Serious climate changes and energy-related environmental
problems
are currently critical issues in the world. In order to reduce carbon
emissions and save our environment, renewable energy harvesting technologies
will serve as a key solution in the near future. Among them, triboelectric
nanogenerators (TENGs), which is one of the most promising mechanical
energy harvesters by means of contact electrification phenomenon,
are explosively developing due to abundant wasting mechanical energy
sources and a number of superior advantages in a wide availability
and selection of materials, relatively simple device configurations,
and low-cost processing. Significant experimental and theoretical
efforts have been achieved toward understanding fundamental behaviors
and a wide range of demonstrations since its report in 2012. As a
result, considerable technological advancement has been exhibited
and it advances the timeline of achievement in the proposed roadmap.
Now, the technology has reached the stage of prototype development
with verification of performance beyond the lab scale environment
toward its commercialization. In this review, distinguished authors
in the world worked together to summarize the state of the art in
theory, materials, devices, systems, circuits, and applications in
TENG fields. The great research achievements of researchers in this
field around the world over the past decade are expected to play a
major role in coming to fruition of unexpectedly accelerated technological
advances over the next decade.
Long-distance walking with heavy loads is often needed when going hiking or for field rescue, which is prone to cumulative fatigue. There is also a great need for labor-saving and biomechanical energy harvesting in daily life for extended security and communication needs. Here, we report a loadsuspended backpack for harvesting the wasted energy of human motion based on a triboelectric nanogenerator (TENG). Two elastomers are incorporated into the backpack to decouple the synchronous movement of the load and the human body, which results in little or no extra accelerative force. With such a design, through theoretical analysis and field experiments, the backpack can realize a reduction of 28.75 % in the vertical oscillation of the load and 21.08 % in the vertical force on the wearer, respectively. Meanwhile, the mechanical-to-electric energy conversion efficiency is modeled and calculated to be 14.02 % under normal walking conditions. The designed backpack has the merits of labor-saving and shock absorption as well as electricity generation, which has the promising potential to be a power source for small-scale wearable and portable electronics, GPS systems, and other self-powered health care sensors.
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