Your search keyword '"Heat generation"' showing total 15,130 results

1. Numerical study of hybrid nanofluid and thermal transport in sun-powered energy ship within the application of parabolic trough solar collectors

Author

Obalalu, A.M., Fatunmbi, E.O., Madhukesh, J.K., Shah, S.H.A.M., Khan, Umair, Ishak, Anuar, and Muhammad, Taseer

Published

2024

2. Stagnation point flow of third-order nanofluid towards a lubrication surface using hybrid homotopy analysis method.

Author

Ahmad, M., Bashir, Basharat, Muhammad, Taseer, Taj, M., and Faisal, Muhammad

Subjects

*STAGNATION point, *BROWNIAN motion, *HEAT transfer, *ORDINARY differential equations, *BOUNDARY layer (Aerodynamics)

Abstract

In recent times, the interaction of nanoparticles has significantly enhanced the thermal association of heat transport. This phenomenon plays a crucial role in hydraulic systems, particularly in the context of lubrication and its associated consequences on mass and heat transport. Current studies have focused on investigating the thermal effects of a third-order nanofluid on a lubricated stretched surface near an analytical stagnation point. The lubrication process involves the use of a thin, adjustable coating of lubricant fluid. To analyze this complex system, we employ the Buongiorno model and explore thermophoresis and the Brownian motion phenomenon. For deriving analytical results of updated boundary layer ordinary differential equations, we rely on the dependable and effective hybrid homotopy analysis method (HHAM). To exhibit the effectiveness of our study, we provide a numerical comparison. Based on theoretical flow assumptions, we establish a range of flow parameters. In the presence of lubrication, we physically examine how these parameters affect temperatures, velocities, concentration, and other relevant quantities of thermal interest. These new findings have practical applications in polymer production, heat transmission, and hydraulic systems. [ABSTRACT FROM AUTHOR]

Published

2024

3. The association of maintenance hormone therapy with overall survival in advanced-stage low-grade serous ovarian carcinoma: A risk-set matched retrospective study.

Author

Barakzai, Syem K., Bregar, Amy J., del Carmen, Marcela G., Eisenhauer, Eric L., Goodman, Annekathryn, Rauh-Hain, Jose A., Gockley, Allison A., and Melamed, Alexander

Subjects

*PROPENSITY score matching, *HORMONE therapy, *ACADEMIC medical centers, *OVERALL survival, *ELECTROCHEMISTRY, *OVARIAN cancer

Abstract

We conducted a multi-institutional observational study to investigate whether maintenance hormone therapy following primary treatment of low-grade advanced-stage ovarian cancer (LGSOC) is associated with an overall survival advantage. We included patients with histologically confirmed stage III or IV LGSOC diagnosed between Jan 1, 2004, and Dec 31, 2019, treated in Commission on Cancer-accredited cancer programs in the US. Patients who received hormone therapy within six months of diagnosis were matched to controls who did not initiate hormone therapy during this timeframe by risk-set propensity score matching. The primary outcome was the risk of death from any cause within five years of initiation of HT or observation. There were 296 patients who initiated maintenance hormone therapy within six months of diagnosis and 2805 potential controls. Patients who received hormone therapy were more often treated in academic medical centers (55% vs. 44%), diagnosed later in the study period (62% vs. 23% diagnosed in 2018–2019), and frequently received no chemotherapy during initial treatment (45% vs. 17%). After risk set propensity score matching, we identified 225 patients treated with HT and 225 untreated controls who were otherwise similar with respect to measured covariates. In the matched cohort, hormone therapy was associated with a reduction in the risk of death (hazard ratio 0.60; 95% CI 0.38–0.94), corresponding to a 60-month survival of 75% compared with 65%. Following primary management of LGSOC, maintenance hormone therapy was associated with improved overall survival compared with observation. • Hormone maintenance therapy for low-grade serous carcinoma has increased substantially since 2004. • Hormone maintenance therapy for low-grade serous carcinoma is associated with an overall survival benefit. • An ongoing trial will assess the therapeutic benefit of hormone therapy in patients with low-grade serous carcinoma. [ABSTRACT FROM AUTHOR]

Published

2024

4. Advancements in Numerical Solutions: Fractal Runge-Kutta Approach to Model Time-Dependent MHD Newtonian Fluid with Rescaled Viscosity on Riga Plate.

Author

Arif, Muhammad Shoaib, Abodayeh, Kamaleldin, and Nawaz, Yasir

Subjects

NEWTONIAN fluids, FLUID dynamics, NUSSELT number, PARTIAL differential equations, FOURIER series

Abstract

Fractal time-dependent issues in fluid dynamics provide a distinct difficulty in numerical analysis due to their complex characteristics, necessitating specialized computing techniques for precise and economical solutions. This study presents an innovative computational approach to tackle these difficulties. The main focus is applying the Fractal Runge-Kutta Method to model the time-dependent magnetohydrodynamic (MHD) Newtonian fluid with rescaled viscosity flow on Riga plates. An efficient computational scheme is proposed for handling fractal time-dependent problems in flow phenomena. The scheme is comprised of three stages and constructed using three different time levels. The stability of the scheme is shown by employing the Fourier series analysis to solve scalar problems. The scheme's convergence is guaranteed for a time fractal partial differential equations system. The scheme is applied to the dimensionless fractal heat and mass transfer model of incompressible, unsteady, laminar, Newtonian fluid with rescaled viscosity flow over the flat and oscillatory Riga plates under the effects of space- and temperature-dependent heat sources. The first-order back differences discretize the continuity equation. The results show that skin friction local Nusselt number declines by raising the coefficient of the temperature-dependent term of heat source and Eckert number. The numerical simulations provide valuable insights into fluid dynamics, explicitly highlighting the influence of the temperature-dependent coefficient of the heat source and the Eckert number on skin friction and local Nusselt number. [ABSTRACT FROM AUTHOR]

Published

2024

5. An exact analysis of radiation absorption and Dufour effect on MHD convective flow of Cu-water nanofluid with heat generation and chemical reaction.

Author

Bordoloi, Rajdeep, Gohain, Dipunja, Ahmed, Nazibuddin, and Chamkha, Ali J.

Subjects

*RADIATION absorption, *CONVECTIVE flow, *CHEMICAL reactions, *NANOFLUIDS, *POROUS materials, *HYDRAULICS, *FREE convection

Abstract

The combined effects of diffusion-thermo and radiative absorption on free convective hydromagnetic heat-generating chemically reactive flow of Cu-water nanofluid past an instantaneously accelerated unlimited vertical plate nested in a porous medium are investigated. A comparative analysis is executed for both isothermal and ramped conditions. The set of transformed domain equations has been obtained using a closed form of the Laplace transform method with the help of the Heaviside step function. Graphical and tabular explanations are provided for the physical characteristics of several flow parameters affecting the problem. Graphs are generated using MATLAB computing software. Findings of the problem manifest that the diffusion-thermo parameter and the radiation absorption parameter intensify the velocity and fluid temperature in the entire fluid area. This augmentation is most prominent for copper nanoparticles. Concentration, temperature, and velocity profiles in the case of ramped conditions are less than in isothermal conditions. Furthermore, the ramped parameter amplifies the heat transfer rate while reversing the mass transfer rate. It is also established that the volume concentration of nanoparticles enhances the heat transfer rate. The present study is of great interest in numerous fields of industry and machine-building applications. [ABSTRACT FROM AUTHOR]

Published

2024

6. Investigation of heat generation and radiation effects on boundary layer flow of Prandtl liquid with Cattaneo–Christov double diffusion models.

Author

Sohail, Muhammad, Rafique, Esha, Singh, Abha, and Tulu, Ayele

Subjects

BOUNDARY layer (Aerodynamics), FLUID dynamics, HEAT radiation & absorption, MASS transfer coefficients, HEAT conduction, NON-Newtonian flow (Fluid dynamics)

Abstract

In this analysis, a bidirectional stretched sheet is used to produce a 3 D flow of Prandtl liquid with improve mass diffusion and heat conduction models. This study advances knowledge of magnetohydrodynamics, radiation impacts, and heat production in fluid dynamics and transport processes. The Prandtl fluid model is critical for modeling non-Newtonian fluids, capturing its viscoelastic features, and allowing for precise simulation in industrial applications. It gives a mathematical foundation for analyzing complex fluid behaviors, which is necessary for optimizing operations utilizing such fluids. It uses the boundary layer method to simplify the fundamental equations and Cattaneo–Christov double diffusion models. The optimal homotopy analysis method is used to solve nonlinear ODEs caused by non-dimensional similarity variables. This investigation undertakes the calculation of drag coefficient for surfaces mass transfer rates and heat transfer rates proximate to the solid boundary. Furthermore, it conducts a comprehensive analysis of the influences exerted by various parameters on concentration and temperature profiles employing graphical representations for a rigorous examination. The Prandtl fluid model describes the viscoelastic characteristics of non-Newtonian fluids through constitutive equations, dimensional evaluation, and numerical simulations, which are frequently validated by experiments. The results show that changes in thermal and concentration relaxation parameters are accompanied by a decline in temperature. Temperature field rises as the thermal radiation parameter and heat generation increases. The work's novelty consists in its advanced modeling of Prandtl non-Newtonian fluids via Cattaneo–Christov double diffusion models, which incorporate magnetohydrodynamics and radiation effects and use optimal homotopy analysis for accurate parametric analyses of heat and mass transfer. [ABSTRACT FROM AUTHOR]

Published

2024

7. Thermoelastic analysis of variable thickness truncated conical shell subjected to thermomechanical load with internal heat generation using perturbation technique.

