Abstract
It is meaningful to research the Triboelectric Nanogenerators (TENG), which can create electricity anywhere and anytime. There are many researches on the structures and materials of TENG to explain the phenomenon that the maximum voltage is stable and the current is increasing. The output voltage of the TENG is high about 180–400 V and the output current is small about 39 μA, which the electronic devices directly integration of TENG with Li-ion batteries will result in huge energy loss due to the ultrahigh TENG impedance. A novel interface circuit with the high-voltage buck regulator for TENG is introduced firstly in this paper. The interface circuit can transfer the output signal of the TENG into the signal fit to a lithium ion battery. Through the circuit of the buck regulator, the average output voltage is about 4.0 V and the average output current is about 1.12 mA. Further, the reliability and availability for the lithium ion battery and the circuit are discussed. The interface circuit is simulated using the Cadence software and verified through PCB experiment. The buck regulator can achieve 75% efficiency for the High-Voltage TENG. This will lead to a research hot and industrialization applications.
Similar content being viewed by others
Introduction
There are many researches to put the electrostatic energy as a part of the self-powered portable electronics in the recent years1. With the tremendous increase number of mini electronics, it is vitally important to develop energy storage related technology. This is the field of nano-energy, which is the power for sustainable, maintenance free and self-powered operation of nano-systems2,3. Recently, Professor Wang invented the triboelectric nano-generator (TENG), which is used to convert mechanical energy into electricity by a conjunction of triboelectrification and electrostatic induction4,5,6,7. However, the equivalent circuit model of TENG is a very high voltage source in series with a small capacitor, which is about below nF range8,9. For the TENG, the power management circuits are worth investigating because TENGs are emerging energy harvesters10,11. In this case, the most important function of circuit should be improving the charging efficiency since direct integration of TENG with lithium ion batteries will result in huge energy loss due to the ultrahigh TENG impedance12.
So far, there are three modes of the TENG: Vertical Contact-Separation mode, In-plane Sliding mode and Rotation Mode9. The first mode is Vertical Contact-Separation: Dielectric-to-Dielectric Case. The output short-circuit current is formed by the two electrodes with the induced charge density13. For the mode, the vibration frequency will impact these factors of the velocity, distance and output voltage14,15. As each contact, the amount of all the electrons and the discharge time are limited, that the current is only about microampere level. For the structure, the average output voltage is about 40 V and the maximum output voltage is about 125 V, with the average output current is about 0.15 mA and the maximum output current is 0.3 mA. The maximum output power is about 3 mW16. For the Metal-to-Dielectric case, the principle is almost the same as the Dielectric-to-Dielectric case. The maximum output voltage is about 300 V and the output current is low to about 80 μA17,18. For the useful in-plane sliding mode of the Dielectric-on-Dielectric Case and the Metal-on-Dielectric Case, the maximum output voltage is about 400 V and the output current is about 50 μA19,20. So the maximum output power is about 8 mW. For the schematic diagram of a cylindrical rotating TENG with 6 strip units, the maximum voltage stays stable about 350 V at sundry rotation speeds. The output current is about 39 μA, when the rotation speed is about 600 r/min21,22. In the all, the maximum output voltage generated by TENG is about 180 V to 400 V and the output current is about 39 to 175 μA as shown in Table 1. It is very difficult to design circuit for power manager with high efficiency, as the output power is extremely low for the usually energy harvester. The output voltage of TENG is very high, which is easy to destroy some electronic devices, most notably CMOS-integrated circuits and some MOSFET transistors. In this paper, we introduce an interface circuit, using some special devices to solve the high resistance and high voltage with high efficiency to store the power. Making the nano-energy power sources is availability and stability.
In this letter, the lithium ion battery is chosen to store the power of the TENG, whose nominal voltage is 3.6 V23. The minimum voltage is about 2.5 V when all the power is consumed. The voltage is decreasing followed by the power consumption. For the lithium ion battery, the lightweight, high voltage, plasticity and high energy density are its merits. However, the lithium ion battery, without overcharging protection, maybe caused an explosion when is overcharged.
Results
Design of the interface circuit
For the TENG, the output high voltage and low current are not common for the piezoelectric generator24,25,26, solar battery27 and wind energy, whose power sources have their own power manger circuits in market, none for the TENG. A novel circuit to manage the power of the TENG is chosen and designed28. The buck regulator put the output voltage and current fit to the lithium battery. Protect circuit must be designed, as the over-charge may cause the battery explosive. When the charge battery is consumed, the replace available battery should be considered to extend the battery life. The reliability of the whole system should also be considered as the Fig. 1.
