Your search keyword '"Liu, Guoxu"' showing total 9 results

1. Electret elastomer-based stretchable triboelectric nanogenerators with autonomously managed power supplies for self-charging systems

Author

Liu, Jia Xin, Liu, Guoxu, Guo, Zi Hao, Hu, Weiguo, Zhang, Chi, and Pu, Xiong

Published

2023

2. Composite film with hollow hierarchical silica/perfluoropolyether filler and surface etching for performance enhanced triboelectric nanogenerators

Author

Fan, Beibei, Liu, Guoxu, Fu, Xianpeng, Wang, Zhaozheng, Zhang, Zhi, and Zhang, Chi

Published

2022

3. Autonomous cantilever buck switch for ultra-efficient power management of triboelectric nanogenerator.

Author

Zhou, Han, Liu, Guoxu, Bu, Tianzhao, Wang, Zheng, Cao, Jie, Wang, Zhaozheng, Zhang, Zhi, Dong, Sicheng, Zeng, Jianhua, Cao, Xiaoxin, and Zhang, Chi

Subjects

*NANOGENERATORS, *CANTILEVERS, *ELECTROSTATIC fields, *ENERGY consumption

Abstract

Power management is an efficacious route to promote the development of triboelectric nanogenerators (TENGs), in which the buck switch for efficient energy extraction has always been a challenge. Here, we propose a three-port cantilever buck switch which can autonomously release energy from the TENG in maximum by the generated electrostatic field of the TENG. The influence of closing voltage of the buck switch on different structure parameters has been thoroughly investigated. The U-Q curve indicates that the optimal energy extraction can reach 90.86%, and the matched impedance of the TENG is reduced from 60 MΩ to 470 kΩ. Compared to the output power at matched impedance, the average power managed by this three-port cantilever buck switch is increased by 1.554 times, which can power the Bluetooth device, electronic watch, calculator and thermo-meter. This work has realized ultra-efficient power management of TENG by leveraging an autonomous cantilever buck switch, which can contribute to the efficient utilization of micromechanical energy. • A three-port cantilever buck switch controlled by the electrostatic field of the TENG for its power management is pioneered. • A detailed analysis of the force-electricity conversion process has been conducted. • U-Q curve and P-R curve has been linked to characterize the output efficiency for the first time. [ABSTRACT FROM AUTHOR]

Published

2024

4. Self-powered overspeed wake-up alarm system based on triboelectric nanogenerators for intelligent transportation.

Author

Cao, Jie, Lin, Yuan, Fu, Xianpeng, Wang, Zheng, Liu, Guoxu, Zhang, Zhi, Qin, Yuhan, Zhou, Han, Dong, Sicheng, Cheng, Guanggui, Zhang, Chi, and Ding, Jianning

Abstract

Overspeed information monitoring and collecting becomes increasingly important with the rapid development of intelligent transportation, but current overspeed monitoring technologies are constrained by traditional power-supply for large-scale use. Herein, we proposed a self-powered overspeed wake-up alarm system (SOWAS) based on triboelectric nanogenerators. The SOWAS consists of an energy harvesting triboelectric nanogenerator (E-TENG), an energy management module (EMM), an overspeed sensing triboelectric nanogenerator (S-TENG), a power-switch module (PSM) and a wireless transceiver module (WTM). The E-TENG and EMM are used for mechanical energy harvesting, management, and powering for the SOWAS, while the S-TENG, PSM and WTM are employed for active overspeed monitoring and alarm signals transmitting. When the vehicle speed exceeds the setting threshold, the PSM will be activated, and the WTM will send alarm signals with the harvested energy. The response characteristics dependence of the SOWAS on various working parameters were investigated in detail. The developed SOWAS could work sustainably in unattended traffic environment without external power supply for autonomous overspeed monitoring and alarming. Meanwhile, intelligent monitoring of overspeed and improved energy utilization were achieved. This work has enormous potentials and promising prospects for TENG in intelligent transportation, Internet of Vehicles and autonomous driving. [Display omitted] • A self-powered overspeed wake-up alarm system (SOWAS) based on TENGs is developed. • The SOWAS enables sustainable self-powered overspeed monitoring and alarm by harvesting the mechanical energy from traffic system. • Intelligent overspeed monitoring is achieved by the designed wake-up circuit and the efficient use of energy. [ABSTRACT FROM AUTHOR]

Published

2023

5. Organic tribovoltaic nanogenerator with electrically and mechanically tuned flexible semiconductor textile.

Author

Liu, Guoxu, Luan, Ruifei, Qi, Youchao, Gong, Likun, Cao, Jie, Wang, Zhihao, Liu, Feng, Zeng, Jianhua, Huang, Xinlong, Qin, Yuhan, Dong, Sicheng, Feng, Yuan, Huang, Long-Biao, and Zhang, Chi