Author

Seddighi, Hamideh, Ghannad, Mehdi, Loghman, Abbas, and Zamani Nejad, Mohammad

Subjects

*MECHANICAL loads, *CONICAL shells, *SHEAR (Mechanics), *FINITE element method, *ASYMPTOTIC expansions

Abstract

In this article, the behavior of the truncated conical shell subjected to thermomechanical loading in their inner and outer layers with internal heat generation source is investigated. The displacement field obeys kinematic of the first order shear deformation theory and the first-order temperature theory is used. Two-dimensional temperature analysis has been performed along the thickness and axis of the shell, which can be defined under various loading and thermomechanical boundary conditions. The set of governing equations is a system of differential equations with variable coefficients which are solved by using the analytical matched asymptotic expansion of the perturbations technique. The mentioned solution has little computational cost, therefore can be used well in parametric studies for optimization. It was shown, axial displacement is somehow independent of the radial axis and its maximum value occurs near the upper boundary. The conical shell has expanded in the radial direction. Also the maximum temperature happens approximately in the middle of the length of the conical shell. The parametric study showed, with the increase heat flux in the outer layer thereby expanding the area of heat application which would let more heat in than out. Also it was found, controlling the lifetime of the structure is the result of directing the cone angle. The results obtained from the analytical solution were compared with the Finite Element Method (FEM) analysis and the results of similar related articles, only to show a good agreement. [ABSTRACT FROM AUTHOR]

Published

2024

8. Fuel Wood Pellets Produced from Sawdust of Scots Pine Mature and Juvenile Wood: Self-Heating and Off-Gassing Tests at Industrial Scale.

Author

Siwale, Workson, Finell, Michael, Frodeson, Stefan, Henriksson, Gunnar, and Berghel, Jonas

Subjects

*WOOD, *MANUFACTURING processes, *RAW materials, *FATTY acid oxidation, *MULTIPLE regression analysis, *WOOD waste, *WOOD pellets

Abstract

This study investigated self-heating and off-gassing of Scots pine (Pinus sylvestris) wood pellets made from sawdust generated from separated mature and juvenile wood. The pellets were produced at an industrial scale and stored in large piles of about 7.2 tonnes. The production process involved drying the sawdust using three different methods and to varying moisture contents. The results indicated significant influences of both raw material type (F(6) = 61.97, p < 0.05) and drying method (F(2) = 65.38, p < 0.05) on the self-heating of the pellets. The results from the multiple regression analysis further showed that both the raw material type and pellet moisture content significantly influenced the temperature increase, with strong correlations observed for pellets produced using low-temperature drying (F(3, 14) = 83.52, multiple R2 = 0.95, p < 0.05), and medium temperature drying (F(3, 13) = 62.05, multiple R2 = 0.93, p < 0.05). The pellets produced from fresh mature wood sawdust were found to be more prone to self-heating and off-gassing while steam drying the sawdust at high temperature and pressure led to a significant reduction in heat and gas generation across all materials. The heightened self-heating and off-gassing in mature wood pellet can be attributed to a higher proportion of sapwood in the raw material. The probable explanations to the observed differences are in line with biological mechanisms for self-heating and off-gassing, as well as the chemical oxidation of fatty and resin acids. [ABSTRACT FROM AUTHOR]

Published

2024

9. An analysis of annular fin’s thermal conductivity and heat production using the DTM-Pade approximation.

Author

Sarwe, Deepak Umarao, Sharma, Vishnu, Gaur, Pradip Kumar, and Raj, Stephan Antony

Subjects

*FINS (Engineering), *THERMAL stresses, *THERMAL conductivity, *ORDINARY differential equations, *TEMPERATURE distribution, *NONLINEAR differential equations, *ANALYTICAL solutions

Abstract

The DTM-Pade approximation is used in the current work to analyze the thermal behavior and thermal stresses of an annular fin while accounting for temperature-dependent thermal conductivity and internal heat generation. The energy problem is converted into a nonlinear ordinary differential equation (ODE) using non-dimensional parameters, and the DTM-Pade approximation is then utilized to provide an approximate analytical solution. The impacts of various settings on the temperature field are also graphically analyzed. It has been found that increasing the heat generation parameter causes the temperature distribution to improve. The growing thermo-geometric parameter values lead to an improvement in fin efficiency. [ABSTRACT FROM AUTHOR]

Published

2024

10. Flow reversal for hybrid nanofluid with heat generation and slip effect in Darcy porous medium: The stability analysis.

Author

Saran, Har Lal and Chetteti, RamReddy

Subjects

*POROUS materials, *FREE convection, *THERMAL boundary layer, *ORDINARY differential equations, *NANOFLUIDS, *FLOW separation, *NANOFLUIDICS

Abstract

This investigation focuses on the flow reversal and separation of hybrid nanofluid, with heat generation and first-order velocity slip, in a Darcy porous medium. The Choi–Eastman nanofluid model is used to formulate the hybrid nanofluid mathematical model. Suitable similarity transformations convert partial differential equations into a system of ordinary differential equations. The resultant systems are numerically solved by implementing the shooting approach. Multiple solutions are found for this current problem, and intriguingly, the velocity and temperature profiles of these two solution branches exhibit opposing characteristics. In conclusion, conducting a stability study on these two alternative solutions is worthwhile to determine which solution is more realistic and stable. The temporal stability test reveals that only the first solution is stable or physically valid. The important outcomes of this study, based on the stable solutions, are as follows: (i) the hybrid nanofluid's Nusselt number, skin friction, and velocity rise when the inclined magnetic parameter rises, (ii) the value of the smallest eigenvalue increases with higher values of the inclined magnetic parameter, and (iii) the thickness of momentum and thermal boundary layers is thinner for the first solution than the second solution. Additionally, the identification of flow separation and reversal points is valuable for aerospace technology, following the Prandtl theory. Finally, this study provides streamlined patterns to enhance the understanding of fluid flow behavior. [ABSTRACT FROM AUTHOR]

Published

2024

11. Thermal Management of Lithium-Ion Battery Pack Using Equivalent Circuit Model.

Author

Kaliaperumal, Muthukrishnan and Chidambaram, Ramesh Kumar

Subjects

BATTERY management systems, THERMAL batteries, ELECTRIC batteries, COOLING systems, ELECTRIC circuits, THERMAL management (Electronic packaging)

Abstract

The design of an efficient thermal management system for a lithium-ion battery pack hinges on a deep understanding of the cells' thermal behavior. This understanding can be gained through theoretical or experimental methods. While the theoretical study of the cells using electrochemical and numerical methods requires expensive computing facilities and time, the Equivalent Circuit Model (ECM) offers a more direct approach. However, upfront experimental cell characterization is needed to determine the ECM parameters. In this study, the behavior of a cell is characterized experimentally, and the results are used to build a second-order equivalent electrical circuit model of the cell. This model is then integrated with the cooling system of the battery pack for effective thermal management. The Equivalent Circuit Model estimates the internal heat generation inside the cell using instantaneous load current, terminal voltage, and temperature data. By extrapolating the heat generation data of a single cell, we can determine the heat generation of the cells in the pack. With the implementation of the ECM in the cooling system, the coolant flow rate can be adjusted to ensure the attainment of a safe operating cell temperature. Our study confirms that 14% of pumping power can be reduced when compared to the conventional constant flow rate cooling system, while still maintaining the temperature of the cells within safe limits. [ABSTRACT FROM AUTHOR]

Published

2024

12. Effect of Operation Parameters on the Thermal Characteristics in a Planar Solid Oxide Fuel Cell.

Author

Wang, Mingyuan, Wang, Ke, Wang, Yongqing, Chen, Jiangshuai, An, Bo, and Tu, Shantung

Abstract

Effective operation strategies in the solid oxide fuel cell (SOFC) can adjust the spatial distribution of temperature gradient favoring the long-term stability. To investigate the effects of different operating conditions on the thermal behavior inside SOFC, a three-dimensional model is developed in this study. The model is verified by comparing it with the experimental data. The heat generation rate and its variation under different operating conditions are analyzed. The combined effects of operating voltage and gas temperature are considered to be the key factor influencing the temperature gradient. Compared to the original case, the temperature of SOFC decreases by 21.4 K when the fuel velocity reaches 5 m/s. But the maximum temperature gradient increases by 21.2%. Meanwhile, higher fuel velocities can eliminate about 32% of the area with higher temperature gradient. And when the oxidant velocity reaches 7.5 m/s, the peak temperature gradient effectively decreases by 16.59%. Simultaneous adjustment of the oxidant and fuel velocities can effectively reduce the peak temperature gradient and increase the safety zone. The effects of operation conditions on the temperature gradient of the cell are clarified in this study, which can be a reference for further research on the reliability of SOFCs. [ABSTRACT FROM AUTHOR]

Published

2024

13. Effects of viscous dissipation over an unsteady stretching surface embedded in a porous medium with heat generation and thermal radiation

Author

Samuel Oluyemi Owoeye, Ayodeji Falana, Abiodun Abideen Yussouff, and Quadri Ademola Mumuni

Subjects

thermal radiation, heat generation, porous medium, viscous dissipation, unsteady stretching surface, Mechanical engineering and machinery, TJ1-1570

Abstract

This work analyzes the impact of viscous dissipation on an unstable stretching surface in a porous medium with heat generation and thermal radiation—an important factor for numerous engineering applications like cooling baths and plastic sheets. Using MATLAB's Runge-Kutta fourth-order approach, the controlling partial differential equations are converted into highly nonlinear ordinary differential equations that can be solved numerically. The findings show that a decrease in the skin friction coefficient, temperature profiles, velocity, and Nusselt number occurs when the unsteadiness parameter is increased. In contrast to the Prandtl number, which rises with temperature profile and reduced Nusselt number, the Eckert number rises with a dimensionless temperature profile and reduced Nusselt number. Reduced Nusselt number and temperature profile affect the heat generation parameter; a decrease in skin friction coefficient and velocity profile correlate with the porosity parameter. Furthermore, the radiation parameter rises as the temperature distribution and Nusselt number decrease.

