由于物联网和无线状态监测系统的快速发展,各种分布式能源的利用正在成为一个突出的研究课题。在各种分布式能源中,风能具有分布广泛、可再生、无污染等优点,是一种非常有前景的电力供应机械能。传统的基于电磁和压电效应的风能收集方法存在结构复杂、体积大、机械结构严密、安装成本高等问题。环境机械能的低频和不规则性质使得这些方法通常效率低下,不可避免地阻碍了风能的进一步开发。基于摩擦充电和静电效应的摩擦电纳米发电机(TENGs)也可用于风力发电,并且由于TENG更容易小型化和组装,并且可以实现大规模制造,因此越来越受到研究人员的青睐。本文综述了TENGs在风能利用结构设计、材料选择和潜在应用等方面的研究进展。此外,还总结并讨论了该领域的潜在困难和可能的发展。
The utilization of various distributed energy is becoming a prominent research topic due to the rapid development of the Internet of Things and wireless condition monitoring systems. Among the various distributed energy sources, wind energy has the advantages of being widely distributed, renewable and pollution-free, and is a very promising mechanical energy for power supply. Traditional wind energy harvesting methods based on electromagnetic and piezoelectric effects have issues with complex structure, large size, severe mechanical structures, and high installation costs. The low frequency and irregular nature of ambient mechanical energy makes these methods generally inefficient and inevitably hinders the further exploitation of wind energy. The triboelectric nanogenerators (TENGs) based on frictional charging and electrostatic effects can also be used for wind power generation and are increasingly favored by researchers as TENGs are easier to be miniaturized and assembled, and can realize large-scale manufacturing in comparison. This paper reviews the research on TENGs for wind energy utilization in terms of structural design, material selection and potential applications. In addition, the potential difficulties and possible developments in this field are summarized and discussed.
This paper describes the latest progress of WD-TENG. Firstly, the mechanism of WD-TENG for energy generation is discussed from the aspects of both mechanical design and electrification methods. Then, a series of crucial parameter that can decide the performance of WD-TENG have been thoroughly summarized, while the related performance optimization methods through structure design and material modification have also been elaborated with the consideration of different ranges of wind speed. The output characteristics of TENG and traditional wind energy device using electromagnetic generator (EMG) are compared, where the merits of each technique are carefully discussed. In addition, the combination of WD-TENG with other energy conversion mechanisms to realize the hybrid energy system for collecting energy from different sources is introduced, indicating tremendous application perspective in the field of distributed energy. Finally, based on these works, the existing problems as well as the important challenges of WD-TENG are proposed, in order to guide the future study of TENG for wind-related applications.
Classification | Categories | Advantages | Disadvantages |
---|---|---|---|
Metals and its derivatives | Metal, alloy, semiconductor metallic nanoflakes/nanoparticles/nanowires | Excellent electrical conductivity,high stability,high mechanical robustness,simple process | Low flexibility |
Conducting polymers | PTFE, PVDF, PDMS, PMMA | Easy structural control,heat resistance,corrosion resistance,light weight,good flexibility | Relatively high cost,poor conductivity,low stability,Non-biodegradable,Not-recyclable |
Carbonaceous fillers | Graphite, CNT, Graphdiyne | High conductivity,high stability,good mechanical properties | Cumbersome processing technology |
Natural materials | Rabbit Fur, leaves | Flexible,low cost,biodegradable and easy to process | Poor electrical conductivity,poor durability |
Composite materials | Combination of different conductive materials(e.g., graphene-PDMS) | Synergistic effect | Increased preparation cost and workload |
In addition to the common structures mentioned above, special structures have been designed to achieve efficient wind speed harvesting [66]. In 2018, Kim et al. proposed a WD-TENG that uses polymer micro-beads and their sliding motion in a novel structure to capture the mechanical energy of the wind drive, as shown in Figure 5a [38]. The open circuit voltage and short circuit current can reach 18.5 V and 2.3 µa, respectively, at wind speeds of 10 m/s. The structure enables wind energy to be collected in any direction and the electrical output performance changes rapidly and proportionally with wind speed, allowing it to be used as a self-powered wind speed sensor. Due to the relative flatness of the device, it is easy to integrate. When it is made in a stacked form, its output performance can be further improved.
