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3D Printing: A Revolutionary Process for Industry Applications [Mīkstie vāki]

(Aeronautics and Astronautics, Jiaotong University, China)
  • Formāts: Paperback / softback, 204 pages, height x width: 229x152 mm, weight: 340 g
  • Izdošanas datums: 09-Jun-2022
  • Izdevniecība: Academic Press Inc
  • ISBN-10: 0323994636
  • ISBN-13: 9780323994637
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  • Cena: 176,96 €
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3D Printing: A Revolutionary Process for Industry ApplicationsPalielināt
  • Formāts: Paperback / softback, 204 pages, height x width: 229x152 mm, weight: 340 g
  • Izdošanas datums: 09-Jun-2022
  • Izdevniecība: Academic Press Inc
  • ISBN-10: 0323994636
  • ISBN-13: 9780323994637
Citas grāmatas par šo tēmu:
Permanent link: https://www.kriso.lv/db/9780323994637.html
Keywords:

3D Printing: A Revolutionary Process for Industry Applications examines how some companies have already adopted 3D printing, gives guidance on critical areas such as manufacturing supply, and traces the lifecycle of 3D printing as well as cost drivers and influences. The author leverages his experience in leading engineering firms to bring together an industry-by-industry guide to the potentials of 3D printing for large-scale manufacturing and engineering. The book provides all the skills and insights that a Chief Engineer would need to address complex manufacturing problems in the real-world using 3D printing technology.

As 3D printing is a rapidly growing area with the potential to transform industries, the potential for large-scale adoption involves complex systems crossing engineering disciplines. In order to use 3D printing to solve manufacturing problems in this context, an array of expertise and knowledge about technology, suppliers, the uses of 3D printing by industry, 3D printing lifecycle and cost drivers must be assembled. This book accomplishes that by introducing 3D printing technology with specific references to 18 industry sectors.