Published

2024

14. Exact Analysis of MHD Casson Fluid Flow Past an Exponentially Accelerated Vertical Plate in a Porous Medium with Radiation Absorption, Heat Generation, and Diffusion-Thermo Effects with Thermal and Solutal Ramped Conditions

Author

Dibya Jyoti Saikia, Nazibuddin Ahmed, Ardhendu Kr. Nandi, and Dip Jyoti Bora

Subjects

mhd, radiation absorption, casson fluid, heat generation, dufour effect, Physics, QC1-999

Abstract

The current investigation aims at to examine the effect of radiation absorption, heat generation and Dufour number on MHD Casson fluid flow past an exponentially accelerated vertical plate in a porous medium with chemical reaction. The governing equations for momentum, energy and concentration are solved by implementing the Laplace transformation method. Skin friction, rate of heat transfer and rate of mass transfer expressions are also extracted and depicted in tabular form. Investigation simulates that Casson parameter diminished the fluid velocity, whereas energy flux due to a mass concentration gradient improves the temperature field of the flow problem. In addition to this, temperature field is observed to be developed under the influence of radiation absorption and heat generation. Furthermore, the effects of different non-dimensional parameters on velocity field, temperature fluid and species concentration are exhibited graphically.

Published

2024

15. Contribution of hall and ion slip effects with generalized mass and heat fluxes with entropy analysis on three-dimensional Prandtl model

Author

Sana Akbar, Muhammad Sohail, Syed Tehseen Abbas, and Abha Singh

Subjects

Prandtl fluid, Hall current, Ion slip characteristics, Entropy analysis, Cattaneo Christov, Heat generation, Engineering (General). Civil engineering (General), TA1-2040

Abstract

A major challenging proffered study rely on the inquisitive optimization of entropy together with thermal as well as mass transportation towards the chemically reactive 3-D Prandtl liquid under consideration of applied magnetic field, variable thermal conductivity and also diffusivity, hall current together with ion slip features, viscous dissipation and heat generation. Moreover, in present research study, model such as Cattaneo Christov heat flux was implemented in order to explore the thermal relaxation characteristics. By employing correspondence transformations, the system of modeled equations modified into non-linear ODEs system. The Optimal Homotopy Analysis methodology (OHAM) was adopted to solve the proffered problem. The influential arising constraints demeanor within both velocities (horizontal as well as vertical), temperature and concentration profiles were discussed and also shown graphically. Moreover, outcomes of diverse parameters were also examined and presented graphically within the entropy formation rate and also Bejan number. The effects of implanted factors across the drag force, the rate of thermal as well as mass transportation are accessible in current study via tables and validate the obtained results. Both velocity profiles (horizontal as well as vertical) decreased for increment in Hartman number whilst opposite demeanor seen for other considered constraints. Temperature profile drops for Prandtl number and elastic constraints whereas enhanced for other influential considered parameters whilst concentration profile augmented with Prandtl number. Present problem novelty relies on the modeling of comprehensive system of equations which modified into nonlinear ODEs. In order to obtain the solution numerically, technique such as Optimal Homotopy was opted.

Published

2024

16. Thermal Management of Lithium-Ion Battery Pack Using Equivalent Circuit Model

Author

Muthukrishnan Kaliaperumal and Ramesh Kumar Chidambaram

Subjects

lithium-ion battery, equivalent circuit model, battery parameters, heat generation, thermal management, SoC, Mechanical engineering and machinery, TJ1-1570, Machine design and drawing, TJ227-240, Motor vehicles. Aeronautics. Astronautics, TL1-4050

Abstract

The design of an efficient thermal management system for a lithium-ion battery pack hinges on a deep understanding of the cells’ thermal behavior. This understanding can be gained through theoretical or experimental methods. While the theoretical study of the cells using electrochemical and numerical methods requires expensive computing facilities and time, the Equivalent Circuit Model (ECM) offers a more direct approach. However, upfront experimental cell characterization is needed to determine the ECM parameters. In this study, the behavior of a cell is characterized experimentally, and the results are used to build a second-order equivalent electrical circuit model of the cell. This model is then integrated with the cooling system of the battery pack for effective thermal management. The Equivalent Circuit Model estimates the internal heat generation inside the cell using instantaneous load current, terminal voltage, and temperature data. By extrapolating the heat generation data of a single cell, we can determine the heat generation of the cells in the pack. With the implementation of the ECM in the cooling system, the coolant flow rate can be adjusted to ensure the attainment of a safe operating cell temperature. Our study confirms that 14% of pumping power can be reduced when compared to the conventional constant flow rate cooling system, while still maintaining the temperature of the cells within safe limits.

Published

2024

17. Theoretical assessment of chemically reactive bioconvective flow of hybrid nanofluid by a curved stretchable surface with heat generation.

Author

Haq, Fazal, Ur Rahman, Mujeeb, and Gupta, Manish

Subjects

*REACTIVE flow, *BOUNDARY layer (Aerodynamics), *GRANULAR flow, *MAGNETOHYDRODYNAMICS, *PECLET number

Abstract

Bioconvection in hybrid nanofluids refers to the phenomenon where biological microorganisms such as algae or bacteria exhibit collective movement or pattern formation in a suspension containing nanoparticles. This phenomenon has significance in various fields, including biology, nanotechnology, and engineering. The current investigation emphasizes the bioconvective flow of a water (H2O)−ethylene glycol (C2H6O2)-based hybrid nanofluid flow by a curved stretched sheet. Copper (Cu) and silver (Ag) nanoparticles are suspended in the base fluid. The thermal field is analyzed in the presence of heat generation, dissipation, Joule heating, and the impact of thermal radiation. Binary reactions associated with Arrhenius energy are accounted in the modeling of mass concentration. The phenomenon of bioconvection is considered to regulate the random movement of tiny solid particles within the flow. Boundary layer constraints are implemented to eliminate ineffective terms from modeling. The transformation procedure is adopted to obtain the flow governing system of ODEs. The built-in code of Mathematica (NDSolve) is implemented to obtain the graphical and numerical results. The results show that the velocity field decreases with increasing porosity variable and Hartmann number. An opposite impression of the Eckert number and Schmidt variable on the thermal field is noticed. Bioconvection Peclet and Lewis numbers have a direct relationship with motile density. [ABSTRACT FROM AUTHOR]

Published

2024

18. Comprehensive scrutinization of ternary hybrid Casson nanofluid flow in a conducting porous rotating disk with internal heating.

Author

Kumar, Maddina Dinesh, Suneetha, Sangapatnam, Ramasekhar, Gunisetty, Ramesha, M., Raju, C. S. K, and Raju, S. V. Sivarama

Subjects

*ROTATING disks, *NANOFLUIDS, *NONLINEAR differential equations, *PARTIAL differential equations, *NANOFLUIDICS, *WATER purification, *HEAT radiation & absorption

Abstract

The utilization of a ternary hybrid nanofluid, a recent development in the realm of nanofluids, can result in improved heat transfer. In the ongoing study, a ternary hybrid nanofluid flow is utilized, and it is carried out atop a porous spinning disc, which is exposed to a magnetic field, heat generation, thermal radiation, and Casson fluid. In this study, Blood/Water are taken as base fluids and (Ag–Au–Al2O3) are considered as a ternary hybrid nanoparticle. Nanoparticles made of gold and silver are put to use in a vast number of industries and fields, including nanotechnology and medicine. As a result of surface effects and quantum effects, these precious metals exhibit unique features in nanoform that play a vital role in with optical, magnetic, chemical, and mechanical behavior. Al2O3 unique optical, physical and biochemical qualities make it worthwhile for numerous uses, including nanophotonic, catalysis and the fabrication of high-energy composites. A set of relevant similarity transformations is used to generate non-dimensional forms of controlling paired nonlinear Partial Differential Equations (PDEs). MATLAB is used to perform a numerical solution with ODE45. In addition, the velocity outline decreases, and the temperature profile increases slightly before decreasing over a revolving disk when the values of magnetic parameters are increased. The distribution and radiant heat components heat up as the level gets higher. Aim and objectives of the study: The aim of this study is to analyze the Comprehensive Scrutinization of Ternary hybrid and Casson flow in a conducting porous rotating disk with internal heating. The primary objective of this analysis is to increase awareness of the impending energy crisis among those working in the industrial and technological sectors. Ternary nanoparticles (NPs) have a wide range of applications, which lends credence to the developed model. For example, Al2O3 can be used in a variety of ways that benefit society, it is used in water purification to remove water from the gas streams and extend people's lives. [ABSTRACT FROM AUTHOR]

Published

2024

19. Entropic thermodynamic analysis and radiative performance of unsteady magnetized squeezing hybrid nanofluid flowing via two disks with time-dependent heat generating.