In 2019, inspired by the pendulum structure, Lin et al. designed a symmetrical pendulum-based structure TENG, as shown in Figure 5b [37]. In order to increase the vibration level combined with a reduction in friction, a separate gap of 1 mm is left between the pendulum triboelectric layer and the electrode layer. The pendulum triboelectric layer is connected to the external acrylic spherical shell by means of a cotton thread for free vibration. This structure is very sensitive to external vibrations and small disturbances can cause large oscillations in the pendulum friction layer. The researchers compared the output performance of the pendulum inspired TENG (P-TENG) with that of an in-plane TENG and found that it is 14.2 times more capable of acting as a sustainable energy source than a conventional freestanding TENG, demonstrating its superior energy harvesting capability.
The rotary FS-TENG stands out among the various energy harvesters/generators due to its intensive peak output and high output power. However, it usually requires various rotational motions to drive it, which hinders its use in the prevalent exploitation of low frequency vibrations and linear motions. A series of studies were performed to convert rotational motion into linear motion to trigger TENG work [23][67][68]. As exhibited in Figure 5d, Lu et al. designed a bidirectional gear transmission triboelectric nanogenerator (BGT-TENG). Under the action of an external excitation, the plate undergoes a reciprocating motion, which transmits mechanical energy via the rack to the two reverse-mounted gear trains and further triggers the continuous rotation of the flywheel. By connecting it to a rectifier bridge, an effective power supply for commercial thermometers was achieved, showing its potential application in the field of energy harvesting.
In Figure 5c, a novel free-standing layer TENG structure based on the contact separation of PTFE particles and Al electrodes was proposed, creatively using a real-time signal output terminal structure (RTS) and the pulsed signal output terminal structure (PTS) to characterize the output performance of the TENG [39]. Experiments show that the current at the pulsed signal output can reach more than 13 times that at the real time signal output with better stability, demonstrating the advantages of the pulsed TENG for energy harvesting, which can capture low frequency mechanical energy from wind and water. Low cost, high efficiency conversion of electrical energy to drive the electrolysis of hydrogen in seawater.
In order to provide continuous, regular electrical energy above a critical speed, as can be seen from Figure 5e, Liu et al. designed a magnetic switch structured triboelectric nanogenerator (MS-TENG) consisting of a drive gear, an energy modulation module and a power generation unit with a magnetic switch structure [69]. Unlike previous designs, the storage and release of energy from this structure is determined by the magnetic force of the magnet and does not depend on the wind speed. The MS-TENG supplies 500 LEDs in series and a thermometer, showing that the MS-TENG has good prospects for wind energy harvesting applications. Its design advantages in converting wind energy into a reliable electrical output could provide a useful guide for future wind energy harvesting.
Figure 5. Other structures of WD-TENG. (a) WD-TENG based on rolling motion of beads. Reproduced with permission of [38], Copyright 2018, Elsevier. (b) A pendulum-spired WD-TENG. Reproduced with permission of [37], Copyright 2019, Elsevier. (c) A pulsed cylindrical WD-TENG. Reproduced with permission of [39], Copyright 2021, Elsevier. (d) A bidirectional gear transmission triboelectric nanogenerator (BGT-TENG). Reproduced with permission of [23], Copyright 2020, Elsevier. (e) WD-TENG controlled energy collection by magnetic switch. Reproduced with permission of [69], Copyright 2021, Elsevier.
As the designs of WD-TENG become smaller, lighter, and more durable, they become more adaptable to varying wind speeds, humidity, and other external environmental conditions [70]. WD-TENG shows great potential in various applications such as powering small electronic devices, as secondary energy stored in capacitors, as self-powered sensors for wind vectors or parameters such as humidity, and self-powered electrochemical systems, as depicted in Figure 6a–f.
