Simulation and validation of air flow and heat transfer in an autoclave process for definition of thermal boundary conditions during curing of composite parts

Bohne, Tobias; Frerich, Tim; Jendrny, J.; Jürgens, Jan-Patrick; Ploshikhin, Vasily

doi:10.1177/0021998317729210

Cited by 24 publications

(32 citation statements)

References 6 publications

Supporting

Mentioning

Contrasting

Order By: Relevance

“…The different temperatures and heating rates were determined by the variation in flow velocity of the air through the mold. Figure 4 a also shows that when the autoclave was pressurized at t = 150 min, the heating rate at each point increased, reflecting the influence of the operating pressure on the heating rate [ 38 ]. The abnormal fluctuation observed at point 15 was due to the failure of the thermocouple; owing to this, point 15 was excluded from the subsequent discussion.…”

Section: Methodsmentioning

confidence: 99%

Influence of Mold and Heat Transfer Fluid Materials on the Temperature Distribution of Large Framed Molds in Autoclave Process

Zhang

Luo

et al. 2021

Materials

View full text Add to dashboard Cite

Massive composite components manufactured by autoclave curing in large framed molds are extensively used in the aerospace industry. The high temperature performance of the large framed mold is the key to achieving the desired composite part quality. This paper explores and summarizes the important thermal properties of metal and heat transfer fluid materials influencing the heating performance of large framed molds, with the aim of improving the mold temperature distribution. Considering the fluid–thermal–solid interaction inside the autoclave, a reliable computational fluid dynamics (CFD) simulation model was developed and verified by a temperature monitoring experiment to achieve the prediction of the temperature distribution of the large framed mold. Then, numerical simulations were designed on the basis of the CFD model, and the single-variable method was used to study the effects of the material thermal properties on the temperature performance of large framed molds. Our simulation predicts that when copper is used as the mold material, the temperature difference decreases by 30.63% relative to that for steel, and the heating rate increases by 3.45%. Further, when helium is used as the heat transfer medium, the temperature difference decreases by 68.27% relative to that for air, and the heating rate increases by 32.76%. This paper provides a reference for improvement of large framed mold manufacturing and autoclave process in terms of heating rate and temperature uniformity.

show abstract

Section: Methodsmentioning

confidence: 99%

Influence of Mold and Heat Transfer Fluid Materials on the Temperature Distribution of Large Framed Molds in Autoclave Process

Zhang

Luo

et al. 2021

Materials

View full text Add to dashboard Cite

show abstract

“…The validation of the CFD simulation of the HTC in an autoclave was carried out according to the results given in [28]. Figure 19 shows the temperature distribution fields on the part surface at different times, corresponding to the thermal cycle areas with a constant air flow temperature (110, 180, 20°С).…”

Section: U-shaped Part With Heat Transfer Coefficient From Cfd Simulationmentioning

confidence: 99%

“…But material model in this research does not take into account the effect of resin chemical shrinkage. Airflow simulation and estimation of convection boundary conditions in autoclave are presented in [27][28][29].…”

Section: Introductionmentioning

confidence: 99%

Method for residual strain modeling taking into account mold and distribution of heat transfer coefficients for thermoset composite material parts

Kiauka

Kasatkin

Tcygantceva

et al. 2021

Int J Adv Manuf Technol

View full text Add to dashboard Cite

The article presents a technique for process-induced residual strain modeling for thermoset composite material parts. The model takes into account the mechanical and thermal contact between the part and the mold. The technique is implemented in the ABAQUS software using user subroutines. Using the technique, it is possible to clarify the distribution of the heat transfer coefficient on the surface of the part and mold using the CFD method. Distribution of heat transfer coefficients are obtained in ANSYS CFX under the appropriate process conditions. The method is verified for the U-shaped sample. Also, the results of modeling the stringer-stiffened curved composite panel using the developed technique without taking into account the mold and heat transfer coefficient distribution are presented.

show abstract

“…It is assumed here that the convective heat transfer coefficient, h = 70 Wm À2 K À1 , was one of the lowest values found in the conducted measurements. 17 The autoclave temperature is assumed to be 20°C higher than the part temperature. In this study, ε 1 = 0.1 was used for the smooth surfaces of the aluminum plate.…”

Section: Cht In Autoclavementioning

confidence: 99%

“…Finally, the transient temperature fields of the calorimeter inside an autoclave are simulated using the CFD-FEM coupled model with two different coupling procedures. For validation of the proposed approach, a comparison of computational results obtained with known experimental data 17 is presented. This simulation approach demonstrates great potential for an industrial application and in a thermal optimization of autoclave processing with reasonable computational cost and accuracy.…”

Section: Introductionmentioning

confidence: 99%

A quasi-transient coupling approach to the modeling of conjugate heat transfer in the autoclave

Zhu¹,

Frerich

Dimassi³

et al. 2021

Journal of Reinforced Plastics and Composites

Self Cite

View full text Add to dashboard Cite

Structural aerospace composite parts are generally cured in an autoclave. To achieve a homogeneous curing, computational fluid dynamics simulations have been increasingly used in thermal optimization. However, a transient computational fluid dynamics simulation of autoclave processing is resource intensive. This article outlines the concept of a quasi-transient coupling strategy to deal with the conjugate heat transfer problem inside an autoclave. In this approach, a computational fluid dynamics model is coupled with a finite element method (FEM) model through incorporating an empirical-based analytic equation, which describes the dependence of the heat transfer coefficient on pressure and temperature, into the computational fluid dynamics computations. This approach bridges the temporal disparities between the fluid and the solid, thus minimizing the global computing time. To validate this method, two simulation cases have been studied. In both cases, two different coupling computations are compared, namely a full-transient simulation as the reference computation and the introduced quasi-transient simulation. First, the quasi-transient coupling approach is implemented by performing the transient heat transfer analysis on a flat plate. The results indicate that this approach can predict accurate transient temperature fields, and the computational effort is reduced by up to 87%. Subsequently, this method is used in a real autoclave and validated by known experimental data. The simulation results are in good agreement with the experimental results, with a mean temperature error lower than 1.9°C. This indicates the capability and efficiency of this approach in solving a conjugate heat transfer problem for autoclave processing.

show abstract

Simulation and validation of air flow and heat transfer in an autoclave process for definition of thermal boundary conditions during curing of composite parts

Cited by 24 publications

References 6 publications

Influence of Mold and Heat Transfer Fluid Materials on the Temperature Distribution of Large Framed Molds in Autoclave Process

Influence of Mold and Heat Transfer Fluid Materials on the Temperature Distribution of Large Framed Molds in Autoclave Process

Method for residual strain modeling taking into account mold and distribution of heat transfer coefficients for thermoset composite material parts

A quasi-transient coupling approach to the modeling of conjugate heat transfer in the autoclave

Contact Info

Product

Resources

About