Author

Elsaid, Essam M., Eid, Mohamed R., and Abdel-wahed, Mohamed S.

Subjects

*TRUCK brakes, *SURFACE forces, *FRICTION, *PARTIAL differential equations, *THERMAL conductivity, *FOOD transportation

Abstract

This paper investigates the squeezing action of hybridized nanofluid flow that takes place in the mechanism of truck brakes, dampers, polymer manufacturing, power transportation, oiling structure, and food production. The modeling technique relied on a set of partial differential equations to direct the fluid, taking into consideration external factors like the magnetized force and the time-dependent source of heat and thermal radiation. The hybridized nanofluid consists of copper and aluminum oxide nanoparticles that are dispersed in the machine oil. Entropic thermodynamic analysis is also examined to evaluate its role in the thermal examination of the system. The optimal homotopy asymptotic and Adomian decomposition methods were used to solve the problem. The study examined the changes in the rate of entropy formation and the characteristics of fluid velocities, heat transference rate, and performance based on the kind and concentration of nanoparticles and external thermal impacts. The results are presented in many key components, including a notable 30% increase in heat conductivity when using a combination of nanoparticles. The use of hybridized nanofluids manages to reduce surface frictional force, whereas the employment of a combination of particles results in an increase in friction owing to the heightened viscosity of the mixture. [ABSTRACT FROM AUTHOR]

Published

2024

20. Numerical Investigation of Melting in Pressurized Water Reactor Fuel Rod Considering Operational Parameters of the Core.

Author

Ahmadi, J. and Aghaie, M.

Abstract

AbstractThe meltdown of a fuel rod is a severe accident resulting from the overheating of the reactor core. In the present study, a numerical investigation of this process, focusing on the loss of coolant has been conducted. The objective of this study is to conduct a numerical simulation of transient heat conduction and melting at various points within a typical pressurized water reactor fuel rod. In this analysis, heat conduction in the radial direction of a fuel rod, including the UO2 fuel pellet, the gap, and the zircaloy cladding, is investigated. The FRAPCON steady-state code is employed to calculate the operational parameters of the fuel rod. The calculated parameters, such as coolant and fuel temperatures, fission gas fraction, gap heat transfer coefficient, and burnup, are utilized to evaluate and compare the melting phenomena at different time intervals.In the investigation of the phase change in various parts of the pellet and fuel rod, the explicit finite difference (FD) method is utilized with enthalpy instead of temperature-dependent equations. Finally, the temperature history, phase change, and melting map at different points along the radial and axial directions of the fuel rod during coolant loss and heat transfer coefficient reduction are evaluated based on various operating parameters of the core. To enhance the quality of the results, an uncertainty analysis of effective parameters is conducted.According to this analysis, the heat transfer coefficient of the coolant under accident conditions (0.2 ± 5% kWm−2K−1) and the thermal conductivity of the fuel have the most significant impact on the temperature history and melting process. Highlights include the following:1. The meltdown of a nuclear fuel rod is analyzed under a loss-of-coolant accident.2. The enthalpy formula is discretized by the explicit FD numerical method.3. Effective parameters in melting, such as coolant temperature, burnup, and gap heat transfer coefficient, are obtained by FRAPCON.4. The temperature history, phase changes, and melting map of various radial points within the fuel pellet and cladding along the axial direction of the fuel rod are determined. [ABSTRACT FROM AUTHOR]

Published

2024

21. Effect of Thermal Radiation on Fractional MHD Casson Flow with the Help of Fractional Operator.

Author

Abbas, Shajar, Parveen, Iram, Nisa, Zaib Un, Amjad, Muhammad, Metwally, Ahmed Sayed M., Nazar, Mudassar, and Jan, Ahmed Zubair

Abstract

This study examines the effects of Newtonian heating along with heat generation, and thermal radiation on magnetohydrodynamic Casson fluid over a vertical plate. At the boundary, the Newtonian heating phenomena has been employed. The problem is split into two sections for this reason: momentum equation and energy equations. To transform the equations of the given model into dimensionless equations, some particular dimensionless parameters are defined. In this article, generalized Fourier’s law and the recently proposed Caputo Fabrizio fractional operator are applied. The corresponding results of non-dimensional velocity and heat equations can be identified through the application of Laplace transform. Moreover, Tzou’s algorithm as well as Stehfest’s algorithm is implemented to recognize the inverted Laplace transform of heat and momentum equations. Finally, a graphical sketch is created using Mathcad 15 software to demonstrate the results of numerous physical characteristics. It has been reported that the heat and velocity drop with rising Prandtl number values, whereas the fluid’s velocity has been seen to rise with increasing Grashof number values. Additionally, current research has shown that flow velocity and temperature increase with rising values of a fractional parameter. [ABSTRACT FROM AUTHOR]

Published

2024

22. Experimental Methodology to Identify Optimal Friction Stir Welding Parameters Based on Temperature Measurement.

Author

Abboud, Moura, Dubourg, Laurent, Racineux, Guillaume, and Kerbrat, Olivier

Subjects

WELDED joints, WELDING, TEMPERATURE measurements, PROCESS optimization, THERMOCOUPLES

Abstract

Friction stir welding (FSW) is a widely employed welding process, in which advancing and rotational speeds consitute critical parameters shaping the welding outcome and affecting the temperature evolution. This work develops an experimental methodology to identify optimal FSW parameters based on real-time temperature measurement via a thermocouple integrated within the tool. Different rotational and welding speeds were tested on AA5083-H111 and AA6082-T6. Our results underscore the importance of attaining a minimum temperature threshold, specifically 0.65 times the solidus temperature, to ensure high-quality welds are reached. The latter are defined by combining temperature measurements with joint quality information obtained from cross-sectional views. Our research contributes to advancing the efficiency and effectiveness of friction stir welding in industrial settings. Furthermore, our findings suggest broad implications for the manufacturing industry, offering practical insights for enhancing weld quality and process optimization. [ABSTRACT FROM AUTHOR]

Published

2024

23. Ceramic Implant Rehabilitation: Consensus Statements from Joint Congress for Ceramic Implantology: Consensus Statements on Ceramic Implant.

Author

Schnurr, Etyene, Sperlich, Mathias, Sones, Amerian, Romanos, George E., Rutkowski, J. L., Duddeck, Dirk U., Neugebauer, Jörg, Att, Wael, Sperlich, Markus, Volz, Karl Ulrich, and Ghanaati, Shahram

Subjects

DENTAL implants, VISUAL analog scale, SATISFACTION, CLINICAL trials, QUALITY of life, QUALITY of life measurement, IMMEDIATE loading (Dentistry)

Abstract

The objectives of the study group focused on the following main topics related to the performance of 1- and 2-piece ceramic implants: defining bone-implant-contact percentages and its measurement methods, evaluating the pink esthetic score as an esthetic outcome parameter after immediate implantation, recognizing the different results of ceramic implant designs as redefined by the German Association of Oral Implantology, incorporating the patient report outcome measure to include satisfaction and improvement in oral health–related quality of life, and conducting preclinical studies to address existing gaps in ceramic implants. During the Joint Congress for Ceramic Implantology (2022), the study group evaluated 17 clinical trials published between 2015 and 2021. After extensive discussions and multiple closed sessions, consensus statements and recommendations were developed, incorporating all approved modifications. A 1-piece implant design features a coronal part that is fused to the implant body or interfaces with the postabutment restoration platform, undergoing transmucosal healing. Long-term evaluations of this implant design are supported by established favorable clinical evidence. Inaccuracies in the pink esthetic score and bone-implant-contact percentages were managed by establishing control groups for preclinical studies and randomizing clinical trials. The patient-reported outcome measures were adjusted to include an individual visual analog scale, collected from each clinical study, that quantified improved oral health and quality of life. Preclinical investigations should focus on examining the spread of ceramic debris and the impact of heat generation on tissue and cellular levels during drilling. Further technical advancements should prioritize wound management and developing safe drilling protocols. [ABSTRACT FROM AUTHOR]

Published

2024

24. EXACT ANALYSIS OF MHD CASSON FLUID FLOW PAST AN EXPONENTIALLY ACCELERATED VERTICAL PLATE IN A POROUS MEDIUM WITH RADIATION ABSORPTION, HEAT GENERATION, AND DIFFUSION-THERMO EFFECTS WITH THERMAL AND SOLUTAL RAMPED CONDITIONS.

