Abstract:
A system and attendant assembly for incorporating at least one alternate fuel supply, such as of the type used in combination with a conventional distillate fuel, to power a heavy duty industrial vehicle, such as a mine haul dump truck. The system and attendant assembly includes a mounting assembly structured for containment and support of a primary fuel tank and an auxiliary fuel tank. The mounting assembly is disposed on a mounting area laterally adjacent between the two tires on a side of the truck, wherein the mounting assembly and mounting area are cooperatively disposed and structured to facilitate storage of the alternate fuel and operative communication and distribution thereof with the powering operations of the vehicle.

Description:
BACKGROUND OF THE INVENTION 
     1. Field of the Invention 
     This invention relates to a hybrid fuel assembly and system for supplying an industrial vehicle with at least one alternate fuel supply. Specifically, at least one hybrid fuel assembly is mounted and disposed laterally on a side of the vehicle and in fluid communication with the vehicle, such as to increase the operational time and/or effectiveness of the vehicle. 
     2. Description of the Related Art 
     Mine haul trucks are off-highway, two axle, rigid dump trucks, specifically engineered for use in high production mining and heavy duty construction environments. As such, haul truck capacities typically range from 50 short tons (45 tons) to 400 short tons (363 tons). In addition, the largest and highest payload capacity of such mine haul trucks is referred to as “ultra class” trucks. This ultra class includes haul trucks having a payload capacity of at least 300 short tons or greater. Numerous manufacturers throughout the world produce such mammoth vehicles which are engineered for both performance and long operable life. Trucks of this type are developed specifically for high production duty wherein material is transported in large quantities in order to lower transportation costs on a cost-per-ton basis. 
     Typically mine haul trucks are powered by either direct drive diesel or diesel electric power trains frequently including a multiple horse power turbo charged diesel engine. Due to the exceptional size and weight of such vehicles, they cannot be driven on public access roads, but are ideal for high production environments wherein massive quantities of material must be moved, handled, relocated, etc. on a continuous or regular basis. 
     Accordingly, it is well recognized that distillate fuels, specifically diesel, are used as the primary fuel source for such vehicles. Attempts to maximize the operational efficiency, while maintaining reasonable safety standards, have previously involved modified throttle control facilities. These attempts serve to diminish adverse effects of control mechanisms which may be potentially harmful to the vehicle engine operation as well as being uneconomical. Typical adverse effects include increased fuel consumption and wear on operative components. Therefore, many diesel engines and the vehicles powered thereby are expected to accommodate various types of high capacity payloads and provide maximum power for relatively significant periods of operation. As a result, many diesel engines associated with heavy duty and off-road vehicles are commonly operated at maximum or near maximum capacity resulting in an attempted maximum power delivery from the vehicle engine and consequent high rates of diesel consumption. It is generally recognized that the provision of a substantially rich fuel mixture in the cylinders of a diesel engine is necessary for providing maximum power when required. Such continued high capacity operation of the vehicle engine results not only in wear on the engine components but also in high fuel consumption rates, lower operating efficiencies, more frequent oil changes and higher costs of operation. 
     Accordingly, there is a long recognized need for a fuel control system specifically intended for use with high capacity, off-road vehicles including mine haul vehicles of the type generally described above that would allow the use of more efficient fueling methods using other commonly available fuel sources. Therefore, an improved fuel control system is proposed which is determinative of an effective and efficient operative fuel mixture comprised of a combination of gaseous and distillate fuels. More specifically, gaseous fuel can comprise natural gas or other appropriate gaseous type fuels, wherein distillate fuel would typically include diesel fuel. Additionally, improved fuel control systems may further include increased capacity to carry lubricating fluids such as hydraulic fluid for powering a hydraulic lift or truck bed on such vehicles. 
     Such a preferred and proposed fuel control system should be capable of regulating the composition of the operative fuel mixture on which the vehicle engine currently operates to include 100% distillate fuel, when the vehicle&#39;s operating mode(s) clearly indicate that the combination of gaseous and distillate fuels is not advantageous. Further, such a proposed fuel control system could have an included auxiliary function to act as a general safety system serving to monitor critical engine fuel system and chassis parameters. As a result, control facilities associated with such a preferred fuel control system should allow for discrete, user defined control and safety set points for various engine, fuel system and chassis parameters with pre-alarm, alarm and fault modes. 