The interaction of flexible flags with steel plates as a powerful vibration source for triboelectric nanogenerator has attracted extensive attention from researchers. In 2017, Xu et al. designed a TENG based on aeroelastic flutter-based TENG (AF-TENG) and investigated different chattering behaviors caused by differences in the size, liquid-solid mass ratio, and bending stiffness of the flexible film, and actively sensed the wind speed by measuring the flutter frequency [71]. In 2018, Liu et al. reported for the first time a system capable of polarizing BaTiO3 (BTO) materials, making full use of the high voltage and low current characteristics of TENG [[72]. By comparing the effectiveness of commercial DC polarization equipment (DC-PE) and TENG for polarizing ferroelectric BTO films with thicknesses between 0.3 mm and 0.7 mm, it was found that higher piezoelectric and pyroelectric constants were obtained for most samples polarized with TENG polarization.
In 2019, Han et al. designed a self-powered NOX uptake and nitrate and nitrite degradation system driven by wind energy [73]. This program is characterized by low cost, simple equipment and easy availability of materials. This work provides a basis for future applications in the field of pollutant gas removal in the TENG environment. In 2020, Liu et al. designed an efficient wind barrier based on WD-TENG to collect natural wind and slipstream energy induced by vehicle travel. Self-driven wind speed sensing can also be performed using the flutter frequency of the film. Guo et al. designed a self-powered humidity sensor by taking advantage of PTFE’ s sensitivity to dielectric constant, which can simultaneously detect humidity and airflow velocity [74]. In 2022, Dai et al. prepared an omnidirectional wind energy harvester (OWEH) consisting of eight slit-effect based frictional electric nanogenerators (TENG) using transparent degradable hydroxyethyl cellulose (HEC) films, as shown in Figure 6f, for wind energy harvesting and self-supplied wind vector monitoring. By analyzing the eight independent output signals in real time, wind speed information can be obtained with a wind speed sensitivity of 78.36 V/(m/s). LED lights indicate the wind direction at this time. This work provides new ideas for further intelligent agriculture.
Figure 6. Applications of WD-TENG. (a) Experimental set-up and characterization of fluttering behavior of AF-TENG. Reproduced with permission of [71], Copyright 2017, Elsevier. (b) Schematic diagram and working mechanism of ferroelectric BTO disk polarized by WD-TENG. Reproduced with permission of [72], Copyright 2017, Elsevier. (c) Self-powered air purification system. Reproduced with permission of [73], Copyright 2020, ACS Nano. (d) Application scenario of the TENG-based wind barrier. Reproduced with permission of [16], Copyright 2020, Nano Energy. (e) Schematic diagram and (inset) digital photograph of the designed ATNG sensor. Reproduced with permission of [74], Copyright 2014, American Chemical Society. (f) WD-TENG is used to realize self-powered wind vector monitoring. Reproduced with permission of [75], Copyright 2021, Elsevier.
In order to realize the complementary advantages of various energy conversion mechanisms in obtaining mechanical energy and self-powered sensing, the combination of TENGs with electromagnetic and piezoelectric energy collection mechanisms is considered. Let us start with the mixture of multiple mechanisms. In 2018, Qian et al. designed a wind hybrid energy harvester (WH-EH) consisting of a TENG, two EMG groups and solar cells [30], as shown in Figure 7a. The WH-EH is demonstrated to light hundreds of LEDs and power small electronics. This research further advances solid progress in the practical application of hybrid nanogenerators for mechanical energy harvesting and self-powered wireless sensor monitoring systems.
As exhibited in Figure 7b, Zheng et al. developed a hybrid generator based on TENG and pyroelectric-piezoelectric nanogenerators (PPENGS) that can harvest wind and thermal energy separately or simultaneously [76]. In this case, the wind-driven TENG is based on a chattering structure that uses PVDF film at the bottom to create a PPRNG for thermal energy harvesting. When the PPENG is hybridized with the TENG, the charging rate of a 22 μF capacitor is increased by a factor of almost three. Integration of this structure into a mask to capture energy through human breathing has been used in the field of medical monitoring. Rahman et al. integrated three energy harvesting units, TENG, PENG and EMG, into a rotating system to form a fully enclosed wind turbine, as shown in Figure 7c [77]. The flexible piezoelectric layer PVDF with PET substrate is attached to the wind-driven rotating system as a PENG. Under the action of the induced wind, the wind turbine rotates the shaft and rotor blades. The researchers have verified its feasibility for many self-powered wireless sensor applications such as underground tunnel lighting and billboards.
