Numerical Simulation Model of Electrothermal De-Icing Process on Composite Substrate

Abstract A numerical simulation model of electrothermal de-icing process on carbon fiber reinforced polymer (CFRP) composite is conducted to study the effect of thermal properties of the substrate on the ice melting process. A novel melting model which is based on the enthalpy-porosity method is applied to study the transient ice melting process and heat transfer of the de-icing sys-tem. Multi-layered electrothermal de-icing systems including composites with different fiber orientation are used to analyze the effects of orthotropic heat conductivity of the CFRP composite on the ice melting process and heat transfer. Movement of the ice-water interface, the melted zone thickness and the melted zone area on CFRP composite are investigated on the three-dimensional electrothermal de-icing unit. The effects of thermal properties of substrate on the temperature distribution of the ice-airfoil interface are analyzed. The computational results show that the thermal properties of substrates affect the temperature on the ice-airfoil interface, the temperature distribution in the substrate, ice melting area, ice melting rate and ice melting volume significantly. The time that ice starts to melt on the CFRP composite substrate is earlier than that on the metal substrate. However, it takes more time for the ice to melt completely on the ice-CFRP interface than that on the ice-metal inter-face. The orthotropic heat conductivity of CFRP composite results in strong directivity of the melting area on the ice-CFRP in-terface. A ratio parameter is defined to represent the matching degree of substrate materials and geometry model of de-icing system. The simulation model can be applied to study electrothermal de-icing system of nacelle inlet and airfoil made of composite. The results in present work is also helpful to predict the change of temperature during de-icing process and provide guidelines for the optimizing the electrothermal de-icing system to reduce power consumption according to the fiber structure of composite.

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Fundamental Examination of Numerical Simulation Model for Pressure Rise due to Underwater Arc

IEEJ Transactions on Power and Energy ◽

10.1541/ieejpes.134.604 ◽

2014 ◽

Vol 134 (7) ◽

pp. 604-613 ◽

Cited By ~ 3

Author(s):

Toshiya Ohtaka ◽

Tomo Tadokoro ◽

Masashi Kotari ◽

Tadashi Amakawa

Keyword(s):

Numerical Simulation ◽

Simulation Model ◽

Pressure Rise

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Numerical Simulation Model of Dioxin Production in Grate Furnace-Based Municipal Solid Waste Incineration Process

2018 37th Chinese Control Conference (CCC) ◽

10.23919/chicc.2018.8483676 ◽

2018 ◽

Author(s):

Zihao Guo ◽

Jian Tang ◽

Junfei Qiao

Keyword(s):

Numerical Simulation ◽

Municipal Solid Waste ◽

Simulation Model ◽

Solid Waste ◽

Waste Incineration ◽

Municipal Solid Waste Incineration ◽

Incineration Process

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Evaluation of an improvement in runoff control by means of a construction of an infiltration sewer pipe under a porous asphalt pavement

Water Science & Technology ◽

10.2166/wst.1997.0699 ◽

1997 ◽

Vol 36 (8-9) ◽

pp. 397-402

Author(s):

Yasuhiko Wada ◽

Hiroyuki Miura ◽

Rituo Tada ◽

Yasuo Kodaka

Keyword(s):

Numerical Simulation ◽

Simulation Model ◽

Asphalt Pavement ◽

Considerable Effect ◽

Rainfall Infiltration ◽

Sewer Pipe ◽

Porous Asphalt ◽

Runoff Control

We examined the possibility of improved runoff control in a porous asphalt pavement by installing beneath it an infiltration pipe with a numerical simulation model that can simulate rainfall infiltration and runoff at the porous asphalt pavement. From the results of simulations about runoff and infiltration at the porous asphalt pavement, it became clear that putting a pipe under the porous asphalt pavement had considerable effect, especially during the latter part of the rainfall.

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Study on the regional characteristics during foam flooding by population balance model

Energy Exploration & Exploitation ◽

10.1177/0144598720983614 ◽

2020 ◽

pp. 014459872098361

Author(s):

Zhongbao Wu ◽

Qingjun Du ◽

Bei Wei ◽

Jian Hou

Keyword(s):

Numerical Simulation ◽

Simulation Model ◽

Oil Recovery ◽

Population Balance ◽

Growth Zone ◽

Balance Model ◽

Population Balance Model ◽

Liquid Ratio ◽

One Dimensional ◽

Foam Flooding

Foam flooding is an effective method for enhancing oil recovery in high water-cut reservoirs and unconventional reservoirs. It is a dynamic process that includes foam generation and coalescence when foam flows through porous media. In this study, a foam flooding simulation model was established based on the population balance model. The stabilizing effect of the polymer and the coalescence characteristics when foam encounters oil were considered. The numerical simulation model was fitted and verified through a one-dimensional displacement experiment. The pressure difference across the sand pack in single foam flooding and polymer-enhanced foam flooding both agree well with the simulation results. Based on the numerical simulation, the foam distribution characteristics in different cases were studied. The results show that there are three zones during foam flooding: the foam growth zone, stable zone, and decay zone. These characteristics are mainly influenced by the adsorption of surfactant, the gas–liquid ratio, the injection rate, and the injection scheme. The oil recovery of polymer-enhanced foam flooding is estimated to be 5.85% more than that of single foam flooding. Moreover, the growth zone and decay zone in three dimensions are considerably wider than in the one-dimensional model. In addition, the slug volume influences the oil recovery the most in the foam enhanced foam flooding, followed by the oil viscosity and gas-liquid ratio. The established model can describe the dynamic change process of foam, and can thus track the foam distribution underground and aid in optimization of the injection strategies during foam flooding.

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