Abstract: A mechanism for capturing mechanical energy and converting it to electrical energy for use continually charging or providing emergency power to mobile, battery-powered devices comprises a plurality of elongated piezoelectric elements mounted at one or support points to one or more support structures. The plurality of piezoelectric elements are preferably structured and arranged so that at least each three-dimensional coordinate axis has at least one element with a dominant mode of deflection in a plane normal to the axis, in order to permit harvesting energy from forces applied in any direction without regard to the orientation of the energy harvesting mechanism to the source of forces. This results in improved coupling of the transducer with the random movements or vibrations that may not confined to any particular plane or in a plane that is not necessarily aligned with the plane in which a piezoelectric element is designed to bend, thus improving the efficiency of energy capture.

Abstract: Sensitive elements and devices include at least one piezoelectric material and a compliant polymer substrate having elastomeric properties to lend flexibility without affecting sensitivity of the element and/or device. Sensitive elements are in operable communication with a control system; communication is wireless. Interaction of a sensitive element/sensitive device with an operator/environmental object/device is provided through use of an impedance controller and filter.

Abstract: A mechanism for capturing mechanical energy and converting it to electrical energy for use continually charging or providing emergency power to mobile, battery-powered devices comprises a plurality of elongated piezoelectric elements mounted at one or support points to one or more support structures. The plurality of piezoelectric elements are preferably structured and arranged so that at least each three-dimensional coordinate axis has at least one element with a dominant mode of deflection in a plane normal to the axis, in order to permit harvesting energy from forces applied in any direction without regard to the orientation of the energy harvesting mechanism to the source of forces. This results in improved coupling of the transducer with the random movements or vibrations that may not confined to any particular plane or in a plane that is not necessarily aligned with the plane in which a piezoelectric element is designed to bend, thus improving the efficiency of energy capture.

Abstract: A mechanism for capturing mechanical energy and converting it to electrical energy for use continually charging or providing emergency power to mobile, battery-powered devices comprises a plurality of elongated piezoelectric elements mounted at one or support points to one or more support structures. The plurality of piezoelectric elements are preferably structured and arranged so that at least each three-dimensional coordinate axis has at least one element with a dominant mode of deflection in a plane normal to the axis, in order to permit harvesting energy from forces applied in any direction without regard to the orientation of the energy harvesting mechanism to the source of forces. This results in improved coupling of the transducer with the random movements or vibrations that may not confined to any particular plane or in a plane that is not necessarily aligned with the plane in which a piezoelectric element is designed to bend, thus improving the efficiency of energy capture.

Abstract: The present invention includes methods, devices, and compositions having improved piezoelectric characteristics with high energy density. Compositions of the present invention are ceramic materials of the formula: Pb[(Zr0.52Ti0.48)O3]1?x[(Zn1/3Nb2/3)O3]x+Mn, where x is 0.05 to 0.20 and Mn is manganese in a form that is present from about 0.1 to 1.5 wt %. Suitable manganese forms include MnCO3, MnO2, MnO, and Mn3O4. The compositions exhibit a high product of piezoelectric voltage constant and piezoelectric stress constant. The compositions are polycrystalline or textured with a dense microstructure and small grain. The piezoelectric voltage constant and piezoelectric stress constant obtained from such compositions are superior to those of conventional hard or soft ceramics and yield a magnitude product of the piezoelectric voltage constant and piezoelectric stress constant that is significantly higher than those reported in the literature or in available with commercial or conventional ceramic compositions.