Abstract: A Self-Sustaining-extensible-multi-stage-Vibrational-and-Acoustic-Piezoelectric-Resonator-Acoustic-Refrigeration-Core Generator of Electricity, Heating and Cooling comprises a plurality of acoustically-driven mechanically-coupled tuned-closed-column-resonator-tuned-Helmholtz-resonator-piezo-poly-passive-radiator-electromagnetic-induction-circuit vibrational-and-acoustic-piezoelectric-resonator-acoustic-refrigeration-core systems that mechanically amplifies induced sound pressure levels via standing wave resonance such that the anti-node/s of the natural resonant frequency/ies in the tuned-closed-column-resonator/s occur/s in the plane/s consistent with the coupling port/s of the attached tuned-Helmholtz resonator/s acoustically driving the tuned-Helmholtz resonator/s such that standing wave resonance occurs within the tuned-Helmholtz resonators one wall of which is a piezo-poly-passive-radiator connecting the preceding stage to the proceeding stage finally driving the axial-regenerating-stack acoustic-refrige

Abstract: A plurality of acoustically-driven mechanically-coupled tuned-closed-column-resonator-tuned-Helmholtz-resonator-piezo-poly-passive-radiator-electromagnetic-induction-circuit vibrational and acoustic piezoelectric resonator systems constitute an acoustic energy harvesting device that mechanically amplifies induced sound pressure levels via standing wave resonance such that the anti-node/s of the natural resonant frequency/ies in the tuned-closed-column-resonator/s occur/s in the plane/s consistent with the coupling port/s of the attached tuned-Helmholtz resonator/s and subsystems, acoustically driving the tuned-Helmholtz resonator/s of physical parameters such that standing wave resonance occurs within the tuned-Helmholtz resonators one wall of which comprises a sympathetically oscillating poled-piezo-polymer-surround-mounted-non-poled-piezo-polymer tympanic membrane the face/s of which is/are mounted with thin film ferromagnetic solenoids that derive electric fields from the oscillating poled-piezo-polymer su

Abstract: A plurality of pressurized sequentially perpendicularly coupled and tuned piezoelectric resonators mechanically amplifies ambient and induced Sound Pressure Levels via Standing Wave Resonance such that the anti-node of the Natural Resonant Frequency in each resonator occurs in a plane consistent with the coupling port of the subsequent resonator thereby acting as a mechanically amplified acoustic driver for the proceeding resonator until acoustically driving mechanically coupled and tuned Piezoelectric Helmholtz resonators with physical parameters such that Standing Wave Resonance occurs within the Piezoelectric Helmholtz Resonant Cavities and Acoustic Refrigeration Units comprising cylindrical resonant cavities with axial regenerating stacks acted upon by tuned frequencies such that the hot heat exchangers are in the center of said cavities while the cold heat exchangers comprise the termination of the second ends of said cavities. The latent heat generates steam in a pressurized vessel.