Impact of Sandwich Structures
The book focuses on the impact response of lightweight sandwich structures. As a kind of lightweight structure, sandwich structure has been widely used in various engineering fields, such as aerospace, ships, vehicles and so on, because of its high specific stiffness, high specific strength and versatility. During service, the sandwich structures may be subjected to various impact loads, which may result in serious damage, thereby reducing the stiffness, strength and load-bearing ca-pacity, thereby shortening the service life and bringing safety hazards. Therefore, an in-depth understanding of impact behavior and failure mechanisms is of great significance for the wider application of sandwich structures. In the past decades, many scholars have conducted in-depth research on related topics. But it is difficult for readers to systematically read all the literature in a short time. This book seeks to succinctly summarize the development and the results achieved in this field.
This book focuses on simple, classical structures, such as beams, plates, and shells, under loads such as low-velocity impact, explosive load, and bullet penetrations. The main research methods are theoretical analysis, numerical simulation and experimental investigation. The purpose is to reveal the deep mechanism and lay a foundation for the application of sandwich structure in engineering practice.
Sample Chapter(s)
Preface (121 KB)
Components of the Book:
  • About Author
  • Preface
  • Chapter 1. Cellular Material and Sandwich Structure
    • 1.1. Cellular Material
    • 1.2. Sandwich Structure
  • Chapter 2. Low-Velocity Impact of Sandwich Beams
    • 2.1. Low-Velocity Impact of Aluminum Honeycomb Sandwich Beam
    • 2.2. Low-Velocity Impact of Metal Foam Sandwich Beams
    • 2.3. Low-Velocity Impact of Composite Foam Sandwich Beams
    • 2.4. Low-Velocity Impact of Corrugated and Y-Frame Cores Sandwich Beams
  • Chapter 3. Low-Velocity Impact of Sandwich Plates
    • 3.1. Low-Velocity Impact of Metal Honeycomb Sandwich Plates
    • 3.2. Low-Velocity Impact of Metal Foam Sandwich Plates
    • 3.3. Low-Velocity Impact of FRP-Synthetic Foam Sandwich Panels with Lattice Web
    • 3.4. Low-Velocity Impact Response of Curvilinear-Core Sandwich Structures
    • 3.5. Low-Velocity Impact of Sandwich Panels with Lattice Core Reinforcement
  • Chapter 4. Low-Velocity Impact of Sandwich Shells
    • 4.1. Low-Velocity Impact of Curved Sandwich Beams Based on Four-Variable Refined Shear Deformation Theory
    • 4.2. Low-Velocity Impact of Curved Composites Sandwich Plates with Layer-Wise Graded Cores
    • 4.3. Low-Velocity Impact Response of a Curved Sandwich Beam
    • 4.4. Low-Velocity Impact of Composite Sandwich Beams with Various Curvatures and Debonds
    • 4.5. Low-Velocity Impact on Curved Sandwich Beams with FML Face-Sheets and Flexible Core
  • Chapter 5. Blast Loading of Sandwich Beams
    • 5.1. Blast Loading of Metal Sandwich Beams in Small Deflection
    • 5.2. Blast Loading of Metal Sandwich Beams in Large Deflection under Impulsive Loading
    • 5.3. Locally Blast Loading of Metal Foam Sandwich Beams
    • 5.4. Blast Loading of Composite Foam Sandwich Beams
    • 5.5. Blast Response of Sandwich Beams with Thin-Walled Tube-Cores
    • 5.6. Blast Response of Sandwich Beams with Metallic Auxetic Honeycomb Cores
  • Chapter 6. Blast Loading of Sandwich Plates
    • 6.1. Analytical Model for Blast Loading of Rectangular Sandwich Plates
