Soft Computing Model for Inverse Prediction of Surface Heat Flux from Temperature Responses in Short-Duration Heat Transfer Experiments

IF 1.6 4区 工程技术 Q3 ENGINEERING, MECHANICAL
Sima Nayak, Niranjan Sahoo, Masaharu Komiyama
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Abstract

Aerodynamic experiments in high speed flow domain mainly rely on precise measurement transient surface temperatures and subsequent quantification of heat flux. These experiments are mainly simulated in high enthalpy short-duration facilities for which test flow duration are in the order of few milliseconds and the thermal loads resemble the nature of step/impulse. This study focuses on a specially designed fast-response coaxial surface junction thermal probe (CSTP) with capability of capturing transient temperature signals. The short-duration calibration experiments are realized to mimic the simulated flow conditions of high enthalpy test facilities. The classical one-dimensional heat conduction modelling has been used to deduce surface heat flux from the acquired temperature responses. It demonstrates a commendable accuracy of 2.5% when compared with known heat loads of calibration experiment. An advanced soft computing technique, the Adaptive Neuro-Fuzzy Inference System (ANFIS), is introduced for short-duration heat flux predictions. This methodology successfully recovers known (step or ramp) heat loads within a specific experimental time frame (0.2s). The results exhibit excellent agreement in prediction of trend and magnitude, carrying uncertainties of 3% for radiative and 5% for convective experiments. Consequently, the CSTP appears as a rapidly responsive transient heat flux sensor; for real-time short-duration experiments. The soft computing approach (ANFIS) offers an alternative means of heat flux estimation from temperature history irrespective of mode of heat transfer and nature of heat load, marked by its prediction accuracy, diminished mathematical intricacies, and reduced numerical requisites.
根据短时传热实验中的温度响应反向预测表面热通量的软计算模型
高速流动领域的空气动力学实验主要依靠精确测量瞬态表面温度和随后的热通量量化。这些实验主要是在高焓短时设备中模拟进行的,测试流动持续时间为几毫秒,热负荷类似于阶跃/脉冲性质。本研究的重点是专门设计的快速反应同轴表面结热探头(CSTP),它具有捕捉瞬态温度信号的能力。短时校准实验是为了模拟高焓测试设备的模拟流动条件而实现的。经典的一维热传导模型被用来从获取的温度响应中推导出表面热通量。与校准实验的已知热负荷相比,其精确度高达 2.5%,值得称赞。针对短时热通量预测,引入了先进的软计算技术--自适应神经模糊推理系统(ANFIS)。这种方法在特定的实验时间范围内(0.2 秒)成功地恢复了已知(阶跃或斜坡)热负荷。预测结果在趋势和幅度方面表现出极好的一致性,辐射实验的不确定性为 3%,对流实验的不确定性为 5%。因此,CSTP 是一种快速响应的瞬态热通量传感器,适用于实时短时实验。软计算方法(ANFIS)提供了一种从温度历史记录估算热通量的替代方法,无论热传导模式和热负荷性质如何,其特点是预测准确、数学复杂性降低、数值要求减少。
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来源期刊
Journal of Thermal Science and Engineering Applications
Journal of Thermal Science and Engineering Applications THERMODYNAMICSENGINEERING, MECHANICAL -ENGINEERING, MECHANICAL
CiteScore
3.60
自引率
9.50%
发文量
120
期刊介绍: Applications in: Aerospace systems; Gas turbines; Biotechnology; Defense systems; Electronic and photonic equipment; Energy systems; Manufacturing; Refrigeration and air conditioning; Homeland security systems; Micro- and nanoscale devices; Petrochemical processing; Medical systems; Energy efficiency; Sustainability; Solar systems; Combustion systems
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