A TENG sensing system for simultaneous detection of wind speed and wind direction based on a rotating structure was presented in the previous paper. Although the system can achieve detection in eight directions, its multiple signal acquisition and processing ports and signal circuit design are complex. In 2022, Xu et al. designed a self-powered wind vector sensor by combining optoelectronic and triboelectric technologies [78]. As shown in Figure 7d, the sensor system consists of an angle-shaped triboelectric sensor (ASTS) at the top, a wind vane in the middle and a wind direction sensor (WDS) at the bottom. In this case, the frictional electric sensor has two disconnected Al foils attached to an acrylic plate as frictional electric layer and electrodes forming an angle of 15° between each other and a PTFE film sprayed with PTFE nanoparticles placed between them. The device based on the optimal parameters has a wide detection range in the range 2.9~24.0 m/s, within which the current frequency shows a good linear relationship with the wind speed, showing its practical potential for self-powered wind speed detection.
Now, the most common of the hybrid energy harvesting mechanisms is still the combination of TENG and EMG, where a hybrid EMG-frictional electric generator can effectively harvest broadband wind energy [79][80][81][82]. In 2021, Lu et al. designed a composite energy harvesting system consisting of a cylindrical TENG and EMG that can be used to harvest breeze energy, based on a previously studied swing-type TENG (SS-TENG) [83]. Its structure is shown in Figure 8. Its frictional electric layer has a certain air gap between it and the electrodes, and the frictional resistance is reduced, which can reduce its starting wind speed and improve the durability of the device. It can be seen that the presence of the rectifier bridge causes the output current of the EMG to drop significantly, its output voltage itself is lower and the effective output power of the ENG is consumed to a large extent at the rectifier bridge. In the existing hybrid nano-generators, the peak and average rectified power of the TENG section are 60 and 635 times higher than the EMG section, respectively, when the coil is moderate. This result suggests that the TENG is better suited to derive energy from low frequency motion than the ENG.
Figure 8. (a) A swinging breeze collection system consisting of EMG and TENG. (b) Photograph of a digital thermometer powered by a SS–TENG array under the wind triggering. (c) Output performance of the TENG part and EMG. Reproduced with permission of [83], Copyright 2021, John Wiley and Sons.
TENGs offer significant advantages in low-frequency vibration energy harvesting, but their pulse output is sparse and contact TENGs are not immune to material wear, which greatly limits their output power and stability.In 2015, Guo et al. designed a waterproof frictional electro-magnetic hybrid generator by indirectly driving the movable part of a TENG using non-contact attraction between a pair of magnets [84]. The TENG can be driven by the attraction generated between the two sets of magnets as the EMG rotates, eliminating the need for direct contact and enabling the waterproof packaging of the TENG. The waterproof triboelectric-electromagnetic hybrid generator (WPHG) was shown to harvest wind energy and underwater water flow energy to directly power dozens of commercial LEDs during rainy days. This work has greatly facilitated the process of putting TENG and hybrid TENG into practical use. While exhibiting good output performance, these hybrid mechanism-based models tend to draw energy from only a single source and, with the limitations of power generation firmware, are difficult to package and maintain, all drawbacks that limit the use of TENGs in everyday life. In 2019, by combining EMG and TENG, Fan et al. designed a hybrid generator that converts sliding friction into a form of contact separation, where all power generating units are completely sealed inside the equipment box and isolated from the harsh environment. Zhong et al. realized a non-contact hybrid nanogenerator (NG) with the help of a device called a magnetic coupler [85]. Experimental results show that mixed NG has higher output power than single TENG and single EMG. Because there is no physical connection between the magnetic circuit driver and the magnetic circuit, the circuit can be easily disassembled, maintained and re-installed, and the structure can easily be fully encapsulated in waterproof materials to withstand a variety of harsh environment. In 2021 the team made further optimization of the structure and proposed as shown in Figure 9b [86]. The new a multi-cylinder-based hybridized electromagnetic-triboelectric nanogenerator (MCNG) shown, which obtains dual operating frequencies through the relative rotation of two energy harvesting units, enables the harvesting of two independent fluid energies. The design provides a new idea for simultaneously harvesting independent fluid energy and improving output performance.
