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航空航天粉末材料及技术(Powder Materials and Technologies in Aerospace Engineering:英文)

航空航天粉末材料及技术(Powder Materials and Technologies in Aerospace Engineering:英文)

书籍作者:彭文飞 ISBN:9787122423603
书籍语言:简体中文 连载状态:全集
电子书格式:pdf,txt,epub,mobi,azw3 下载次数:9151
创建日期:2024-03-23 发布日期:2024-03-23
运行环境:PC/Windows/Linux/Mac/IOS/iPhone/iPad/Kindle/Android/安卓/平板
内容简介

The objective of this book is to systematically describe the application of powder materials in aerospace engineering. It is intended to enable readers to have a deeper understanding of powder materials and their applications, as well as to provide ideas and cases for creating new powder materials and improving existing powder forming technology.
The main contents of this book include basic materials for aerospace, basic principles of powder metallurgy, basic principles of powder metallurgy of nanomaterials, powder metallurgy structural materials, hot resisting materials and materials strong to high-temperature, composite materials, friction materials, special-purpose functional materials, new technologies in powder metallurgy, special applications of metal powders.
The book serves as a reference for teachers, undergraduates, graduate students, scientific researchers and engineering technicians who are engaged in theoretical and technical research in powder metallurgy, material forming, additive manufacturing and other fields.

作者简介

彭文飞,副教授,博士后。主要从事运载工具(汽车、高铁、航空航天)金属与碳纤维零/构件轻量化成形制造的研究工作。主持大型项目4项,其中国家自然科学基金2项,国家政府间交流项目1项,高端外国专家项目1项,省部级项目5项,市厅级项目4项;作为主要成员参加国家973项目1项,国家自然科学基金4项;主持完成横向科研项目3项;共同撰写专著2部;以一作者或通讯作者发表 SCI/EI论文30余篇;获教育部技术发明二等奖1项,浙江省技术发明二等奖1项,中国机械科学技术奖三等奖1项。

编辑推荐

本书正是基于此对航空航天领域粉末材料与技术的应用展开介绍,详细讨论了各种适合航空航天领域的粉末材料及其相关技术。本书有以下几大特色:
(1)本书是作者多年研究成果的总结,介绍新的航空航天领域粉末材料与技术,以期为行业发展提供指导;
(2)本书是英文版著作,以符合国内外有英文需求的相关行业读者的需求;
(3)本书中介绍了部分粉末材料的应用实例,理论与实例相结合,应用指导性强。

前言

The development of aerospace is one of the important symbols of human modernization,and also the embodiment of the national science and technology level and industry level.Materials and aerospace have been developing continuously under mutual promotion, and the application of advanced materials is one of the most important driving forces for the development and progress of aerospace technology. Therefore, aerospace materials are the basis for the technical performance, survivability, life extension and economic affordability of aerospace products, which are key technologies for priority development and key breakthroughs.
Powder metallurgy has made great contributions to the research and development of aerospace materials and complex structural components, which has great potential and competitiveness in aerospace construction. Powder metallurgy is a process technology for preparing metal powder or using metal powder (or a mixture of metal powder and non-metal powder) as raw material, through forming and sintering, to manufacture metal materials, composite materials and various types of products. It has a unique chemical composition and mechanical and physical properties, which cannot be obtained by traditional casting methods. It is common knowledge that the aerospace industry has very strict requirements on material properties. In addition to the materials with the highest stability and specific strength, the materials are usually required to have the highest comprehensive performance. There are two types of powder metallurgy materials used in the aviation industry. One type is special functional materials, such as friction materials, anti-wear materials, sealing materials, filter materials, etc., which are mainly used for auxiliary machines, instruments and airborne equipment of aircraft engines. The other is high-temperature and high-strength structural materials, which are mainly used for important structural components on the main engine of aircraft engines.
The feature of this book is to sort out the types of powder metallurgy materials and their technical application research detailedly. It systematically shows the application and technological progress of powder metallurgy materials in aerospace. The system of powder metallurgy materials is more complete, and the application technology advances with the times. Aerospace powder metallurgy theory and techniques help to address significant needs in aerospace material preparation and processing. We hope the book will be helpful for the development of aerospace powder metallurgy theory and technology and the solution to the major needs of aerospace material preparation and processing.
The content structure of this book is planned by Peng Wenfei. Each chapter is co-written by Peng Wenfei, Moliar Oleksandr, Lin Longfei, Shao Yiyu, Li He and Suo Xinkun of Ningbo University, Trotsan Anatolii and Tishchenko Anton of Ningbo Wuzhong Yuanjing Copper Co., Ltd.
This book is supported by the National Natural Science Foundation of China (No.52075272 and No. 51405248), the Major Special Projects in Ningbo (No. 2019B10100 and No. 2021Z099) and Publishing Fund of Academic Library of Ningbo University. We are grateful to Ninghai Kechuang Group Co., Ltd.—Ningbo University High Performance Lightweight Manufacturing Research Institute, China Research Center of Frantsevich Institute for Problems of Materials Science of Ukrainian National Academy of Sciences and Ningbo Wuzhong Yuanjing Copper Co., Ltd., Part Rolling Key Laboratory of Zhejiang Province, Key Laboratory of Impact and Safety Engineering, Ministry of Education for providing good facilities and conditions for related research.
Due to the rapid development of powder metallurgy science and technology and the limitation of the author's level, there are inevitably some inaccuracies in the book, hoping readers to criticize and correct them.