     In addition, the operation of such a fuel control system would be facilitated by the inclusion of a preferred mounting assembly for the alternate fuel supply. As such, the included and preferred mounting assembly would be readily adaptive for use on different vehicles while facilitating the secure, safe and efficient distribution of the alternate fuel in the intended manner. 
     SUMMARY OF THE INVENTION 
     This invention is directed to a system and attendant assembly to support at least one alternate fuel supply on a vehicle, wherein the fuel supply may be used with an improved fuel control system. The fuel control system may comprise controls for powering the hydraulic lift bed of a vehicle and appropriate injections of hydraulic fluid and lubricating fluid. The fuel control system may also comprise technology that allows for the safe and efficient use of a gaseous fuel such as, but not limited to, liquid natural gas (LNG), in combination with a predetermined quantity of conventional distillate fuel, such as diesel fuel. As a result, the composition of an “operative fuel mixture” used to power a vehicle engine will, be dependent on the operating modes of the vehicle engine and operating characteristics of the engine during the operating modes, be either a predetermined combination of gaseous fuel and distillate fuel or substantially entirely distillate fuel, absent any contribution of gaseous fuel. 
     In initially broad terms, one embodiment of the present invention is directed to a system having a first hybrid fuel assembly, a second hybrid fuel assembly, and a fuel interconnect disposed on an industrial vehicle. As such, the first hybrid fuel assembly is disposed along a first side of the vehicle, preferably at a position laterally adjacent between the two tires, such as to provide sufficient clearance to the two tires. Similarly, the second hybrid fuel assembly is disposed along a second side of the vehicle, in a position laterally adjacent between the two tires of the second side of the vehicle. The vehicle is preferably a heavy duty industrial vehicle, such as a mine haul dump truck comprising Komatsu models 830 and 930. The fuel interconnect may be disposed on the vehicle and in fluid communication between the first and second fuel assemblies, such as to allow the refilling of both fuel assemblies from a single side of the vehicle. 
     At least one preferred embodiment of the present invention is directed to a hybrid fuel assembly that may be utilized in the system described above. Accordingly, the hybrid fuel assembly may comprise a mounting assembly, an auxiliary fuel tank, and a shield assembly. The shield assembly is cooperatively structured to operatively engage the mounting assembly in order to retain the auxiliary fuel tank therein. The mounting assembly comprises a primary fuel tank formed along a substantially hollow interior within the mounting assembly. The mounting assembly will also comprise a recessed portion or auxiliary fuel area dimensioned and structured to operatively retain the auxiliary fuel tank. 
     In at least one embodiment, the primary fuel tank is structured to contain diesel fuel and the mounting assembly is operatively connected and in fluid communication with the vehicle and a powering engine thereof, in order to deliver the diesel fuel to effect the operation of the vehicle. In another embodiment, the primary fuel tank may be structured to contain hydraulic fluid, and the mounting assembly may be operatively connected and in fluid communication with the vehicle and a hydraulic bed lift, in order to deliver hydraulic of lubricating fluid to effect the operation of the lift bed. In embodiments where the primary tank is intended to contain hydraulic fluid, the primary fuel tank may be smaller relative in proportion to the auxiliary fuel tank, because generally a mine haul dump truck requires less hydraulic fluid relative to diesel and/or LNG fuel. The auxiliary fuel tank is structured to contain liquefied natural gas (LNG) fuel, and may comprise varying dimensions, inversely related to the size and dimension of the primary fuel tank. 
     The auxiliary fuel area may comprise an auxiliary fuel platform that is designed to retain the auxiliary fuel tank, such that the auxiliary fuel tank may be bolted down or otherwise attached to the platform. Additional auxiliary fuel retainers may be utilized to provide additional stability in securing the auxiliary fuel tank. 
