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This invention pertains to a low cost, low noise strain sensor based on a web of continuous core-shell nanofibers with conductive shell and mechanically robust core that can be attached or embedded on a variety objects for directional monitoring of static or dynamic changes in mechanical deformation

This invention pertains to a low cost, low noise strain sensor based on a web of continuous core-shell nanofibers with conductive shell and mechanically robust core that can be attached or embedded on a variety objects for directional monitoring of static or dynamic changes in mechanical deformation and pressure. This is a low cost, highly sensitive strain sensor, with low noise and ease of integration for different applications from synthetic tactile skins, to vibrational and health monitoring.

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1. A resistive sensor device comprising: a first fiber mesh comprising a first plurality of elongate fibers, wherein each fiber of the first plurality of fibers comprises an electrical conductor comprising an electrically conductive exterior surface reversibly positionable into and out of electrical

1. A resistive sensor device comprising: a first fiber mesh comprising a first plurality of elongate fibers, wherein each fiber of the first plurality of fibers comprises an electrical conductor comprising an electrically conductive exterior surface reversibly positionable into and out of electrically conductive contact with the electrically conductive exterior surfaces of adjacent fibers of the first plurality of fibers; andat least one resiliently deformable encapsulating film that encapsulates the first fiber mesh, whereby resilient deformation of the at least one encapsulating film moves fibers of the first plurality of fibers and reversibly controls electrically conductive contact between the exterior surfaces of adjacent fibers of the first plurality of fibers and changes electrical resistance of the first fiber mesh. 2. The resistive sensor device of claim 1, further comprising first and second electrical contacts, wherein the electrical conductor of at least one of the first plurality of fibers is electrically conductively coupled to the first electrical contact, and the electrical conductor of at least one of the first plurality of fibers is electrically conductively coupled to the second electrical contact, wherein the first and second electrical contacts are spaced apart from each other and operable to apply electrical voltage or current across at least a portion of the first fiber mesh to define a first desired direction of current through the first fiber mesh. 3. The resistive sensor device of claim 2, further comprising first and second electrical wires connected to the first and second electrical contacts respectively. 4. The resistive sensor device of claim 2, further comprising: a second fiber mesh comprising a second plurality of elongate fibers, wherein each fiber of the second plurality of fibers comprises an electrical conductor comprising an electrically conductive exterior surface reversibly positionable into and out of electrically conductive contact with the electrically conductive exterior surfaces of adjacent fibers of the second plurality of fibers;third and fourth resiliently deformable encapsulating films that encapsulate the second fiber mesh between the third and fourth encapsulating films and that are adhered together and to the second plurality of fibers, whereby resilient deformation of the third and fourth encapsulating films moves fibers of the second plurality of fibers and reversibly controls electrically conductive contact between the exterior surfaces of adjacent fibers of the second plurality of fibers and changes electrical resistance of the second fiber mesh; andthird and fourth electrical contacts, wherein the electrical conductor of at least one of the second plurality of fibers is electrically conductively coupled to the third electrical contact, and the electrical conductor of at least one of the second plurality of fibers is electrically conductively coupled to the fourth electrical contact, wherein the third and fourth electrical contacts are spaced apart from each other and operable to apply electrical voltage or current across at least a portion of the second fiber mesh to define a second desired direction of current through the second fiber mesh, wherein the second desired direction differs from the first desired direction. 5. The strain sensor device of claim 4, wherein the second desired direction is generally perpendicular to the first desired direction. 6. The strain sensor device of claim 4, wherein the second fiber mesh is layered over the first fiber mesh. 7. The resistive sensor device of claim 1, wherein each fiber of the first plurality of fibers comprises a core and a conductive shell comprising the electrical conductor. 8. The resistive sensor device of claim 1, wherein the fibers of the first plurality of fibers comprise nanofibers. 9. A resistive sensor assembly comprising a plurality of resistive sensor devices, wherein: each of the plurality of resistive sensor devices comprises: first and second electrical contacts;a fiber mesh comprising a plurality of elongate fibers, wherein each fiber of the plurality of fibers comprises an electrical conductor comprising an electrically conductive exterior surface reversibly positionable into and out of electrically conductive contact with the electrically conductive exterior surfaces of adjacent fibers of the plurality of fibers, wherein the electrical conductor of at least one of the plurality of fibers is electrically conductively coupled to the first electrical contact, and the electrical conductor of at least one of the plurality of fibers is electrically conductively coupled to the second electrical contact, wherein the first and second electrical contacts are spaced apart from each other and operable to apply electrical voltage or current across at least a portion of the fiber mesh to define a desired direction of current through the fiber mesh;at least one resiliently deformable encapsulating film that encapsulates the fiber mesh, whereby resilient deformation of the at least one encapsulating film moves fibers of the plurality of fibers and reversibly controls electrically conductive contact between the exterior surfaces of adjacent fibers of the plurality of fibers and changes electrical resistance of the fiber mesh; andfirst and second electrical wires connected to the first and second electrical contacts respectively; andeach of the plurality of resistive sensor devices is positionable on a surface of an object in a different position or with a different desired direction of current than others of the plurality of resistive sensor devices. 10. A method of fabricating a resistive sensor device, the method comprising: depositing fiber mesh comprising a plurality of elongate fibers, wherein each fiber of the plurality of fibers comprises an electrical conductor comprising an electrically conductive exterior surface reversibly positionable into and out of electrically conductive contact with the electrically conductive exterior surfaces of adjacent fibers of the plurality of fibers;electrically conductively coupling a first electrical contact with the electrical conductor of at least some of the plurality of fibers;electrically conductively coupling a second electrical contact with the electrical conductor of at least some of the plurality of fibers; andencapsulating the plurality of fibers in at least one encapsulating film on the core shell nanofibers whereby resilient deformation of the at least one encapsulating film moves fibers of the plurality of fibers and reversibly controls electrically conductive contact between the exterior surfaces of adjacent fibers of the plurality of fibers and changes electrical resistance of the fiber mesh. 11. The method of claim 10, wherein each fiber of the plurality of fibers comprises a core and a conductive shell comprising the electrical conductor. 12. The method of claim 11, wherein depositing the fiber mesh comprises electrospinning or forcespinning the cores of the plurality of fibers. 13. The method of claim 11, further comprising depositing the conductive shell using sputtering or electrodeposition. 14. The method of claim 11, further comprising co-electrospinning the plurality of fibers. 15. The method of claim 10, further comprising patterning the fiber mesh to match the geometry to a source of resilient deformation.