    • 6.2. Experiments for Blast Loading of Rectangular Sandwich Plates
    • 6.3. Blast Loading of Metal Lattice Sandwich Plates
    • 6.4. Blast Loading of Metal Circular Sandwich Plates
    • 6.5. Blast Loading of Composite Sandwich Plates
  • Chapter 7. Blast Loading of Sandwich Shells
    • 7.1. Blast Loading of FG Curved Sandwich Beams with Self-Adapted Auxetic 3D Double-V Meta-Lattice Core
    • 7.2. Blast Loading of Cylindrical Sandwich Shells with Metallic Foam Cores
    • 7.3. Blast Loading of Composite Curved Sandwich Shells
    • 7.4. Blast Loading of Doubly-Curved Sandwich Shells
    • 7.5. Foam Projectile Impact of Sandwich Shells
    • 7.6. Blast Loading of Spherical Sandwich Shells
  • Chapter 8. Ballistic Impact of Sandwich Plates
    • 8.1. Ballistic Impact of Composite Sandwich Panel with Honeycomb Core
    • 8.2. Ballistic Impact of Triangular Corrugated Sandwich Plates
    • 8.3. Ballistic Impact of Multilayer Composite Armor Sandwich Plates
    • 8.4. Ballistic Impact of Layered-Gradient Foam Sandwich Plates
    • 8.5. Ballistic Impact of Sandwich Panel with Functional Graded Face-Sheets and Honeycomb Core
    • 8.6. Ballistic Impact of Circular Sandwich Shell with Aramid and Aluminum Honeycomb Cores
  • Chapter 9. Ballistic Impact of Sandwich Shells
    • 9.1. Ballistic Impact of Cylindrical Sandwich Shell with Uniform Metal Foam Cores
    • 9.2. Ballistic Impact of Cylindrical Sandwich Shell with Gradient Metal Foam Cores
    • 9.3. The Ballistic Impact of Composite Curved Corrugated Sandwich Shell
    • 9.4. The Ballistic Impact of Cylindrical Sandwich Shell with Honeycomb Cores
    • 9.5. The Ballistic Impact of Hemispherical Sandwich Shell with Honeycomb Cores
  • Reference
Readership: Students, academics, teachers and other people attending or interested in impact response of lightweight sandwich structures.
1
About Author
Jianxun Zhang
PDF (93 KB)
2
Preface
Jianxun Zhang
PDF (121 KB)
1
Chapter 1. Cellular Material and Sandwich Structure
Jianxun Zhang
PDF (747 KB)
9
Chapter 2. Low-Velocity Impact of Sandwich Beams
Jianxun Zhang
PDF (2402 KB)
55
Chapter 3. Low-Velocity Impact of Sandwich Plates
Jianxun Zhang
PDF (1999 KB)
99
Chapter 4. Low-Velocity Impact of Sandwich Shells
Jianxun Zhang
PDF (2578 KB)
157
Chapter 5. Blast Loading of Sandwich Beams
Jianxun Zhang
PDF (2827 KB)
205
Chapter 6. Blast Loading of Sandwich Plates
Jianxun Zhang
PDF (2621 KB)
249
Chapter 7. Blast Loading of Sandwich Shells
Jianxun Zhang
PDF (1546 KB)
279
Chapter 8. Ballistic Impact of Sandwich Plates
Jianxun Zhang
PDF (3107 KB)
345
Chapter 9. Ballistic Impact of Sandwich Shells
Jianxun Zhang
PDF (2168 KB)
375
Reference
Jianxun Zhang
PDF (258 KB)
Jianxun Zhang
He is an associate professor in the School of Aerospace Engineering, Xi’an Jiaotong University, China. Currently his research is focused on plastic behavior and impact response of lightweight cellular structures. He has published 80 peer-reviewed research papers in journals such as IJSS, JAM-ASME, MoM, IJIE, CSTE, Compos A, Compos B, IJMS, among which 68 papers are first/corresponding-authored.
This Book

343pp. Published March 2024

Scientific Research Publishing

Category:Engineering

ISBN: 978-1-64997-727-4

(Paperback) USD 35.00

ISBN: 978-1-64997-728-1

(E-Book) USD 9.00

Books by Subjects
Resources
Follow SCIRP
Contact us
book@scirp.org
WhatsApp +86 18163351462(WhatsApp)
Click here to send a message to me 1243940697
Book Publishing WeChat
Copyright © 2006-2024 Scientific Research Publishing Inc. All Rights Reserved.
Top