Energy harvesting from controlled buckling of piezoelectric beams

Ansari, M. H.; Karami, M. Amin

doi:10.1088/0964-1726/24/11/115005

Cited by 38 publications

(16 citation statements)

References 34 publications

Supporting

Mentioning

Contrasting

Order By: Relevance

“…Although the IMU system provides a sufficiently rich kinematic information for gait analysis, it faces the issue of relatively high power consumption (370 mW) in practice. However, new advances in power management and energy-harvesting [39,40] can address this issue.…”

Section: Resultsmentioning

confidence: 99%

A Robust Automatic Gait Monitoring Approach Using a Single Imu for Home-Based Applications

Ghobadi

Esfahani

2017

J. Mech. Med. Biol.

View full text Add to dashboard Cite

A new approach of human activity monitoring with a single Inertial Measurement Unit (IMU) capable of gait recognition and assessment is proposed for home-based applications. The method estimates the foot motion using a single IMU, then automatically segments the motion into steps, and extracts multiple kinematics templates. It classifies each segment by extracting Mahalanobis distance-based features from multiple sections of the motion templates and then training a Support Vector Machine. The proposed wearable system can distinguish between nine classes of activities with a classification accuracy of 99.6%. It can also discriminate between normal and abnormal gait patterns with an accuracy of 98.7%. In addition to a high recognition rate, the proposed approach provides a Gait Similarity Score (GSS) of the performed gait to its desired/normal pattern. The experimental results indicate the capability of GSS measure for assessing the quality of motion in “pre-”, “initial”, “mid” and “terminal” stages of swing phase.

show abstract

Section: Resultsmentioning

confidence: 99%

A Robust Automatic Gait Monitoring Approach Using a Single Imu for Home-Based Applications

Ghobadi

Esfahani

2017

J. Mech. Med. Biol.

View full text Add to dashboard Cite

show abstract

“…The impulses are applied at the point indicated by the red arrow in Figure 1(a) using fast manual taps. Such impulses may be envisioned to originate from diverse energies such as human motion-based (Ylli et al, 2015) or transportation-based (Ansari and Karami, 2015) impulses. The beam tip displacements, corresponding to the displacements of magnets 1 and 2 at the cantilever tips, are measured by two laser displacement sensors (ILD-1420; Micro Epsilon).…”

Section: Experimental and Simulation Methodsmentioning

confidence: 99%

Impulsive energy conversion with magnetically coupled nonlinear energy harvesting systems

Dai

Park

Harne

2018

Journal of Intelligent Material Systems and Structures

View full text Add to dashboard Cite

Magnets have received broad attention for vibration energy harvesting due to noncontact, nonlinear forces that may be leveraged among harvesting system elements. Yet, opportunities to integrate multi-directional coupling among a nonlinear energy harvesting system subjected to impulsive excitations have not been scrutinized, despite widespread prevalence of such excitations. To characterize these potentials, this research investigates an energy harvesting system with magnetically induced nonlinearities and coupling effects under impulsive excitations. A system model is formulated and validated with experimental efforts to reconstruct static and dynamic properties of the system via simulations. Then, the model is harnessed to scrutinize dynamic response of the system when subjected to impulse conditions. This research reveals the clear impulse strength dependence and influence of asymmetries on total electrical energy capture and energy conversion efficiency that are tailored by magnetic force coupling. Asymmetry is found to promote greater impulse-to-electrical energy conversion when compared to the symmetric counterpart system and a benchmark nonlinear energy harvester. The roles of initial conditions exemplify how stored energy in an asymmetric energy harvesting system may be released during nonlinear impulsive response. These results provide insights about opportunities and challenges to incorporate magnetic coupling effects in nonlinear energy harvesting systems subjected to impulses.

show abstract

“…without loss of comfort or radical change in shoe design [15]. Ansari designed horizontal and vertical buckling harvesters placed on the road to scavenge the mechanical energy from passing vehicle or walking people [16]. To the best knowledge of the authors, there is no literature mentioned on the study of vertical buckling harvester mounted on the shoe to harvest human's biomechanical energy, especially the comparison study of horizontal and vertical buckling harvesters.…”

Section: Energy Harvesting From Human Motions For Wearable Applicationsmentioning

confidence: 99%

Energy harvesting from human motions for wearable applications

Cao

2018

Industria Textila

View full text Add to dashboard Cite

Harvesting biomechanical energy from human’s movement is an alternative solution to effectively power the wearable electronics. In this paper, two impact-driven piezoelectric energy harvesters were developed which can be integrated within human shoe-soles and also can be tailored to integrate in commercial carpets or outdoor roadway to harvest the massive mechanical energy from the passing vehicles or people crowds at low frequencies. For a comprehensive study, two buckling types of PVDF harvesters were selected and tested. It has been shown that the mechanical responses of the arch type prototype and the C type prototype are different. In addition, the mechanical response of the C type can be affected by the vertical height of the C type. The peak-peak voltage of the C type increases with the vertical height of the C type decreases. The peak-peak voltage of arch type is almost the same with the C type when the vertical height of which is 25 mm. The stability of the output voltage of the arch type is the worst when compared with that of the three C types. The stability of the output voltage of the C type when the vertical height of which is 25 mm is the worst among the three different vertical heights

show abstract

Energy harvesting from controlled buckling of piezoelectric beams

Cited by 38 publications

References 34 publications

A Robust Automatic Gait Monitoring Approach Using a Single Imu for Home-Based Applications

A Robust Automatic Gait Monitoring Approach Using a Single Imu for Home-Based Applications

Impulsive energy conversion with magnetically coupled nonlinear energy harvesting systems

Energy harvesting from human motions for wearable applications

Contact Info

Product

Resources

About