Author

Agarwal, Hemant and Chakraborty, Shyamanta

Subjects

*MAGNETOHYDRODYNAMICS, *FLUID flow, *RADIATION absorption, *MOMENTUM (Mechanics), *FRICTIONAL resistance (Hydrodynamics)

Abstract

The current investigation aims at to examine the effect of radiation absorption, heat generation and Dufour number on MHD Casson fluid flow past an exponentially accelerated vertical plate in a porous medium with chemical reaction. The governing equations for momentum, energy and concentration are solved by implementing the Laplace transformation method. Skin friction, rate of heat transfer and rate of mass transfer expressions are also extracted and depicted in tabular form. Investigation simulates that Casson parameter diminished the fluid velocity, whereas energy flux due to a mass concentration gradient improves the temperature field of the flow problem. In addition to this, temperature field is observed to be developed under the influence of radiation absorption and heat generation. Furthermore, the effects of different non-dimensional parameters on velocity field, temperature fluid and species concentration are exhibited graphically. [ABSTRACT FROM AUTHOR]

Published

2024

25. Thermal analysis of rectangular moving fins with temperature‐variant properties by employing the Galerkin scheme.

Author

Gouran, Sina and Ghasemi, S. E.

Subjects

*THERMAL analysis, *HEAT transfer coefficient, *THERMAL conductivity, *PECLET number, *FINS (Engineering)

Abstract

In the present study, the thermal behavior of a longitudinal fin considering three types of heat transfer mechanisms (conduction, convection, and radiation) is investigated. For this research, thermal conductivity, heat source, and heat transfer coefficient are assumed nonindependent. A semianalytical scheme called the Galerkin Method is utilized for solving the dimensionless governing equation. The impacts of important physical variables like Peclet number, gradient of thermal conductivity, thermo‐geometric parameter, and radiation–conduction parameter on temperature profiles are analyzed comprehensively. The obtained results indicate that raising the thermo‐geometric parameter from 0 to 2 leads to a 32% reduction in the temperature profile. Also from the results, it can be found that a 28% increment in the temperature is observed by changing the gradient of thermal conductivity from 0 to 2. [ABSTRACT FROM AUTHOR]

Published

2024

26. Orthogonal experimental study to optimise the combustion conditions of blended municipal sludge and cotton stalks.

Author

LI Jing, XU Feng, and HE Zihan

Subjects

*COTTON stalks, *COMBUSTION, *IGNITION temperature, *COTTON fibers, *ACTIVATION energy

Abstract

Taking heat generation as the evaluation index, the orthogonal experiment was used to optimize the combustion conditions of blending municipal sludge and cotton stalks. The result showed that the primary and secondary factors affecting the heat generation of the sludge mixture were cotton stalks blending ratio > stirring time > particle size of blending, and the optimal blending conditions were 40% of cotton stalks blending, stirring time of 5 min, and blending particle size of 0.075 mm. Under optimal mixing conditions, the ignition and combustion temperatures of urban sludge were significantly reduced, the heat generation was increased by 34%, the comprehensive combustion characteristic index was increased by 3.97 times, the activation energy was reduced by 12.74 kJ/mol, and the sludge and cotton stalks were in the stage of positive facilitation in the combustion process almost the whole time. [ABSTRACT FROM AUTHOR]

Published

2024

27. EFFECTS OF VISCOUS DISSIPATION OVER AN UNSTEADY STRETCHING SURFACE EMBEDDED IN A POROUS MEDIUM WITH HEAT GENERATION AND THERMAL RADIATION.

Author

Falana, Ayodeji, Owoeye, Samuel Oluyemi, Yussouff, Abiodun Abideen, and Mumuni, Quadri Ademola

Subjects

ENERGY dissipation, HEAT radiation & absorption, PLASTIC sheets, NUSSELT number, SKIN friction (Aerodynamics)

Abstract

This work analyzes the impact of viscous dissipation on an unstable stretching surface in a porous medium with heat generation and thermal radiation-an important factor for numerous engineering applications like cooling baths and plastic sheets. Using MATLAB's Runge-Kutta fourth-order approach, the controlling partial differential equations are converted into highly nonlinear ordinary differential equations that can be solved numerically. The findings show that a decrease in the skin friction coefficient, temperature profiles, velocity, and Nusselt number occurs when the unsteadiness parameter is increased. In contrast to the Prandtl number, which rises with temperature profile and reduced Nusselt number, the Eckert number rises with a dimensionless temperature profile and reduced Nusselt number. Reduced Nusselt number and temperature profile affect the heat generation parameter; a decrease in skin friction coefficient and velocity profile correlate with the porosity parameter. Furthermore, the radiation parameter rises as the temperature distribution and Nusselt number decrease. [ABSTRACT FROM AUTHOR]

Published

2024

28. Heat transport performance of hydromagnetic hybrid nanofluid under the slip regime.

Author

Ahmad, S., Anjum, Aisha, Sheriff, Samreen, Saleem, Saira, and Farooq, M.

Abstract

Heat transport analysis corresponded to converging/diverging consideration has attained the attensions because of engineering and industrial utilization. Typical examples encompass cold drawing operation in polymer industry, enhancement of rate of heat transport during process of heat exchangers for milk flowing, molten polymers extrusion via converging dies, processing plants, power stations, and numerous others. Due to this fact, the present analysis has been established. The current research describes the hybrid nanofluid flow through convergent/divergent channel in the regime of hydromagnetic phenomenon. Here, water based nanoparticles i.e., graphene oxide and polystyrene are considered. Heat transport under the viscous dissipation and heat generation/ absorption is evaluated. Velocity slip condition is also imposed on channel wall. Suitable variables are employed to get strong form of non-dimensional coupled equations which are solved by using homotopic analytical technique. The results for velocity and temperature against pertinent parameters are analyzed through graphs. Effects of skin friction and Nusselt numbers are presented through graphs. The current investigation tells us that surface drag has diminished for Reynolds and Hartmann number. Furthermore, dissipative factor intensifies the heat transport rate. Owing by such applications, the present examination has been established. [ABSTRACT FROM AUTHOR]

Published

2024

29. Convective boundary layer flow of MHD tangent hyperbolic nanofluid over stratified sheet with chemical reaction.

Author

Alhefthi, Reem K., Shahzadi, Irum, Khan, Husna A., Khan, Nargis, Hashmi, M. S., and Inc, Mustafa

Subjects

CONVECTIVE boundary layer (Meteorology), CHEMICAL reactions, NANOFLUIDS, NANOFLUIDICS, STAGNATION flow, NUSSELT number, BROWNIAN motion, THERMAL conductivity

Abstract

We investigated the combined impact of convective boundary conditions, thermal conductivity, and magnetohydrodynamic on the flow of a tangent hyperbolic nanofluid across the stratified surface. Furthermore, the ramifications of Brownian motion, thermophoresis, and activation energy were considered. Heat generation, chemical reactions, mixed convection, thermal conductivity, and other elements were considered when analyzing heat transfer phenomena. The governing equations were converted via similarity transformations into non-dimensional ordinary differential equations in order to analyze the system. Using the shooting method, the problem’s solution was determined. We showed the mathematical significance of the temperature, concentration profiles, and velocity of each fluid parameter. These profiles were thoroughly described and shown graphically. The findings demonstrated that as the Weissenberg number and magnetic number increased, the fluid velocity profile decreased. Higher heat generation and thermophoresis parameters resulted in an increase in the temperature profile. Higher Brownian motion and Schmidt parameter values resulted in a drop in the concentration profile. Tables were used to discuss the numerical values of skin friction (Cfx), Nusselt number (Nux), and Sherwood number (Shx). For the greater values of Weissenberg number and mixed convection parameters, skin friction numerical values fell while Nusselt numbers rose. [ABSTRACT FROM AUTHOR]

Published

2024

30. A Cementless Binder Based on High-Calcium Fly Ash, Silica Fume, and the Complex Additive Ca(NO 3) 2 + MgCl 2 : Phase Composition, Hydration, and Strength.

Author

Barabanshchikov, Yurii and Usanova, Kseniia

Subjects

MORTAR admixtures, FLY ash, MAGNESIUM chloride, HEAT of hydration, CALCIUM nitrate, MORTAR

Abstract

This study aimed to comprehensively investigate the properties of a binder based on high-calcium fly ash and silica fume with a complex additive consisting of calcium nitrate and magnesium chloride. The strength characteristics, the characteristics of the hydration process, and the phase composition of the hydration products of the binder were investigated. Silica fume was used to suppress the expansion of fly ash during hydration. A complex additive (CA) consisting of Ca(NO3)2 and MgCl2 provided a higher strength of binder than each of these salts separately. When testing a mortar with sand, the CA additive ensured that the strength of the specimens was 43.5% higher than the strength of the mortar with the addition of Ca(NO3)2 and 7.5% higher than the strength of the mortar with the MgCl2 additive. Calcium nitrate greatly accelerated the process of heat release in the first 60 min of binder hydration, and subsequently, conversely, slowed it down. The addition of MgCl2 gave a significantly greater thermal effect than Ca(NO3)2. When the two salts acted together, even a small fraction of magnesium chloride (0.2 of CA) compensated for the retarding effect of calcium nitrate and provided heat release for the binder that was almost as good as that of MgCl2. [ABSTRACT FROM AUTHOR]

Published

2024

31. Solution scheme development of the nonhomogeneous heat conduction equation in cylindrical coordinates with Neumann boundary conditions by finite difference method.

