Simulation Analysis of Interface Circuits for Piezoelectric Energy Harvesting with Damped Sinusoidal Signals and Random Signals

Various interface circuits for collecting the energy of piezoelectric cantilever beams have been widely investigated. Such circuits include the standard interface, series synchronized switch harvesting interface circuit, parallel synchronized switch harvesting interface, synchronized charge extraction interface, and others. Most studies focus on the performance of different interface circuits with standard sinusoidal excitations. However, in real situations where constant harmonic vibrations are not present, the equivalent voltage from piezoelectric cantilever beams with excitations is not necessarily sinusoidal. In the present study, a simulation analysis of four different interface circuits with signal sources that are both damped sinusoidal and random was performed using Matlab and PSpice. The results show that the interface circuits have improved performance under low load resistance values with damped sinusoidal signal. In addition, the parallel and series synchronized switch harvesting interface circuits may perform well in collecting piezoelectric energy with random excitations

Synchronous charge extraction and voltage inversion (SCEVI): a new efficient vibration-based energy harvesting scheme

This paper presents a new interface technique called synchronous charge extraction and voltage inversion (SCEVI), which consists of a synchronous inductor and a buck-boost converter for vibration-based energy harvesting using piezoelectric elements. The theoretical calculation of the harvested power obtained by using such a technique are proposed and compared with the so-called Standard, SECE (Synchronous Electric Charge Extraction), Parallel-SSHI (Parallel Synchronized Switch Harvesting on Inductor) and Series-SSHI (Series Synchronized Switch Harvesting on Inductor) methods commonly used in piezoelectric vibration-powered generator considering both constant displacement amplitude and force amplitude. From the harvested power point of view, SCEVI and Parallel – SSHI techniques are the better ones and each has its own merits. But the harvested power of SCEVI is independent of the load connected to the generator and Parallel – SSHI depend on the load resistance. The harvested power of SECE is also independent of the load, but the further experimental results show that the proposed SCEVI interface technique dramatically increases the harvested power by almost up to 150 % compared with the SECE method under the same amplitude of displacement excitation

Analysis on One-Stage SSHC Rectifier for Piezoelectric Vibration Energy Harvesting

Conventional SSHI (synchronized switch harvesting on inductor) has been believed to be one of the most efficient interface circuits for piezoelectric vibration energy harvesting systems. It employs an inductor and the resulting RLC loop to synchronously invert the charge across the piezoelectric material to avoid charge and energy loss due to charging its internal capacitor ($C_P$). The performance of the SSHI circuit greatly depends on the inductor and a large inductor is often needed; hence significantly increases the volume of the system. An efficient interface circuit using a synchronous charge inversion technique, named as SSHC, was proposed recently. The SSHC rectifier utilizes capacitors, instead of inductors, to flip the voltage across the harvester. For a one-stage SSHC rectifier, one single intermediate capacitor ($C_T$) is employed to temporarily store charge flowed from $C_P$ and inversely charge $C_P$ to perform the charge inversion. In previous studies, the voltage flip efficiency achieves 1/3 when $C_T = C_P$. This paper presents that the voltage flip efficiency can be further increased to approach 1/2 if $C_T$ is chosen to be much larger than $C_P$

Self-Powered Electronics for Piezoelectric Energy Harvesting Devices

International audienc

Piezoelectric energy harvesting solutions

This paper reviews the state of the art in piezoelectric energy harvesting. It presents the basics of piezoelectricity and discusses materials choice. The work places emphasis on material operating modes and device configurations, from resonant to non-resonant devices and also to rotational solutions. The reviewed literature is compared based on power density and bandwidth. Lastly, the question of power conversion is addressed by reviewing various circuit solutions

Rectification, amplification and switching capabilities for energy harvesting systems: power management circuit for piezoelectric energy harvester

