已收录 272962 条政策
 政策提纲
  • 暂无提纲
Vibrational energy harvesting using piezoelectric ceramics and free-standing thick-film structures
[摘要] This thesis presents a series of broad but systematic and consecutive investigations on the topic of piezoelectric energy harvesting. These include material fabrication and characterisation, harvester fabrication and material parameter selection, electric output and dynamic behaviour tests of energy harvesters, and the feasibility of utilising lead-free piezoelectric materials for energy harvesting. Three lead-based and one lead-free perovskite solid-solutions compositions have been researched individually and compared to each other. In the form of bulk ceramics the lead-free composition is considered capable of replacing the lead-based compositions for vibrational energy harvesting at room temperature. Typical properties of ε\(_r\)≈4700, \(P\)\(_r\)≈9 μC/cm\(^2\), \(d\)\(_3\)\(_3\)≈500 pC/N, \(k\)\(_p\)≈0.51 have been achieved for the lead-free and lead-based compositions respectively. Vibrational energy harvesting based on a novel structure of piezoelectric/silver multi-layer free-standing thick-film unimorph and bimorph cantilevers have been investigated using two of the lead-based compositions. A planar shrinkage difference of 3-6% between the silver and piezoelectric layers is suggested in order to ensure successful fabrication. When tested under harmonic vibration conditions, a comparison of unimorph individual harvesters suggests that higher piezoelectric voltage and electromechanical coupling coefficients may be preferred when selecting materials. Further optimisations involving bimorph devices with tip proof mass have demonstrated maximum harvester outputs (root mean square) of about 9 μW and 2.8 V with approximately 14% bandwidth under resonant vibrations (I 00-150 Hz, 0.5 - I.Og). In addition, the cantilevers have utilised to harvest wind energy with a modified spinning configuration, exhibiting 3.4 V average open-circuit output voltage in optimum wind conditions.
[发布日期]  [发布机构] University:University of Birmingham;Department:School of Metallurgy and Materials
[效力级别]  [学科分类] 
[关键词] T Technology;TK Electrical engineering. Electronics Nuclear engineering [时效性] 
   浏览次数:15      统一登录查看全文      激活码登录查看全文