Studying the Temperature Operating Conditions of Vacuum Electrical Resistance Furnace Structural Elements Using the Structural Mathematical Modeling Method

Authors

  • Михаил [Mikhail] Яковлевич [Ya.] Погребисский [Pogrebisskiy]
  • Виктор [Viktor] Петрович [P.] Рубцов [Rubtsov]
  • Эльмира [Elmira] Фёдоровна [F.] Сальманова [Salmanova]

DOI:

https://doi.org/10.24160/1993-6982-2019-4-101-109

Keywords:

vacuum resistance furnace, Tamman furnace, temperature operating conditions, unsteady processes, structural modeling, control system, temperature sensor location

Abstract

The article demonstrates the importance of developing a structural mathematical model of a high-temperature vacuum electrical resistance furnace (ERF) for studying the thermal processes in it with determining the temperature of each furnace element, predicting the service life of heating elements, screens, and other furnace structural elements, selecting the temperature sensor installation place, and making relevant adjustment of the temperature control system.

The commonly used model, in which the furnace is represented by a first-order inertial section, does not provide such possibility, because the furnace average temperature is calculated in that case. Therefore, it is necessary to construct a model based on the energy balance equations for macro elements (heater, each of the screens, loading, etc.) taking into account radiant heat transfer between the macro elements.

A mathematical structural model of a Tamman vacuum high-temperature electric furnace equipped with a heater in the form of a coal or graphite pipe and thermal insulation in the form of graphite cylinders-screens has been developed and implemented in the Simulink software package. The thermal resistance of graphite screens thermal conductivity, which is commonly neglected in design calculations of widely used thin metal screens, was taken into account in simulating the thermal processes.

The temperature operating conditions of individual structural elements (heaters, screens, etc.) are analyzed, both at constant power supply voltage of the heaters and in using a closed-loop temperature control system. The effect the temperature sensor installation place has on the automatic temperature control quality is shown. The advisability of using the developed model for adjusting the proportional-integral-differential controller to ensure the required control quality is substantiated.

Author Biographies

Михаил [Mikhail] Яковлевич [Ya.] Погребисский [Pogrebisskiy]

Ph.D. (Techn.), Assistant Professor of Electric Supply of Industrial Enterprises and Electrical Engineering Dept., NRU MPEI, e-mail: PogrebisskiyMY@mpei.ru

Виктор [Viktor] Петрович [P.] Рубцов [Rubtsov]

Dr.Sci. (Techn.), Professor of Electric Supply of Industrial Enterprises and Electrical Engineering Dept., NRU MPEI, e-mail: RubtsovVP@mpei.ru

Эльмира [Elmira] Фёдоровна [F.] Сальманова [Salmanova]

Ph.D.-student  of  f  Electric  Supply  of  Industrial  Enterprises  and  Electrical  Engineering Dept., NRU MPEI, e-mail: efs2009@ya.ru

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Для цитирования: Погребисский М.Я., Рубцов В.П., Сальманова Э.Ф. Исследование температурного режима элементов конструкции вакуумной электропечи сопротивления методом структурного математического моделирования // Вестник МЭИ. 2019. № 4. С. 101—109. DOI: 10.24160/1993-6982-2019-4-101-109.

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Published

2019-08-22

Issue

No. 4 (2019): Bulletin № 4

Section

Electrotechnology (05.09.10)