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Welded High Strength Steel Structures: Mechanical Properties, Welding, and Fatigue Performance

為了解決Structural Engineer 的問題，作者Jiang, Jin,Chiew, Sing Ping,Peng, Zhiwei 這樣論述：

Dr. Jin Jiang is Senior Researcher of Civil Engineering at Nanyang Technological University, Singapore. He also serves as associate director of complex steel structure research center of Guangdong province, China. He was previously served as research engineer at Keppel Offshore & Marine Technology C

enter (KOMTech). He is a technical assessor of Singapore Accreditation Council (SAC). He is a member of American Society of Civil Engineers (ASCE) and Singapore Structural Steel Society. He has delivered many industry and conference lectures and published more than 20 peer-reviewed technical papers

in international journals.

Structural Engineer 進入發燒排行的影片

貨櫃屋建築技術規範之研究

為了解決Structural Engineer 的問題，作者簡明儒 這樣論述：

目錄摘要 ⅠAbstract Ⅱ目錄 Ⅳ圖目錄 Ⅶ表目錄 Ⅸ第一章 緒論 11.1. 研究動機 11.2. 研究目的 11.3. 研究方法 21.4. 論文章節與內容 3第二章 文獻回顧 52.1. 貨櫃建築概述 52.2. 歷年來國內外有關貨櫃建築的研究與探討 132.2.1. 貨櫃概要 142.2.2. 貨櫃建築在環境永續性及可行性的相關研究 152.2.3. 貨櫃建築在結構性能的相關研究 182.2.4. 貨櫃建築在隔熱保溫性能的相關研究 232.2.5. 貨櫃建築在通風、採

光、隔音吸音與防火性能的相關研究 262.3. 國際間有關貨櫃建築技術規範的發展 302.4. 小結 33第三章 中美兩國貨櫃建築技術規範介紹 343.1. 中國貨櫃建築技術規範介紹 353.1.1. 中國貨櫃建築技術規範之總則、術語、符號 353.1.2. 外圍護結構構造、內部構造和內裝修規定 383.1.3. 建築設計、模塊化設計規定 513.1.4. 結構設計基本規定、結構計算、結構節點設計 533.1.5. 地基基礎 623.1.6. 建築防火、防腐蝕、集裝箱式房屋的製作施工及驗收規定 643.2. 美國貨櫃建築技術規範

介紹 703.3. 小結 71第四章 適用於臺灣的貨櫃建築技術規範建議與相關問題探討 734.1. 適用於臺灣的貨櫃建築技術規範建議 734.1.1. 貨櫃建築技術規範總則、專有名詞定義、符號說明建議 734.1.2. 外殼構造、內部構造與內裝修規範建議 754.1.3. 建築設計、模組化設計規範建議 844.1.4. 結構設計基本規定、結構計算、結構節點設計規範建議 854.1.5. 貨櫃建築基礎規範建議 964.1.6. 建築防火、防腐蝕規範建議 974.1.7. 貨櫃建築製作與施工驗收規範建議 1004.2. 貨櫃建築相關

問題的探討 1044.2.1. 貨櫃在投入運輸貨物以外的最早期運用歷史 1044.2.2. 貨櫃建築的優點與缺點 1064.2.3. 貨櫃能堆疊多高 1084.3. 關於貨櫃建築耐風、隔熱保溫的探討 1094.3.1. 貨櫃建築的耐風 1094.3.2. 貨櫃建築的隔熱保溫 1104.4. 典型的模組化貨櫃建築運用實例 1114.4.1. 中國大陸在集裝箱組合房屋與裝配式建築的推廣發展歷程 1134.4.2. 火神山、雷神山醫院的設計與施工 1154.4.3. 火神山、雷神山醫院的設計與施工特點解析 1174.5. 小結

132第五章 結論與建議 1345.1. 結論 1345.2. 建議 136參考文獻 138附錄 162

Scaffolds and Falsework: Constructions, Structural Design, Assessment

為了解決Structural Engineer 的問題，作者Hertle, Robert 這樣論述：

When designing and realizing commercial buildings, plants, bridges, tunnels and other types of engineering constructions as well as when defining constructions sequences in ship yards and process oriented measurements in other industrial branches, it is crucial to take concern of the essential bound

ary conditions resulting from the choice of temporary works equipment, e.g. falsework, formwork and both working and access scaffolds, and protection scaffolds. In addition it is essential to comprehend temporary works equipment as an integral part of the building site technology. An appropriate ana

lysis of the interaction between temporary works equipment and the future construction, considering structural aspects as well as work on site aspects, is essential for the overall success of a project. The European harmonization and standardization process results in updating and modernizing the ge

nerally acknowledged set of technical regulations for temporary works equipment. This book focuses on selected topics of temporary works equipment, especially on structural and safety aspects. It is based on twenty years of experience in planning and consultancy in structural engineering, e.g. bridg

es, industrial plants, temporary structures. The author brings in his background knowledge from the European and German standard committees. Dr.-Ing. Robert Hertle studied structural and civil engineering at the Technical University Munich and gained his doctorate from this university. In 1992 he

founded the Consulting Company Hertle Ingenieure. Robert Hertle is a licensed checking engineer for structural design and a court appointed expert in the fields dynamics, steel construction, falsework and scaffolds. He is member and chairman of national and international working committees on techni

cal standards, e.g. CEN/TC53 Temporary Works Equipment. At the TU Munich he is a Honorary Professor since 2012.