     The mounting assembly of the hybrid fuel assembly will be cooperatively structured in order to operatively engage a mounting area of the industrial vehicle. As such, mounting assembly may comprise at least one bracket or mounting structure which may be used to secure the mounting assembly to a side of the industrial vehicle. Further, additional shock absorber bushings may be added to minimize movement and/or absorb a portion of the force of impact against a side of the industrial vehicle during transit. 
     At least one fuel access port will be integrated within the mounting assembly. In at least one embodiment, a second mounting assembly may comprise a rear fuel access port, which may be in fluid communications with the fluid interconnect, in order enable the refueling of the mounting assembly from a first mounting assembly on another side of the vehicle. In a preferred embodiment, a first mounting assembly may comprise a front diesel access port, a LNG access port, as well as a hydraulic refill port for refilling the various fuels and/or fluids necessary for the operation of the vehicle. 
     The primary fuel tank formed within the mounting assembly may further comprise at least one baffle. The baffle is formed along an interior of the primary fuel tank in order to partition the primary fuel tank into a plurality of primary fuel compartments. This provides the benefit of minimizing slosh dynamics, so unwanted aeration does not occur in the fuel during the transit of the vehicle at high speeds and/or on rugged terrain. A plurality of structural baffles may be formed along the interior of the primary fuel tank to further bolster the structural integrity of the primary fuel tank and hybrid fuel assembly. The baffles may be disposed in varying configurations to provide for additional weight stability of the hybrid fuel assembly. 
     In at least one embodiment, the mounting assembly may further comprise an access ladder, which is sufficiently dimensioned and disposed to allow an operator to gain access to a bed hoist cylinder of the vehicle and/or a hydraulic truck bed lift of the vehicle. Additional access points or areas may be built into the mounting assembly, such as to allow access to a LNG vaporizer integrated on a lower exterior of the mounting assembly. 
     These and other objects, features and advantages of the present invention will become clearer when the drawings as well as the detailed description are taken into consideration. 
    
    
     
       BRIEF DESCRIPTION OF THE DRAWINGS 
       For a fuller understanding of the nature of the present invention, reference should be had to the following detailed description taken in connection with the accompanying drawings in which: 
         FIG. 1  is a top rear schematic view of a system for implementing at least one alternate fuel supply to facilitate the operation of an industrial vehicle, specifically, first and second hybrid fuel assemblies are mounted on the lateral portions of the vehicle and in fluid communication with a powering engine of the vehicle. 
         FIG. 2  is a rear perspective view of a hybrid fuel assembly for providing at least one alternate fuel supply to an industrial vehicle, specifically the fuel assembly may comprise diesel and liquefied natural gas. 
         FIG. 3  is a front perspective view in partial cutaway of the hybrid fuel assembly of  FIG. 2 . 
         FIG. 4  is rear perspective view in partial cutaway of the hybrid fuel assembly of  FIG. 2 , illustrating the internals of the primary fuel tank. 
         FIG. 5  is a perspective view in exploded form of another hybrid fuel assembly for providing at least one alternate fuel supply to an industrial vehicle, specifically the fuel assembly may comprise hydraulic fluid and liquefied natural gas. 
         FIG. 6  is a front perspective view in partial cutaway of the hybrid fuel assembly of  FIG. 5 . 
         FIG. 7  is a rear perspective view in partial cutaway of the hybrid fuel assembly of  FIG. 5 , illustrating the internals of the primary fuel tank. 
         FIG. 8  is a detailed perspective view of a front lower portion of the hybrid fuel assembly of  FIG. 5 , illustrating the fuel access ports. 
         FIG. 9  is a detailed perspective view in partial cutaway and of a bottom portion of the hybrid fuel assembly of  FIG. 5 , illustrating the integrated vaporizer and vaporizer access area. 
     
    
    
     Like reference numerals refer to like parts throughout the several views of the drawings. 
     DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENT 
     As illustrated by the accompanying drawings, the present invention is directed to an assembly and system for modifying an industrial vehicle to include at least one alternate fuel supply used to facilitate the operation of the vehicle. 
