The disclosure relates to vehicles, such as military vehicles, that may be subjected to blasts originating beneath or closely adjacent to the vehicle. More specifically, the disclosure relates to a vehicle hull geometry and method of construction providing improved protection from such blasts.
Military vehicles used in combat zones must provide ballistic and blast protection for occupants of the vehicle's crew compartment. One of the challenges in designing a military vehicle is to achieve the proper balance between crew protection (survivability) and mobility.
Good mobility generally calls for a vehicle to be lightweight and to have a relatively low center-of-gravity. To achieve a low center-of-gravity, the vehicle should sit as low to the ground as possible while still providing required ground clearance.
Survivability, on the other hand, drives vehicle design towards more armor, resulting in more weight and therefore a higher center-of-gravity. One way to improve survivability versus a detonation originating close to or below the crew compartment (such as detonation of a lane mine or IED) is to increase the clearance between the bottom of the crew compartment and ground. Increased armor weight and greater ground clearance may result in the vehicle center-of-gravity being so high as to cause an unacceptable roll-over risk when travelling over uneven terrain.
Improved vehicle survivability has recently been demonstrated by what is referred to as a Double-V hull configuration, the general concept of which is shown in
In a disclosed embodiment, a vehicle hull has a longitudinal blast mitigation duct between left and right hull portions. The duct comprises a first section oriented at a first angle to a longitudinal reference line, and a second section adjacent to the first section and oriented at a second angle to the reference line. The second angle is greater than the first angle to form a diverging surface for a shock wave travelling from the first to the second section.
In another embodiment, a rib projects generally perpendicular from a joint between the first and second sections. The rib is configured to initiate separation of the shock wave from the hull, thereby reducing the amount of energy transferred to the hull.
In another embodiment, the diverging surface formed by the first and second sections diverges toward a forward end of the hull, and the blast mitigation duct further comprises a two-section, rearward diverging surface for a shock wave travelling rearward along the hull.
In another embodiment, a vehicle hull comprises a left portion, a right portion, and a central portion between the left and right portions. The central portion is raised relative to the left and right portions to form a downward-opening duct having a first section oriented at first angle to a longitudinal reference line and a second section adjacent to the first section and oriented at a second angle to the reference line. The second angle is greater than the first angle to form a diverging surface.
In another embodiment, a vehicle hull comprises a first plate, a second plate attached to the first plate along a joint, and a rib attached to the first and second plates. The rib projects generally perpendicular from the second plate a distance sufficient to cause a shock wave to separate from the hull after passing the joint, thereby reducing energy transfer from the shock wave
Embodiments of the present invention will now be described by way of example only with reference to the accompanying drawings in which:
a is a transverse cross-section of a Double-V hull according to the prior art;
b is a longitudinal cross-section taken along line 1b-1b of
a is a graphic depiction of computer simulation results showing kinetic energy transfer to a prior art hull design;
b is a graphic depiction of computer simulation results showing reduced kinetic energy transfer to a hull having design features as disclosed herein; and
As required, detailed embodiments of the present invention are disclosed herein; however, it is to be understood that the disclosed embodiments are merely exemplary of the invention that may be embodied in various and alternative forms. The figures are not necessarily to scale; some features may be exaggerated or minimized to show details of particular components. Therefore, specific structural and functional details disclosed herein are not to be interpreted as limiting, but merely as a representative basis for teaching one skilled in the art to variously employ the present invention.
As seen in
Terms such as up, down, horizontal, and vertical, as used herein, assume that vehicle 10 is in a normal running condition, with its wheels/tracks resting on a relatively flat and level surface. As such, this disclosure assumes that the longitudinal and lateral axes of vehicle 10 are generally parallel with the horizontal plane and the vertical axis of the vehicle is normal to the horizontal plane.
The lower section of hull 12 generally comprises a left hull portion 20, a right hull portion 22, and a central hull portion 24 disposed between the left and right portions. Left and right hull portions 20, 22 may extend along substantially the full length of the vehicle and substantially parallel to the longitudinal centerline of the hull. As best seen in
As best seen in
Forward blast mitigation duct 26 comprises a first duct section 32 extending forward from vertex 30 and sloping upward at an angle α1 from longitudinal reference line L (which in this view is horizontal), and a diverging duct section 34 joined to and extending forwardly from the first duct section. Diverging duct section 34 makes an angle β1 with longitudinal centerline L as shown, and β1 is greater than α1 so that a convex corner 36 having a divergence angle δ1 is formed at the intersection or joint between the two duct sections 32, 34.
Duct sections 32, 34 may be arched or curved to have downward-facing concave surfaces, as best seen in
Rear blast mitigation duct 28 is generally similar in geometry to forward duct 26, comprising a first duct section 38 extending rearward from vertex 30 and sloping upward at an angle α2 from longitudinal reference line L, and a diverging duct section 40 joined to and extending rearward from the first duct section 38. Diverging duct section 40 makes an angle β2 with reference line L as shown, and β2 is greater than α2 so that a convex corner 42 having a divergence angle δ2 is formed at the intersection or joint between the two duct sections 38, 40.
