走在汽車革命的路上論文書籍站
Microbial fuel cell的問題,透過圖書和論文來找解法和答案更準確安心。 我們找到下列包括價格和評價等資訊懶人包
Microbial fuel cell的問題,我們搜遍了碩博士論文和台灣出版的書籍,推薦寫的 Organic Pollutants: Toxicity and Solutions 和Pinto, Alexandra M. F. R./ Oliveira, Vania B./ Falcao, Daniela S的 Direct Alcohol Fuel Cells for Portable Applications: Fundamentals, Engineering and Advances都 可以從中找到所需的評價。
另外網站Performance of Pilot Scale Plug Flow Microbial Fuel Cell for ...也說明:Microbial Fuel Cell. Throughout this study the reactor's performance is assessed on two levels; energy recovery and effluent quality.
這兩本書分別來自 和所出版 。
國立陽明交通大學 電機工程學系 廖育德所指導 郭浩毅的 應用於移動式 UHF 射頻充電的高效率且寬輸入範圍之電源管理晶片採用自適應負載/輸入功率匹配技術 (2021),提出Microbial fuel cell關鍵因素是什麼,來自於無線充電、寬輸入範圍整流器、自適應負載、輸入功率匹配、MPPT。
而第二篇論文國立臺北科技大學 環境工程與管理研究所 陳孝行所指導 林志達的 應用微生物燃料電池同時處理有機污染物與六價鉻之研究 (2021),提出因為有 微生物燃料電池、質子交換膜、六價鉻、粉圓廢水、同步氧化還原的重點而找出了 Microbial fuel cell的解答。
最後網站Microbial Fuel Cells - materiability則補充:Photo microbial fuel cells are bioelectrochemical devices capable of harnessing solar energy and turning it into electrical current with the help of ...
Organic Pollutants: Toxicity and Solutions
為了解決Microbial fuel cell 的問題,作者 這樣論述:
Dr. M. Vasanthy is an Associate Professor in the Department of Environmental Biotechnology at Bharathidasan University in Tiruchirappalli, India. She completed her graduation (in chemistry), Post-graduation and Doctorate in Environmental Sciences from Bharathidasan university, Tiruchirappalli. She i
s credited with 70 research papers in national and International peer - reviewed journals. Also, she has contributed 6 book chapters and has co-authored 4 books. She bagged the Environmental management award in 2012 and UGC Research Award (2015 - 2017). For her credit, she has completed major resear
ch projects of UGC, TNSCST, DST and MoEf for about 86.65 lakhs. Her research focuses mainly on Solid waste management, drinking and wastewater treatment.Dr. V. Sivasankar is an Assistant Professor in the Department of Chemistry at Pachaiyappa’s College, India. He received his doctorate in Chemistry
in 2009 from Bharathidasan University, Tiruchirappalli, Tamil Nadu, India. He is a JSPS Post-Doctoral Fellow in 2016 from Nagasaki University in Nagasaki, Japan. He has been a faculty member in the Department of Chemistry in Pachaiyappa’s College, Chennai, India since 2014. His research areas includ
e materials synthesis and wastewater treatment. To his credit, he has more than 65 research articles in Peer - Reviewed journals and five book chapters in volumes with of renowned publishers. He edited books on Surface Modified Carbons as Scavengers of Fluoride from Water (2016) and Microbial Fuel C
ell Technology for Bio-electricity (2018) with Springer. He collaborates and performs research with professors in universities and research laboratories in Algeria, France, Japan, Iran and South Africa.Dr. T. G. Sunitha is an Assistant Professor in the Department of Chemistry at Pachaiyappa’s Colleg
e, India. She was awarded the doctorate degree in Chemistry in 2009 from Anna University in Chennai, India. She has more than 20 international publications in the form of journal articles and book chapters into her account.