     Drawing attention to  FIG. 1 , a system  100  of the present invention may comprise a first hybrid fuel assembly  300 , a second hybrid fuel assembly  200 , and a fuel interconnect  101  disposed on an industrial vehicle  500 . Accordingly, the first hybrid fuel assembly  300  is disposed along an exterior of the vehicle  500 , preferably at a mounting area  103  which is laterally adjacent and between the two tires  501  and  502  on a first side of the vehicle  500 . Similarly, the second hybrid fuel assembly  200 , if any, may be disposed at a mounting area  102  which is laterally adjacent and between the two tires  501 ′ and  502 ′ on a second side of the vehicle  500 . Each of the first and second hybrid fuel assemblies  200 ,  300  are sufficiently structured and disposed to provide the tires  501 ,  502 ,  501 ′,  502 ′ with sufficient clearance taking in account of tire rotation. 
     The industrial vehicle  500  may comprise any type of heavy duty industrial vehicles such as mine haul vehicles, dump trucks, bull dozers, and other commercial vehicles known to those skilled in the art. In a preferred embodiment, the present invention is designed to operatively engage and operate on commercial dump trucks, including but not limited to Komatsu models 830E, 830E-AC, 930E, 930E-4, 930E-4SE, and other present and future variations of these models. 
     In a preferred embodiment, the first fuel assembly  300  comprises a hydraulic and liquefied natural gas (LNG) hybrid assembly, while the second fuel assembly  200  comprises a diesel and LNG hybrid assembly. The hydraulic fluid may be used to facilitate the operation of a hydraulic truck bed lift of the vehicle  500 . The diesel fuel and LNG may be used for powering a drive train of the vehicle  500 . The fuel interconnect  101  may be in fluid communication between the first fuel assembly  300  and the second fuel assembly  200 , such as to allow the refilling of both assemblies and respective tank(s) thereof from a single side of the industrial vehicle  500 . In other embodiments, either the hybrid fuel assembly  200  or  300  may also be mounted singularly on a side of the vehicle, leaving the other side of the vehicle empty, and in such an embodiment a fluid interconnect  101  between the two assemblies may be omitted. Each of the first and second fuel assemblies  200 ,  300  are described in greater detail below. 
     As represented in  FIGS. 2-4 , one illustrative embodiment of a hybrid fuel assembly  200  is shown to initially comprise a mounting assembly  201 , an auxiliary fuel tank  220 , and a shield assembly  202 . The shield assembly  202  is cooperative structured to operatively engage the mounting assembly  201  in order to retain the auxiliary fuel tank  220  therein, and to protect both the auxiliary fuel tank  220  and the mounting assembly  201  from the external environment. The shield assembly  202  may accordingly be thermal insulated and/or be formed of sufficiently rigid material(s). 
     The mounting assembly  201  comprises a primary fuel tank  210  formed along a hollow interior within said mounting assembly  201 . The mounting assembly  201  further comprises an auxiliary fuel area  225  sufficiently dimensioned and structured to operatively retain the auxiliary fuel tank  220 . The mounting assembly  201  may be formed in the dimensions of a substantially trapezoidal prism with a hollow interior on a diagonal side structured to retain the auxiliary fuel tank  220 , such as at the auxiliary fuel area  225 . 
     In at least one embodiment, the primary fuel tank  210  is structured to contain diesel fuel for powering an engine and/or drive train of the vehicle  500 , whereas the auxiliary fuel tank  220  is structured to contain LNG as an alternate fuel also for powering an engine and/or drive train of the vehicle  500 . The primary fuel tank  210  may comprise approximately 650 gallons of useable diesel fuel, but may also comprise diesel fuel amounts in the  500  to  700  gallon range, in various embodiments designed for the Komatsu  830  or  930  model dump trucks. The auxiliary fuel tank  220  containing LNG may then comprise of corresponding sizes, in order to accommodate for the relatively larger diesel fuel capacity, and so as to not overload the weight bearing capacity on a side of the vehicle  500 . For example, the larger the primary fuel tank  210  capacity, the smaller the auxiliary fuel tank  220  capacity. 
