Robust composite temperature control of electrical tube furnaces by using disturbance observer

“…A tempered glass furnace system was designed using two sliding mode controllers (SMCs) to manage the temperature of the glass plate, the upper and lower walls, and the furnace to a common desired temperature [8]. For the electrical tube furnace (ETF), a robust composite control (RCC) approach offered accurate and reliable temperature tracking performance [9]. On the electric furnace (EF) temperature control (TC) system, the PID accelerated (PIDA) controller design based on the modified flower pollination algorithm (MFPA) [10], an improved approach of extended non-minimal state space (ENMSS) fractional order model predictive control (FOMPC) [11], is tested.…”

Temperature Control of Electric Furnace Using Adaptive Lag Compensator Based on Improved Gorilla Troops Optimization: Towards Energy Efficiency

“…A tempered glass furnace system was designed using two sliding mode controllers (SMCs) to manage the temperature of the glass plate, the upper and lower walls, and the furnace to a common desired temperature [8]. For the electrical tube furnace (ETF), a robust composite control (RCC) approach offered accurate and reliable temperature tracking performance [9]. On the electric furnace (EF) temperature control (TC) system, the PID accelerated (PIDA) controller design based on the modified flower pollination algorithm (MFPA) [10], an improved approach of extended non-minimal state space (ENMSS) fractional order model predictive control (FOMPC) [11], is tested.…”

Temperature Control of Electric Furnace Using Adaptive Lag Compensator Based on Improved Gorilla Troops Optimization: Towards Energy Efficiency

High-precision air temperature control considering both hardware elements and controller design

A two-degree-of-freedom controller for a high-precision air temperature control system with multiple disturbances