本书梳理、总结了复合材料夹芯结构领域的部分科研内容，全书共七章，主要内容包括：复合材料夹芯结构的基本概念，泡沫、木材夹芯复合材料结构的受力性能与设计方法，复合材料夹芯结构的工程应用。较系统地介绍了复合材料夹芯结构梁、板、柱等基本构件的静力、疲劳、蠕变性能和压缩吸能机理，并选取典型工程案例，对复合材料夹芯结构体系的应用现状作了详细介绍。本书结构条理清晰，内容兼具前沿性与实用性。本书可供土木工程、复合材料力学及相关专业的高年级本科生、研究生以及从事复合材料结构设计及研究的工程技术人员参考。

Preface
1 Introduction
1.1 Application of FRP composites in civil infrastructure
1.2 Research status of composite sandwich structure
1.2.1 Static behavior
1.2.2 Fatigue behavior
1.2.3 Creep behavior
1.2.4 Energy absorption behavior
References
2 Flexural properties of foam core sandwich structures
2.1 Flexural behavior of hybrid composite beams with a bamboo layer and lattice ribs
2.1.1 Material characterization
2.1.2 Experimental programme
2.1.3 Analysis and discussion
2.1.4 Summary
2.2 Nonlinear flexural properties of lattice-web reinforced foam core sandwich panels
2.2.1 Experimental program
2.2.2 Experimental results and discussion
2.2.3 Finite element analysis
2.2.4 Parametric studies
2.2.5 Summary
References
3 Static properties of wood core sandwich structures
3.1 Flexural properties of sandwich panels with web reinforced wood core
3.1.1 Experimental program
3.1.2 Experimental results and discussion
3.1.3 Analytical modeling
3.1.4 FE modeling
3.1.5 Summary
3.2 Flexural properties of innovative GFRP-bamboo-wood sandwich beams -.
3.2.1 Experimental program
3.2.2 Experimental results of flexuralbehavior
3.2.3 Analytic and finite element modeling
3.2.4 Design optimization
3.2.5 Summary
3.3 Compressive properties of wood-filled GFRP square columns
3.3.1 Experimental programme
3.3.2 Experimental results and discussions
3.3.3 Analysis and comparison of the experimental results
3.3.4 Summary
References
5 Fatigue properties of composite sandwich structures
4.1 Fatigue properties of GFRP-balsa sandwich beams
4.1.1 Materials and specimens
4.1.2 Static bending experimental study
4.1.3 Fatigue bending experimental study
4.1.4 Proposition and verification of the fatigue damage model
4.1.5 Summary
4.2 Fatigue properties of lattice-web reinforced GFRP-balsa sandwich beams
4.2.1 Experimental programs
4.2.2 Experimental results
4.2.3 Fatigue cumulative damage model
4.2.4 Fatigue damage and life prediction
4.2.5 Summary
References
5 Creep properties of composite sandwich beams
5.1 Flexural creep behavior and life prediction of GPRP-balsa sandwich beams
5.1.1 Materials and specimens
5.1.2 Static three-point bending tests
5.1.3 Flexure creep tests
5.1.4 Fitting and prediction
5.1.5 Summary
5.2 Flexural creep behavior of web reinforced GFRP-balsa sandwich beams:Experimental investigation and modeling
5.2.1 Experimental section
5.2.2 Experimental results
5.2.3 Discussion
5.2.4 Summary
References
6 Energy absorption properties of composite sandwich structures 2
6.1 Energy absorption of foam-filled lattice composite cylinders under lateral compressive loading
6.1.1 Materials and methods
6.1.2 Experimental results and discussion
6.1.3 Finite element modelling
6.1.4 Parametric study
6.1.5 Summary
6.2 The energy absorption behaviour of novel foam-filled sandwich composite panels reinforced by trapezoidal latticed webs
6.2.1 Experimental program
6.2.2 Experimental results and discussion
6.2.3 Finite element modelling
6.2.4 Parametric study
6.2.5 Finite element analysis of composite anti-collision device for Wuhu Yangtze River Bridge
6.2.6 Summary
References
7 Engineering application of composite sandwich structures 2
7.1 Frame assemblies in port regions
7.2 FRP composite bumper systems for bridge piers
7.2.1 Fixed composite bumper system
7.2.2 Floating composite bumper system
7.2.3 Large-scale floating composite bumper system
7.3 Floating FRP structures for supporting solar panels
7.4 Pavement mats for emergency
7.5 Building floor
7.6 Summary
References