應用於移動式 UHF 射頻充電的高效率且寬輸入範圍之電源管理晶片採用自適應負載/輸入功率匹配技術
為了解決Microbial fuel cell 的問題,作者郭浩毅 這樣論述:
近年來由於物聯網的興起,使得環境中佈建的無線感測器之需求快速上升。傳統的無線感測器之能量來源主要藉由化學電池提供,因此要具有較長的生命週期與較小的體積是相當困難的。無線能量擷取技術為透過環境中的能量來驅動電子電路的相關技術,提供無線感測節點所需的能量並且延長電池壽命。RF功率擷取方法是目前最常使用於短距離(數十公尺內)能量傳遞的方法之一,但由於目前的RF能量管理電路的高效率受限於窄小的輸入功率範圍,因此相關的應用依舊十分受限。本論文以應用於物聯網之無線能量擷取系統為出發點,除了使用可重構式技術來改善傳統交直流轉換架構之窄小輸入範圍的能量轉換曲線達成具有大動態輸入範圍之交直流轉換電路外,更藉由
後端包含負載調變電路的MPPT技術與低壓降穩壓器穩定輸出電壓值來提高高輸入功率時整體系統之效率。整體系統以CMOS 0.18μm製程製作,為一個全整合式之積體電路,其寬輸入動態範圍之交直流轉換電路具有54.2%之最佳轉換效率、-19.6dBm之靈敏度與20dB大輸入範圍且高轉換效率(Efficiency > 20%)。高轉換效率的能量擷取與高整合晶片將可以有效地解決過去RF能量擷取的效率不佳及能量浪費等問題,並且可以應用於更多功率以及體積限制的植入式生物感測器系統、智慧感測系統、自動電子收費系統貼片及無線充電等需要無線能量傳輸及穩定輸出電壓值的電路中。
Direct Alcohol Fuel Cells for Portable Applications: Fundamentals, Engineering and Advances
為了解決Microbial fuel cell 的問題,作者Pinto, Alexandra M. F. R./ Oliveira, Vania B./ Falcao, Daniela S 這樣論述:
Direct Alcohol Fuel Cells for Portable Applications: Fundamentals, Engineering and Advancespresents the fundamental concepts, technological advances and challenges in developing, modeling and deploying fuel cells and fuel cell systems for portable devices, including micro and mini fuel cells. The au
thors review the fundamental science of direct alcohol fuel cells, covering, in detail, thermodynamics, electrode kinetics and electrocatalysis of charge-transfer reactions, mass and heat transfer phenomena, and basic modeling aspects. In addition, the book examines other fuels in DAFCs, such as for
mic acid, ethylene glycol and glycerol, along with technological aspects and applications, including case studies and cost analysis. Researchers, engineering professionals, fuel cell developers, policymakers and senior graduate students will find this a valuable resource. The book's comprehensive co
verage of fundamentals is especially useful for graduate students, advanced undergraduate students and those new to the field.Provides a comprehensive understanding of the fundamentals of DAFCs and their basic components, design and performancePresents current and complete information on the state-o
f-the-art of DAFC technology and its most relevant challenges for commercial deploymentIncludes practical application examples, problems and case studiesCovers the use of other fuels, such as formic acid, ethylene glycol and glycerol Alexandra M. F. R. Pinto obtained her PhD on Combustion in 1991,
after which she focused her activities on the transport phenomena area with particular interest in Mass Transfer and Characterization of two-phase flow patterns using advanced optical techniques. She integrated the know-how acquired with other skills of her core formation in chemical engineering in
to energy applications, in particular direct methanol and ethanol fuel Cells, microbial fuel cells, PEM fuel cells and hydrogen generators and storage systems. Dr. Pinto develops her research activities in the CEFT-Transport Phenomena Research Centre since its foundation in 1997, where she is presen
tly the leader of the Energy Group. She was principal investigator in nine national projects and participated in other 12 projects, including two with industry partners. She has also been a member of European Network FCTESTNET (Fuel Cell Testing and Standardisation Network). Currently, Dr. Pinto is
a professor at Renewable Energies and Chemical Engineering Laboratory of the Chemical Engineering Department of Porto University (DEQ-FEUP), Portugal, where she is director of the Doctoral Program in Chemical and Biological Engineering.
應用微生物燃料電池同時處理有機污染物與六價鉻之研究
為了解決Microbial fuel cell 的問題,作者林志達 這樣論述:
過去在處理廢水的過程,不但耗能、成本高等缺點,再加上近年來出現能源短缺的問題,為了解決以上的問題,因此使用微生物燃料電池作為處理技術,應用於兩種不同廢水以及產生能源。本研究利用雙槽式微生物燃料電池結合質子交換薄膜探討同步氧化還原粉圓廢水與六價鉻實廠廢水,並探討反應過程中的發電效率及汙染物的去除率;粉圓廢水的主要特性為含有高濃度的有機物廢水,可以利用厭氧生物將粉圓廢水中的有機物降解,形成電子與質子;而六價鉻是電鍍工業中常見的有毒污染物,利用外導線將電子傳遞至六價鉻廢水中,使六價鉻接受電子形成較低毒性的三價鉻,甚至是形成氫氧化鉻的沉澱物。陽極在不同的水力停留時間下,在極化曲線中,以最長的水力停留
時間(26小時)可以表現出最佳的性能,內阻為510Ω,並可以達到最高COD去除率80.93%,產生的庫倫效率為21.56%,而六價鉻還原率也在26小時的水力停留時間是最高的,還原率為96.6%;陰極在不同pH值的六價鉻實廠廢水下,在極化曲線中,以pH值為1.3可以表現出最佳的性能,內阻為510Ω,並可以產生最高功率密度為35.74 mW/m2、電流密度為120.83 mA/m2、電壓為0.2958 V,而六價鉻的去除率可以在48小時達到90%以上,最後循環伏安法了解到陽極與陰極有明顯的氧化還原反應,並表明兩者同步進行氧化還原。