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Structural and Multidisciplinary Optimization
Erschienen in: Structural and Multidisciplinary Optimization 1/2017

18.08.2016 | RESEARCH PAPER

Optimized design of sandwich panels for integral thermal protection systems

verfasst von: Xuewei Fang, Jian Chen, Bingheng Lu, Yiqing Wang, Shanguang Guo, Zhengyi Feng, Minglong Xu

Erschienen in: Structural and Multidisciplinary Optimization | Ausgabe 1/2017

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Abstract

This paper proposes a new ITPS panel with special corrugated-core webs which are designed with cutouts for weight saving. The structural design problem was formulated with mass per unit area of the ITPS as the objective function and some functional requirements as constraints. We developed the optimizer fulfilling both thermal and structural functions for minimal areal density. The optimization problem was solved by interpolating the residual error of response surface approximation (RSA) with Radial Basis Function (RBF) to establish the improved RSA (IRSA). The 400 preliminary design points were obtained using Latin Hypercube Sampling method. The quadratic polynomial RSA of the ITPS sandwich panel performance was generated by the least squares method (LSM) based on finite element results and IRSA was used to optimize the constraints. Transient heat transfer, stress and buckling analyses were conducted using finite element method (FEM). Finally, a new ITPS panel with optimal dimensions was obtained. The optimization results show that the areal density of the new ITPS panel decreases by 26.27 % compared with the previous research, which proves the potential of this new design optimization method for the future spacecraft vehicles.
Vorheriger Artikel Synthesis of auxetic structures using optimization of compliant mechanisms and a micropolar material model
Nächster Artikel Shakedown analysis of circular plates using a yield criterion of the mean

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Literatur
Bapanapalli SK, Martinez OM, Gogu C, Sankar BV, Haftka RT, Blosser ML (2006) Analysis and design of corrugated core sandwich panels for thermal protection systems of space vehicles. AIAA Paper 1942:2006
Blosser ML (1997) Development of metallic thermal protection systems for the reusable launch vehicle. AIP Conf Proc 387(1):1125–1144
Blosser ML (2013) Analytical solution for transient thermal response of an insulated structure. J Thermophys Heat Transf 27(3):422–428CrossRef
Blosser ML, Chen RR, Schmidt IH, Dorsey JT, Poteet CC, Bird, RK (2002) Advanced metallic thermal protection system development. 40th Aerospace Sciences Meeting & Exhibit, Reno, NV, Jan 14–17
Blosser ML, Poteet CC, Chen RR, Dorsey JT, Schmidt IH, Bird RK, Wurster KE (2004) Development of advanced metallic-thermal-protection system prototype hardware. J Spacecr Rocket 41(2):183–194CrossRef
Crittenden PE, Cole KD (2005) Design of experiments for thermal characterization of metallic foam. J Thermophys Heat Transf 19(3):367–374CrossRef
David EM, Martin CJ, Blosser ML (2000) Parametric weight comparison of advanced metallic, ceramic tile, and ceramic blanket thermal protection systems. NASA Technical Memorandum, Paper No. NASA TM-2000-210289
Dorsey JT, Chen RR, Wurster KE, Poteet CC (2004) Metallic thermal protection system requirements, environments, and integrated concepts. J Spacecr Rocket 41(2):162–172CrossRef
Forrester AIJ, Keane AJ (2009) Recent advances in surrogate-based optimization. Prog Aerosp Sci 45(1):50–79CrossRef
Gogu C, Bapanapalli SK, Haftka RT, Sankar BV (2009) Comparison of materials for an integrated thermal protection system for spacecraft reentry. J Spacecr Rocket 46(3):501–513CrossRef
He YR, Wang XZ, Han JC, Liu X, Wu Z (2014) Numerical investigation on actively cooled thermal protection systems with Ni-based alloys. J Propuls Power 30(3):604–616CrossRef
Martinez OA, Sharma A, Sankar BV, Haftka RT, Blosser ML (2010) Thermal force and moment determination of an integrated thermal protection system. AIAA J 48(1):119–128CrossRef
Matsumura T,Haftka RT,Sankar BV (2011) Reliability estimation including redesign following future test for an integrated thermal protection system. 9th World Congress on Structural and Multidisciplinary Optimization, June 13-17, Shizuoka, Japan
Poteet CC, Abu-Khajeel H, Hsu SY (2004) Preliminary thermal-mechanical sizing of a metallic thermal protection system. J Spacecr Rocket 41(2):173–182CrossRef
Rasky DJ, Milos FS, Squire TH (2012) Thermal protection system materials and costs for future reusable launch vehicles. J Spacecr Rocket 38(38):294–296
Sharma A (2010) Multi-fidelity design of an integral thermal protection system for future space vehicle during re-entry. Dissertations & Theses - Gradworks, University of Florida
Sharma A, Gogu C, Martinez OA, Sankar BV, Haftka RT (2008) Multi-fidelity design of an integrated thermal protection system for spacecraft reentry. Forty-Ninth AIAA/ASME/ASCE/AHS/ASC Structures, Structural Dynamics, and Materials Conf., AIAA 2062
Williams SD, Curry DM, Bouslong SA, Rochelle WC (1995) Thermal protection system design studies for lunar crew module. J Spacecr Rocket 32(3):456–462CrossRef
Xie G, Wang Q, Sunden B, Zhang W (2013) Thermomechanical optimization of lightweight thermal protection system under aerodynamic heating. Appl Therm Eng 59(1):425–434CrossRef
Yan C, Meng S, Chen G, Du S (2006) Development of insulations for metallic thermal protection system and its current status. Missiles Space Veh 25(4):48–52
Yang Y, Yang J, Fang D (2008) Research progress on the thermal protection materials and structures in hypersonic vehicles. Appl Math Mech 29(1):51–60 (in Chinese) CrossRefMATH
Yang X, Sun Y, Shi D, Cao F, Feng J (2015) Experimental investigation on mechanical property of an integrated thermal protection structure. Recent Advances in Structural Integrity Analysis-Proceedings of the International Congress (APCFS/SIF 2014). Woodhead Publishing 432
Yao C (2011) Reusable metallic thermal protection system[J]. Aerosp Mater Technol 41(2):1–4
Yao C, Hongjun L, Jia Z, Jia X, Yan L, Li H (2008) A study on metallic thermal protection system panel for Reusable Launch Vehicle. Acta Astronautica 63(1-4):280–284CrossRef
Zhang J, Chowdhury S, Messac A (2012) An adaptive hybrid surrogate model. Struct Multidiscip Optim 46(2):223–238CrossRef
Zhao SY, Li JJ, Zhang CX, Zhang WJ, Lin X, He XD, Yao YT (2015) Thermo-structural optimization of integrated thermal protection panels with one-layer and two-layer corrugated cores based on simulated annealing algorithm. Struct Multidiscip Optim 51(2):479–494CrossRef
Metadaten
Titel
Optimized design of sandwich panels for integral thermal protection systems
verfasst von
Xuewei Fang
Jian Chen
Bingheng Lu
Yiqing Wang
Shanguang Guo
Zhengyi Feng
Minglong Xu
Publikationsdatum
18.08.2016
Verlag
Springer Berlin Heidelberg
Erschienen in
Structural and Multidisciplinary Optimization / Ausgabe 1/2017
Print ISSN: 1615-147X
Elektronische ISSN: 1615-1488
DOI
https://doi.org/10.1007/s00158-016-1560-9

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