The present device relates to a protective armor for critical areas of vehicles, including underbody armor for military vehicles. More specifically, the device relates to a attachable/detachable blast protection structure and attachment means for use on a personnel cabin when needed to protect the vehicle occupants from blast energy and fragmentation resulting from an improvised explosive device (IED).
Armored vehicles are threatened by IEDs designed to cause harm to the vehicle and its occupants. IEDs are found in either a pure blast mode which is comprised of a detonation of a mass of explosive material, or a fragmentation device which is made of one or more grouped artillery shells redeployed and detonated in an effort to inflict casualties. Harm from these devices typically comes in the form of high pressure blast energy or blast energy and ballistic fragmentation in the following predominant ways: (1) rapid surface pressure and destructive hull deformation resulting in hull breach and direct occupant exposure to blast pressures and intense heat; (2) high velocity, hull and/or floor accelerations resulting in occupant incapacities; and (3) high velocity fragmentation passing through armor and impacting occupants.
Armor countermeasures typically consist of heavy metal structure placed between the threat and the vehicle occupants in such a way as to resist hull breach and aggressive floor accelerations. These heavy metal structures may also work in concert with layers of additional metal, ceramic, composite or plastic materials designed to prevent lethal high velocity fragments from entering the vehicle. The heavy metal structures are typically mounted to the underside of the vehicle in various shapes in an effort to take advantage of shape efficiency and deflection characteristics when presented with incoming pressure and fragmentation. Carrying heavy blast and fragment resistant hulls results in significant performance disadvantage to the vehicle in terms of reduced fuel economy, lost cargo capacity and increased transportation shipping costs, as well as, weight challenges for the environment the vehicles operate in.
Therefore, it would be advantageous to have the option to attach and detach a blast protection structure, depending on the requirements of the situation and environment the vehicle will be subjected to. The present device is a removable blast protection structure having an attachment/detachment means, which permits the structure to be easily attached and detached from a vehicle depending on the specific situation. The structure is designed to protect the occupants from blast energy and fragmentation, and because it is offered as modular sections or panels, can be customized to meet different levels of threats depending on the unique operational situation.
There is disclosed herein an improved system and method for protecting a personnel cabin of a military vehicle which avoids the disadvantages of prior systems while affording additional structural and costs advantages.
Generally speaking, the present device is a detachable blast structure for use as an exterior underbody protection of a personnel cabin for a vehicle. The blast structure comprises at least one modular section attachable to a side of the underbody, and means for attaching and detaching the modular sections to the underbody.
In another embodiment, an armored blast system for attachment to and detachment from a vehicle having a cabin hull is disclosed. The armored blast system comprises a plurality of modular panels separately attachable to and removable from a portion of the cabin hull and a means for attaching and detaching the panels.
In yet another embodiment, an armored blast system for attachment to and detachment from a vehicle having a cabin hull is disclosed. The armored blast system comprises a plurality of modular panels separately attachable to and removable from a portion of the cabin hull, a means for attaching and detaching the panels, and a comb and wedge fastening system, wherein a blast load is transferred between the modular panels and the cabin hull through the comb and wedge fastening system.
These and other features and advantages of the present detachable blast structure can be more readily understood from the following detailed discussion with reference to the appended drawing figures.
Referring to
Specifically, when needed, the blast structure 10 is designed to attach to an underbody interface 14, forming the underside of the cabin 12. It should be understood, however, that the blast structure can be attached to any portion of the cabin needing additional protection. In this manner, the blast structure 10 functions to diminish or halt certain classes of ballistic and blast threats, while providing a structural and automotive function as part of the occupant cabin and/or hull of the vehicle.
Armored vehicles having integrated blast solutions are often extremely heavy to begin with, and face weight challenges in the environments they operate. Additionally, because of their weight, such vehicles are often a challenge for transporting to locations where they are needed. Thus, it would be advantageous to have an attachable/detachable blast system, which permits the attachment of a blast structure only when needed, or alternatively, provides the option to remove a large portion of the weight on the vehicle so it can be transported, and/or not carry weight that is not needed.
The underbody interface section 14 of the vehicle is generally configured having a mounting flange to accept the load transfer comb/key structures 50, 51 and allow bolting of the underbody blast protection structure 10 to the cabin 12. Alternative embodiments and configurations of the underbody can include curvilinear, saddle and sinusoidal shapes. While a specific shape or embodiment will be illustrated, it should be understood that other configurations, such as those created by sharper, rectangular, or square lines, and peaks and valleys, may also be used in creating the configuration of the underbody.
The plurality of high and low areas of the underbody section 14 plus the blast protection structure 10 create deflection faces and venting openings, or blast surfaces, which deflect and vent the blast and resulting fragmentation away from the interior of the cabin 12, as well as, provide separation distances for separating the interior of the cabin from the blast force. The high and low areas of the underbody section 14 plus the blast protection structure 10 further act to dissipate the force of the explosion. The blast structure 10 of the present disclosure is designed to be attachable and detachable to the various shapes of the underbody of the vehicle, and the modular characteristic of the blast structure provides various options, and are customizable for attachment to the possible shape variations of the underbody.
In addition to the blast protection structure 10 shown in
Attachment of the blast structure to the cabin hull can be accomplished by any known attaching and detaching means, such as a fastener. Examples of fasteners include screws or bolts 30, which are commonly used to attach the individual panels to the chassis. Regardless of the type of fastener used, it should be compatible with standard tools that can be carried in the field, quickly attachable and detachable, and readily available.
During a blast event, the energy loading between the base hull cabin 12 and the blast protection structure 10 is transferred through the use of a unique comb 50 and key or wedge 51 design. In this design, the comb material is loaded in shear as the two separate components—the removable blast protection 10 and the cabin hull 12—are forced either apart or together by the explosive force of the blast. The key or wedge 51 component of the system keeps the comb structure 50 fully engaged between the cabin hull 12 and the removable blast protection structure 10.
The attachable/removable blast protection structure 10 of the present disclosure is designed to meet or exceed military requirements for hull breach and occupant performance criteria when subjected to a given type of blast threat. In addition, the blast structure meets the requirements for minimal floor (subfloor) deformation and tactical load requirements, while being manufactured at competitive costs. Finally, the blast structure and its modular components provide the advantage of accommodating various shapes of vehicles, and are independently attachable/detachable to meet weight and levels of protection requirements.
This application claims the benefit of U.S. Provisional Patent Application Ser. No. 61/615,688 filed on Mar. 26, 2012.
Number | Date | Country | |
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61615688 | Mar 2012 | US |