     Auxiliary fuel area  225  may further comprise an auxiliary fuel platform  221  which is substantially flat and designed to retain the auxiliary fuel tank  220 , such that auxiliary fuel tank  220  may be bolted down onto the platform  221 . In order to provide additional stability to the attachment of the auxiliary fuel tank  220 , auxiliary fuel area  225  may further comprise additional auxiliary fuel retainers  222  shaped to conform to an exterior of the auxiliary fuel tank  220 . These auxiliary fuel retainers  222  may form arch-like structures that are in abutting and partially surrounding relations to the auxiliary fuel tank  220 , when the auxiliary fuel tank  220  is operatively disposed and engaged with the auxiliary fuel area  225 . 
     In order to affix the hybrid fuel assembly  200  to the vehicle  500 , the mounting assembly  201  is cooperatively structured to operatively engage a mounting area of the industrial vehicle. The mounting area is preferably located at an area laterally adjacent between the two tires on a side of the vehicle, such as illustrated in  FIG. 1  at mounting areas  102  or  103 . To facilitate the operative engagement of the mounting assembly  201  to a mounting area of the vehicle, the mounting assembly  201  may further comprise at least one bracket  215  for affixing or mounting the mounting assembly  201  to the industrial vehicle  500 . A plurality of bushings or shock absorber bushings  214  is preferably formed along a rear exterior of the mounting assembly  201 , such as to absorb and minimize the force of impact against a side of the industrial vehicle  500 , and/or to provide a cushion and minimize movement of the mounting assembly relative to the industrial vehicle  500  when the vehicle is operating at high speeds and/or on rough terrain. The shock absorber bushings  214  may be formed from a number of shock absorbing materials, such as polymers, visco-elastic polymers, visco polymers, rubber, neoprene, silicone, and the like. 
     Mounting assembly  201  may additionally comprise a front fuel access port  211 , and may further comprise a rear fuel access port  211 ′. In embodiments where each of two hybrid fuel assemblies  200  are mounted on each of two sides of a vehicle, a user may utilize the rear fuel access port  211 ′ of one hybrid fuel assembly  200 , in fluid connection with a fuel interconnect to the other hybrid fuel assembly  200 , such that the user may refuel both hybrid fuel assemblies  200  from on a single side of the vehicle. The fuel access ports  211 ,  211 ′ may be in fluid communication with the primary fuel tank  210  in at least one embodiment, but may also be in communication with the auxiliary tank  220  in other embodiments. Additional and separate fuel access ports may be used for the auxiliary tank  220  in yet other embodiments. Mounting assembly  201  is also structured and disposed to facilitate the operative communication of its primary fuel tank  210  and auxiliary fuel tank  220  with a powering engine, drivetrain, and/or other mechanical or electrical operations of the vehicle. 
     Drawing attention to  FIG. 4 , a partially rear cut away view further illustrates the details of the primary fuel tank  210  formed along an interior of the mounting assembly  201 . Accordingly, and in a preferred embodiment, the primary fuel tank  210  comprises at least one baffle  212  formed along an interior of the primary fuel tank  210 . The baffle  212  is structured and disposed to partition the primary fuel tank  210  into a plurality of primary fuel compartments  213 . In preferred embodiments, a plurality of structural baffles  212  are formed along an interior of the primary fuel tank  210  to bolster the structural integrity of the mounting assembly  201 . This is particularly advantageous due to the substantially hollow interior of the mounting assembly  201  used for storage of a fuel. 
     The resulting smaller primary fuel compartments  213  is also advantageous because it reduces the slosh dynamics of the liquid fuel, and thus results in a higher efficiency of operation for the vehicle. Further, reduced slosh dynamics also decreases the amount of entrained air or cavitation in diesel fuel, which may otherwise cause retarded injection timing and thus negatively affect diesel engine performance. In at least one embodiment, the primary fuel tank  210  additionally comprises at least one primary fuel compartment  213 ′ disposed in underlying relations relative to the auxiliary fuel platform  221 . The existence of the lower fuel compartment  213 ′ provides further weight stability to the hybrid fuel assembly  200 , and reduces potential movement of the assembly  200  relative to the vehicle  500 , which offers another added advantage particularly when the vehicle  500  is functioning on uneven and off-road terrain. 
