Hybridized Mechanical and Solar Energy-Driven Self-Powered Hydrogen Production

Wei, Xuelian; Wen, Zhen; Liu, Yina; Zhai, Ningning; Wei, Aimin; Feng, Kun; Yuan, Guotao; Zhong, Jun; Ye, Qiang; Sun, Xuhui

doi:10.1007/s40820-020-00422-4

Cited by 45 publications

(25 citation statements)

References 50 publications

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“…The solar thermal conversion could convert solar radiation into heat and then generate electrical output based on a thermoelectric conversion system. Photovoltaic devices are considered to be the most promising energy conversion technology in the next decade because they can convert solar energy into electricity directly based on the photovoltaic effect ( Dudem et al., 2016 ; Li et al., 2020 ; Liu et al., 2018b ; Wang et al., 2016a ; Wei et al, 2020 ; Zhang et al., 2016b ). After decades of creative progress, there has been a lot of mature achievement around the solar energy collection technology based on the photothermal and photoelectric effect.…”

Section: The Principle Of Hybridized Nanogeneratorsmentioning

confidence: 99%

“…In addition to the planar structure, the rotatory-disc-shaped devices are also commonly used in energy harvester for their unique structural characteristics. Lately, a hybridized energy system based on a rotatable TENG and WO 3 /BiVO 4 heterojunction solar cell has been demonstrated, which can harvest mechanical energy in water ( Wei et al, 2020 ). The schematic of the self-powered hydrogen generation system is exhibited in Figure 11 F, and the insert is the photograph of the TENG model.…”

Section: The Classification Of Harvesting Solar Energymentioning

confidence: 99%

“… (F and G) The schematic diagram of the self-powered hydrogen generation system and the rate of hydrogen production at different conditions. Reproduced with permission, from ref ( Wei et al, 2020 ), Copyright 2020, Springer. …”

Section: The Classification Of Harvesting Solar Energymentioning

confidence: 99%

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Hybridized nanogenerators for effectively scavenging mechanical and solar energies

Zhao

Wang

et al. 2021

iScience

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Summary Solar and wind energy harvesting technology is increasingly an economical and efficient energy form and receives excellent support from government policies worldwide. Various functional and structural nanogenerators based on multi-effects named hybridized nanogenerators have been reported separately or simultaneously to effectively generate the wasted mechanical and solar energy in our daily life. We review the development of hybridized nanogenerators, including the working mechanism of solar and mechanical energies. Moreover, the classification of nanogenerators for scavenging mechanical and solar energies is discussed. The potential applications of hybridized nanogenerators are reviewed. Finally, the challenge and prospective of hybridized nanogenerators and the future explored improvements of output performance, stability, preparation, large-scale utilizing, and efficiency are discussed. The hybridized nanogenerator as the energy technology will be popularized in energy and self-powered sensor systems.

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Section: The Principle Of Hybridized Nanogeneratorsmentioning

confidence: 99%

Section: The Classification Of Harvesting Solar Energymentioning

confidence: 99%

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Hybridized nanogenerators for effectively scavenging mechanical and solar energies

Zhao

Wang

et al. 2021

iScience

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“…Many efforts with TENGs have already been undertaken to achieve the efficient collection of blue energy. [ 6–12 ] Many efforts with TENGs have already been undertaken to achieve the efficient collection of blue energy. [ 13–20 ] However, considering that the richest blue energy is generally in faraway ocean, it is still a great challenge to effectively use the generated electrical energy from TENGs when the cable for the electricity transmission is impractical.…”

Section: Introductionmentioning

confidence: 99%

Blue Energy Collection toward All‐Hours Self‐Powered Chemical Energy Conversion

Zhai

Wen

Chen

et al. 2020

Advanced Energy Materials

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The conversion and transmission of blue energy in the ocean are critical issues. By employing triboelectric nanogenerators (TENGs), blue energy can be harvested but the corresponding electricity transmission and storage are still great challenges. In this work, an automatic high‐efficiency self‐powered energy collection and conversion system is proposed that converts blue energy to chemical energy. A gear‐driven unidirectional acceleration TENG is designed to convert disordered and low‐frequency water wave energy to low voltage and high current DC output. The output bias from the TENG can be used to drive a Ti–Fe2O3/FeNiOOH based photoelectrochemical cell under sunlight to produce hydrogen. Moreover, under the situation without sunlight, the self‐powered system can be automatically switched to another working state to charge a Co3O4 based lithium‐ion battery. The hydrogen production rate reaches to 4.65 µL min‐1 under sunlight at the rotation speed of 120 rpm. The conversion efficiency of the whole system is calculated to be 2.29%. The system triggered by photoswitches can automatically switch between two working states with or without sunlight and convert the blue energy to either hydrogen energy or battery energy for easy storage and transmission, which widens the future applications for blue energy.

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“…In general, to detect such kinds of problems, regularly manual checks are adopted, [26,27] which, however, are both inefficient and inaccurate and often fail to detect potential faults in time. [28,29] Therefore, it is highly expected that a new approach will be invented to inspect potential mechanical failure in real time and with high accuracy.…”

mentioning

confidence: 99%

A Triboelectric Nanogenerator Consisting of Polytetrafluoroethylene (PTFE) Pellet for Self‐Powered Detection of Mechanical Faults and Inclination in Dynamic Mechanics

et al. 2020

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A reliable mechanical fixation plays a pivotal role in guaranteeing normal operation for large‐scale equipment. The detection of screw loosening or breakage as well as susceptor tilting is of significance in mechanical dynamics, especially in those with large vibration amplitude during operation. Herein, a novel triboelectric nanogenerator (TENG) is reported that consists of polytetrafluoroethylene (PTFE) pellets and a single electrode installed on the bottom of a cylinder. The basic electricity‐generating principle is the coupling of triboelectrification and electrostatic induction between the pellets and electrode. The dependence of the output voltage on the diameter/number of pellets is explored deeply, suggesting, by enlarging the diameter or increasing the number of pellets, the output voltage can be improved. By integrating the fabricated TENG on a vibration table, the capacity of self‐powered detection of screw loosening or breakage can be achieved based on TENGs, which can predict a potential mechanical failure in real time. More importantly, the TENG can be tuned to output eight‐channel data simultaneously, which enables recognizing the tiny inclining signs of equipment. This work provides a new method for the design and manufacture of intelligent sensors that can be used for failure inspection and diagnosis in future intelligent mechanics.

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Hybridized Mechanical and Solar Energy-Driven Self-Powered Hydrogen Production

Cited by 45 publications

References 50 publications

Hybridized nanogenerators for effectively scavenging mechanical and solar energies

Hybridized nanogenerators for effectively scavenging mechanical and solar energies

Blue Energy Collection toward All‐Hours Self‐Powered Chemical Energy Conversion

A Triboelectric Nanogenerator Consisting of Polytetrafluoroethylene (PTFE) Pellet for Self‐Powered Detection of Mechanical Faults and Inclination in Dynamic Mechanics

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