The architecture diagram of the energy harvesting system.
The system consists of the energy harvester, storage battery and power management. The charge circuit involves rectifier, filter and regulator. The power management includes battery capacity indicator, switch over consumption and overcharging protection.
As showing in Fig. 1, energy harvesting system consists of the energy harvester, storage battery and power management. The charge circuit involves rectifier, filter and regulator. The power management includes battery capacity indicator, switch over consumption and overcharging protection. The available energy from the environment depends on the time-varying conditions, which is extracted and stored to the battery. Thus, the load can still work, while the environment energy is not available. The buck regulator is used to gather more available energy from harvester to battery. The primary factors of interface circuit include stability, transform efficiency and complexity. With the power management, it must achieve follow function: 1) it can monitor output voltage of the battery and makes sure the voltage is between the Under Voltage (UV) and Over Voltage (OV) threshold to stay in the safe range. 2) It can use LED to monitor the battery capacity.
Considering the reliability, the range of the input voltage should be more free space. Maximum voltage of the TENG is set at 400 V, the lowest current is set at 25 μA and the AC frequency is set among 1 Hz to 100 Hz. Through the interface circuit, the voltage is about 4.2 V, fitting to the lithium ion battery. Before the high voltage and current were delivered to the battery, some transistors with highly breakdown voltage and transformer should be designed to reduce the disturbance of high voltage.
Rectifier circuit and Filter circuit
The equivalent circuit model of TENG should be a voltage source in series with a small capacitor about below nF as the Fig. 2a8. Because of the inherent capacitive characteristics, TENGs can only provide unstable AC voltage/current outputs, which is uneasy to simulation the complicate signal28. The TENG has a bottom stator and a top rotor, as shown in Fig. 2b,c. On the rotor board, there is a radial array of copper gratings, each of which has a length of 7.2 cm and central angle of 10°. On top of the stator, a radially interdigital structure of the two copper electrodes is covered by a Kapton thin film. Each “finger” of the underneath copper grating also has a central angle of about 10°14. The output open voltage and the output short current can be tested to verify the function of the circuit in the Fig. 2d,e. For the output voltage, the form is more liking AC signal, which includes not only one frequency. The Short-circuit output current also exhibits AC behavior, with equal amount of electrons flowing in the opposite directions within one cycle.
The rectifier and the filter circuit structure and the output voltage and current of the rotating TENG.
(a) The rectifier and the filter circuit structure. (b) Schematic illustration showing a real disk TENG. (c) Schematic illustration showing a disk TENG of its back. (d) The output voltage. (e) The output current.
The rectifier and filter transfer high AC voltage signal into a DC voltage signal, which facilitate the subsequent signal processing. The block diagram of the rectifier and filter is shown in Fig. 2a. The simulation results are shown in the Fig. 3a,b. After rectified, the capacitor can filter some noise. When the capacitance is bigger than 1 uF, it will be the electrolytic capacitor, which has a lot of inductive component. To reduce it, the large electrolytic capacitor is usually in parallel with a small one. In the Fig. 2a, the circuit of π filter consists of C1, C2 and L1 to form a rectified DC voltage. Every capacitor has a resistor in parallel to form the RC loop. The current can be calculated as the equation (1).
The performance of the Rectifier and Filter circuit.
(a) The rectified voltage through the transformer and the diodes. (b) The rectified current through the transformer and the diodes. (c) The test voltage through the transformer and the diodes. (d) The test current through the transformer and the diodes.
With the voltage of the actually structure tested result is shown in the Fig. 3c, the maximum voltage is about 25 V. The current is about 1 mA. The power is calculated in the equation (2).
Where θ is the angle between the phase of the voltage and the current. The output power can get the maximum when there is no any angle between the phase of the voltage and current.
Regulator Circuit
The output voltage of the rectifier and filter is also a challenge for these switch circuits. The highly cost of MOSFET and traditional Pulse Width Modulation(PWM) are limited in the high voltage and low current situation. In this letter, the technology of the StackFET is taken, which uses some economical MOSFET in lower voltage and other modes in the circuit. In the situation, the voltage of widely input range and simple circuit is designed to the regulator circuit. As the Fig. 4a, the two transistors with ultra-low power consumption are used to control and transport the total current, which can charge as much electric as possible into the battery.
The regulator circuit structure, simulation results and the test results.
(a) The regulator circuit. (b) The DC Sweep results of the current through the transistor Q1 and Q2. (c) The Time Domain results of the current through the transistor Q1 and Q2. (d) The Time Domain result of the total output current. (e) The actual output voltage of the buck regulator. (f) The actual output current of the regulator.