Abstract

Obtaining a wear-resistant, high-output, flexible direct current (DC) friction energy harvester is quite important for implementing self-powered portable electronic devices and Internet of Things (IoT). In this work, a direct current flexible textile organic tribovoltaic nanogenerator (FT-OTG) is reported, which is consisted of blended film of 11.11% poly(3,4-ethylenedioxythiophene): poly(styrene sulfonate) (PEDOT: PSS) and 88.89% polyvinyl alcohol (PVA), a hydrophilic conductive ink, a hydrophobic conductive textile and Al slider. The working mechanism of OTG is that after absorbing friction energy, abound electron-hole pairs are excited at the metal-semiconductor interface. These carriers move directionally under the joint drive of electrostatic field and the built-in electric field to form a current. After PVA doping, the output performance of DC-OTG, including open-circuit voltage and short-circuit current, is improved 5.6 times and 4.2 times, respectively. Furthermore, the mechanical properties of blended film, such as wear resistance, elongation and tensile strength, are improved, among which elongation at break is increased by 8 times and tensile strength increased by 3.2 times. By simplify series connecting, 3 FT-OTGs can constantly power portable electronics, like electronic watch, thermometer and calculator, respectively. This work provides an effective way for simultaneously enhanced output performance and mechanical properties of FT-OTG, which is expected to be a robust way for harvesting friction energy for self-powered electronics device and IoT sensors. [Display omitted] • A direct current FT-OTG is reported. By simplify series connecting, 3 FT-OTGs can constantly power portable electronics. • The enhancement mechanism is the E CE and E built-in field jointly promote the directional motion of charge carriers. • After PVA doping, output performance and mechanical performance have been significantly improved. [ABSTRACT FROM AUTHOR]

Published

2023

6. Honeybee-inspired electrostatic microparticle manipulation system based on triboelectric nanogenerator.

Author

Li, Wenjian, Lu, Liqiang, Liu, Guoxu, Zhang, Chi, Loos, Katja, and Pei, Yutao

Abstract

Electrostatic manipulation of particles or droplets has raised huge interests across many fields including biomedical analysis, microchemistry and microfabrication/patterning, because of its merits of simple configuration and easy operation. However, traditionally applied bulky high voltage sources for electrostatic manipulation not only have potential safety risk to the operator and the devices, but also limit the portability. Here, we proposed an electrostatic microparticle manipulation system (EMMS) based on a triboelectric nanogenerator (TENG). Inspired from the pollen collection principle of honeybees, the EMMS featured a simple pin-to-plate electrodes system, which was electrostatically powered by the high voltage of the TENG. Different manipulation modes, including contact manipulation and noncontact manipulation were systematically studied. With a sliding displacement of 5 cm, the TENG delivered an output voltage of ± 3.2 kV, which could manipulate dielectric microparticles with weights of 1.7 mg, 0.9 mg and 13.3 mg at contact manipulation mode, noncontact manipulation (vertical lift) and noncontact manipulation (parallel move) mode, respectively. Manipulation mechanisms for both dielectric and conductive microparticles under different configurations of the pin-to-plate electrodes system were investigated. Finally, potential applications including micropatterning, dust remove and drug release/microchemistry were demonstrated to show the great prospects of the proposed TENG-based EMMS. [Display omitted] • A honeybee-inspired electrostatic microparticle manipulation system was proposed based on a triboelectric nanogenerator. • Different manipulation modes, including contact manipulation and noncontact manipulation were systematically studied. • Manipulation mechanisms under different configurations of the pin-to-plate electrode system were investigated. • Potential applications including micropatterning, dust remove and drug release/microchemistry were demonstrated. [ABSTRACT FROM AUTHOR]

Published

2022

7. Frequency band broadening and charge density enhancement of a vibrational triboelectric nanogenerator with two stoppers.

Author

Qi, Youchao, Liu, Guoxu, Kuang, Yang, Wang, Lu, Zeng, Jianhua, Lin, Yuan, Zhou, Han, Zhu, Meiling, and Zhang, Chi

Abstract

Vibrational triboelectric nanogenerators (V-TENG) can be used to harvest broadband vibration energy due to the nonlinear impact force induced by a stopper. However, V-TENGs with a single stopper have limited bandwidth and surface charge density, which has limited their application in wideband vibration energy harvesting. Herein, a V-TENG with two stoppers and a charge pumping effect is proposed for frequency band broadening and charge density enhancement. The theoretical analysis and experimental validation have indicated the V-TENG with two stoppers could improve the bandwidth by 75% compared with one stopper at a gap distance of 0.5 mm. Moreover, a charge pump can be constructed with two output channels, which has improved surface charge density by about 14 times. With the frequency varying from 18 to 38 Hz, the V-TENG can continually power 400 LEDs and charge a commercial capacitor quickly. This work has shown an encouraging method for enhancing the performance of V-TENGs, which also has great prospects in harvesting wideband vibration energy from machines, cars, ships, and human motions for self-powered electronics. The frequency band broadening mechanism and charge density enhancement technique of the vibrational TENG (V-TENG) were systematically elaborated. The introduction of double-sided stoppers strengthens the nonlinear characteristics of the V-TENG and broadens the frequency band. Furthermore, a high-performance V-TENG based on charge pump (CPV-TENG) is constructed according to the two output channels of the V-TENG. [Display omitted] • Research on the frequency band characteristics of a V-TENG based on two stoppers by theoretical analysis and simulation. • Demonstration of the frequency band broadening features of V-TENG under different conditions by experimental exploration. • A high-performance CPV-TENG based on the charge pump effects is constructed according to two output channels of V-TENG. [ABSTRACT FROM AUTHOR]

