Cylinder‐based hybrid rotary nanogenerator for harvesting rotational energy from axles and self‐powered tire pressure monitoring

He, Jian; Cao, Sheng; Zhang, Hulin

doi:10.1002/ese3.560

Cited by 17 publications

(6 citation statements)

References 52 publications

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“…This technology possesses distinct benefits and unique properties that make it highly suitable for this purpose. There has been a growing proliferation of research groups proposing the utilization of TENG in the development of autonomous sensing systems capable of harnessing energy for application in automobiles [108][109][110][111][112][113][114][115][116][117].…”

Section: Tengs For Motored Mobility 421 Carsmentioning

confidence: 99%

“…The spinning wheel also generates robust steady energy. The capability of TENG to effectively gather and convert rotational energy into electrical energy has been demonstrated [112][113][114]. In the year 2019, the research team of He successfully designed and created a hybrid electromagnetic generator TENG (EMG-TENG) device with the purpose of collecting rotational energy [112].…”

Section: Tengs For Motored Mobility 421 Carsmentioning

confidence: 99%

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Recent progress towards smart transportation systems using triboelectric nanogenerators

Nguyen,

Huynh,

Luu

et al. 2024

J. Phys. Energy

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The field of transportation plays a crucial role in the development of society. It is vital to establish a smart transportation system (STS) to increase the convenience and security of human life. The incorporation of artificial intelligence (AI) and the Internet of Things (IoT) into the traffic system has facilitated the emergence of innovative technologies like autonomous vehicles or unmanned aerial vehicles (UAVs), which contribute to the reduction of traffic accidents and the liberation of human driving time. However, this improvement involves the use of multiple sensor devices that need external power sources. As a result, pollution occurs, as do increases in manufacturing costs. Therefore, the quest to develop sustainable energy remains a formidable obstacle. Triboelectric nanogenerators (TENG) have emerged as a possible solution for addressing this problem owing to their exceptional performance and simple design. This article explores the use of TENG-based self-power sensors and their potential applications in the field of transportation. Furthermore, the data collected for this study might aid readers in enhancing their comprehension of the benefits linked to the use of these technologies to promote their creative ability.

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Section: Tengs For Motored Mobility 421 Carsmentioning

confidence: 99%

Section: Tengs For Motored Mobility 421 Carsmentioning

confidence: 99%

Recent progress towards smart transportation systems using triboelectric nanogenerators

Nguyen,

Huynh,

Luu

et al. 2024

J. Phys. Energy

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show abstract

“…[291,292] On the other hand, the vibration energy produced by human-driven vehicles can be utilized to realize self-powered IoT monitoring systems without the electricity from the automobile battery. [293][294][295] Maharjan et al have proposed a universal self-chargeable power module by hybridizing two types of TENGs and an EMG as shown in Figure 13g. [296] Under the external vibration, the movable unit consisting of a magnet and Al layers will move downward and upward, resulting in the magnetic flux across the coils change and the sliding friction between the Al strip and the PTFE inner wall, thus generating the electromagnetic and triboelectric outputs respectively.…”

Section: Wwwadvancedsciencenewscommentioning

confidence: 99%

“…[ 291,292 ] On the other hand, the vibration energy produced by human‐driven vehicles can be utilized to realize self‐powered IoT monitoring systems without the electricity from the automobile battery. [ 293–295 ] Maharjan et al. have proposed a universal self‐chargeable power module by hybridizing two types of TENGs and an EMG as shown in Figure 13g.…”

Section: Tengs Integrated Hybrid Devices As Ehs In Indoor and Outdoor...mentioning

confidence: 99%

Triboelectric Nanogenerator Enabled Wearable Sensors and Electronics for Sustainable Internet of Things Integrated Green Earth

