초록 ▼

The present invention discloses a class of arch-structured, multi-layer, lightweight composites with high capacity to absorb and disperse single or multiple incoming objects with associated energy flux that directly strikes onto one side of the composite, so as minimize the impact and possible damag

The present invention discloses a class of arch-structured, multi-layer, lightweight composites with high capacity to absorb and disperse single or multiple incoming objects with associated energy flux that directly strikes onto one side of the composite, so as minimize the impact and possible damage to the objects behind another side of the composite, wherein the upcoming moving objects can be projectiles, or an upcoming shock wave front produced by blasts, or the impact during a collision, for examples, a crush-landing of an air-vehicle and the impact of heavy truck's wheel to a bridge's deck. This class of composite is termed “Lightweight Multi-layer Arch-structured Composite”, in short, LMAR, which implements the art of arch bridges' design into the art of mesoscopic structural design of the composites, allowing optimized combination in geometries and materials to gain desired physical properties and to manufacture with affordable cost.

대표청구항 ▼

1. A multiple layer composite apparatus configured to protect an object, the multiple layer composite apparatus comprising: at least one cell configured to redistribute at least one applied load, the at least one cell comprising:a first planar layer with a first material, wherein the first planar la

1. A multiple layer composite apparatus configured to protect an object, the multiple layer composite apparatus comprising: at least one cell configured to redistribute at least one applied load, the at least one cell comprising:a first planar layer with a first material, wherein the first planar layer is configured to receive the at least one applied load in at least one applied load area;a second planar layer with a second material and a second fracture toughness, wherein the first material differs from the second material; andat least one structurally robust arched plate operatively connected to and disposed between the first and second planar layers configured to disperse energy created by the at least one applied load;wherein the at least one arched plate is corrugated and defined by at least one first arch and at least one second arch; andwherein the at least one first arch is operatively connected to and overlaid with the first planar layer and the at least one second arch is operatively connected to and overlaid with the second planar layer so that a contact-induced nonlinear deformation results between the arches and the first and second planar layers upon receipt of the at least one applied load. 2. The apparatus according to claim 1, wherein the at least one structurally robust arched plate is configured to transition from at least one linear deformation to at least one nonlinear deformation. 3. The apparatus according to claim 1, wherein the at least one structurally robust arched plate is configured to sustain a nonlinear deformation and dissipate the energy created by the at least one applied load into heat. 4. The apparatus according to claim 1, wherein the at least one structurally robust arched plate diverges a nonlinear deformation created by the at least one applied load into a dispersed area, the dispersed area being greater than the at least one applied load area. 5. The apparatus according to claim 1, wherein the at least one applied load causes the at least one first arch to deform the first layer and the at least one second arch to deform the second layer. 6. The apparatus according to claim 1, wherein the at least one applied load is caused by at least one impact object or an energy flow. 7. The apparatus according to claim 6, wherein the at least one impact object is a projectile, shock wave, a blast, or forces imparted by a collision with at least one independent body. 8. The apparatus according to claim 1, wherein the object being protected is disposed underneath the at least one cell. 9. The apparatus according to claim 1, wherein the at least one cell further comprises a composite filler disposed inside a void defined by a space between the first and second arches of the at least one structurally robust arched plate. 10. The apparatus according to claim 1, wherein the object being protected by the apparatus is surrounded by the at least one cell. 11. The apparatus according to claim 10, wherein the apparatus forms at least one protective layer for the object being protected by the apparatus, and wherein the object is a vehicle, a protective deck, a wearing deck, a wall, a container, a door, or a person. 12. The apparatus according to claim 1, wherein the at least one structurally robust arched plate further comprises a segment disposed between and integral to the first and second arches, wherein the segment is configured to mechanically connect the first arch and the second arch to each other. 13. The apparatus according to claim 1, wherein the at least one cell further comprises a second structurally robust arched plate operatively connected to and disposed between the first and second layers configured to disperse energy created by the at least one applied load; wherein the second structurally robust arched plate is defined by at least one first arch and at least one second arch;wherein the second structurally robust arched plate is oriented parallel with the at least one structurally robust arched plate;wherein the at least one first arch of the at least one structurally robust arched plate corresponds to the at least one second arch of the second structurally robust arched plate; andwherein the at least one second arch of the at least one structurally robust arched plate corresponds to the at least one first arch of the second structurally robust arched plate. 14. The apparatus according to claim 13, wherein the at least one cell further comprises a third structurally robust arched plate operatively connected to and disposed between the first and second layers configured to disperse energy created by the at least one applied load; wherein the third structurally robust arched plate is defined by at least one first arch and at least one second arch; andwherein the third arched structurally robust plate is oriented perpendicular to the at least one structurally robust arched plate. 15. The apparatus according to claim 14, wherein the at least one cell further comprises a fourth structurally robust arched plate operatively connected to and disposed between the first and second layers configured to disperse energy created by the at least one applied load; wherein the fourth structurally robust arched plate is defined by at least one first arch and at least one second arch;wherein the fourth structurally robust arched plate is oriented parallel to the third structurally robust arched plate;wherein the at least one first arch of the fourth structurally robust arched plate corresponds to the at least one second arch of the third structurally robust arched plate; andwherein the at least one second arch corresponds to the at least one first arch of the third structurally robust arched plate. 16. The apparatus according to claim 1, wherein a curvature and a size of that least one first arch is equal to or differs from a curvature and a size of the at least one second arch. 17. The apparatus according to claim 1, wherein the at least one cell further comprises: a second structurally robust arched plate operatively connected and disposed underneath the second layer; anda third layer operatively connected and disposed underneath the second structurally robust arched plate, wherein the third layer comprises a third material;wherein the second structurally robust arched plate is oriented parallel to the at least one structurally robust arched plate;wherein the at least one applied load is transferred through that the at least one structurally robust arched plate causing a curvature and a size of the at least one first arch of the at least one structurally robust arched plate to deform causing the second layer to be conformed to the at least one structurally robust arched plate; andwherein energy created by the at least one applied load is diverged by the at least one structurally robust arched plate and the second layer. 18. The apparatus according to claim 1, wherein the at least one cell further comprises: a second structurally robust arched plate operatively connected and disposed underneath the second layer; anda third layer operatively connected and disposed underneath the second structurally robust arched plate, wherein the third layer comprises a second material;wherein the second structurally robust arched plate is oriented perpendicular to the at least one structurally robust arched plate;wherein the at least one applied load is transferred through that least one structurally robust arched plate causing a curvature and a size of the at least one first arch of the at least one structurally robust arched plate to deform causing the second layer to be conformed to the at least one structurally robust arched plate; andwherein energy created by the at least one applied load is diverged by the at least one structurally robust arched plate and the second layer. 19. The apparatus according to claim 2, wherein the at least one first arch and at least one second arch form at least one bell by completely rotating a panel defined by a curve between a first position of the at least one first arch operatively connected to the first layer and a second position of the at least one second arch operatively connected to the second layer. 20. The apparatus according to claim 19, wherein the at least one applied load causes the at least one bell to deform the first layer at the first position and the at least one second layer at the second position; and wherein the at least one bell of the at least one structurally robust arched plate diverges a nonlinear deformation created by the at least one applied load into a dispersed area, the dispersed area being greater than the at least one applied load area. 21. The apparatus according to claim 1, wherein the first and second materials differ in one or more of material hardness, yield strength, fracture toughness, or Poisson's ratio.