Over the past few decades the use of portable and wearable electronics has grown steadily.
These devices are becoming increasingly more powerful. However, the gains that have been
made in the device performance have resulted in the need for significantly higher
power to operate the electronics. This issue has been further complicated due
to the stagnant growth of battery technology over the past decade. In order to
increase the life of these electronics, researchers have begun investigating methods
of generating energy from ambient sources such that the life of the electronics
can be prolonged. Recent developments in the field have led to the design of a
number of mechanisms that can be used to generate electrical energy, from a
variety of sources including thermal, solar, strain, inertia, etc. Many of these
energy sources are available for use with humans, but their use must be carefully
considered such that parasitic effects that could disrupt the user’s gait or endurance
are avoided. These issues have arisen from previous attempts to integrate power
harvesting mechanisms into a shoe such that the energy released during a heal strike
could be harvested. This study develops a novel energy harvesting backpack that
can generate electrical energy from the differential forces between the wearer
and the pack. The goal of this system is to make the energy harvesting device
transparent to the wearer such that his or her endurance and dexterity is not
compromised. This will be accomplished by replacing the traditional strap of the
backpack with one made of the piezoelectric polymer polyvinylidene fluoride (PVDF).
Piezoelectric materials have a structure such that an applied electrical potential results
in a mechanical strain. Conversely, an applied stress results in the generation
of an electrical charge, which makes the material useful for power harvesting
applications. PVDF is highly flexible and has a high strength, allowing it to effectively
act as the load bearing member. In order to preserve the performance of the
backpack and user, the design of the pack will be held as close to existing systems
as possible. This paper develops a theoretical model of the piezoelectric strap
and uses experimental testing to identify its performance in this application.
About the cover: The figure in the upper left is an idealization of an actual test structure with loose internal parts that was subjected to an 18 Hz base input on a shake table. Los Alamos National Laboratory, an affirmative action/ equal opportunity employer, is operated by Los Alamos
This paper describes the development of the next generation of an extremely compact,
wireless impedance sensor node for use in structural health monitoring (SHM) and
piezoelectric active-sensor self-diagnostics. The sensor node uses a recently developed,
low-cost integrated circuit that can measure and record the electrical impedance of a
piezoelectric transducer. The sensor node also integrates several components, including a
microcontroller for local computing, telemetry for wirelessly transmitting data, multiplexers
for managing up to seven piezoelectric transducers per node, energy harvesting and storage
mediums, and a wireless triggering circuit into one package to truly realize a
comprehensive, self-contained wireless active-sensor node for various SHM applications. It
is estimated that the developed sensor node requires less than 60 mW of total power for
measurement, computation, and transmission. In addition, the sensor node is
equipped with active-sensor self-diagnostic capabilities that can monitor the condition
of piezoelectric transducers used in SHM applications. The performance of this
miniaturized device is compared to our previous results and its broader capabilities are
demonstrated.
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