Dissertação de mestrado em Biomedical EngineeringA new energy mechanism needs to be addressed to overcome the battery dependency, and consequently extend Wireless Sensor Nodes (WSN) lifetime effectively. Energy Harvesting is a promising technology that can fulfill that premise. This work consists of the realization of circuit components employable in a management system for a piezoelectric-based energy harvester, with low power consumption and high efficiency. The implementation of energy harvesting systems is necessary to power-up front-end applications without any battery. The input power and voltage levels generated by the piezoelectric transducer are relatively low, especially in small-scale systems, as such extra care has to be taken in power consumption and efficiency of the circuits. The main contribution of this work is a system capable of amplifying, rectifying and switching the unstable signal from an energy harvester source. The circuit components are designed based on 0.13 Complementary Metal-Oxide-Semiconductor (CMOS) technology. An analog switch, capable of driving the harvesting circuit at a frequency between 1 and 1 , with proper temperature behaviour, is designed and verified. An OFF resistance of 520.6 Ω and isolation of −111.24 , grant excellent isolation to the circuit. The designed voltage amplifier is capable of amplifying a minor signal with a gain of 42.56 , while requiring low power consumption. The output signal is satisfactorily amplified with a reduced offset voltage of 8 . A new architecture of a two-stage active rectifier is proposed. The power conversion efficiency is 40.4%, with a voltage efficiency of up to 90%. Low power consumption of 17.7 is achieved by the rectifier, with the embedded comparator consuming 113.9 . The outcomes validate the circuit’s power demands, which can be used for other similar applications in biomedical, industrial, and commercial fields.Para combater a dependência dos dispositivos eletrónicos relativamente ás baterias é necessário um novo sistema energético, que permita prolongar o tempo de vida útil dos mesmos. Energy Harvesting é uma tecnologia promissora utilizada para alimentar dispositivos sem bateria. Este trabalho consiste na realização de componentes empregáveis num circuito global para extrair energia a partir ds vibrações de um piezoelétricos com baixo consumo de energia e alta eficiência. Os níveis de potência e voltagem gerados pelo transdutor piezoelétrico são relativamente baixos, especialmente em sistemas de pequena escala, por isso requerem cuidado extra relativamente ao consumo de energia e eficiência dos circuitos. A principal contribuição deste trabalho é um sistema apropriado para amplificar, retificar e alternar o sinal instável proveniente de uma fonte de energy harvesting. Os componentes do sistema são implementados com base na tecnologia CMOS com 0.13 . Um interruptor analógico capaz de modelar a frequência do sinal entre 1 e 1 e estável perante variações de temperatura, é implementado. O circuito tem um excelente isolamento de −111.24 , devido a uma resistência OFF de 520.6 Ω. O amplificador implementado é apto a amplificar um pequeno sinal com um ganho de 42.56 e baixo consumo. O sinal de saída é satisfatoriamente amplificado com uma voltagem de offset de 8 . Um retificador ativo de dois estágios com uma nova arquitetura é proposto. A eficiência de conversão de energia atinge os 40.4%, com uma eficiência de voltagem até 90%. O retificador consome pouca energia, apenas 17.7 , incorporando um comparador de 113.9 . Os resultados validam as exigências energéticas do circuito, que pode ser usado para outras aplicações similares no campo biomédico, industrial e comercial

A Nail-Size Piezoelectric Energy Harvesting System Integrating a MEMS Transducer and a CMOS SSHI Circuit

Piezoelectric vibration energy harvesting has drawn much interest to power distributed wireless sensor nodes for Internet of Things (IoT) applications where ambient kinetic energy is available. For certain applications, the harvesting system should be small and able to generate sufficient output power. Standard rectification topologies such as the full-bridge rectifier are typically inefficient when adapted to power conditioning from miniaturized harvesters. Therefore, active rectification circuits have been researched to improve overall power conversion efficiency, and meet both the output power and miniaturization requirements while employing a MEMS harvester. In this paper, a MEMS piezoelectric energy harvester is designed and cointegrated with an active synchronized switch harvesting on inductor (SSHI) rectification circuit designed in a CMOS process to achieve high output power for system miniaturization. The system is fully integrated on a nail-size board, which is ready to provide a stable DC power for low-power mini sensors. A MEMS energy harvester of 0.005 cm3 size, co-integrated with the CMOS conditioning circuit, outputs a peak rectified DC power of 40.6 µW and achieves a record DC power density of 8.12 mW/cm3 when compared to state-of-the-art harvesters

A Cold-Startup SSHI Rectifier for Piezoelectric Energy Harvesters with Increased Open-Circuit Voltage

Piezoelectric vibration energy harvesting has drawn much research interest over the last decade towards the goal of enabling self-sustained wireless sensor nodes. In order to make use of the harvested energy, interface circuits are needed to rectify and manage the energy. Among all active interface circuits, SSHI (synchronized switch harvesting on inductor) and SECE (synchronous electric charge extraction) are widely employed due to their high energy efficiencies. However, the cold-startup issue still remains since an interface circuit needs a stable DC supply and the whole system is completely out of charge at the beginning of implementations or after a certain period of time without input vibration excitation. In this paper, a new cold-startup SSHI interface circuit is presented, which dynamically increases the open-circuit voltage generated from the piezoelectric transducer (PT) in cold-state to start the system under much lower excitation levels. The proposed circuit is designed and fabricated in a 0.18 um CMOS process and experimentally validated together with a custom MEMS (microelectromechanical systems) harvester, which is designed with split electrodes to work with the proposed power extraction circuit. The experiments were performed to start the system from the cold state under variable excitation levels. The results show that the proposed system lowers the required excitation level by at least 50% in order to perform a cold-startup. This aids restarting of the energy harvesting system under low excitation levels each time it enters the cold state