Published

2022

8. Scalable fabrication of stretchable and washable textile triboelectric nanogenerators as constant power sources for wearable electronics.

Author

Xu, Fan, Dong, Shanshan, Liu, Guoxu, Pan, Chongxiang, Guo, Zi Hao, Guo, Wenbin, Li, Longwei, Liu, Yanping, Zhang, Chi, Pu, Xiong, and Wang, Zhong Lin

Abstract

The textile-based triboelectric nanogenerator (tTENG) is one of the most promising energy harvesting devices for realizing self-powered smart textiles and wearable electronics. Herein, we report a scalable machine-knitting fabrication of stretchable, washable and breathable tTENGs for harvesting human motion energies. A plating stitch technique is employed to fabricate tTENGs using various common yarn materials and working in different modes (coplanar sliding mode and contact-separation mode). The tTENG can output voltage up to 232 V and power density up to 66.13 mW/m2. Furthermore, it can constantly power different wearable electronics by integrating with a small-size power management module, which converts the irregular AC output to a stable DC output and improves the energy utilization of tTENG. The stretchability, washability and air permeability of the tTENG are also demonstrated. These findings provide a practically viable textile-based power source that holds great promise in future self-powered wearable electronics and smart textiles. [Display omitted] A stretchable, washable and breathable textile-based triboelectric nanogenerator is fabricated by a scalable knitting method for harvesting human motion energies, which can provide continuous power to different small electronics with the aid of a small-sized power management module. This work presents a feasible and practical power alternative for wearable electronics and E-textiles. • Scalable fabrication of stretchable, washable and breathable textile triboelectric nanogenerators (tTENG) is demonstrated. • The tTENG generates high electrical outputs by harvesting human motion energies. • The tTENG can constantly power different wearable electronics with the aid of a small-size power management module. [ABSTRACT FROM AUTHOR]

Published

2021

9. Kirigami-inspired triboelectric nanogenerator as ultra-wide-band vibrational energy harvester and self-powered acceleration sensor.

Author

Qi, Youchao, Kuang, Yang, Liu, Yaoyao, Liu, Guoxu, Zeng, Jianhua, Zhao, Junqing, Wang, Lu, Zhu, Meiling, and Zhang, Chi

Subjects

*LASER beam cutting, *ENERGY harvesting, *STRUCTURAL design, *DETECTORS, *ARTIFICIAL intelligence

Abstract

A compact, springless, easy-to-process kirigami-inspired TENG (KI-TENG) is developed. The frequency responses of the KI-TENG under the influence of mass, acceleration, and initial distance are investigated in detail to optimize its structural design. Moreover, the TENG coupled with the kirigami structure could collect ultra-wide-band vibration energy and as a sensor measuring acceleration. [Display omitted] • A compact and springless kirigami-inspired TENG (KI-TENG) is developed. • The frequency response characteristics of the KI-TENG are investigated. • The KI-TENG can harvest ultra-wide-band vibration energy from 2 to 49 Hz. • The output of the KI-TENG at different vibration tilt angles is explored. • The KI-TENG can effectively monitor acceleration changes from 1 to 9 m/s2. Triboelectric Nanogenerators (TENGs) based on spring-assisted structures play a central role in scavenging vibrational energy that is widely available in the natural environment. However, they suffer from difficulties in adjusting the stiffness and bonding the springs to the triboelectric layer. Here, a kirigami-inspired TENG (KI-TENG) with a kirigami structure is demonstrated, which can be used as an ultra-wide-band vibrational energy harvester and self-powered acceleration sensor. The triboelectric layer of the KI-TENG can be easily processed into the kirigami structure with one or two-degree-of-freedom by laser cutting technology. The frequency responses of the KI-TENG under the influence of mass, acceleration, and initial distance are investigated in detail to optimize the structural design. With optimized structural parameters, the KI-TENG can not only harvest broadband vibration energy from 2 to 49 Hz in vertical vibration state but also obtain high output performance over a wide frequency range in horizontal vibration state. Moreover, the KI-TENG can be used as a sensor measuring acceleration from 1 to 9 m/s2. This work demonstrates a compact TENG coupled with the kirigami structure for energy harvesting and active sensing, which has great prospects in intelligent plants, artificial intelligence, and the internet age. [ABSTRACT FROM AUTHOR]

Published

2022