An energy absorbing liner system and method of making it, preferably by thermoforming. A helmet has an energy absorbing inner system positioned inside the shell. The liner has thermoformed interconnected energy absorbing modules that non-destructively rebound after one or more impacts. At least some
An energy absorbing liner system and method of making it, preferably by thermoforming. A helmet has an energy absorbing inner system positioned inside the shell. The liner has thermoformed interconnected energy absorbing modules that non-destructively rebound after one or more impacts. At least some of the modules in the layer have a basal portion with upper and lower sections when viewed in relation to the wearer's head. The upper section has one or more energy absorbing units. At least some of the units are provided with a wall with a domed cap that faces the outer shell. The units at least partially cushion the blow by absorbing energy imparted by an object that impacts the outer shell. The lower comfort section has a tiered arrangement of layers. The layers are relatively compliant and thus provide a comfortable yet firm fit of the helmet upon the wearer.
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1. An energy absorbing liner system that is interposed between an incident surface that receives an impacting force and a mass to be protected from at least some of the impacting force, the energy absorbing liner system having one or more energy absorbing modules, at least some of which having the c
1. An energy absorbing liner system that is interposed between an incident surface that receives an impacting force and a mass to be protected from at least some of the impacting force, the energy absorbing liner system having one or more energy absorbing modules, at least some of which having the characteristic of reversion after impact to or towards an un-deflected configuration, one or more of the energy absorbing modules consisting essentially of a thermoplastic urethane and having an upper energy absorbing section having an upper basal layerone or more energy absorbing units that extend from the upper basal layer, at least some of the one or more energy absorbing units being provided witha flexible wall that extends from the upper basal layer, the one or more energy absorbing units at least partially absorbing energy generated by an impacting object by the flexible wall bending inwardly or outwardly without rupture;a lower compliant section having a lower basal layer that interfaces with the upper basal layer of the upper energy absorbing sectiona tiered arrangement of layers extending from the lower basal layer, the arrangement including a radially outermost layer that cooperates with and lies inside a perimeter of the lower basal layer, one or more radially intermediate layers extending from and within the outermost layer and a radially innermost layer that extends from and within an intermediate layer, the layers in the tiered arrangement being relatively compliant and cooperating at least partially in a telescoping manner in response to a force transmitted across the lower compliant section, thereby providing a comfortable yet firm fit of the energy absorbing modules to the mass to be protected from at least some of the impacting force. 2. The liner system of claim 1, further including an incident surface that cooperates with the one or more energy absorbing modules in response to an impacting object, the incident surface being selected from the group consisting of a helmet, an automotive headliner, an anatomical member, a knee bolster, a bumper, a steering wheel, a knee pad, an elbow guard, a shoulder pad, an abdominal protector, a vehicular floor, a vehicular panel and a wrist pad. 3. The liner system of claim 1, wherein the upper layer, the lower layer or both are made by a process selected from the group consisting of thermoforming, injection molding and combinations thereof and are joined by uniting at least a part of the upper and lower basal layers. 4. The liner system of claim 1, further including one or more ribs that extend between at least some of the energy absorbing units. 5. The liner system of claim 1, wherein some of the modules include clusters adapted for being arranged radially around the head or cranium, the clusters including a pair of side clusters that are configured for at least partially surrounding or covering the head or cranium of a wearer;one or more back clusters that are configured for at least partially covering the back of a wearer's head; andone or more front clusters that are configured for at least partially covering a wearer's forehead. 6. The liner system of claim 1 wherein the flexible wall defines a substantially frustoconical surface. 7. The liner system of claim 1 wherein the flexible wall and the upper basal layer define a perimeter where they intersect, the perimeter defining a shape that is selected from the group consisting of a circle, an oval, an ellipse, an oblate oblong, a polygon, a quadrilateral with rounded edges and combinations thereof. 8. The liner system of claim 1 wherein the flexible wall has an upper edge that meets a dome, the upper edge defining a perimeter where they intersect, the perimeter defining a shape that is selected from the group consisting of a circle, an oval, an ellipse, an oblate oblong, a polygon, a quadrilateral with rounded edges and combinations thereof. 9. The liner system of claim 1, wherein the lower compliant section includes a lower section that is at least partially inflated primarily for fit. 10. The liner system of claim 1, further including one or more drainage or ventilation locations in one or more energy absorbing modules. 11. The liner system of claim 1 wherein the plurality of energy absorbing units are reusable after exposure to multiple impacts, each energy absorbing unit including a side wall that reverts at least partially to or towards an un-deflected configuration within a time (T) after impact, thereby absorbing energy non-destructively after being impacted. 12. The liner system defined in claim 1, wherein the at least one energy absorbing unit reverts to or towards a compression-set configuration after impact. 13. The liner system defined in claim 1, wherein the side wall bends in response to impact and springs back to an un-deflected configuration in further response to impacting forces. 14. The liner system defined in claim 2, further including a domed end wall that is supported by an upper periphery of a flexible wall and deflects inwardly, thereby absorbing a portion of the energy dissipated during impact. 15. The liner system of claim 11 wherein the time (T) is less than 90 seconds. 16. The liner system defined in claim 1, wherein at least some of the energy absorbing units revert to or towards a configuration that is selected from the group consisting of a pre-impact configuration and a compression set configurationafter a number (N) of impacts, where the number (N) is 1 or morewithin a time (T) for reversion to the pre-impact or compression set configuration, where 0.01
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