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塑膠模具設計與機構設計(第三版)

為了解決尿素價格的問題，作者顏智偉 這樣論述：

　　當前塑膠模具的應用益形重要，作者累積多年的教學經驗及工作經驗編著而成。本書內容詳實，讀者可於各種常用之鋼材、塑材、模具之規格、特性、公差及加工方法有正確認識。對於模具設計及成本設計要領均有詳細述及，同時又有各大公司機構設計及模具設計考題。可作為學校、職訓中心之研修教材；機構設計、模具設計及射出成形從業人員工具書及資料查閱用書。 本書特色 　　1.作者在從事模具設計及機構設計近二十年，將所有精華寫在書中，內容最實用。 　　2.詳讀此書，對於設計機構零件有莫大幫助，不但開模、成型容易、好加工亦可自行估價減少成本，更能設計出避免電磁波干擾的零件。

中醫神藥青蒿(黃花蒿)

為了解決尿素價格的問題，作者李政育,吳哲豪 這樣論述：

　　中醫藥研究者屠呦呦因受到東晉醫書《肘後備急方》記載： 　　「青蒿一握，以水二升漬，絞取汁，盡服之」之啟發， 　　研發治瘧疾藥「青蒿素」成功，榮獲諾貝爾醫學獎。 　　青蒿因而被譽為「中國神藥」。 　　附最古老醫書《五十二病方》，絕不可錯過。　　 　　 　　青蒿（黃花蒿）的效用不僅抗瘧而已；中醫藥典籍記載，青蒿性味苦、辛、寒；可入肝、膽經、三焦、腎經。功能清透虛熱，涼血除蒸，解暑，截瘧。可用於暑邪或陰虛發熱，夜熱早涼，骨蒸勞熱，瘧疾寒熱，濕熱黃疸。還能辛香透散，為陰虛發熱要藥，兼有解暑退熱作用。 　　現代研究發現，青蒿能提高淋巴細胞的轉化率，增強免疫作用；還可抑菌、消炎，

揮發油還能治皮膚病；但以防癌抗癌作用最受到重視。本書作者為國內最善用青蒿治病者，其臨床經驗值得大家重視。 　　

用於可充放電鋅空氣電池陰極觸媒之研究

為了解決尿素價格的問題，作者郭鈺嗣 這樣論述：

Abstract i摘要 iii誌謝 ivList of Tables ixList of Figures xChapter 1：Introduction 1Chapter 2：Literature Review 42.1 Introduction to Metal air battery 42.2 Structure and working principle of zinc-air battery 52.3 Zinc metal anode: 82.3.1 Zinc alloy 92.3.2 Microstructure of zinc metal 122.4 E

lectrolyte 132.4.1 Aqueous electrolyte 132.4.1.1 Alkaline electrolyte 142.4.1.2 Neutral electrolyte 142.4.1.3 Acid electrolyte 142.4.2 Gel electrolyte 142.4.3 Ionic liquid electrolyte 152.4.4 Solid polymer electrolyte 152.5 Air cathode 162.5.1 Precious metal catalysts 162.5.2 Transition me

tal catalysts and metal-free catalysts 172.5.3 Carbon black supports 202.6 Motivation 24Chapter 3：Experimental 253.1 Equipment 253.2 Experimental materials 263.3 Experimental procedure 273.3.1 Preparation of carbon/metal composite catalyst by oil bath method 273.3.2 Preparation of carbon/met

al composite catalyst for urea treatment 283.3.3 Preparation of carbon/metal composite catalyst by high temperature hydrothermal method 303.3.4 Preparation of NiFe-LDH catalyst 313.3.5 Preparation of air electrode 323.3.6 Water-based zinc-air battery components 333.4 Analysis of cyclic charge a

nd discharge of zinc-air battery 343.5 Material determination method and analysis 353.5.1 X-ray diffraction (XRD) powder diffraction analysis 353.5.2 Scanning electron microscope (SEM) analysis 353.5.3 Energy Dispersive Spectroscopy (EDS) analysis 353-5-4 X-ray photoelectron spectroscopy (XPS)

analysis 353-5-5 Raman spectrometer (RAMAN) analysis 36Chapter 4：Results and discussion 374.1 System 1: Different carbon blacks use oil bath synthesis catalysts 374.1.1 Physical characterization 374.1.1.1 Powder X-ray diffraction (XRD) analysis 374.1.1.2 Raman spectroscopy investigation to var

ious carbon supports 384.1.1.3 Raman spectroscopy analysis to VXC-72R catalyst 414.1.2 Electrochemical zinc-air batteries performance 424.1.3 Summary of system 1: Oil bath synthesis of different carbon black catalysts 494.2 System 2: The impact of urea addition on the catalyst 504.2.1 Material

structure and composition 504.2.1.1 Powder diffraction analysis by X-ray diffractometer (XRD) 504.2.1.2 SEM/EDS analysis 524.2.1.3 X-ray photoelectron spectroscopy (XPS) analysis 544.2.2 Electrochemical zinc-air battery performance 574.2.3 System 2: The impact of urea addition on catalyst summa

ry 654.3 System 3: The influence of different preparation methods on the catalyst 664.3.1 Material structure and composition 664.3.1.1 X-ray diffraction (XRD) powder diffraction analysis 664.3.2 Electrochemical zinc-air batteries performance 674.3.3 System 3: The influence of different preparat

ion methods on catalyst summary 684.4 Summary of systems 1 to 3 694.4.1 Material structure and composition 694.4.1.1 X-ray diffraction (XRD) powder diffraction analysis 694.4.2 Electrochemical zinc-air batteries performance 71Chapter 5：Conclusions and future perspective 745.1 Conclusions 745.

2 Future perspective 76Reference 77