Devices, systems, and methods for downhole power generation

What is claimed is: 1. A downhole energy harvesting system for use in a wellbore, the downhole energy harvesting system comprising: a housing subjected to periodic oscillations when deployed in the wellbore, the housing having a pocket recessed in an outer surface or inner surface of the housing; an energy harvesting device disposed within the pocket and configured to generate electricity based on the periodic oscillations, wherein the energy harvesting device includes a clamp secured to the pocket, a cantilevered body with a first end connected to the clamp and a free second end spaced from the clamp and disposed opposite the first end, and piezoelectric material that extends along at least part of a length of the cantilevered body between the first end and the free second end, wherein the cantilevered body and the piezoelectric material are configured to flex to cause the piezoelectric material to generate electrical alternating current in response to the periodic oscillations, and wherein the free second end of the cantilevered body includes a tuning mass with a track configured to adjust position of the tuning mass at the free second end of the cantilevered body to change resonant frequency of the cantilevered body; an energy storage device connected to the energy harvesting device; at least one sensor configured to determine harmonic frequency of the housing when deployed in the wellbore and subjected to the periodic oscillations; and a controller configured to adjust position of the tuning mass at the free second end of the cantilevered body such that resonant frequency of the cantilevered body corresponds to the harmonic frequency of the housing when deployed in the wellbore and subjected to the periodic oscillations. 2. The downhole energy harvesting system of claim 1 , wherein the cantilevered body is oriented parallel to a rotational axis of the housing. 3. The downhole energy harvesting system of claim 1 , wherein the cantilevered body includes a vibrating plane that intersects a rotational axis of the housing. 4. The downhole energy harvesting system of claim 1 , wherein the cantilevered body includes a vibrating plane that is parallel to a rotational axis of the housing. 5. A method for downhole energy generation in a wellbore, the method comprising: deploying the downhole energy harvesting system of claim 1 in the wellbore, which subjects the housing of the energy harvesting system to periodic oscillations; based on the periodic oscillations, generating electricity with the energy harvesting device of the downhole energy harvesting system with the at least one sensor and the controller of the downhole energy harvesting system cooperating to adjust position of the tuning mass along the track such that resonant frequency of the cantilevered body corresponds to the harmonic frequency of the housing; and at least one of (i) storing the electricity on the energy storage device of the downhole energy harvesting system or (ii) using the electricity to operate a powered component coupled to the housing of the downhole energy harvesting system. 6. The method of claim 5 , wherein the periodic oscillations include torsional oscillations. 7. The downhole energy harvesting system of claim 1 , further comprising: an electric signal processor coupled between the energy harvesting device and the energy storage device, wherein the electric signal processor is configured to convert electrical alternating current generated by the piezoelectric material of the energy harvesting device to electrical direct current for supply to the energy storage device. 8. The downhole energy harvesting system of claim 1 , wherein: the piezoelectric material comprises a piezoelectric strip connected to the cantilevered body. 9. The downhole energy harvesting system of claim 8 , wherein: the piezoelectric strip is located at a location of maximum strain on the cantilevered body. 10. The downhole energy harvesting system of claim 8 , wherein: the piezoelectric strip is orientated to generate energy based on directional vibration of the cantilevered body. 11. The downhole energy harvesting system of claim 1 , wherein: the cantilevered body has a variable thickness over the length of the cantilevered body. 12. The downhole energy harvesting system of claim 1 , wherein: the cantilevered body has a three-dimensional shape selected from a group including rectangular prism, pyramidal, triangular prismatic, rectangular prismatic, pentagonal prismatic, hexagonal prismatic, prismatic of any shape, cymbals, rods, discs, and combinations thereof.