  • Covers a range of 18 industries in forensic detail, giving the 'what, why, when, who, where and how' of 3D printing technology
  • Discusses how large companies have already adopted 3D printing for the design and production of complex parts
  • Gives guidance on essential issues in industry, including manufacturing supply
  • Details the conversion of traditional design and production processes to 3D printing technology
  • Helps companies lower costs and increase product quality through 3D printing
Preface xi
1 Introduction
1(2)
2 3-D printing in the aerospace industry
3(10)
2.1 What
3(4)
2.2 When
7(1)
2.3 Where
8(1)
2.4 Key benefits of additive technologies for aerospace manufacturing
9(1)
2.5 Why
9(1)
2.6 How
10(1)
2.7 Who
10(1)
2.8 3-D bioprinting in space
11(1)
2.9 Construction of structures using 3-D printing
11(1)
2.10 Conclusion
12(1)
References
12(1)
3 3-D printing of airplane parts
13(8)
3.1 3-D printing airplane parts
13(1)
3.2 Advantages
14(1)
3.3 Airplane parts
15(2)
3.4 What
17(1)
3.5 Where
17(1)
3.6 Who
18(1)
3.7 Why
18(1)
3.8 When
18(1)
3.9 How
18(3)
References
19(1)
Further reading
20(1)
4 3-D printing in the auto industry
21(10)
4.1 When: since when has 3-D printing been used in the auto industry
21(1)
4.2 How: how has 3-D printing impacted the racing world?
22(1)
4.3 What: what are the benefits of 3-D materials and technologies?
23(2)
4.4 Why: why should automotive companies use 3-D technology?
25(1)
4.5 Where: where is 3-D printing being used?
26(1)
4.6 Who: who is getting the benefit from 3-D technology?
27(4)
References
29(1)
Further reading
29(2)
5 3-D printing in the chemical industry
31(8)
5.1 Introduction
31(1)
5.2 What
32(1)
5.3 When
33(1)
5.4 Who
33(1)
5.5 Where
34(1)
5.6 How
35(4)
References
38(1)
6 3-D printing in the construction industry
39(8)
6.1 What?
39(1)
6.2 Where?
40(1)
6.3 When?
41(1)
6.4 Why?
42(1)
6.5 How?
43(1)
6.6 Who?
44(3)
References
46(1)
7 3-D printing in dental care
47(12)
7.1 3-D Introduction
47(3)
7.2 How have dentists used 3-D printers?
50(1)
7.3 Capabilities of 3-D printing in dentistry
51(3)
7.4 Benefits of 3-D printing in dentistry
54(1)
7.5 Use of 3-D printing technology in endodontics and periodontics
55(1)
7.6 Advantages of 3-D printing technology in dentistry
55(1)
7.7 Disadvantages of 3-D printing technology in dentistry
55(4)
References
57(2)
8 3-D printing in the drone industry
59(10)
8.1 What
59(2)
8.2 Why
61(1)
8.3 Where
62(1)
8.4 When
63(1)
8.5 How
63(1)
8.6 Who
64(2)
8.7 The specificities of the aeronautics sector
66(1)
8.8 Conclusion
66(3)
References
67(2)
9 3-D printing in education
69(10)
9.1 What
69(1)
9.2 Where
70(2)
9.3 Who
72(1)
9.4 When
72(1)
9.5 Why
73(2)
9.6 How
75(1)
9.7 Conclusion
76(3)
References
77(1)
Further reading
78(1)
10 3-D printing in the fashion industry
79(14)
10.1 Introduction
79(1)
10.2 What
80(1)
10.3 When
80(1)
10.4 Who
80(1)
10.5 Where
81(1)
10.6 How
82(1)
10.7 Apparel: 3-D printing clothes by Danit Peleg
82(1)
10.8 Jacket without seams
83(1)
10.9 Jewelry example: nervous system bracelet
83(1)
10.10 Footwear
83(1)
10.11 Watches
84(1)
10.12 Ornaments
84(1)
10.13 Recent 3-D fashions
84(1)
10.14 Annie Foo, original 3-D printed shoes
84(1)
10.15 Anouk Wipprecht and her Proximity Dress
85(1)
10.16 Ganit Goldstein, custom fashion
85(1)
10.17 Iris Van Herpen, between 3-D printing and nature
86(2)
10.18 Met Gala 2019, the presence of 3-D technologies
88(1)
10.19 Why: importance and future
88(5)
References
91(1)
Further reading
92(1)
11 3-D printing in the food industry
93(10)
11.1 What
93(1)
11.2 How
94(1)
11.3 Why
94(2)
11.4 Who
96(1)
11.5 3-D printing products reduce waste
97(3)
11.6 Conclusion
100(3)
References
101(2)
12 3-D printing in the footwear industry
103(8)
12.1 What
103(1)
12.2 When
104(1)
12.3 Where
104(1)
12.4 Who
105(2)
12.5 Why
107(1)
12.6 How
108(3)
References
110(1)
13 3-D printing in healthcare
111(10)
13.1 How
111(1)
13.2 What
112(1)
13.3 When
113(1)
13.4 Where
114(1)
13.5 How
115(1)
13.6 Why is 3-D printing important in medicine?
116(1)
13.7 Organ transplant
116(1)
13.8 Surgical plan
116(1)
13.9 Temperature and sterilization
116(1)
13.10 Pointed equipment
117(1)
13.11 Function
117(1)
13.12 Porosity
117(1)
13.13 Prosthetic structure
118(1)
13.14 Medical intervention
118(1)
13.15 Countless possibilities
118(1)
13.16 Who
119(1)
13.17 The case of Eric Moger
119(1)
13.18 The case of Kaiba Gionfriddo
119(2)
References
120(1)
Further reading
120(1)
14 3-D printing in the hearing aid industry
121(10)
14.1 Introduction
121(1)
14.2 What
122(2)
14.3 Where
124(1)
14.4 Who
124(1)
14.5 Why
125(3)
14.6 When
128(1)
14.7 How
128(1)
14.8 Conclusion
129(2)
References
129(1)
Further reading
130(1)
15 3-D printing in the maritime industry
131(10)
15.1 What
131(1)
15.2 Prototypes, interiors, spare parts, tools
132(1)
15.3 Large ship parts from industrial 3-D printers
132(1)
15.4 When
133(1)
15.5 Where
133(2)
15.6 Who
135(1)
15.7 Why
136(1)
15.8 How
137(4)
References
139(2)
16 3-D printing in the mechanics industry
141(10)
16.1 What
141(1)
16.2 Why
142(1)
16.3 Where
143(1)
16.4 When
143(3)
16.5 Who
146(1)
16.6 How
147(4)
References
149(2)
17 3-D printing in the movie industry
151(10)
17.1 Introduction
151(1)
17.2 What
151(1)
17.3 Why
152(1)
17.4 When
153(1)
17.5 Who
154(1)
17.6 Where
155(1)
17.7 How
155(3)
17.8 Types of glasses for 3-D
158(1)
17.9 Passive 3-D glasses (anaglyph lenses)
158(3)
References
159(2)
18 3-D printing in the tool and die industries
161(10)
18.1 How
161(1)
18.2 Who
162(1)
18.3 Why
163(1)
18.4 When
164(1)
18.5 Where
165(3)
18.6 Advantages of 3-D printing in tool manufacturing
168(1)
18.7 What
169(2)
References
170(1)
19 3-D printing in the toy industry
171(8)
19.1 What
171(1)
19.2 When
172(1)
19.3 Where
173(1)
19.4 Who
174(1)
19.5 How
175(2)
19.6 3-D printing still faces many technical challenges
177(2)
References
179(1)
20 Summary and conclusion
179(2)
20.1 Summary
179(1)
20.2 Conclusion
179(2)
Index 181
Richard Sheng is Senior Professor in Aeronautics and Astronautics at Shanghai Jiaotong University, China. He holds two doctorates from Pepperdine University and Northcentral University and has two decades' experience with Boeing/McDonnel Douglas in the USA as a Technical Fellow. He currently conducts research at the COMAC Shanghai Aircraft Design Research Institute as a Senior Technical Fellow. His work specializes in organizational and project development, as well as systems engineering, 3D printing and other key areas. He has published numerous papers and holds eight patents. Previously he published System Engineering for Aerospace, with Elsevier's Academic Press (2019).