Peng Wenfei and Moliar Oleksandr

目录

Chapter 1 Basic Materials for Aerospace Engineering 001
1.1 Basic Metal Materials Used in Aerospace Engineering 001
1.2 Approaches to Choosing Constructional Materials for Aircraft 003
1.3 Some Examples of Choosing Materials for Specific Plane Units 005
1.4 Role and Place of Materials in Aerospace Engineering 008

Chapter 2 Introduction to Powder Metallurgy 015
2.1 The Properties of Powders 017
2.1.1 Physical Properties 017
2.1.2 Chemical Properties 019
2.2 Production of Sintered Products 021
2.2.1 Powder Preparation 021
2.2.2 Powder Forming 022
2.2.3 Sintering 026
2.3 Additional Processing of Sintered Products 028

Chapter 3 Basic Principles of Powder Metallurgy of Nanomaterials 031
3.1 General Information 031
3.2 Methods of Obtaining Nanopowders 034
3.3 Size Effects in Nanoparticles 035
3.4 Consolidation of Bulk Nanomaterials 037
3.4.1 Pressing of Nanopowders 037
3.4.2 Sintering 041
3.5 Nano-Oriented Surface Treatment Technology 043

Chapter 4 Sintered Construction Materials 045
4.1 Aluminum Powder Alloys 045
4.2 Titanium Powder Alloys 051
4.3 Magnesium Powder Alloys 055
4.4 Beryllium Powder Alloys 056

Chapter 5 Hot Resisting Materials and Materials Strong to High-Temperature 059
5.1 Refractory Metals and Alloys 060
5.2 Superalloys 063
5.3 Dispersion-Strengthened Materials068
5.4 Metal Refractory Compounds (Intermetallic Compounds)074
5.5 Special Ceramic Materials with High-Temperature Strength 076

Chapter 6 Composite Materials 079
6.1 General Concepts about Composite Materials 079
6.2 Methods of Obtaining Composite Materials 081
6.3 Metal Constructional Composite Materials 082
6.4 Heat-Resistant Composite Materials 085

Chapter 7 Materials for Friction Joints 092
7.1 Introduction to Tribology 092
7.1.1 Basic Terms of Tribology 093
7.1.2 Some Examples of the Influence of Friction on the Operation of Mechanisms 096
7.2 Antifriction Powder Materials 098
7.2.1 Bearing Iron-Based Materials100
7.2.2 Copper Based Materials102
7.2.3 Metal-Polymeric Bearing Materials 104
7.2.4 Nickel-Based Materials 107
7.3 Frictional Powder Materials108
7.3.1 Copper Based Friction Materials 110
7.3.2 Iron-Based Friction Materials 110
7.3.3 Cermets for Aircraft Brakes 112
7.3.4 Composite Materials with Carbon and Ceramic Matrix 113

Chapter 8 Special-Purpose Functional Materials 117
8.1 Concept of Functional Materials, and Their Roles in Engineering 117
8.2 Heavy Alloys 118
8.3 Porous Permeable Materials120
8.3.1 Filters 120
8.3.2 Porous Ionizers 123
8.3.3 Sweating Materials 124
8.3.4 Self-Cooling Sweating Materials 126
8.3.5 Capillary Structures of Heat Pipes 128
8.3.6 Porous Electrodes for Fuel Cells 131
8.4 Stalant Materials 131
8.5 Powder Materials for Electrical and Radio Technical Purposes 134
8.5.1 Optical Ceramics 134
8.5.2 Radio Transparent Materials 140
8.5.3 Magnetic Materials 146