Author

Yıldız, Melih

Subjects

PARABOLIC differential equations, ELLIPTIC differential equations, FINITE differences, FINITE volume method, CRANK-nicolson method, STOKES equations, THERMAL conductivity

Published

2024

32. Investigation on heat generation in fast charging of lithium-ion batteries: Effect of charging rate and battery component thickness.

Author

Lei, Deyong, Wang, Yun, Shi, Jing, and Wang, Yachao

Subjects

*NEGATIVE electrode, *LITHIUM-ion batteries, *TEMPERATURE distribution, *OHMIC resistance, *ENTHALPY, *ELECTRODES, *ELECTRIC charge

Abstract

AbstractUnderstanding heat generation mechanisms during fast charging is essential for designing and optimizing lithium-ion batteries. In this study, we have formulated a three-dimensional electrochemical-thermal coupling model for pouch lithium-ion batteries. The model is validated by the experimental results based on the distribution of temperature, current, and voltage. We investigate the effects of charging rate, active material coating thickness, and current collector thickness (each at three levels) on heat generation and temperature distribution. The electrodes account for most of the total heat generation (87.5% with a 2.5C charging rate), and the percentage decreases as the charging rate increases. The heat generated at the negative electrode is slightly higher than that at the positive electrode. Reversible heat is the main heat source at a low charging rate, and it decreases as the charging rate rises. The effects of battery component thicknesses on thermal behaviors under fast charging are significant. The overall battery temperature increases by 11.5 K as the positive electrode thickness increases from 40 to 70 µm due to the rise in ohmic resistance and polarization resistance within the electrode. The increased ohmic resistance in the separator and the current collector raises the temperature. Reducing the thickness of the current collector by 33% resulted in a doubling of heat generation from the current collectors. Yet, it had minimal impact on the overall temperature of the battery. [ABSTRACT FROM AUTHOR]

Published

2024

33. Enhanced thermal management of electric vehicle lithium-ion batteries with Al2O3–MWCNT–ethylene glycol hybrid nanofluid-based helical coiled pulsating heat pipe (HC-PHP).

Author

Thawkar, Vivek, Dhoble, Ashwinkumar S., and Shewalkar, Akshay G.

Subjects

*HYBRID electric vehicles, *ELECTRIC vehicle batteries, *ELECTRIC vehicles, *HEAT pipes, *NANOFLUIDS, *ETHYLENE glycol, *TEMPERATURE distribution

Abstract

The study aims to investigate the performance of a thermal management system for lithium-ion batteries in electric vehicles (EVs) by utilizing a helical coiled pulsating heat pipe (HC-PHP) combined with a hybrid nanofluid consisting of Al2O3–MWCNT–ethylene glycol. The experimental investigation focuses on evaluating the effectiveness of this system under various operating conditions. The outcomes of this study will provide valuable insights into the influence of thermal management on power output, driving range, and safety of EVs. During a continuous discharge process at room temperature of 25 °C and discharge rates of 1C, 2C, and 3C, the lithium-ion battery's temperature remains below 42 °C, ensuring that it does not exceed the specified safety limit. Additionally, the maximum temperature gradient across the battery, which indicates temperature variation within the battery, remains below 2 °C. These findings demonstrate the effectiveness of the thermal management system in maintaining safe and uniform temperature distribution during high-discharge operations. The observed results provide strong evidence for the exceptional heat dissipation capabilities of the thermal management system utilizing HC-PHP and an Al2O3–MWCNT–ethylene glycol-based nanofluid. The system effectively minimizes temperature gradient and enhances thermal uniformity across the battery surface. As a result, the HC-PHP ensures optimal performance of the lithium-ion battery by maintaining temperatures within the desired range of 20–50 °C, which is crucial for its reliable operation. [ABSTRACT FROM AUTHOR]

Published

2024

34. Influence of heat flow due to concentration gradient on unsteady MHD heat and mass transform dissipative flow with spanwise fluctuating temperature.

Author

Rajakumar, K. V. B., Sreenivasulu, G., and Balamurugan, K. S.

Abstract

AbstractThis study investigates the influence of heat flow due to a concentration gradient on unsteady Newtonian free convective magnetohydrodynamic heat and mass transform dissipative fluid flow over a heated normal porous plate in the presence of radiation absorption and chemical reaction. The plate temperature is assumed to fluctuate in a spanwise cosinusoidal manner over a time and exhibit heat generation with suction velocity. The analysis employs the multiple regular perturbation method to evaluate the governing equations under stipulated boundary conditions. The outcomes are visually depicted to assess the impact of various parameters on the system dynamics. Graphical representations illustrate the physical significance of various parameters on velocity, temperature, and concentration. Additionally, skin friction, mass transfer rate, and heat transfer coefficients are presented in tabular form. The significant findings indicate that velocity, temperature, and skin friction are directly proportional to parameters such as radiation absorption, heat generation, and heat flux due to a chemical potential gradient, whereas Sherwood and concentration are inversely proportional to the Schmidt number and chemical reaction. The outcomes obtained in this study have been cross-referenced with existing scientific literature, demonstrating strong concordance. This alignment provides confidence in the numerical results. [ABSTRACT FROM AUTHOR]

Published

2024

35. Numerical study on the influence of tri-nanoparticles suspension on heat transfer in MHD Oldroyd-B fluid.

Author

Nawaz, M., Madkhali, Hadi Ali, Ahmed, M., Alharbi, Sayer Obaid, Alqahtani, A. S., and Malik, M. Y.

Subjects

*HEAT transfer fluids, *ALUMINUM oxide, *HEAT transfer

Abstract

This article studies the impact of multi-nanoparticles on the entropy generation where heat transfer in Oldroyd-B fluid is subjected to Joule heating and heat generation. C 2 H 6 O 2 is assumed to obey the constitutive behavior in the context of the Oldroyd-B model. Three types of nanoparticles ( Al 2 O 3 , TiO 2 and SiO 2 ) are assumed to be dispersed simultaneously in C 2 H 6 O 2 . The numerical scheme is used for the numerical simulations and simulations are observed and various predictions are made. The dynamics of entropy generation versus relaxation and retardation times. Momentum relaxation time is helpful in controlling entropy generation. It is also observed that C 2 H 6 O 2 with Al 2 O 3 has minimum entropy generation relative to C 2 H 6 O 2 with Al 2 O 3 and TiO 2 and C 2 H 6 O 2 with Al 2 O 3 , TiO 2 and SiO 2 . Relative to hybrid and mono-nanoparticles, the highest wall shear stresses are noticed in C 2 H 6 O 2 with tri-nanoparticles is observed. Momentum retardation time enhances entropy generation. Therefore, it is recommended not to use fluid with Oldroyd-B behavior in mechanisms where entropy generation is not required. In mechanisms where entropy generation is not required, the base fluid or nanofluid should not be heat-generating because heat generation helps in enhancing the generation of entropy. However, heat-absorbing fluid would be favorable for the minimization of entropy. [ABSTRACT FROM AUTHOR]

Published

2024

36. A novel model for viscoelastic fluid flow and heat near a stretchable plate using variable fluid properties: A computational study.

Author

Gull, Laiba, Mustafa, M., and Haq, Rizwan Ul

Subjects

*VISCOELASTIC materials, *PROPERTIES of fluids, *FLUID flow, *TRANSPORT equation, *BOUNDARY layer (Aerodynamics)

Abstract

This article is concerned with the boundary layer formations over a deforming plane heated surface in a viscoelastic fluid having temperature-dependent physical properties. Viscoelastic fluid obeys a well-accepted Jeffrey fluid model that characterizes both relaxation and retardation times phenomena. Mathematical modeling is performed by considering exponential variations in viscosity, thermal conductivity, relaxation time, and retardation time with temperature. Transport equations are formulated under the aforesaid assumption and are solved for self-similar solutions using a numerical scheme. Solutions are utilized to generate streamlines and isotherms in both Newtonian and viscoelastic fluids. The momentum and thermal layers are specifically scrutinized for various controlling parameters. Illustrative results are included reflecting the consequences of variable physical properties on the induced viscoelastic fluid motion and accompanying heat transfer. In addition, skin friction factor for Jeffrey fluid with variable properties is evaluated and described. [ABSTRACT FROM AUTHOR]

Published

2024

37. Thermal Transportation in Heat Generating and Chemically Reacting MHD Maxwell Hybrid Nanofluid Flow Past Inclined Stretching Porous Sheet in Porous Medium with Solar Radiation Effects.