The regulator circuit is designed to transfer the output voltage fitting to the lithium ion battery. In the circuit, the zener diode D5 and the base voltage VB1 of the transistor Q1(NPN) are adopted to the reference voltage, as shown in the Fig. 4a. The reference voltage is on the resistor R6, which can get the constant output current. However, as the widely range of the voltage, the current of the zener diode would be varied and the power would be increasing. The transistor Q2 (PNP) and resistor R5 can get the supplementary current. So that the current IC1 is provided on the low input voltage by Q1 and the current IC2 is provided on high input voltage by Q2 in case some interference signal, as shown in the Fig. 4b,c. The total current Iout is offered by Q1 and Q2, which is almost the constant at different input voltage as shown in the equation (3).
The total current through R6 is about 15 mA, as shown in the Fig. 4d. The constant available voltage can get through the diode D6. D6 is a transient voltage suppression diode, which connect the power line and grand in parallel. Once there is a transient high voltage, it can release the signal immediately to protect the other components and it will recover the non-conductive state instantly, which is considered as the reliability design. As the equation (3), VD5 − VQ2BC is set 12 V and VD5 is about 15 V. Using D6, the reasonable load can be designed to form the available voltage. Through the circuit, it can transport the power of TENG to storing in the battery. Furthermore, The actual voltage and current of the TENG are just like the AC signal shown in the Fig. 2. The average output voltage is about 40 V in the testing TENG. The maximum voltage can get about 125 V. Through the buck regulator, the voltage and current test results are shown in the Fig. 4e,f. The average output voltage is about 4 V. The average current is about 1.12 mA with the load resistance is about 3 kΩ.
Real-time Monitoring Management
At the same time, it is very important to design a real-time monitoring management in the battery. The module can monitor its full power or completely consumed. When continuing to charge at the full power situation, it will be exploded29. The protect circuit should be designed and the LED should be lighted to warning. The indicator circuit shows in the Fig. 5a. The voltage of regulators D6 is about 5 V. Through the R16 and R17 the reference voltage is set as 3 V. When the battery gets the full power, its output will be more than the reference voltage and the Operational Amplifier (OA) will output zero. The transistor Q5 and the transistor Q6 are off, so that the LED D9 will be lighted. Otherwise, the LED D10 will be lighted and the battery is power full in the situation. Q6 is used to prevent the battery charged again. The capacitor C4, C5 and C6 are mainly to reduce the noise, to be more reliable and stable.
The circuit structures of the battery capacity indicator, the switch over consumption and the overcharging protection.
Thinking about the reliability and availability, a real-time monitoring management about the battery is designed.
Discussion
By the way, all the power manger system can be fabricated as the sample in the Fig. 6e. The PCB was designed and fabricated to test and verify the performance and efficiency of the power manager system. The test results of the circuit PCB samples is shown in Fig. 6. From the result we can see that as the load resistor is bigger, the voltage would be increase. As the direct of the TENG, when the load is about 260 kΩ, the output maximum power is about 6 mW with the voltage is about 40 V. Through the integrated power manger, when the load is about 3 kΩ, the output maximum power is about 4.5 mW, with the output voltage is about 4 V. The efficiency of the TENG can be calculated as the equation (4).
Optimization of the performance of the integrated TENG system and optical photo of the integrated power manger.
(a) With the integrated TENG system, the DC voltage under different load resistances. (b) With the integrated TENG system, average output power under different load resistances. (c) With the integrated power manger, the output voltage under different load resistances. (d) With the integrated power manger, average output power under different load resistances. (e) The actual PCB sample of the system.
In summary, in the letter for the TENG, the high voltage and low current never appear in the market and research. It is the first time to design the buck regulator for the TENG in this letter. We have mainly solved two problems. Firstly, we have done many researches on the structures and materials of Triboelectric Nanogenerators (TENG) to explain the phenomenon that the maximum voltage is stable and the current is increasing. The output voltage of the TENG is high about 100–400 V and the output current is small about 25 μA, which is not easy to use in the electronic devices. Secondly, a novel interface circuit with the high-voltage buck regulator for TENG is introduced firstly in this manuscript. The interface circuit can transfer the output signal of the TENG into the signal fit to a lithium ion battery. Further, the reliability and availability for the lithium ion battery and the circuit are discussed. The interface circuit is simulated using the Cadence software and verified through PCB experiment. The buck regulator can achieve 75% efficiency for the High-Voltage TENG. In that situation, the power of the TENG can drive some small electronics30,31, which could be used widely for the remote and mobile environmental sensors, homeland security and even wearable personal electronics32,33.
