Planning of numerical and physical experiment in simulation of technological processes

Q3 Materials Science
A. Akberdin, A. S. Kim, R. B. Sultangaziev
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引用次数: 7

Abstract

Technological processes are multifactorial. The choice of the most significant of them for the correct analysis of the object of research is an important task. For such a ranking of factors, researchers usually rely on their own experience or the opinions of specialists in this field, assessing their consistency in terms of mathematical criteria. However, when developing a new process, this approach can not be used. In this case, experimental methods of selecting factors are preferable. But the cost, duration, and sometimes impossibility of using this method is obvious. In this paper we use a different approach. It was considered that thermodynamic modeling is an experiment, but only numerical. Therefore, you can apply it to the method of mathematical design of the experiment, allowing for one calculation to take into account the effect on the objective function of more than a dozen factors. The partial dependencies of the process indices obtained in this case make it possible, without setting up physical experiments, to weed out insignificant factors and leave strong ones, estimating them by the methods of mathematical statistics. Another important advantage of its application is the ability to evaluate the dynamics of changes in phase and elementary products of smelting, process feasibility according to convection and temperature conditions with the control of and mathematical criterion of the acquired data. The method also allows the process to be controlled by all the factors involved, which cannot be met in everyday modeling. For demonstration, this approach was applied during the development of the ferroborone production technology by carbothermic method using local raw materials. Thermodynamic modeling was performed using pre-selected factors. They were also used in physical simulation of the process in a high-temperature furnace. The experiment confirmed significance of the factors, which were chosen theoretically. The use of the planning method also reduced the number of numerical experiments in 25, and physical – in 125 times for predefined data.Using this approach, the authors have made it possible to compare the obtained data with the results of physical experiment to develop measures to approximate practical results to equilibrium ones with the use of strongly acting factor.
工艺过程模拟中数值和物理实验的规划
技术过程是多因素的。选择其中最显著的特征对于正确分析研究对象是一项重要任务。对于这样的因素排名,研究人员通常依靠自己的经验或该领域专家的意见,根据数学标准评估其一致性。但是,在开发新工艺时,不能使用这种方法。在这种情况下,选择因子的实验方法是可取的。但是,使用这种方法的成本、持续时间和有时不可能是显而易见的。在本文中,我们使用了一种不同的方法。热力学模拟被认为是实验,而仅仅是数值模拟。因此,可以将其应用到实验的数学设计方法中,允许一次计算考虑到十几个因素对目标函数的影响。在这种情况下获得的过程指数的部分依赖性使得不需要建立物理实验,就可以通过数理统计的方法来剔除不重要的因素,留下重要的因素。其应用的另一个重要优点是能够根据对流和温度条件对所获得的数据进行控制和数学判据来评估熔炼的相和初级产品的变化动态,以及工艺可行性。该方法还允许由所有相关因素控制过程,这在日常建模中无法满足。为了证明这一点,该方法应用于利用当地原料的碳热法生产硼铁酮技术的开发。热力学建模使用预先选择的因素进行。它们还被用于高温炉过程的物理模拟。实验结果证实了理论选取的影响因素的显著性。规划方法的使用还使预定数据的数值实验次数减少了25次,物理实验次数减少了125次。利用这种方法,作者可以将得到的数据与物理实验结果进行比较,从而利用强作用因子制定将实际结果近似于平衡结果的措施。
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来源期刊
Izvestiya Vysshikh Uchebnykh Zavedenij. Chernaya Metallurgiya
Izvestiya Vysshikh Uchebnykh Zavedenij. Chernaya Metallurgiya Materials Science-Materials Science (miscellaneous)
CiteScore
0.90
自引率
0.00%
发文量
81
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