Radiative-conductive Heat Transfer Research Articles

Inhomogeneous steady-state problem of complex heat transfer

An inhomogeneous steady-state problem of radiative-conductive heat transfer in a three-dimensional domain is studied in the framework of the P1 approximation of the nonlinear complex heat transfer model. The unique solvability of the problem is proved. The Lyapunov stability of solutions is shown.

Diffusion approximation of the radiative-conductive heat transfer model with Fresnel matching conditions

The paper is concerned with a problem of diffraction type. The study starts with equations of complex (radiative and conductive) heat transfer in a multicomponent domain with Fresnel matching conditions at the interfaces. Applying the diffusion, P1, approximation yields a pair of coupled nonlinear PDEs describing the radiation intensity and temperature for each component of the domain. Matching conditions for these PDEs, imposed at the interfaces between the domain components, are derived. The unique solvability of the obtained problem is proven, and numerical experiments are conducted.

Improved social spider optimization algorithms for solving inverse radiation and coupled radiation–conduction heat transfer problems

A novel bio-inspired swarm algorithm, social spider optimization (SSO), is introduced to solve the inverse transient radiation and coupled radiation–conduction problems for the first time. Based on the original model, five improved SSO (ISSO) algorithms are developed to enhance search ability and convergence velocity. The sensitivity analysis of measured signals with respect to the physical parameters of the medium are described. After which, the SSO and ISSO algorithms are applied to solve the inverse estimation problems in a one-dimensional participating medium. Two cases concerns radiative transfer problems are investigated, in which the radiative source term, extinction coefficient, scattering albedo, and scattering symmetry factor are reconstructed. Furthermore, the coupled radiation–conduction heat transfer model is considered and the main parameters such as the conduction–radiation parameter, boundary emissivity, and scattering albedo are retrieved. All retrieval results show that SSO-based algorithms are robust and effective in solving inverse estimation problems even with measurement errors. Findings also show that the proposed ISSO algorithms are superior to the original SSO model in terms of computational accuracy and convergence velocity.

Asymptotic approximations for the stationary radiative-conductive heat transfer problem in the two-dimensional system of plates

Abstract Special asymptotic approximations, namely, the first and second homogenized problems are proposed for the boundary value problem describing a stationary radiative-conductive heat transfer in a two-dimensional system of heat-conducting plates of thickness ɛ separated by vacuum layers. The unique solvability of homogenized problems is proved, the comparison theorem is established, and estimates of solutions are obtained. The first homogenized problem has the error estimate of order O ( ε ) $ O(\sqrt{\varepsilon}) $ .

Unique Solvability of Stationary Radiative-Conductive Heat Transfer Problem in a System of Semitransparent Bodies

We consider the boundary value problem for a system of differential equations consisting of the stationary nonlinear heat equation and the integro-differential radiative transfer equation and describing stationary radiative-conductive heat transfer in a system of semitransparent bodies, taking into account the effects of reflection and refraction of radiation according to the Fresnel laws at the boundaries of bodies. We take into account the dependence of radiation intensity and optical properties of bodies on the radiation frequency. We establish the existence and uniqueness of a weak solution. We prove the comparison theorem and derive a priori estimates for weak solutions and obtain a regularity result.

Numerical quantification of coupling effects for radiation-conduction heat transfer in participating macroporous media: Investigation of a model geometry

Radiative-conductive heat transfer in porous media is usually investigated by decoupling the heat transfer modes and solving the volume-averaged continuum equations using effective transport properties. However, both modes are naturally coupled and coupling effects might significantly affect the results. We aim at providing quantitative understanding of the coupling effects occurring in a model geometry. This is an important first step towards improving the accuracy of heat transfer predictions in engineering applications.We developed a numerical method using a structured mesh, cell centered finite volumes and Monte Carlo ray tracing techniques in order to simulate the 3-dimensional and unsteady coupled radiative-conductive heat transfer in semitransparent macroporous media. We have optimized the numerical method with regards to memory and computational requirements leading to optimal performance and allowing to perform a parameter variation study for various steady state cases.We conducted a parameter study considering different optical and thermal material properties and boundary conditions in order to quantify the coupling effect between conduction and radiation, and to demonstrate its dependencies. In terms of thermal properties, it was found that the ratio of bulk thermal conductivities is governing the coupling effect. A distinct peak at a given conductivity ratio was found. The influence of optical properties is discussed in details. It was found that a significant coupling effect exists, reaching up to 15% of the total thermal heat flux.The verified modeling framework in conjunction with our non-dimensionalization offers a tool to investigate the importance of radiation-conduction coupling in a quantitative manner. It is an important step towards understanding the detailed mechanisms of radiation and conduction coupling and provides engineering guidelines on the importance of these effects.

