[1] Wang X M, Su Y D, Wu B et al. Application for additive manufacturing of lattice materials on integrated aircraft structures and functions[J]. Aeronautical Manufacturing Technology, 61, 16-25(2018).
[2] Zhu J H, Zhou H, Wang C et al. Status and future of topology optimization for additive manufacturing[J]. Aeronautical Manufacturing Technology, 63, 24-38(2020).
[3] Cheng L, Liu J K, Liang X et al. Coupling lattice structure topology optimization with design-dependent feature evolution for additive manufactured heat conduction design[J]. Computer Methods in Applied Mechanics and Engineering, 332, 408-439(2018).
[4] Zheng Q, Ji B, Li H et al. Compressive behavior of sandwich panels with multilayer pyramidal truss cores by additive manufacturing[J]. Journal of Aeronautical Materials, 38, 77-82(2018).
[5] Zhang N. Thermo-mechanical performance of micro-truss sandwiched panel with flow channels made by 3D printing[D](2016).
[6] Tian J, Lu T J, Hodson H P et al. Cross flow heat exchange of textile cellular metal core sandwich panels[J]. International Journal of Heat and Mass Transfer, 50, 2521-2536(2007).
[7] Lu T J, Valdevit L, Evans A G. Active cooling by metallic sandwich structures with periodic cores[J]. Progress in Materials Science, 50, 789-815(2005).
[8] Kim T. Fluid-flow and heat-transfer in a lattice-frame material[D](2004).
[9] Kim T, Hodson H P, Lu T J. Fluid-flow and end wall heat-transfer characteristics of an ultralight lattice-frame material[J]. International Journal of Heat and Mass Transfer, 47, 1129-1140(2004).
[10] Kim T, Hodson H P, Lu T J. Pressure loss and heat transfer mechanisms in a lattice-frame structured heat exchanger[J]. Proceedings of the Institution of Mechanical Engineers, Part C: Journal of Mechanical Engineering Science, 218, 1321-1336(2004).
[11] Kim T, Hodson H P, Lu T J. Contribution of vortex structures and flow separation to local and overall pressure and heat transfer characteristics in an ultralightweight lattice material[J]. International Journal of Heat and Mass Transfer, 48, 4243-4264(2005).
[12] Wen T, Tian J, Lu T J et al. Forced convection in metallic honeycomb structures[J]. International Journal of Heat and Mass Transfer, 49, 3313-3324(2006).
[13] Luo S K, Song H W, Huang C G et al. Thermal-fluid-solid coupling analysis of light-weight actively cooled panel with lattice-framed material[J]. Structure & Environment Engineering, 39, 31-40(2012).
[14] Lundgren J, Klarbring A, Lundgren J E et al. Topology optimization of periodic 3D heat transfer problems with 2D design[J]. Structural and Multidisciplinary Optimization, 60, 2295-2303(2019).
[15] Wu S H, Zhang Y C, Liu S T. Topology optimization for minimizing the maximum temperature of transient heat conduction structure[J]. Structural and Multidisciplinary Optimization, 60, 69-82(2019).
[16] Guo K, Qi W Z, Liu B T et al. Optimization of an “area to point” heat conduction problem[J]. Applied Thermal Engineering, 93, 61-71(2016).
[17] Jin L T. Experimental study on flow and heat transfer of truss structure heat exchanger[D](2019).
[18] Chadwick S S. Ullmann’s encyclopedia of industrial chemistry[J]. Reference Services Review, 16, 31-34(1988).
[19] Helou M, Kara S. Design, analysis and manufacturing of lattice structures: an overview[J]. International Journal of Computer Integrated Manufacturing, 31, 243-261(2018).
[20] Wadley H N G, Queheillalt D T. Thermal applications of cellular lattice structures[J]. Materials Science Forum, 539/540/541/542/543, 242-247(2007).
[21] Saltzman D, Bichnevicius M, Lynch S et al. Design and evaluation of an additively manufactured aircraft heat exchanger[J]. Applied Thermal Engineering, 138, 254-263(2018).
[22] Yang G, Hou C, Zhao M et al. Comparison of convective heat transfer for Kagome and tetrahedral truss-cored lattice sandwich panels[J]. Scientific Reports, 9, 3731(2019).
