in cubic or rectangular blocks. These are arranged in a 3 dimensional grid. A series of conveyor belts moves the fuel. There is one belt for each row, running right/left. This passes the fuel element to another conveyor belt, moving perpendicular to the right/left ones, i.e. front/back. Additional conveyor apparatus could allow for many layers of fuel elements to be built up (in the up/down direction). 
     B) The fuel could be loaded as spherical elements. The advantage of spherical elements is that they could roll over each other and roll on a smooth surface. They could then be pumped into the aircraft, and possibly “flow” or roll through a fuel line from storage tank to warmer. On the other hand, increased storage space would be required for a given amount of fuel, compared to storing cubic or rectangular blocks, which “fit together”. Also, the greater surface area of spherical elements would mean increased combustibility, compared to cubic or rectangular elements. In general, the total fuel surface area (or more specifically the area to volume ratio or area to mass ratio) for any of the methods under II is greater than those involving fuel with similar shape and only a single (or small number of) fuel block(s), as in I. Spherical fuel elements have the least favorable surface area to volume ratio among those shapes discussed herein. 
     C) Same as II(B) but cylindrical elements are used. These can roll, though not as freely as the spherical ones. As compared with spherical elements, they have the advantages of less surface area and less lost storage volume. 
     D) The fuel is contained in hard/smooth-surfaced spherical shells with multiple holes. The advantage is that these can roll easily. The shells roll or are propelled to a warming chamber, where the fuel melts and drips out of the shell. The disadvantage of the approach is the waste of space, and that the shells add weight. 
     E) Same as II(D) but using cylindrical shells. 
     There has thus been shown and described a novel method and apparatus for treating fuel to temporarily reduce its combustibility which fulfills all the objects and advantages sought therefor. Many changes, modifications, variations and other uses and applications of the subject invention will, however, become apparent to those skilled in the art after considering this specification and the accompanying drawings which disclose the preferred embodiments thereof. All such changes, modifications, variations and other uses and applications which do not depart from the spirit and scope of the invention are deemed to be covered by the invention, which is to be limited only by the claims which follow.

Technology Category: 1