As exhibited in Figure 9c, Zhang et al. invented a hybrid triboelectric nanogenerator that is efficient, reliable and suitable for breeze harvesting [36]. The magnetic element not only provides the magnetic source, but also reduces the electrostatic attraction between the friction layers by its own gravity, which effectively reduces the wear of the electrode material. The design is conducive to collecting low-speed wind energy and effectively prolongs the operating life of the equipment. As shown in Figure 9d, Fan et al. designed a rotating intermittent contact TENG (IC-TENG) with automatic switching of the rotation mode [87], using a tensed rope to generate initial torsional potential energy to ensure self-activation of IC-TENG at low frequencies. This novel TENG structure provides a new strategy for low frequency vibration energy collection.
The selection of WD-TENGs should be made in conjunction with the advantages and disadvantages of the WD-TENG classification in Table 2 and specific application scenarios. Table 3 summarizes the reported WD-TENGs suitable for energy harvesting or sensing in breezy environments, and it is observed that wind power generation in low wind environments can be achieved by selecting flexible, low-density materials and optimizing the structure. It is expected that these more detailed presentations can provide methodological guidance and design inspiration for future research and applications of WD-TENGs in breezy environments.
Figure 9. Hybrid TENGs combined with EMG and TENG. (a) The structure of the TEHG. Reproduced with permission of [88], Copyright 2019, Elsevier. (b) Structural design of the MCNG. Reproduced with permission of [86], Copyright 2021, Elsevier. (c) Schematic illustration of the W-HNG. Reproduced with permission of [36], Copyright 2020, Springer. (d) Structure and working principle of the IC-TENG. Reproduced with permission of [87], Copyright 2021, Elsevier.
Table 2. Summary and comparison of various WD-TENGs.
Structures |
Triboelectric Materials |
Modes |
Voltage(v) |
Current (uA) |
Power |
Ref |
Rotational sweeping mode |
Al & PTFE |
CS&LS |
250 |
250 |
62.5 mW(900 r/min) |
[29] |
Rotational sweeping mode |
Al & PTFE |
SE |
55 |
– |
0.03 mW |
[89] |
Rotational sweeping mode |
Al & PVDF |
FT |
650 |
50 |
10 mW(900 r/min) |
[51] |
In-plane cycled sliding mode |
Cu & Kapton |
FT |
320 |
3400 |
– |
[28] |
bidirectional gear transmission structure |
FEP & Cu |
CS |
- |
- |
4 mW(50 MΩ) |
[23] |
Transform the rotating structure into a linear structure |
PTFE & Cu |
CS |
200 |
2.9 |
180 μw(1 subunit, 60 rpm) |
[68] |
Transform the rotating structure into a linear structure |
PTFE & Cu |
CS |
320 |
20 |
0.37 mW(6 subunit,60 rpm) |
[67] |
Single-side-fixed |
Al & FEP |
CS |
100 |
1.6 |
0.16 mW(100 MΩ) |
[52] |
Single-side-fixed |
Au & PTFE |
CS |
200 |
60 |
0.86 mW(15 m/s) |
[58] |
Single-side-fixed |
FTO & PTFE |
CS |
36 |
4.1 |
– |
[74] |
Single-side-fixed |
Al & PTFE |
CS |
400 |
60 |
3.7 mW |
[54] |
Single-side-fixed |
FEP & Cu |
CS |
36 |
11.8 |
0.15 mW |
[59] |
Single-side-fixed |
PTFE & Al |
CS |
297 |
- |
0.46 Mw(10 m/s) |
[26] |
Single-side-fixed |
Hosta Leaf & PMMA |
SE |
230 |
9.5 |
45 mW/m2(1 × 107 Ω) |
[49] |
Single-side-fixed |
wheat straw & FEP |
SE |
250 |
20 |
404 μW/m2 |
[48] |
Single-side-fixed |
PTFE & MGDY |
CS |
100 |
3.5 |
- |
[50] |
Single-side-fixed |
PLL modified leaf powder & PVDF |
CS |
1000 |
60 |
17.9 mW(11 MΩ) |
[41] |
Double-side-fixed |
Al & PTFE |
CS |
334 |
67 |
5.5 mW |
[90] |
Double-side-fixed |
Cu &PTFE |
CS |
342 |
140 |
- |
[53] |
Lawn structure |
ITO & PET |
CS |
78 |
16.3 |
- |
[62] |
Angle-shaped |
FEP& Al |
CS |
64 |
2.5 (10 m/s) |
- |
[61] |
Venturi tube |
PTFE& PC |
CS |
- |
- |
4.5 mW(5 m/s) |
[31] |
Flag structure |
Ni & Kapton |
CS |
40 |
30 |
135 mW/kg(22 m/s) |
[32] |
fluttering double-flag type |
FEP & Cu |
CS |
- |
- |
600 mW/m2(10 m/s) |
[64] |
Vortex-induced |
PANI & PTFE |
CS |
- |
- |
96.79 mW/m2(2.78 m/s) |
[34] |
galloping structure |
Nylon & FEP |
CS |
200V(1.4 m/s) |