     As represented in  FIGS. 5-9 , another illustrative embodiment of a hybrid fuel assembly  300  is shown, also for mounting on a side of the vehicle  500 . Similarly, this embodiment initially comprises a mounting assembly  301 , an auxiliary fuel tank  320 , and a shield assembly  302 , which may comprise a two piece construction as illustrated in  FIG. 5 . Similar to the above embodiment, the shield assembly  302  is cooperative structured to operatively engage the mounting assembly  301  in order to retain the auxiliary fuel tank  320  therein, and to protect both the auxiliary fuel tank  320  and the mounting assembly  301  from the external environment. The shield assembly  302  may accordingly be thermal insulated and/or be formed of sufficiently rigid material(s). 
     The auxiliary fuel tank  320  is similar to the hybrid fuel assembly  200  above, but may comprise differential sizes, shapes, and/or dimensions. The mounting assembly  301  also comprises a primary fuel tank  310  formed along a hollow interior within the mounting assembly  301 , and may share certain characteristics and components of the mounting assembly  201  above. The mounting assembly  201  may similarly be formed in the dimensions of a substantially trapezoidal prism, having a hollow interior along a diagonal side structured to retain the auxiliary fuel tank  320 , such as at the auxiliary fuel area  325 . The hybrid fuel assembly  300  further comprises a LNG vaporizer  330 , as well as additional components on the mounting assembly  301  that will be discussed in greater detail below. 
     In a preferred embodiment, the primary fuel tank  310  is structured to contain hydraulic fluid for powering a hydraulic truck bed lift of the vehicle  500 , whereas the auxiliary fuel tank  320  is structured to contain LNG as an alternate fuel for powering an engine and/or drive train of the vehicle  500 . The primary fuel tank  310  may comprise approximately 246 gallons of hydraulic fluid, while the auxiliary fuel tank  320  may comprise approximately 300 gallons of LNG. Other preferred ranges may comprise 200-300 gallons of hydraulic fluid in the primary fuel tank  310 , and 250-350 gallons of LNG in the auxiliary fuel tank  320 . Fewer amounts of hydraulic fluid relative to LNG may be used depending on the utilization of the truck&#39;s hydraulic truck bed lift versus the range of travel of the vehicle  500 . 
     The auxiliary fuel area  325  may similarly comprise an auxiliary fuel platform  321  as well as auxiliary fuel retainers  322 . The auxiliary fuel platform  321  is substantially flat and structured to retain the auxiliary fuel tank  320 , such that the auxiliary fuel tank  320  may be bolted down or otherwise affixed to the platform  321 . Auxiliary fuel retainers  322  may further be used to provide added stability to the auxiliary fuel area  325 , the retainers  322  may be shaped to at least partially conform to an exterior of the auxiliary fuel tank  320 . The retainers  322  may, as illustrated in  FIG. 5 , form partially arching structures that are in abutting and partially surrounding relations to the auxiliary fuel tank  320  when the auxiliary fuel tank  320  is disposed in an operative engagement with the auxiliary fuel area  325 . 
     The mounting assembly  301  may also comprise similar structural components for facilitating the mounting of the hybrid fuel assembly  300  to the vehicle  500 . Preferably, the hybrid assembly will also be mounted at an area laterally adjacent between the two tires on a side of the vehicle, such as at areas  102  or  103  in accordance with  FIG. 1 . To facilitate the operative engagement of the mounting assembly  301  with the industrial vehicle  500 , similar mounting brackets, not shown, may be utilized. However, in a preferred embodiment and design for the Komatsu dump truck vehicles models 830 and 930, the present hybrid fuel assembly  300  is intended to replace and improve upon an existing manufacturer hydraulic tank. Accordingly, the mounting assembly  301  may comprise mounting structures  341  on each side of the mounting assembly  301 . These mounting structures  341  are structured to be backwards compatible with an existing mount area on the vehicle  500 . Mounting assembly  301  may similarly comprise a plurality of bushings or shock absorber bushings  314  using like materials described above, so as to minimize movement and/or absorb the force of impact against a side of the industrial vehicle  500  during transit in rugged terrain. 