Methods
Design of the interface circuit
As we use the the Triboelectric Nanogenerators (TENG) from Dr. Zhang Chi, the Maximum voltage of the TENG is set at 400 V, the lowest current is set at 25 μA and the AC frequency is set among 1 Hz to 100 Hz. The energy harvesting system consists of the energy harvester, storage battery and power management. The charge circuit involves rectifier, filter and regulator. The power management includes battery capacity indicator, switch over consumption and overcharging protection to ensure the harvesting system work.
Measurement of the TENG
To measure the triboelectric output voltage, a 100× probe (HP9258) was connected to the oscilloscope (Agilent DSO-X 2014A). The equivalent internal resistance is 260 kΩ and the corresponding settings in the oscilloscope was adjusted to 100×. To measure the triboelectric output current, a 260 kΩ external resistance was connected parallel to the TENG and the measured signal was calculated to the current value. In the electromagnetic part, 260 kΩ probe was used to measure the voltage and 100 Ω external resistance was parallel connected to measure the current.
Simulink circuit
The Simulink circuit includes three parts: Rectifier circuit and Filter circuit, Regulator Circuit and Real-time Monitoring Management. These are simulated using the Cadence software and verified through PCB experiment. The test result can be shown in the correspondence figure and the PCB is showing in the Fig. 6e.
Additional Information
How to cite this article: Luo, L.-C. et al. A Low Input Current and Wide Conversion Ratio Buck Regulator with 75% Efficiency for High-Voltage Triboelectric Nanogenerators. Sci. Rep. 6, 19246; doi: 10.1038/srep19246 (2016).
References
Roundy, S., Wright, P. K. & Rabaey, J. A study of low level vibrations as a power source for wireless sensor nodes. Comput. Commun. 26, 1131–1144 (2003).
Wang, Z. L. Triboelectric Nanogenerators as New Energy Technology for Self-Powered Systems and as Active Mechanical and Chemical Sensors. Acs Nano 7, 9533–9557 (2013).
Glynne-Jones, P., Tudor, M. J., Beeby, S. P. & White, N. M. An electromagnetic, vibration-powered generator for intelligent sensor systems. Sensor Actuat a-Phys. 110, 344–349 (2004).
Fan, F. R., Tian, Z. Q. & Wang, Z. L. Flexible triboelectric generator! Nano Energy 1, 328–334 (2012).
Wang, Z. L. Self-Powered Nanosensors and Nanosystems. Adv. Mater. 24, 280–285 (2012).
Mitcheson, P. D. et al. MEMS electrostatic micropower generator for low frequency operation. Sensor Actuat a-Phys. 115, 523–529 (2004).
Lo, H. W. & Tai, Y. C. Parylene-based electret power generators. J. Micromech. Microeng. 18, 10.1088/0960-1317/18/10/104006 (2008).
Niu, S. M. et al. Simulation method for optimizing the performance of an integrated triboelectric nanogenerator energy harvesting system. Nano Energy 8, 150–156 (2014).
Fan, F. R. et al. Transparent Triboelectric Nanogenerators and Self-Powered Pressure Sensors Based on Micropatterned Plastic Films. Nano Lett. 12, 3109–3114 (2012).
Fan, F. R. et al. Highly transparent and flexible triboelectric nanogenerators: performance improvements and fundamental mechanisms. J. Mater. Chem. A 2, 13219–13225 (2014).
Kim, S. et al. Transparent Flexible Graphene Triboelectric Nanogenerators. Adv. Mater. 26, 3918–3925 (2014).
Lee, K. Y., Gupta, M. K. & Kim, S. W. Transparent flexible stretchable piezoelectric and triboelectric nanogenerators for powering portable electronics. Nano Energy 14, 139–160 (2015).
Zhu, G. et al. Triboelectric-Generator-Driven Pulse Electrodeposition for Micropatterning. Nano. Lett. 12, 4960–4965 (2012).
Zhou, Y. S. et al. In Situ Quantitative Study of Nanoscale Triboelectrification and Patterning. Nano Lett. 13, 2771–2776 (2013).
Diaz, A. F. & Felix-Navarro, R. M. A semi-quantitative tribo-electric series for polymeric materials: the influence of chemical structure and properties. J. Electrostat. 62, 277–290 (2004).
Zhu, G. et al. Toward Large-Scale Energy Harvesting by a Nanoparticle-Enhanced Triboelectric Nanogenerator. Nano Lett. 13, 847–853 (2013).
