Comparison of temperature distribution in FinFETs and GAAFETs based on Dual-Phase-Lag heat transfer model

Abstract The heat conduction performance of the methanol synthesis reactor is significant for the development of large-scale methanol production. The present work has measured the temperature distribution in the fixed bed at air volumetric flow rate 2.4–7 m3 · h−1, inlet air temperature 160–200°C and heating tube temperature 210–270°C. The effective radial thermal conductivity and effective wall heat transfer coefficient were derived based on the steady-state measurements and the two-dimensional heat transfer model. A correlation was proposed based on the experimental data, which related well the Nusselt number and the effective radial thermal conductivity to the particle Reynolds number ranging from 59.2 to 175.8. The heat transfer model combined with the correlation was used to calculate the temperature profiles. A comparison with the predicated temperature and the measurements was illustrated and the results showed that the predication agreed very well with the experimental results. All the absolute values of the relative errors were less than 10%, and the model was veriﬁed by experiments. Comparing the correlations of both this work with previously published showed that there are considerable discrepancies among them due to different experimental conditions. The influence of the particle Reynolds number on the temperature distribution inside the bed was also discussed and it was shown that improving particle Reynolds number contributed to enhance heat transfer in the fixed bed.

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Modeling of Temperature Distribution in Moving Webs in Roll-to-Roll Manufacturing

Journal of Thermal Science and Engineering Applications ◽

10.1115/1.4028048 ◽

2014 ◽

Vol 6 (4) ◽

Cited By ~ 9

Author(s):

Youwei Lu ◽

Prabhakar R. Pagilla

Keyword(s):

Heat Transfer ◽

Temperature Distribution ◽

Thermal Strain ◽

Heat Transfer Model ◽

Operating Conditions ◽

Transfer Model ◽

Roll To Roll ◽

Flexible Material ◽

Process Line ◽

The Web

A heat transfer model that can predict the temperature distribution in moving flexible composite materials (webs) for various heating/cooling conditions is developed in this paper. Heat transfer processes are widely employed in roll-to-roll (R2R) machines that are used to perform processing operations, such as printing, coating, embossing, and lamination, on a moving flexible material. The goal is to efficiently transport the webs over heating/cooling rollers and ovens within such processes. One of the key controlled variables in R2R transport is web tension. When webs are heated or cooled during transport, the temperature distribution in the web causes changes in the mechanical and physical material properties and induces thermal strain. Tension behavior is affected by these changes and thermal strain. To determine thermal strain and material property changes, one requires the distribution of temperature in moving webs. A multilayer heat transfer model for composite webs is developed in this paper. Based on this model, temperature distribution in the moving web is obtained for the web transported on a heat transfer roller and in a web span between two adjacent rollers. Boundary conditions that reflect many types of heating/cooling of webs are considered and discussed. Thermal contact resistance between the moving web and heat transfer roller surfaces is considered in the derivation of the heat transfer model. Model simulations are conducted for a section of a production R2R coating and fusion process line, and temperature data from these simulations are compared with measured data obtained at key locations within the process line. In addition to determining thermal strain in moving webs, the model is valuable in the design of heating/cooling sources required to obtain a certain desired temperature at a specific location within the process line. Further, the model can be used in determining temperature dependent parameters and the selection of operating conditions such as web speed.

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Specific Absorption Rate and Temperature Increase in Human Eye Subjected to Electromagnetic Fields at 900 MHz

Journal of Heat Transfer ◽

10.1115/1.4006243 ◽

2012 ◽

Vol 134 (9) ◽

Cited By ~ 24

Author(s):

Teerapot Wessapan ◽

Phadungsak Rattanadecho

Keyword(s):