     Mounting assembly  301  preferably comprises separate fuel access ports for refilling the various fuels or alternate fuels used for operation of the vehicle  500 . In the preferred embodiment of hybrid fuel assembly  300 , the mounting assembly  301  may comprise a LNG access port  315 , a diesel access port  316 , and a hydraulic refill port  350 . The diesel access port  316  is intended to interconnect with a primary tank of another mounting assembly, such as the primary tank  210  of mounting assembly  201  recited in the previous embodiment above, via the fuel interconnect  101 . The LNG access port  315  may comprise a fuel connection or interconnect that is connected to and in fluid communication with the auxiliary tank  320 . In at least one embodiment, the LNG access port  315  may further be connected to and in fluid communication with the auxiliary tank  220  of the separate fuel assembly  200 . The hydraulic refill port  350  is connected to and in fluid communication with the primary tank  310  of the mounting assembly  301 . Each of the above fuel access ports or refill ports may further comprise additional components to facilitate the expedient refill of the respective fuels or fluids. For example, a fuel access port may further comprise a one-way check valve to prevent backflow and/or spillage during refill operations. 
     As illustrated in  FIG. 7 , the primary fuel tank  310  formed along the interior of the mounting assembly  301  may also similarly comprise at least one baffle  312 . The baffle  312  is formed along an interior of the primary fuel tank  310  and is structured and disposed to partition the primary fuel tank into a plurality of primary fuel compartments  313 . Two or more structural baffles  312  may be formed within the primary fuel tank  310  and be of sufficient form, material, and dimension to increase the structural integrity of the overall primary fuel compartment  313  and hybrid fuel assembly  300 . The structural baffles  312  may be formed, such that a first baffle  312  is in juxtaposing disposition and perpendicularly disposed relative to a second baffle  312 , which results in at least three primary fuel compartments  313  as shown in  FIG. 7 . Additional horizontal baffles  312 ′ may be formed to further increase the number of primary fuel compartments  313  and/or the overall structural integrity of the primary fuel tank  310 . Fewer or greater structural baffles  312  may be used depending on the size and dimension of the mounting assembly  301  and corresponding primary fuel tank  310 . 
     The resulting smaller primary fuel compartments  313  provides the added benefit of reducing slosh dynamics of the hydraulic fluid. Fluid aeration causes notable problems in hydraulic and lubrication oil systems, including unaccepted noise, poor component response due to the spongy behavior of aerated fluids, cavitation damage as well as severe fluid degradation. Accordingly, because a reduction in slosh dynamics reduces the entrained air in the fluids, these problems may be overcome. A lower fuel compartment may not be necessary in this embodiment, due to the smaller primary fuel tank size  310  and relatively larger auxiliary fuel tank  320 , which provides sufficient wait to stabilize the overall hybrid fuel assembly  300  during vehicle  500  function on even or off-road terrain. 
     The mounting assembly  301  may further comprise an access ladder  232 . The access ladder  232  and mounting assembly  301  is sufficiently dimensioned and disposed such as to allow an operator to gain access to the access ladder  232  in order to access a bed hoist cylinder on the vehicle  500  having a hydraulic truck bed lift. This allows an operator to properly access and maintain a hydraulic truck bed lift of a vehicle  500 . Drawing attention to  FIGS. 8-9 , additional access areas are provided for the convenience access of the LNG vaporizer  330 . A front vaporizer access  317  and/or a bottom vaporizer access  318  may be provided to facilitate the connection and maintenance of the LNG vaporizer  330  to the mounting assembly  301  and the auxiliary fuel tank  320  which comprises the LNG. In some embodiments, access area  317  may comprise a display panel integrated with electronic sensor(s) for displaying the current status of the hybrid fuel assembly  300 , and may comprise fuel status, fill level, maintenance schedule, error codes, etc. The LNG vaporizer  330  is structured and configured to convert the LNG into a gas for use by a powering engine of the vehicle  500 . 
     Since many modifications, variations and changes in detail can be made to the described preferred embodiment of the invention, it is intended that all matters in the foregoing description and shown in the accompanying drawings be interpreted as illustrative and not in a limiting sense. Thus, the scope of the invention should be determined by the appended claims and their legal equivalents. 
     Now that the invention has been described,