25 research outputs found
Noncontact Free-Rotating Disk Triboelectric Nanogenerator as a Sustainable Energy Harvester and Self-Powered Mechanical Sensor
In this work, we introduced an innovative noncontact, free-rotating disk triboelectric nanogenerator (FRD-TENG) for sustainably scavenging the mechanical energy from rotary motions. Its working principle was clarified through numerical calculations of the relative-rotation-induced potential difference, which serves as the driving force for the electricity generation. The unique characteristic of the FRD-TENG enables its high output performance compared to its working at the contact mode, with an effective output power density of 1.22 W/m<sup>2</sup> for continuously driving 100 light-emitting diodes. Ultrahigh stability of the output and exceptional durability of the device structure were achieved, and the reliable output was utilized for fast/effective charging of a lithium ion battery. Based on the relationship between its output performance and the parameters of the mechanical stimuli, the FRD-TENG could be employed as a self-powered mechanical sensor, for simultaneously detecting the vertical displacement and rotation speed. The FRD-TENG has superior advantages over the existing disk triboelectric nanogenerator, and exhibits significant progress toward practical applications of nanogenerators for both energy harvesting and self-powered sensor networks
Robust Triboelectric Nanogenerator Based on Rolling Electrification and Electrostatic Induction at an Instantaneous Energy Conversion Efficiency of ∼55%
In comparison to in-pane sliding friction, rolling friction not only is likely to consume less mechanical energy but also presents high robustness with minimized wearing of materials. In this work, we introduce a highly efficient approach for harvesting mechanical energy based on rolling electrification and electrostatic induction, aiming at improving the energy conversion efficiency and device durability. The rolling triboelectric nanogenerator is composed of multiple steel rods sandwiched by two fluorinated ethylene propylene (FEP) thin films. The rolling motion of the steel rods between the FEP thin films introduces triboelectric charges on both surfaces and leads to the change of potential difference between each pair of electrodes on back of the FEP layer, which drives the electrons to flow in the external load. As power generators, each pair of output terminals works independently and delivers an open-circuit voltage of 425 V, and a short-circuit current density of 5 mA/m<sup>2</sup>. The two output terminals can also be integrated to achieve an overall power density of up to 1.6 W/m<sup>2</sup>. The impacts of variable structural factors were investigated for optimization of the output performance, and other prototypes based on rolling balls were developed to accommodate different types of mechanical energy sources. Owing to the low frictional coefficient of the rolling motion, an instantaneous energy conversion efficiency of up to 55% was demonstrated and the high durability of the device was confirmed. This work presents a substantial advancement of the triboelectric nanogenerators toward large-scope energy harvesting and self-powered systems
Sliding-Triboelectric Nanogenerators Based on In-Plane Charge-Separation Mechanism
Aiming at harvesting ambient mechanical
energy for self-powered
systems, triboelectric nanogenerators (TENGs) have been recently developed
as a highly efficient, cost-effective and robust approach to generate
electricity from mechanical movements and vibrations on the basis
of the coupling between triboelectrification and electrostatic induction.
However, all of the previously demonstrated TENGs are based on vertical
separation of triboelectric-charged planes, which requires sophisticated
device structures to ensure enough resilience for the charge separation,
otherwise there is no output current. In this paper, we demonstrated
a newly designed TENG based on an in-plane charge separation process
using the relative sliding between two contacting surfaces. Using
Polyamide 6,6 (Nylon) and polytetrafluoroethylene (PTFE) films with
surface etched nanowires, the two polymers at the opposite ends of
the triboelectric series, the newly invented TENG produces an open-circuit
voltage up to ∼1300 V and a short-circuit current density of
4.1 mA/m<sup>2</sup> with a peak power density of 5.3 W/m<sup>2</sup>, which can be used as a direct power source for instantaneously
driving hundreds of serially connected light-emitting diodes (LEDs).
The working principle and the relationships between electrical outputs
and the sliding motion are fully elaborated and systematically studied,
providing a new mode of TENGs with diverse applications. Compared
to the existing vertical-touching based TENGs, this planar-sliding
TENG has a high efficiency, easy fabrication, and suitability for
many types of mechanical triggering. Furthermore, with the relationship
between the electrical output and the sliding motion being calibrated,
the sliding-based TENG could potentially be used as a self-powered
displacement/speed/acceleration sensor
Sliding-Triboelectric Nanogenerators Based on In-Plane Charge-Separation Mechanism
Aiming at harvesting ambient mechanical
energy for self-powered
systems, triboelectric nanogenerators (TENGs) have been recently developed
as a highly efficient, cost-effective and robust approach to generate
electricity from mechanical movements and vibrations on the basis
of the coupling between triboelectrification and electrostatic induction.