運用仿生支架進行骨軟骨修復組織工程的生物設計策略

為了解決Structural Engineer 的問題，作者Swathi Nedunchezian 這樣論述：

Acknowledgment iii摘要 vAbstract viiList of figures xiii1. Chapter One 1Introduction 11.1 Problem statement 11.1.1 Articular cartilage 31.1.2 Structure and composition of articular cartilage 31.1.3 Articular cartilage defect 51.2. Surgical techniques for cartilage and Osteochondral repair

currently in use 61.2.1 Bone marrow techniques 61.2.2 Mosaiplasty 81.2.3 Autologous chondrocyte implantation method 91.2.4 Matrix induced autologous chondrocyte implantation 111.3. Tissue engineering approaches to Osteochondral defect repair 121.3.1 Scaffold and hydrogel-based cell delivery 1

41.4. Cell source for tissue engineering purposes 161.4.1 Chondrocyte cells 161.4.2 Adult somatic stem cells 171.4.3 Bone marrow-derived stem cell (BMSCs) 181.4.4 Adipose-derived stem cells (ADSCs) 191.5 Scaffolds and hydrogels for tissue engineering 211.5.1 Natural hydrogels in cartilage tiss

ue engineering 251.6. Crosslinking of hydrogel for tissue engineering purpose 291.6.2 Silicon-dioxide Nanoparticle as crosslinkers in tissue engineering 341.6.3 Interaction of SiO2 nanoparticle with adipose-derived stem cells 361.7 Bio ceramics for Osteochondral tissue engineering and regenerati

on 371.7.1 Bio ceramics in Tissue engineering applications 371.7.2 Applications of bioceramics in Osteochondral tissue engineering 391.8 Research Objectives 421.8.1 The specific aims of this thesis are as follows: 43Chapter Two 44Characteristic and chondrogenic differentiation analysis of hybr

id hydrogels comprise of hyaluronic acid methacryloyl (HAMA), gelatin methacryloyl (GelMA), and the acrylate functionalized nano-silica crosslinker 442.1 Introduction 442.2 Materials and methods 522.2.1 Materials 522.2.2 Synthesis of HAMA hydrogel 522.2.4 Synthesis of acrylate functionalized nS

i crosslinker (AFnSi) 532.2.5 Identification of the synthesis HAMA and GelMA 542.2.6 Production of hybrid hydrogels 552.2.7 Identification of the synthesis AFnSi cross-linker 552.2.8 Fabrication of HG hybrid hydrogels 562.2.9.Swelling ratio evaluation 562.2.10 The microstructure morphology ana

lysis 572.2.11 Mechanical properties evaluation 572.2.12 In vitro degradation assay by hyaluronidase 582.2.13 Isolation and culturing of hADSCs 592.2.14 Cell viability assay 602.2.15 Chondrogenic marker gene expression 612.2.15 Quantification of DNA, sGAG deposition and collagen type Ⅱ synthes

is 622.2.16 Statistical analysis 632.3. Results and Discussion 632.3.1.Identification of the synthesis HAMA and GelMA 632.3.2 Identification of the AFnSi crosslinker 672.3.3 Swelling ratio of HG hybrid hydrogels 702.3.4 Morphological examination of HG hybrid hydrogels 722.3.5 Compressive stud

y of HG hybrid hydrogels 752.3.6.Viscoelastic property of HG hybrid hydrogel 782.3.7. Degradation study of HG hybrid hydrogels 812.3.8.Cell viability evaluation of hADSCs on HG hybrid hydrogels 822.3.8. Chondrogenic differentiation ability of HG hybrid hydrogels 852.4. Conclusion 90Chapter Thr

ee 92Multilayer-based scaffold for Osteochondral defect regeneration in the rabbit model 923.1 Introduction 923.2 Materials and methods 963.2.1 Preparation and Characterization of the 3D bioceramic scaffold by DLP method 963.2.2 Cell isolation and culture 973.2.3 Fabrication of the cell-laden

hydrogel/ 3D bioceramic scaffolds mimicking the Osteochondral tissue. 983.2.4 Surgery 983.2.5 Macroscopic Examination 993.2.6 Tissue Processing for paraffin block 993.2.7 Histological and Immunohistochemical Evaluation 1003.2.8 Masson’s trichrome stain 1013.3 Results and discussion 1023.3.1 C

haracterization of the 3D bioceramic scaffold by DLP method 1023.3.2 Fabrication of the hydrogel with hADSCs into the 3D bioceramic scaffold 1043.3.3 In-vivo studies using rabbit as an animal model 1053.3.5 Histological evaluation of neocartilage formation 1073.3.6 Masson’s trichrome staining an

alysis for neocartilage formation 1093.4. Conclusion 110Chapter four 1104.1 General discussion 1124.2 Future work 1134.2.1 Macroscopic Observation of neocartilage formation for 8 weeks 1145.Reference 115