Zhong, J. W. et al. Finger typing driven triboelectric nanogenerator and its use for instantaneously lighting up LEDs. Nano Energy 2, 491–497 (2013).
Wang, S. H., Lin, L. & Wang, Z. L. Nanoscale Triboelectric-Effect-Enabled Energy Conversion for Sustainably Powering Portable Electronics. Nano Lett. 12, 6339–6346 (2012).
Zhu, G. et al. Linear-Grating Triboelectric Generator Based on Sliding Electrification. Nano Lett. 13, 2282–2289 (2013).
Wang, S. H. et al. Sliding-Triboelectric Nanogenerators Based on In-Plane Charge-Separation Mechanism. Nano Lett. 13, 2226–2233 (2013).
Lin, L. et al. Segmentally Structured Disk Triboelectric Nanogenerator for Harvesting Rotational Mechanical Energy. Nano Lett. 13, 2916–2923 (2013).
Bai, P. et al. Cylindrical Rotating Triboelectric Nanogenerator. Acs Nano 7, 6361–6366 (2013).
Wei, X. Y. et al. Interface-Free Area-Scalable Self-Powered Electroluminescent System Driven by Triboelectric Generator. Sci. Rep. 5, 10.1038/srep13658 (2015).
Jung, W. S. et al. High Output Piezo/Triboelectric Hybrid Generator. Sci Rep. 5, ARTN 9309 0.1038/srep09309 (2015).
Wang, X. D., Song, J. H., Liu, J. & Wang, Z. L. Direct-current nanogenerator driven by ultrasonic waves. Science 316, 102–105 (2007).
Cha, S. N. et al. Sound-Driven Piezoelectric Nanowire-Based Nanogenerators. Adv. Mater. 22, 10.1002/adma.201001169 (2010).
Xu, J. T., Chen, Y. H. & Dai, L. M. Efficiently photo-charging lithium-ion battery by perovskite solar cell. Nature Communications 6, ARTN 8103 10.1038/ncomms9103 (2015).
Zi, Y. et al. Standards and figure-of-merits for quantifying the performance of triboelectric nanogenerators. Nature Communications 6, 10.1038/ncomms9376 (2015).
Liao, L. F. Impact of manager’s social power on R&D employees’ knowledge-sharing behaviour. Int. J. Technol. Manage. 41, 169–182 (2008).
Tice, J. D., Rosheck, J. B., Hamlin, C. D., Apblett, C. A. & Kenis, P. J. A. Normally-Closed Electrostatic Microvalve Fabricated Using Exclusively Soft-Lithographic Techniques and Operated With Portable Electronics. J. Microelectromech. S. 22, 1251–1253 (2013).
Yang, W. Q. et al. Harvesting Energy from the Natural Vibration of Human Walking. Acs Nano 7, 11317–11324 (2013).
Meng, B. et al. Self-powered flexible printed circuit board with integrated triboelectric generator. Nano Energy 2, 1101–1106 (2013).
Chen, J. et al. Harmonic-Resonator-Based Triboelectric Nanogenerator as a Sustainable Power Source and a Self-Powered Active Vibration Sensor. Adv. Mater. 25, 6094–6099 (2013).
Acknowledgements
This research was supported by the National Natural Science Foundation of China under Grant No. 61434001 and 61574083 and the ‘thousands talents’ program for pioneer researchers and its innovation team, China. Thanks to the support of the TENG from Dr. Zhang Chi.
Author information
Authors and Affiliations
Contributions
L.C.L., D.C.B. and W.Q.Y. conceived the idea and designed the experiment. L.C.L. and D.C.B. performed the measurements and analyzed the data. L.C.L. did the fabrication work. Z.H.Z. set up the test platform. L.C.L., D.C.B., Z.H.Z. and T.L.R. wrote the paper. T.L.R. is the supervisor of this research.
Ethics declarations
Competing interests
The authors declare no competing financial interests.
Rights and permissions
This work is licensed under a Creative Commons Attribution 4.0 International License. The images or other third party material in this article are included in the article’s Creative Commons license, unless indicated otherwise in the credit line; if the material is not included under the Creative Commons license, users will need to obtain permission from the license holder to reproduce the material. To view a copy of this license, visit http://creativecommons.org/licenses/by/4.0/
About this article
Cite this article
Luo, LC., Bao, DC., Yu, WQ. et al. A Low Input Current and Wide Conversion Ratio Buck Regulator with 75% Efficiency for High-Voltage Triboelectric Nanogenerators. Sci Rep 6, 19246 (2016). https://doi.org/10.1038/srep19246
Received:
Accepted:
Published:
DOI: https://doi.org/10.1038/srep19246