Corresponding angles of forward and rear blast mitigation ducts 26, 28 (α1/α2, β1/β2, and δ1/δ2) may be equal or non-equal to one another depending upon design requirements and/or constraints (interior volume, for example) related to hull 12.
Front and rear blast mitigation ducts 26, 28 combine to form a downward-opening channel extending generally parallel with the longitudinal axis of hull 12. The channel may coincide with the vehicle centerline, or it may be offset from the centerline if vehicle design objectives so dictate. Components of the vehicle powertrain (drive shafts, transmissions, motors, batteries, etc.) or other essential equipment (not shown) may be located in the channel, but such components are not shown since they are incidental to this disclosure.
Detonation of an explosive device (such as mine or IED) generates a high-intensity wave front and related supersonic shock wave that radiates outward in all directions from the origin of the detonation. If the detonation origin is directly beneath hull 12 (between the left and right lower hull portions 20, 22), the energy of the detonation is directed against the surfaces of blast mitigation ducts 26, 28 and so is directed forward and/or rearward. The relative proportion of the energy of the detonation directed forward versus rearward depends on where relative to vertex 30 the detonation originates. For example, if the detonation origin is forward of the vertex 30, a larger portion of the detonation energy is directed forward (by forward blast mitigation duct 26) rather than to the rear.
Referring now to
The Prandtl-Meyer angle δ required to achieve shock wave separation depends upon many factors, including the speed of the shock wave (expressed in Mach number), which in turn depends upon the power of the explosive device and the distance of the detonation from the hull surface. Computer simulations have been run utilizing Mach numbers ranging from M=2.9 to M=5.2, with the corresponding δ values of between 11.1 degrees and 20.2 degrees effective to cause shock wave separation.
Simulations using computer models of hull designs featuring the diverging duct contour as described herein have resulted in significant reductions in the amount of kinetic energy transferred to the vehicle. This reduction is depicted in
a and 13b are graphic depictions of computer model simulations showing the reduction in the level of kinetic energy transferred from the detonation to the hull.
A rib 50 (best seen in
Rib 50 has a width substantially greater than the thickness t1 of first duct section 32 so that the lower edge 50a of the rib extends a distance w below the lower/outer surface of duct section 32. Rib 50 thus projects into the flow travelling from duct section 32 toward duct section 34 (indicated by arrows F). Computer simulations of detonations have shown that a rib 50 extending a significant distance beyond the surface of duct 32 enhances the desired separation of the shock wave as the wave transitions from first duct section 32 to divergent duct section 34.
For example, computer simulations have shown that a rib projection distance w ranging from approximately 5 mm (millimeters) to 19 mm enhances or initiates separation of the shock wave from the hull surface. A rib projection distance w=10 mm has, under simulated test conditions, shown a significant reduction in energy transferred to the vehicle.
The projecting rib 50 has the beneficial effect of achieving the desired shock wave separation when used in combination with a duct geometry in which divergence angle δ is smaller than would otherwise be required (per the discussion of the Prandtl-Meyer equation above) if the rib were not present. Rib 50 thus allows a hull design in which the advantageous effects of shock wave separation may be achieved using a smaller divergence angle δ, i.e. the angle β1 of the divergent section 34 may be smaller/shallower, thereby increasing the amount of usable volume inside of hull 12.
Addition of rib 50 to the overlapping joint between duct sections 32 and 40 (as best seen in
The term “welding” is used herein to refer to any of the many joining techniques known in the materials field and is not meant to restrict the type of material used for the structure in any way. For example, components of the hull may be formed of high-strength aluminum alloy, as is well-known in the military vehicle industry. If such an alloy is used, the joints may be formed by friction stir welding, or some other suitable welding method. Full-penetration welds, where such welds are practical, generally provide superior strength. If non-metallic and/or metal-composite materials are used in the hull structure, other appropriate joining/bonding techniques such as adhesives and/or ultrasonic welding may be used.
In summary, the diverging duct causes the shock wave from a detonation to separate from the vehicle hull surface, reducing or negating the ability of the shock wave to transfer kinetic energy to the structure. The rib protruding from the surface at or near the convex joint or corner further enhances/enables shock wave separation and the resulting reduction in kinetic energy transfer.
While exemplary embodiments are described above, it is not intended that these embodiments describe all possible forms of the invention. Rather, the words used in the specification are words of description rather than limitation, and it is understood that various changes may be made without departing from the spirit and scope of the invention. Additionally, the features of various implementing embodiments may be combined to form further embodiments of the invention.
This application claims the benefit of U.S. Provisional Application Nos. 61/598,517 filed Feb. 14, 2012, and 61/601,206 filed Feb. 21, 2012, the disclosures of which are incorporated in their entirety by reference herein.
Number | Date | Country | |
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61601206 | Feb 2012 | US | |
61598517 | Feb 2012 | US |