Chapter 9 New Technologies in Powder Metallurgy 150
9.1 Nanomaterials and Nanotechnology 150
9.2 Additive Technology 162
9.3 Severe Plastic Deformation of Sintered Billets 173
9.4 Self-Propagation High-Temperature Synthesis 176
9.5 Metal Injection Molding (Casting) 184

Chapter 10 Special Applications of Metal Powders 189
10.1 Powder Solders 189
10.2 Metal Fuel 191
10.3 Magnetic Fluid 198
10.4 Powders for Magnetic Abrasive Processing 201

Appendix 204

Reference 206

短评

航空航天领域) 航空航天领域的粉末材料及其技术应用非常广泛,如制造高温合金、陶瓷材料、涂层、监测系统以及增材制造等方面都有很大应用。以下是航空航天粉末材料及技术的一些例子: 1. 高温合金粉末制造:高温合金是航空发动机及涡轮机等高温工作部件的基础材料。通过粉末冶金技术,可以制造出具有良好耐热、耐腐蚀、抗氧化等性能的高温合金,如镍基合金、钴基合金等。 2. 陶瓷材料制造:陶瓷材料可以用于航空航天领域中的高温部件、热障涂层、陶瓷合金等方面。粉末冶金技术可以制造出高品质的陶瓷粉末,例如氧化铝粉末、氮化硅粉末等,这些粉末可用于制造高强度的陶瓷材料。 3. 涂层制造:航空航天领域需要涂层来保护部件不受高温、氧化、腐蚀等腐蚀性物质的侵蚀。粉末冶金技术可以制造出具有高纯度和细度的涂层材料粉末,例如多孔无机涂层、金属粉末涂层等。 4. 监测系统制造:航空航天领域需要使用高性能的传感器进行监测,例如温度、压力、振动等参数。粉末冶金技术可以制造出微型传感器,它具有小尺寸、高精度、多通道等优点。 5. 增材制造:使用3D打印技术,可以将粉末材料直接加工成为具有复杂形状的组件。航空航天领域需要使用高性能的增材制造材料,例如高强度、低密度的钛合金粉末、高硬度的陶瓷粉末等。 总之,航空航天领域利用粉末材料及其技术可以制造出高性能、耐高温、腐蚀性能好的材料用于制造高端航空发动机、航空器等产品,提高整个行业的安全性、可靠性、环保性。

2023-04-09 07:15:03

) 航空航天粉末材料及技术是指用于航空航天领域的粉末制造和应用技术。这些材料包括金属、陶瓷、复合材料、高分子材料等,可以用于制造航空发动机、飞机结构、卫星、宇宙飞船等航空航天器件和设备。 粉末冶金技术是航空航天粉末材料制备中最常用的技术之一。这种技术利用金属、陶瓷等粉末在高温下烧结或者热压来制造零件或器件。粉末冶金技术的优点在于可以制造复杂形状、高强度、高温耐受和耐腐蚀的零件。 在航空航天领域,还广泛使用3D打印技术制造精密部件。这种技术可以在不需要模具的情况下直接打印出3D零件,节约了制造成本和时间。 此外,纳米技术也越来越受到航空航天工业的关注。纳米粉末有着更高的比表面积和更优异的性能,可以被用于制造高性能的航空航天材料。 总之,航空航天粉末材料及技术的发展,为航空航天工业的高效、高质量生产提供了强有力的支持。

2023-04-09 07:15:03

航空航天领域) 航空航天粉末材料及技术是航空航天领域重要的研究领域之一。粉末冶金技术、粉末喷涂技术、粉末成型技术等是其中的代表。 粉末冶金技术将金属、合金等物质粉末进行加工,制成具有特定性能和形状的零部件,广泛应用于航空航天领域。粉末冶金材料具有高强度、高温耐性、耐磨性等特点,是航空发动机零部件、导弹零部件等重要材料。 粉末喷涂技术可以将粉末材料喷涂到航空发动机及航天器表面,形成一层保护层。这些保护层可以起到隔热、抗氧化、耐腐蚀等作用,保护设备免受高温、高压和化学腐蚀的破坏。 粉末成型技术可以将粉末材料按模具形状成型,制成复杂零部件,用于各种航空航天设备和器材的生产中。 总之,航空航天粉末材料及技术在航空航天领域中具有重要的应用价值。随着技术的不断发展,它将继续为航空航天产业的发展和进步做出贡献。

2023-04-09 07:15:03