Analyses of unsteady conduction-radiation heat transfer using unstructured Lattice Boltzmann method

This paper deals with the analyses of unsteady conduction-radiation heat transfer problem in 2-D irregular geometries using the Control Volume- Lattice Boltzmann Method (CVLBM for short). The energy and radiative transfer equations were discretized and a computer code was developed to solve the obtained algebraic equations. Using this code, different problems were numerically simulated and it was noticed that i) the results given by the CVLBM and the Control Volume Finite Element Method (CVFEM) are in good agreement, ii) compared to the blocked-off method, the CVLBM gives more accurate results and needs less number of control volumes, iii) the conduction to radiation heat transfer ratio depends not only on the medium properties (thermal conductivity and extinction coefficient) and temperature but also on the boundary conditions (wall emissivity, convective heat transfer coefficient, applied heat flux) and iv) for the unsteady problem, the conduction to radiation heat transfer ratio increases with time (from a value of zero) to reach a constant value at the steady state (SS). In addition, it was numerically demonstrated that the conduction to radiation heat transfer ratio can be estimated more precisely using the dimensionless number NCR=λβσTref3 than using the expression NCR=λβ4σTref3 used in all previous works.

Coupled radiative-conductive heat transfer problems in complex geometries using embedded boundary method

This study is aimed to analyze combined radiative and conductive heat transfer in two-dimensional irregular geometries using the embedded boundary treatment in Cartesian coordinate system. The main advantage of Cartesian formulation is to simplify grid generation and using efficient Cartesian solvers for problems with complex geometries. The discrete ordinates method is used for angular discretization of radiative transfer equation (RTE) in a participating medium and the finite volume method is used for spatial discretization of RTE and the energy equation. First, the required equations to implement the embedded boundary method in combined conductive-radiative problems are developed. Then, this method is employed to solve several coupled conductive-radiative problems associated with the complex geometry. To assess the accuracy and investigate various characteristics of the embedded boundary method, the results are compared with the other methods for analyzing of irregular geometries, i.e. the blocked-off method and the body-fitted treatment. The results showed that the embedded boundary method is an efficient approach for investigation heat transfer problems of combined conduction-radiation in complex enclosures including inclined or curved boundaries using Cartesian grid system. Especially for calculations near the complex boundaries, this method has high priority over the blocked-off method.

Numerical Simulation of Radiative-Conductive Heat Transfer in an Enclosure with an Isotherm Obstacle

ABSTRACTIn this paper, the lattice Boltzmann method (LBM) and discrete ordinates method (DOM) were applied to investigate the heat transfer in a square radiative-conductive media with heat flux and temperature boundary conditions. Furthermore, an isothermal rectangular obstacle is located in the middle of participating media. The energy equation is solved using the LBM; while the radiative transfer equation is solved using DOM. The effects of various parameters such as the extinction coefficient, scattering albedo, and the conduction–radiation parameter in the presence of an obstacle are studied on temperature and heat flux distributions. It was shown that, decrease in scattering albedo value leads to decrease of the temperature field in participating media. In addition, with increase in scattering albedo value, conductive heat flux increases and radiative heat flux decreases. It was shown that increase in extinction coefficient and decrease in conduction–radiation parameter have some significant effects on increasing the temperature profile, especially in the region with longer distance from obstacle.

Mixed Convective Fully Developed Flow in a Vertical Channel in the Presence of Thermal Radiation and Viscous Dissipation

The effect of thermal radiation and viscous dissipation on a combined free and forced convective flow in a vertical channel is investigated for a fully developed flow regime. Boussinesq and Roseseland approximations are considered in the modeling of the conduction radiation heat transfer with thermal boundary conditions (isothermal-thermal, isoflux-thermal, and isothermal-flux). The coupled nonlinear governing equations are also solved analytically using the Differential Transform Method (DTM) and regular perturbation method (PM). The results are analyzed graphically for various governing parameters such as the mixed convection parameter, radiation parameter, Brinkman number and perturbation parameter for equal and different wall temperatures. It is found that the viscous dissipation enhances the flow reversal in the case of a downward flow while it counters the flow in the case of an upward flow. A comparison of the Differential Transform Method (DTM) and regular perturbation method (PM) methods shows the versatility of the Differential Transform Method (DTM). The skin friction and the wall temperature gradient are presented for different values of the physical parameters and the salient features are analyzed.

Prospective of employing high porosity open-cell metal foams in passive cryogenic radiators for space applications

Passive cryogenic radiators work on the principle of dissipating heat to the outer space purely by radiation. High porosity open-cell metal foams are a relatively new class of extended surfaces. These possess the advantages of high surface area density and low weight, characteristics which the space industry looks for. In case of radiative heat transfer, the porous nature of metal foams permits a deeper penetration of the incident radiation. Consequently, the heat transfer area participating in radiative heat exchange increases thereby enhancing the heat transfer rate. However, effective heat conduction in between the foam struts reduces as a result of the void spaces. These two conflicting phenomenon for radiation heat transfer in metal foams have been studied in this work. Similar to the foam conduction-convection heat transfer analysis, a conduction-radiation heat transfer model has been developed for metal foams in analogy with the conventional solid fin theory. Metal foams have been theoretically represented as simple cubic structures. A comparison of the radiative heat transfer through metal foams and solid fins attached to a surface having constant temperature has been presented. Effect of changes in foam characteristic properties such as porosity and pore density have also been studied.

