Heat transfer property of C/SiC composite pyramidal lattice core sandwich structures

Wang, Xiaohong; Zhong, Zhiqiang; Zeng, Tao; Xu, Genqi; Cui, Yuhua; Zhang, Kun

doi:10.1016/j.compstruct.2022.116215

Cited by 10 publications

(2 citation statements)

References 19 publications

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“…In recent years, the thermal analysis of sandwich structures has become a hot issue. Kantha [1] et al conducted a thermal analysis of honeycomb sandwich panels using the finite element method; Fazzolari [2] et al investigated the effect of temperature distribution along the thickness direction on the thermal stability of sandwich panels made of functional gradient materials; Zhang [3] et al experimentally investigated the effect of high temperature on the stability of sandwich structures; Cheng [4] et al analyzed the one-dimensional thermal conductivity of lattice-core sandwich structures perpendicular to the plane direction and established a theoretical model to predict the equivalent thermal conductivity; Xi [5] et al investigated the effect of temperature on the penetration behavior of aluminum foam sandwich panels through numerical simulations; Wang [6] et al prepared a sandwich structure composite material with composite core and C/SiC laminates that can effectively control the heat radiation; Wei [7] et al investigated the heat transfer mechanism of ZrO2 and ZrB2 corrugated sandwich structures; Protsenko [8] et al experimentally investigated the effect of heat treatment on the physical and mechanical properties of sandwich structures; Li [9] et al developed an equivalent thermal conductivity prediction method and numerically analyzed the heat transfer behavior of an integrated thermal protective system with a C/SiC composite corrugated-core sandwich structure; Le [10] et al proposed a bionic corrugated-core sandwich structure and performed a thermodynamic analysis; Qi [11] et al presented a thermodynamic analysis of an integrated corrugated-core sandwich structure composed of GNP Ni and CNT with excellent electromagnetic shielding capability; Yuan [12] et al designed an experimental setup to evaluate the effective thermal conductivity of metal honeycomb sandwich structures at different temperatures; Shi [13] et al designed an all-composite sandwich structure with corrugated core and developed a one-dimensional analytical model and a two-dimensional finite element model for heat transfer analysis; Wang [14] et al proposed an analytical model for predicting the equivalent thermal conductivity of sandwich structures with pyramidal lattice cores of C/SiC composites, and investigated the heat transfer properties; Xiao [15] et al proposed an open-cell metal-foam corrugated sandwich structure, and investigated its heat transfer properties.…”

Section: Introductionmentioning

confidence: 99%

Study of temperature conduction processes in sandwich structures

Zou,

Chang,

et al. 2024

J. Phys.: Conf. Ser.

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The sandwich structure is a common protective design that has been extensively used in the field of protection, but few studies have been done on its multilayer temperature conduction characteristics. Based on one typical sandwich protective structure, a temperature conduction model is established. The IMEX method is used to solve the established model, and then the attenuation rate of the temperature field with changes in the protective structure’s dimensions is theoretically calculated. Simultaneously, a simulation experimental platform is set up, and temperature conduction experiments are conducted. The results show that the theoretical model could describe the temperature conduction process of the sandwich structure, and the experimental results are in good agreement with the theoretical calculations; when the structural parameters are fixed, the temperature of each layer of the material increased gradually with time and finally tended to be stabilized. The rate of change of temperature is the largest in 0 s ~ 200 s; when the parameters are fixed in time, the temperature decreases gradually with the change of spatial position and finally tends to be stabilized. The thermal conduction rate of each layer of the material determines its change. The temperature change rate of the heat insulation layer and air layer is relatively high. The research can provide support and reference for the design of sandwich temperature protection structures.

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Section: Introductionmentioning

confidence: 99%

Study of temperature conduction processes in sandwich structures

Zou,

Chang,

et al. 2024

J. Phys.: Conf. Ser.

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“…Honeycomb lattices enhancing the heat transportation of nanoparticles have been investigated showing good results 9 . A predictive model for heat flow around a C/SiC composite pyramidal lattice structure is proposed by Wang et al 10 . Furthermore, effect of lattice presence in tubes on fluid flow and heat transfer enhancement, particularly with supercritical CO2, have been explored by Shi et al 11 .…”

Section: Introductionmentioning

confidence: 99%

Strain-based method for fatigue failure prediction of additively manufactured lattice structures

Coluccia,

De Pasquale

2023

Sci Rep

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Lattice structures find application in numerous technological domains, including aerospace and automotive industries for structural components, biomedical sector implants, and heat exchangers. In many instances, especially those pertaining to structural applications, fatigue resistance stands as a critical and stringent requirement. The objective of this paper is to advance the analysis of fatigue failure in additively manufactured lattice structures by introducing a predictive fatigue failure model based on the finite element (FE) method and experimentally validating the results. The model utilizes linear homogenization to reduce computational effort in FE simulations. By employing a strain-based parameter, the most critical lattice cell is identified, enabling the prediction of fatigue crack nucleation locations. The Crossland multiaxial fatigue failure criterion is employed to assess the equivalent stress, furnishing the fatigue limit threshold essential for predicting component failure. Inconel 625 specimens are manufactured via the laser-based powder bed fusion of metals additive manufacturing process. In order to validate the model, cantilevers comprising octa-truss lattice cells in both uniform and graded configurations undergo experimental testing subjected to bending loads within the high cycle fatigue regime. The proposed methodology effectively forecasts the location of failure in seventeen out of eighteen samples, establishing itself as a valuable tool for lattice fatigue analysis. Failure consistently manifests in sections of uniform and graded lattice structures characterized by the maximum strain tensor norm. The estimated maximum force required to prevent fatigue failure in the samples is 20 N, based on the computed Crossland equivalent stress.

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