Author

Jeelani, Mdi Begum, Abbas, Amir, and Alqahtani, Nouf Abdulrahman

Subjects

POROUS materials, NANOFLUIDS, SOLAR radiation, FREE convection, ORDINARY differential equations, CHEMICAL reactions, LORENTZ force

Abstract

The emerging concept of hybrid nanofluids has grabbed the attention of researchers and scientists due to improved thermal performance because of their remarkable thermal conductivities. These fluids have enormous applications in engineering and industrial sectors. Therefore, the present research study examines thermal and mass transportation in hybrid nanofluid past an inclined linearly stretching sheet using the Maxwell fluid model. In the current problem, the hybrid nanofluid is engineered by suspending a mixture of aluminum oxide A l 2 O 3   and copper C u nanoparticles in ethylene glycol. The fluid flow is generated due to the linear stretching of the sheet and the sheet is kept inclined at the angle ζ = π / 6 embedded in porous medium. The current proposed model also includes the Lorentz force, solar radiation, heat generation, linear chemical reactions, and permeability of the plate effects. Here, in the current simulation, the cylindrical shape of the nanoparticles is considered, as this shape has proven to be excellent for the thermal performance of the nanomaterials. The governing equations transformed into ordinary differential equations are solved using MATLAB bvp4c solver. The velocity field declines with increasing magnetic field parameter, Maxwell fluid parameter, volume fractions of nanoparticles, and porosity parameter but increases with growing suction parameter. The temperature drops with increasing magnetic field force and suction parameter values but increases with increasing radiation parameter and volume fraction values. The concentration profile increases with increasing magnetic field parameters, porosity parameters, and volume fractions but reduces with increasing chemical reaction parameters and suction parameters. It has been noted that the purpose of the inclusion of thermal radiation is to augment the temperature that is serving the purpose in the current work. The addition of Lorentz force slows down the speed of the fluid and raises the boundary layer thickness, which is visible in the current study. It has been concluded that, when heat generation parameters increase, the temperature field increases correspondingly for both nanofluids and hybrid nanofluids. The increase in the volume fraction of the nanoparticles is used to enhance the thermal performance of the hybrid nanofluid, which is evident in the current results. The current results are validated by comparing them with published ones. [ABSTRACT FROM AUTHOR]

Published

2024

38. Natural Convective Heat Transfer Analysis of Electrically Conducting Hybrid Nanofluid in a Small Gap Between Rotating Cone and Disc.

Author

Saini, Geetika and Hanumagowda, B. N.

Abstract

In this research, we examine four models—a rotating cone with a stationary disc, a stationary cone with a revolving disc, a co-rotating cone-disc, and a counter-rotating cone-disc—to determine the role of magnetohydrodynamic (MHD) natural convective flow of hybrid nanofluid and heat transfer in a small gap between cone and disc. An amalgamation of two nanoparticles magnesium oxide M g O and copper oxide C u O is used in water H 2 O . The computations of the proposed model were limited to Reynolds number 12 with a corresponding conical angle at α = 4 ∘ . The temperature of a disc surface varies radially. An innovative aspect of the proposed framework is the convective flow of radiative hybrid nanofluid in the presence of buoyancy force and magnetic field. The governing three-dimensional momentum and energy equations are solved for velocity and temperature fields using befitting similarity transformations. The bvp4c technique has been applied. Graphs demonstrate the effect of dimensionless parameters on flow characteristics. Heat transfer rates are calculated at both the cone and disc surfaces for all four models and found that the co-rotation model produces a higher heat transfer rate at the cone surface. The proposed model has characteristics in solar thermal systems, electronics cooling, energy storage, biomedical, and waste heat recovery. This study has been validated with prior research. [ABSTRACT FROM AUTHOR]

Published

2024

39. Effects of Dowel Rotation Welding Conditions on Connection Performance for Chinese Fir Dimension Lumbers.

Author

Zhong, Xiao, Li, De, Xu, Xiaoxue, Li, Quan, Yu, Danyun, Wu, Zhigang, Liang, Jiankun, Peng, Jun, Gu, Wen, Zhao, Xin, Yin, Shuang, Yang, Guifen, and Gong, Feiyan

Subjects

LUMBER, WELDING, X-ray photoelectron spectroscopy, FRICTION stir welding, WOOD, FIR, SCANNING electron microscopy

Abstract

In this study, the rotating welding process of Chinese fir (Keteleeriafortunei) in Guizhou, China, was systematically analyzed. The effects of rotating welding conditions, including the dowel-to-guide hole diameter ratio, welding time, depth, base surface, angle, and dowel type, on the performance of welded Chinese fir were explored. Moreover, the physical and chemical changes oftheChinese fir interface during welding were revealed by Fourier-Transform Infrared Spectroscopy (FT-IR), X-ray Photoelectron Spectroscopy (XPS), X-ray Diffraction (XRD), and Scanning Electron Microscopy (SEM). The results indicated the following: (1) The rotating welding technology can quickly achieve a strong connection between wood through friction heat without chemical adhesives and compared with traditional wood connection technology such as gluing or mechanical fixing;it has the advantages of simple operation, high production efficiency; and environmental friendliness. (2) Aftertherotating welding, the wood underwent significant pyrolysis, especially the degradation of hemicellulose. The heat generated in the welding process caused good melting and mechanical interlocking between the dowel and the wall of the guide hole, but it was also accompanied by afriction loss of the dowel and the substrate. (3) The welding parameters affected the wood's connection strength and stability by altering heat production, distribution, transfer, and frictional losses. The impact of the dowel-to-guide hole diameter ratio had a great influence on the connection strength. When the diameter ratio was 1:0.7, the tensile strength was the highest, reaching 2.27 MPa. (4) The analyses of XPS, FTIR, XRD, and SEM proved thatthechemical composition changes at the interface, leading to a more structured crystalline bond and enhanced connection strength due to fiber entanglement and interlocking. This research providesatheoretical and experimental basis forthefurther innovation and development of wood processing technology and provides a new technical path forthegreen manufacturing of wood structure buildings. [ABSTRACT FROM AUTHOR]

Published

2024

40. Unfolding some numerical solutions for the magnetohydrodynamics Casson–Williamson nanofluid flow over a stretching surface.

Author

Khan, Kashif Ali, Vivas-Cortez, Miguel, Ahammad, N Ameer, Bushra, Hafiza, Gamaoun, Fehmi, Javed, Muhammad Faraz, and Raza, Nauman

Subjects

HEAT convection, ORDINARY differential equations, NUSSELT number, NANOFLUIDS, MAGNETOHYDRODYNAMICS, HEAT radiation & absorption

Abstract

This research focuses on exploring the significance of chemical reactions and thermal radiation on the magnetohydrodynamic (MHD) flow of a Casson–Williamson nanofluid (CWNF) over a stretching sheet. The objective is to comprehend how these factors influence the flow and heat transfer. A mathematical model, comprising partial differential equations adjusted into ordinary differential equations (ODEs) via utilizing some transformation. These ODEs are then tackled by MATLAB's BVP4C method, which is part of the finite difference technique. Results are verified by comparison with existing literature and are depicted visually and in tabular format. Additionally, the study explores the effects of external factors such as magnetic fields and the Lewis number on parameters like Nusselt number, friction factor, and Sherwood number. Furthermore, heat generation in MHD CWNF is analyzed, along with a thorough evaluation of heat transfer near a stretching sheet with a permeable layer. The findings suggest that growing Brownian motion factor (N b) and thermophoresis coefficient (N t) enhance the rate of heat transfer, signifying improved heat transfer rates. Similarly, higher N t values are associated with enhanced Sherwood numbers, indicating better mass transfer. Conversely, higher N b values lead in lower local Sherwood numbers. Physically, an increase in Brownian motion causes significant displacement of nanofluid particles, boosting their kinetic energy and thereby enhancing heat generation within the boundary layer. It is noted that the Eckert number (Ec) reflects the impact of different Ec values on temperature distribution. As Ec increases, there is a proportional increase in fluid temperature due to frictional heating, which stores heat energy within the fluid. This effect becomes more pronounced for non-linear stretching surfaces, demonstrating the response of the thermal region to viscous dissipation. Viscous dissipation has the potential to enhance convective heat transfer, leading to amplified temperature distribution and thickening of the thermal layer. [ABSTRACT FROM AUTHOR]

Published

2024

41. Variable density and heat generation impact on chemically reactive carreau nanofluid heat-mass transfer over stretching sheet with convective heat condition

Author

Zia Ullah, Md Mahbub Alam, Uzma Tariq, Y.M. Mahrous, Feyisa Edosa Merga, Fethi Albouchi, Irfan Haider, and Abdullah A. Faqihi

Subjects

Heat generation, Chemical reaction, Convective heat conditions, Carreau nanofluid, Heat and mass transfer, Stretching sheet, Engineering (General). Civil engineering (General), TA1-2040

Abstract

The present study focuses on the physical significance of heat generation and chemical reaction on Carreau nanofluid with convective heat conditions. Heat transfer is characterized using convective boundary conditions. The governing partial differential equations (PDEs) are transformed into ordinary differential equations (ODEs) by using well define stream functions and similarity transformations. Using a shooting methodology, the Keller-box method with Newton Raphson scheme is used to elaborate the numerical solutions of physical phenomena. Utilizing a similar technique to find the impact of physical parameter such as the production of heat δ, the rate of reaction Λ, Biot numbers γ, Brownian motion variable Nb, the thermophoresis parameters Nt, the Weissenberg quantity We, Prandtl number Pr, and Lewis number Le on velocity profile, temperature profile and mass transmission profile are determined graphically. The skin-friction coefficient −f″(0), local Nusselt −θ′(0), and Sherwood numbers −ϕ′(0) are analyzed numerically. Increment in fluid velocity and slip temperature are depicted with high Biot number. Maximum magnitude of fluid temperature and fluid concentration function are depicted at high value of temperature dependent density. The magnitude of heat and mass transportation enhanced with maximum choice of Brownian motion.