However, all of the previously demonstrated TENGs are based on vertical
separation of triboelectric-charged planes, which requires sophisticated
device structures to ensure enough resilience for the charge separation,
otherwise there is no output current. In this paper, we demonstrated
a newly designed TENG based on an in-plane charge separation process
using the relative sliding between two contacting surfaces. Using
Polyamide 6,6 (Nylon) and polytetrafluoroethylene (PTFE) films with
surface etched nanowires, the two polymers at the opposite ends of
the triboelectric series, the newly invented TENG produces an open-circuit
voltage up to ∼1300 V and a short-circuit current density of
4.1 mA/m<sup>2</sup> with a peak power density of 5.3 W/m<sup>2</sup>, which can be used as a direct power source for instantaneously
driving hundreds of serially connected light-emitting diodes (LEDs).
The working principle and the relationships between electrical outputs
and the sliding motion are fully elaborated and systematically studied,
providing a new mode of TENGs with diverse applications. Compared
to the existing vertical-touching based TENGs, this planar-sliding
TENG has a high efficiency, easy fabrication, and suitability for
many types of mechanical triggering. Furthermore, with the relationship
between the electrical output and the sliding motion being calibrated,
the sliding-based TENG could potentially be used as a self-powered
displacement/speed/acceleration sensor
ClustalX alignment of <i>lepr</i> from <i>E. sinensis</i> and 25 other organisms.
<p>The vacuolar protein sorting 55 (Vps55) domain in <i>lepr</i> starts at Leu7 and ends at Asp127.</p
Oligonucleotide primers used in the experiments.
<p>Oligonucleotide primers used in the experiments.</p
Nucleotide sequence and deduced amino acid sequence of Chinese mitten crab <i>lepr</i>.
<p>Nucleotides (upper) are numbered beginning at the 5′ end. Amino acids (lower), shown using one-letter abbreviations, are numbered beginning at the initiating methionine. The signal peptide is underlined, and the mature peptide is enclosed in the black box. The three conserved cysteine residues in the deduced amino acid sequence are shown in grey boxes. The stop codon is marked by an asterisk. The polyadenylation signal (AATAAA) is enclosed in the black ellipse. Arrows indicate the positions of primers; black boxes indicate the coding region; white lines indicate 5′ and 3′ UTRs; curly bracket indicate position of the EST clone. The <i>E. sinensis lepr</i> sequence was submitted to GenBank under accession number GU443952.</p
Segmentally Structured Disk Triboelectric Nanogenerator for Harvesting Rotational Mechanical Energy
We introduce an innovative design
of a disk triboelectric nanogenerator
(TENG) with segmental structures for harvesting rotational mechanical
energy. Based on a cyclic in-plane charge separation between the segments
that have distinct triboelectric polarities, the disk TENG generates
electricity with unique characteristics, which have been studied by
conjunction of experimental results with finite element calculations.
The role played by the segmentation number is studied for maximizing
output. A distinct relationship between the rotation speed and the
electrical output has been thoroughly investigated, which not only
shows power enhancement at high speed but also illuminates its potential
application as a self-powered angular speed sensor. Owing to the nonintermittent
and ultrafast rotation-induced charge transfer, the disk TENG has
been demonstrated as an efficient power source for instantaneously
or even continuously driving electronic devices and/or charging an
energy storage unit. This work presents a novel working mode of TENGs
and opens up many potential applications of nanogenerators for harvesting
even large-scale energy
<i>Lepr</i> sequences identities between <i>E. sinensis</i> and 25 other organisms.
<p><i>Lepr</i> sequences identities between <i>E. sinensis</i> and 25 other organisms.</p
Triboelectric Active Sensor Array for Self-Powered Static and Dynamic Pressure Detection and Tactile Imaging
We report an innovative, large-area, and self-powered pressure mapping approach based on the triboelectric effect, which converts the mechanical stimuli into electrical output signals. The working mechanism of the triboelectric active sensor (TEAS) was theoretically studied by both analytical method and numerical calculation to gain an intuitive understanding of the relationship between the applied pressure and the responsive signals. Relying on the unique pressure response characteristics of the open-circuit voltage and short-circuit current, we realize both static and dynamic pressure sensing on a single device for the first time. A series of comprehensive investigations were carried out to characterize the performance of the TEAS, and high sensitivity (0.31 kPa<sup>–1</sup>), ultrafast response time (<5 ms), long-term stability (30 000 cycles), as well as low detection limit (2.1 Pa) were achieved. The pressure measurement range of the TEAS was adjustable, which means both gentle pressure detection and large-scale pressure sensing were enabled. Through integrating multiple TEAS units into a sensor array, the as-fabricated TEAS matrix was capable of monitoring and mapping the local pressure distribution applied on the device with distinguishable spatial profiles. This work presents a technique for tactile imaging and progress toward practical applications of nanogenerators, providing potential solutions for accomplishment of artificial skin, human-electronic interfacing, and self-powered systems