Yang

Guo

Zhu

et al. 2022

Advanced Energy Materials

155

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as the components of the IoT network, and they will generate massive data with multidimensions, higher velocity, and improved heterogeneity. [2] Benefiting from this, our world is developing toward a smarter and more well-knit green earth, covering essential blocks like smart homes, smart agriculture, smart cities, smart industries as well as outer space and airlines. [3] In the green earth, the IoT systems are promising to be spread in every smart area, consisting of various sensing modules, signal processing modules, power management modules, power supply modules, etc. Sensing modules are applied to collect abundant information from the target objects or environment, such as temperature, humidity, light intensity, gas concentration, pressure, etc. And the signal processing modules help with the data transmission, processing, and analysis to connect and exchange information with other devices or systems to provide an optimal command to the target object or environment. In addition, the power management modules and power supply modules are to provide the most efficient solutions to reduce the overall power consumption in the operations of the IoT systems. [4][5][6] Thus, looking at the whole earth, it is to be closely connected with the IoT systems, enabling information transfer and communication over the strong network.Narrowing down to a single object like the human body, a single animal, or a robot, wearable electronics have attracted increasing research interest owing to their promising applications in real-time and precious monitoring and tracking of user's preferences and habits on the green earth. [7][8][9][10] Conventional wearable electronics involve smart watches, smart glasses, smart helmets, etc., while most of them are fabricated from nonflexible or rigid materials, resulting in limited wearable comfort, device lifetime, latency response, and loss of sensing information. [11][12][13] To address these issues, the current research focuses on the investigation of sensing materials with flexibility or even stretchability, breathability, washability, lightweight, adhesiveness, etc., enabling improved wearing comfort and long-term wearability. [14][15][16][17] Besides the wearability of the modules in the IoT system, energy issue is within wide research interest and concern as one of the urgent issues contemporarily. Batteries, as the dominant choices for power supply modules, are now revealed asThe advancement of the Internet of Things/5G infrastructure requires a lowcost ubiquitous sensory network to realize an autonomous system for information collection and processing, aiming at diversified applications ranging from healthcare, smart home, industry 4.0 to environmental monitoring. The triboelectric nanogenerator (TENG) is considered the most promising technology due to its self-powered, cost-effective, and highly customizable advantages. Through the use of wearable electronic devices, advanced TENG technology is developed as a core technology enabling self-powered sensors, power supplies, and data comm...

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“…He et al. introduced a rotary cylinder-based nanogenerator, by hybridizing a TENG and an EMG ( He et al., 2019 ), which can operate as a self-powered counter and timer for potential speed detecting. Guo et al.…”

Section: Introductionmentioning

confidence: 99%

A high-performance triboelectric-electromagnetic hybrid wind energy harvester based on rotational tapered rollers aiming at outdoor IoT applications

Fang

Tang

et al. 2021

iScience

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Summary This article proposed a high-performance triboelectric-electromagnetic hybrid wind energy harvester (WEH). By adopting the revolution and rotation movements of tapered rollers, which serve as both the rotor of the electromagnetic generator (EMG) part and freestanding layers of the triboelectric nanogenerator (TENG) part, the WEH can work as a sustainable power source and a self-powered wind speed sensor. When the wind speed is 12 m/s, super-high open-circuit voltage peaks of 47.4 and 683 V can be achieved by the EMG and TENG, respectively, corresponding to the high-power outputs of 62 and 1.8 mW. It was demonstrated that the WEH can easily light up over 600 red light-emitting diodes and even a 5-W globe light. A self-powered wireless temperature and humidity sensing network was also systematically demonstrated. In summary, the proposed WEH exhibits bright future toward IoT applications, such as in border detection, smart buildings, and so on.

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Cylinder‐based hybrid rotary nanogenerator for harvesting rotational energy from axles and self‐powered tire pressure monitoring

Cited by 17 publications

References 52 publications

Recent progress towards smart transportation systems using triboelectric nanogenerators

Recent progress towards smart transportation systems using triboelectric nanogenerators

Triboelectric Nanogenerator Enabled Wearable Sensors and Electronics for Sustainable Internet of Things Integrated Green Earth

A high-performance triboelectric-electromagnetic hybrid wind energy harvester based on rotational tapered rollers aiming at outdoor IoT applications

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