Published

2024

42. Aviation aspects of engine oil conveying copper tiny particles embedded in a rotating disk with a binary chemical reaction

Author

Gunisetty Ramasekhar, Hijaz Ahmad, Dilber Uzun Ozsahin, and Maged F. Alotaibi

Subjects

Marangoni Maxwell fluid, Porous medium, Thermophoresis, Brownian motion, Non-linear radiation, Heat generation, Engineering (General). Civil engineering (General), TA1-2040

Abstract

Nanofluids have significant industrial applications and motivating heat transfer characteristics for various factors that contribute to the movement of nanofluids are essential significance. The aim of the present study focused on importance of heat transfer analysis on engine oil conveying copper nano particles embedded in a porous rotating disk with potential application in aerospace technology. In this model we considered magnetohydrodynamics, non-linear thermal radiation, thermophoresis and Brownian motion. The present investigation utilized copper nanoparticle and engine oil as a base fluid. The mathematical flow equations are transformed into ordinary differential equations (ODEs) by employing suitable self-similarity variables. The resultant ordinary differential equations are solved numerically by using the Midrich technique in the Maple software. The results are calculated to measure the impact of active parameters on velocity, temperature, concentration equations are presented graphically and in tabular form. Higher values of the magnetic field parameter the velocity profile decreased while the opposite tendency we noticed on energy profile. When increasing the radiation parameter values the energy profile increased. In both cases when increasing the magnetic field and radiation parameter values the Nusselt number profile increased. The research has important implications in a number of real-world situations. In particularly, the advancement of aircraft technology has presented manufacturers with new criteria and problems for the functioning of their devices. It is essential that, in order to guarantee the secure operation of aerospace machinery, the failure mechanisms be identified and the operational durability of critical structural components be improved as quickly as possible.

Published

2024

43. Thermal efficiency of radiated nanofluid through convective geometry subject to heating source

Author

Naim Ben Ali, Adnan, Zafar Mahmood, Mutasem Z. Bani-Fwaz, Sami Ullah Khan, and Iskander Tlili

Subjects

Nanofluids, Thermal Radiation, Heat Generation, Engineering (General). Civil engineering (General), TA1-2040

Abstract

Significance of nanofluids cannot be overlooked because of their enhanced characteristics which play vibrant role in their thermal performance. These make them more effective for practical applications. Addition of multiple types of nanoparticles potentially affect the thermal conductivity of base fluid which directly contribute in the heat transfer mechanism. Hence, the current work deals with the study of tetra nanofluid model including the influence of different parameters. The results obtained through numerical approach and examined that the fluid motion enhanced at variable saddle/nodal regions and reverse variations examined for higher λ values. The inclusion of surface convection Bi=0.1,0.2,0.3,0.4 particles concentration from 0.04 to 0.16, heat generation factor (Q1=0.5,1.0,1.5,2.0) and radiation effects (Rd=1.0,2.0,3.0,4.0) are observed reliable physical tools to enhance the heat performance of nanofluids which is advantageous from engineering as well as industrial point of view. Further, thermal boundary layer enlarges for Rd and reduced for Q1 and nanoparticles strength ϕi,i=1,2,3.

Published

2024

44. The numerical and experimental investigation of the transient behaviours of a lithium-ion pouch battery cell under dynamic conditions

Author

Berkay Tahirağaoğlu, Gökhan Sevilgen, and Halil Sadettin Hamut

Subjects

Transient model, Pouch cell, Heat generation, Dynamic conditions, Engineering (General). Civil engineering (General), TA1-2040

Abstract

In this paper, the transient model of a high energy density Lithium-ion pouch battery cell is developed under dynamic conditions. The battery cell has a capacity of 73 Ah and volumetric energy density of 642 Wh L−1. This is one of the few studies included the electro-thermal behaviour of high energy density battery under transient conditions by using second ordered model. The transient model indicated that the state of charge (SOC) decreased by 7 % at the end of the WLTP driving cycle and this value is good agreement with the experimental data. Moreover, the developed model provides an accurate prediction of the terminal voltage with a R2 value of 0.99 and a maximum relative error of 2.0 %. Furthermore, the proposed model predicts the electro-thermal characteristics more precisely and the heat generation rate and the entropic term can also be determined without using measurement device. The calculated total heat emitted from battery is about 6W at 1 C-rate for constant current and the heat generation rate is a peak value of ±1.75 105 Wm−3 under dynamic conditions. By using the estimated heat generation rate, more effective cold plates will be designed for thermal management of high energy density battery cells.

Published

2024

45. Thermal magnetization transport analysis featuring darcian and multi-physical rheological characteristics in chemically reactive dual convective tangent-hyperbolic nanomaterial confined by vertical cone

Author

Lihong Zhang, M. Nasir, M. Salman Kausar, Mawaheb Al-Dossari, M. Waqas, W.A. Khan, and Dilsora Abduvalieva

Subjects

Chemical reaction, Tangent-hyperbolic nanomaterial, Brownian motion, Heat generation, Thermal radiation, Soret-Dufour effect, Engineering (General). Civil engineering (General), TA1-2040

Abstract

The Soret-Dufour characteristics elaborate the phenomena of cross-diffusion where solutal gradients yield heat flux (Dufour aspect) and thermal gradients engender mass flux (Soret effect). Such consideration finds significance in multi-component fluid systems, influencing both heat-mass transportation processes. This study evaluates the porous medium characteristics in convectively heated tangent-hyperbolic nanomaterial driven by a magnetized convected cone. The analysis features Buongiorno nanomaterial model which accounts Brownian motion together with thermophoresis. Thermal transport expression which reports heat transfer characteristics is modeled by considering thermal radiation, convective thermal conditions and heat generation while mass transfer considers the chemical reaction effects. Dimensional expressions are converted into dimensionless forms deploying similarity transformations ensuing in a set of ODEs (ordinary differential expressions) which are computed by deploying bvp4c algorithm. Graphical and tabular behavior of velocity, nanoparticles concentration and temperature fields is inspected corresponding to related variables. This research highlights key findings, revealing a decrease in Nusselt number with increasing heat generation, Dufour parameter and thermophoresis parameter values while opposite trends are verified for radiation parameter values. The velocity function declines for escalating Weissenberg number, magnetic field and permeability parameters but it upsurges with material and buoyancy parameters.

Published

2024

46. Bake It Till You Make It

Author

Dev M. Mehta, Mohammad Hashemi, David S. Koblah, Domenic Forte, and Fatemeh Ganji

Subjects

Side-channel Analysis, Masking, Neural Networks, Heat Generation, T-test, DPA, Computer engineering. Computer hardware, TK7885-7895, Information technology, T58.5-58.64

Abstract

Masking has become one of the most effective approaches for securing hardware designs against side-channel attacks. Regardless of the effort put into correctly implementing masking schemes on a field-programmable gate array (FPGA), leakage can be unexpectedly observed. This is due to the fact that the assumption underlying all masked designs, i.e., the leakages of different shares are independent of each other, may no longer hold in practice. In this regard, extreme temperatures have been shown to be an important factor in inducing leakage, even in correctlymasked designs. This has previously been verified using an external heat generator (i.e., a climate chamber). In this paper, we examine whether the leakage can be induced using the circuit components themselves without making any changes to the design. Specifically, we target masked neural networks (NNs) in FPGAs, one of the main building blocks of which is block random access memory (BRAM). In this respect, thanks to the inherent characteristics of NNs, our novel internal heat generators leverage solely the memories devoted to storing the user’s input, especially when frequently writing alternating patterns into BRAMs. The possibility of observing first-order leakage is evaluated by considering one of the most recent and successful first-order secure masked NNs, namely ModuloNET. ModuloNET is specifically designed for FPGAs, where BRAMs are used to store inputs and intermediate computations. Our experimental results demonstrate that undesirable first-order leakage can be observed and exploited by increasing the temperature when an alternating input is applied to the masked NN. To give a better understanding of the impact of extreme heat, we further perform a similar test on the design using an external heat generator, where a similar conclusion can be drawn.

Published

2024

47. Characterization of Heat Generation and Its Impact with Cell Aging in a Lithium Ion Cell Using Coupled Electrochemical–Thermal Model

Author

Velumani, Deepika, Bansal, Ankit, Tatiparti, Sankara Sarma V., editor, and Seethamraju, Srinivas, editor

Published

2024

48. Physico-Chemical and Thermal Transformations of Wood of Long-Term Natural Ageing

Author

Almenbaev, M. M., Makishev, J. K., Rakhmetulin, B. J., Sivenkov, A. B., Makovická Osvaldová, Linda, editor, Hasburgh, Laura E., editor, and Das, Oisik, editor

Published

2024

49. MHD Convective Flow of Chemically Reacting Viscoelastic Fluid Through an Infinite Inclined Plate via Machine Learning

Author

Reddy, Poli Chandra, Hari Babu, B., Sanjeeva Kumar, P. V., Rama Mohan Reddy, L., Kacprzyk, Janusz, Series Editor, Gunjan, Vinit Kumar, editor, Zurada, Jacek M., editor, and Singh, Ninni, editor

Published

2024

50. Utilization of variable thermal conductivity and diffusion coefficient on non-Newtonian Prandtl model with modified heat and mass fluxes

Author

Sohail, Muhammad and Abbas, Syed Tehseen

Published

2024