Transpiration as a mechanism for mechanical and electrical energy conversion.

摘要

Devices that scavenge power by utilizing energy present in their environment are of interest to researchers for powering sensors in areas where hard-wired connections are not feasible and battery maintenance is costly. Researchers have made of use vibrations, temperature, and other environmental stimuli.;In this thesis, transpiration is researched as a mechanism for mechanical and electrical energy conversion. Two energy scavenging devices inspired by the transpiration mechanism in plants were developed and tested. The first is a class of mechanical actuators that operate via the evaporation of water to generate forces per unit length of 5.75 - 67.75 mN/m, angular rotations of 330° and tip deflections of 3.5 mm. The actuators were also studied as a way to achieve bottom-up self assembly by programming deflection profiles into materials using geometric parameters. These actuators can be used in applications for an evaporation-powered and controlled self-assembly of micro components. The experimental work is coupled with the development of an accurate theoretical model based on the principle of virtual work.;The second type of devices developed in this thesis use an evaporation-induced flow within leaf-like microvasculature networks to drive the movement of gas bubbles through capacitor plates. This motion allows the charge pumping of an energy conversion circuit. Evaporation-driven flow was enhanced by using porous materials at the fluidic channel outlets to achieve a maximum flow velocity of 1.5 cm/s. Changes in capacitance measured at 1 MHz were between 8 - 10 pF and greater than 30 pF at lower frequencies for each bubble. Current generated by capacitance change was measured to reach up to 1 nA. Using the conversion circuit, voltage outputs up to 5 muV were measured for each water to air interface. A theoretical bound of the scavenged power density was calculated as a function of the size of the storage capacitor. Theoretical analysis and simulation results are presented to describe how the circuit can be modified to suit the energy harvesting application.;The primary contribution of this thesis is the demonstration that the transpiration mechanism of plants can be mimicked in microscale devices to provide mechanical and electrical energy.