- |
6 μW(1.4 m/s) |
[35] |
Cantilevered structure |
PTFE & Al |
CS |
270 |
7.6 |
0.9 mW(2.9 m/s,44 MΩ) |
[33] |
rolling motion of polymer beads |
PTFE & Cu |
FT |
17.8 |
5.3 |
1.36 mW/cm2(20 m/s) |
[66] |
structure of the magnetic switch |
FEP & Cu |
FT |
410 |
18 |
4.82 mW |
[69] |
Structures |
Triboelectric Materials |
Characteristic |
Start-UpWindSpeed |
Electric Output |
Ref |
Rotational sweeping mode |
FEP &Cu |
Low density rotor material, a suitable wind scoop structure |
3.3 m/s |
330 v, 7 μA;Pmax = 2.81 mW(4 m/s) |
[56] |
Rotational sweeping mode |
FEP &Cu |
Coupling of TENG with different structural parameters |
2.2 m/s |
5.2 mW |
[57] |
Rotational sweeping mode |
FEP &Cu |
Adopt the dielectric film with high flexibility |
3.5 m/s |
- |
[91] |
Vortex-induced vibration |
PANI & PTFE |
wind energy harvesting based on vortex-induced vibration |
2.78 m/s |
392.72 μW |
[34] |
Single-side-fixed |
PTFE &Al |
Controls the thickness and size of the film and the distance between the plates |
3.4 m/s |
297 v; 3.9 μA;P = 0.46 mW(10 m/s) |
[26] |
Single-side-fixed |
PTFE &Al |
By changing the material, size and aspect ratio of the film |
2.9 m/s |
2.06 μW (10 MΩ) |
[78] |
Single-side-fixed |
PTFE & MGDY |
Unique material, film geometry parameter control |
1.6 m/s |
- |
[50] |
Galloping structure |
Nylon & FEP |
Through the design of two flexible beams to achieve galloping behavior |
1 m/s |
6 uW(1.4 m/s) |
[35] |
Cantilevered structure |
Al& PTFE |
Change electrode structure, electrode weight, rotating radius and cantilever length. |
2.9 m/s |
- |
[33] |
Variable diameter channel |
Al & FEP |
A square variable diameter channel combined with an ordinary double-ended fixed W-TENG |
0.4m/s |
2 V(2 m/s) |
[92] |
Wind energy is a widely distributed, clean, renewable and green energy source, and wind power is an important direction for future new energy development. Based on the advantages of TENG in collecting irregular low-frequency energy, WD-TENG, a new wind energy harvesting technology, is proposed to realize the effective conversion of wind energy in different applications. The existing single WD-TENG device can generate an output voltage up to 1000V. In addition, WD-TENG can be fabricated with environmentally friend materials and the existing WD-TENG can provide power supply for low-power systems such as LEDs, temperature and humidity sensors, environmental monitor and even air cleaning device. This paper systematically reviews the evolution of WD-TENG structure, the latest progress in material selection, and compiles the output performance, advantages and disadvantages of various designs. Then, we summarize the desirable methods for WD-TENG to work effectively at different wind speeds. In addition, WD-TENG can work in concert with other mechanisms to broaden its application areas. In the future, the study of WD-TENG should devote more efforts on following areas:
1.Development of triboelectric materials
Currently, WD-TENG is often used as a self-powered wind vector sensor or to provide energy supply for small temperature and humidity sensors. The actual environmental monitoring system requires about 30–50 mW of power, and in order to ensure that the Bluetooth module continuously transmits monitoring signals to the outside world, it usually requires a large volume of TENG devices or an array of multiple devices connected in parallel. Therefore, in order to achieve a small, portable and fully self-powered environmental monitoring system, the output power density of the TENG needs to be further improved. Slip-mode WD-TENG can provide high output power, but it leads to severe material wear and tear with frictional heat loss. Therefore, the toughness and durability of triboelectric materials are also one of the key parameters to evaluate the output performance of WD-TENG. In addition, the development of flexible, transparent, biodegradable and recyclable triboelectric materials is also an important development direction for WD-TENG to meet more application scenarios.