Heat Transfer ◽

Temperature Distribution ◽

Electromagnetic Fields ◽

Absorption Rate ◽

Specific Absorption Rate ◽

Heat Transfer Model ◽

Transfer Model ◽

Specific Absorption ◽

Eye Model ◽

Human Eye

Human eye is one of the most sensitive parts of the entire human body when exposed to electromagnetic fields. These electromagnetic fields interact with the human eye and may lead to cause a variety of ocular effects from high intensity radiation. However, the resulting thermo-physiologic response of the human eye to electromagnetic fields is not well understood. In order to gain insight into the phenomena occurring within the human eye with temperature distribution induced by electromagnetic fields, a detailed knowledge of absorbed power distribution as well as temperature distribution is necessary. This study presents a numerical analysis of specific absorption rate (SAR) and heat transfer in the heterogeneous human eye model exposed to electromagnetic fields. In the heterogeneous human eye model, the effect of power density on specific absorption rate and temperature distribution within the human eye is systematically investigated. In particular, the results calculated from a developed heat transfer model, considered natural convection and porous media theory, are compared with the results obtained from a conventional heat transfer model (based on conduction heat transfer). In all cases, the temperatures obtained from the developed heat transfer model have a lower temperature gradient than that of the conventional heat transfer model. The specific absorption rate and the temperature distribution in various parts of the human eye during exposure to electromagnetic fields at 900 MHz, obtained by numerical solution of electromagnetic wave propagation and heat transfer equation, are also presented. The results show that the developed heat transfer model, which is the more accurate way to determine the temperature increase in the human eye due to electromagnetic energy absorption from electromagnetic field exposure.

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Analytical solution of dual-phase-lag based heat transfer model in ultrashort pulse laser heating of A6061 and Cu3Zn2 nano film

Optics & Laser Technology ◽

10.1016/j.optlastec.2020.106207 ◽

2020 ◽

Vol 128 ◽

pp. 106207

Author(s):

Jaideep Dutta ◽

Ranjib Biswas ◽

Balaram Kundu

Keyword(s):

Heat Transfer ◽

Analytical Solution ◽

Pulse Laser ◽

Ultrashort Pulse ◽

Laser Heating ◽

Transfer Model ◽

Phase Lag ◽

Dual Phase ◽

Ultrashort Pulse Laser ◽

Pulse Laser Heating

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Numerical Simulation of Hot Rolled Coil Temperature Field in Hot Coil Box

Advanced Materials Research ◽

10.4028/www.scientific.net/amr.338.572 ◽

2011 ◽

Vol 338 ◽

pp. 572-575

Author(s):

Gui Jie Zhang ◽

Kang Li ◽

Ying Zi Wang

Keyword(s):

Heat Transfer ◽

Numerical Simulation ◽

Temperature Field ◽

Temperature Distribution ◽

Heat Transfer Model ◽

Transfer Model ◽

Coil Temperature ◽

Hot Rolled ◽

Strip Coil ◽

Good Agreement

The heat transfer model was developed and the heat transfer of the strip coil stay in the hot coil box was analyzed. The temperature distribution of the strip coil was investigated use the model. The measured results are in good agreement with the calculated ones, has a guiding significance to further improve the technology.

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Investigation of Heat Diffusion at Nanoscale Based on Thermal Analysis of Real Test Structure

Energies ◽

10.3390/en13092379 ◽

2020 ◽

Vol 13 (9) ◽

pp. 2379 ◽

Cited By ~ 1

Author(s):

Tomasz Raszkowski ◽

Mariusz Zubert

Keyword(s):

Heat Transfer ◽

Numerical Algorithms ◽

Silicon Layer ◽

Heat Transfer Model ◽

Test Structure ◽

Heat Diffusion ◽

Transfer Model ◽

Phase Lag ◽

Bottom Part ◽

Proposed Model

This paper presents an analysis related to thermal simulation of the test structure dedicated to heat-diffusion investigation at the nanoscale. The test structure consists of thin platinum resistors mounted on wafer made of silicon dioxide. A bottom part of the structure contains the silicon layer. Simulations were carried out based on the thermal simulator prepared by the authors. Simulation results were compared with real measurement outputs yielded for the mentioned test structure. The authors also propose the Grünwald–Letnikov fractional space-derivative Dual-Phase-Lag heat transfer model as a more accurate model than the classical Fourier–Kirchhoff (F–K) heat transfer model. The approximation schema of proposed model is also proposed. The accuracy and computational properties of both numerical algorithms are presented in detail.

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