2.Design of the device structure
Existing device structure designs are mainly based on rotating and chattering structures. WD-TENG can reduce its start-up wind speed by reducing the weight of the device or optimizing the geometric parameters of the structure. Existing studies can achieve an average power density of 96.79 mW/m2 at wind speeds as low as 2.78 m/s. However, new structures need to be designed to achieve the adjustment of material contact at different wind speeds, in order to maintain a universally high performance of individual devices. In addition, the establishment of mathematical models based on WD-TENG for more accurate design of energy harvesting structures and prediction of optimal operating conditions for TENG in practical applications may also become important research directions for WD-TENG in the future.
3.Power management for WD-TENG
The instability of ambient wind energy makes it difficult to transfer power directly to the load or store it by itself. Therefore, effective power management and energy storage for WD-TENGs is necessary. Existing general-purpose energy management modules for most TENGs can reduce the matching impedance of a TENG from 35 MΩ to 1 MΩ at a low frequency of 1Hz with 80% efficiency, and can store 128 times more energy when charging a 1 mF capacitor [89]. However, these methods are not specially designed to work with wind motions. In the future, researchers need to refine and simplify the power management circuits of conventional WD-TENG, and gradually build power-managed WD-TENG to provide stable and continuous output for electronic devices.
4. Duration of WD-TENG
As already mentioned, the duration of the triboelectric material can have a great impact on the duration of WD-TENG. Besides, the external environmental conditions and with other devices also affect the durability of WD-TENG. In recent years, researchers often reduce the wear of the triboelectric layer by designing the conversion structure of non-contact working modes or by introducing lubricating substances between the contact surfaces of sliding contact TENGs. How to improve the durability of the system while maintaining high output has been a major research direction in this field.
5. Large-scale integration of WD-TENGs
现有单个WD-TENG的输出功率不处于工业应用水平,需要通过集成大量基础单元来增加。由于使用了经济实惠的薄膜和简单的导电电极,生产单个WD-TENG的成本并不高。然而,大量TENG的集成不可避免地带来了资源消耗问题,增加了功率控制和维护的成本。因此,冉德腾的产业化需要以上几个方面的共同进步,以扩大其应用领域。
作者贡献:X.D.准备了评论。Z.L.和P.Y.协助文献整理。X.C.监督了这份手稿的整个过程。所有作者都修改了手稿。所有作者均已阅读并同意已发表的手稿版本。
资金:本研究由国家科技部重点研发项目(2021YFA1201601)、国家自然科学基金项目(批准号62174014)、北京市优秀人才资助青年拔尖人才计划(2017000021223ZK03)、北京市新星计划(Z201100006820063、Z201100006820036)、中国科学院青年创新促进会(2021165)资助。
利益冲突:作者声明,他们没有已知的竞争性经济利益或个人关系,这些利益或个人关系似乎影响了本文报道的工作。
The output power of existing individual WD-TENGs is not at the level of industrial applications and needs to be increased by the integration of a large number of base units. The cost of producing a single WD-TENG is not high due to the utilization of affordable thin film and simple conductive electrodes. However, the integration of a large number of TENGs inevitably brings resource consumption problems and increases the cost of power control and maintenance. Therefore, the industrialization of WD-TENG needs the joint progress of the above aspects in order to expand its application fields.