An Iterative Method for Solving of Coupled Equations for Conductive-Radiative Heat Transfer in Dielectric Layers

The mathematical model for describing combined conductive-radiative heat transfer in a dielectric layer, which emits, absorbs, and scatters IR radiation both in its volume and on the boundary, has been considered. A nonlinear stationary boundary-value problem for coupled heat and radiation transfer equations for the layer, which exchanges by energy with external medium by convection and radiation, has been formulated. In the case of optically thick layer, when its thickness is much more of photon-free path, the problem becomes a singularly perturbed one. In the inverse case of optically thin layer, the problem is regularly perturbed, and it becomes a regular (unperturbed) one, when the layer’s thickness is of order of several photon-free paths. An iterative method for solving of the unperturbed problem has been developed and its convergence has been tested numerically. With the use of the method, the temperature field and radiation fluxes have been studied. The model and method can be used for development of noncontact methods for temperature testing in dielectrics and for nondestructive determination of its radiation properties on the base of the data obtained by remote measuring of IR radiation emitted by the layer.

Modeling of radiative - conductive heat transfer in compositing materials

A layer of composite material is investigated, which is heated one-sidedly with one-dimensional energy transfer accounting for thermal conductivity and radiation. A mathematical model is suggested for non-stationary coefficient thermophysical problem under radiative-conductive heat transfer in a material layer. Temperature dependencies of thermal capacity and thermal conductivity coefficient of composite radio-transparent material have been determined through numerical modeling by solving the coefficient reverse problem of thermal conductivity.

Аппроксимации стационарной задачи радиационно-кондуктивного теплообмена в системе стержней круглого сечения

In applications, it is of great importance to study the heat transfer process in periodic media containing vacuum interlayers or cavities through which the heat transfer is realized by radiation. A numerical solution of such problems requires considerable computational efforts and becomes, in fact, impossible for a large number of heat transferring elements, especially in the case of two-dimensional and three-dimensional structures. Therefore, it is important to construct effective approximation methods. This article continues a series of papers devoted to the construction and substantiation of special semi-discrete and asymptotic approximations of radiation-conductive heat transfer problems in periodic systems of heat-conducting elements separated by a vacuum. In this paper, we consider a stationary problem of radiation-conductive heat transfer in a periodic system consisting of absolutely black heatconducting rods of circular cross section with radius e packed in a square box. We constract two new approximate methods based on special discrete and asymptotic approximations of the original problem. The results of computational experiments are given, which make it possible to draw conclusions about the efficiency of methods and the nature of the dependence of their relative errors on the coefficient of thermal conductivity λ and the radius of the rods e. The seeking value is the absolute temperature. This function is the solution of the boundary-value problem for the stationary heat equation with nonlinear nonlocal intregral conditions describing the heat exchange by a radiation between the rods. Assuming that the temperature on each of the rods is approximately equal to the mean value over the cross section, we comstruct a discrete approximation of the original problem, which is a system of linear algebraic equations with respect to the fourth power of a temperature. Since the matrix of the system is symmetric and positive definite, the method of conjugate gradients can be used to solve it numerically. By its structure, the discrete problem is such that it can be considered as a difference approximation of the homogenized boundary-value problem for the Poisson equation with non-standard boundary conditions. This problem, which we consider as an asymptotic approximation of the original problem, is linear with respect to the fourth power of temperature. A series of computational experiments is carried out, which confirms the operability of the proposed methods for materials with a large coefficient of thermal conductivity. The relative errors of the methods tend to zero as the parameter tends to zero. For a fixed value of radius e, the relative errors of the methods decrease with increasing values of the thermal conductivity, reaching values in the tenths of a percent. As expected, both methods are practically unsuitable for poorly conductive materials and require substantial modification.

Diffusion Approximation to Radiation Heat Transfer in Semitransparent Medium

Conduction-radiation heat transfer problem is usually formulated with a highly nonlinear integrodifferential equation. In this paper we describe a simple technique for modeling radiation heat transfer in a semi-transparent medium with arbitrary varying spectral absorption coefficient and purpose a computational model (described by a coupled system of elliptic-parabolic PDEs) based on flux limited diffusion theory. Numerical simulations of a glass cooling problem in one dimension show that the proposed method is comparable to a higher order discrete ordinate (S8) method.

The errors when determining the thermophysical characteristics of liquids by the laser flash method

The analysis of errors in determining the thermophysical characteristics of typical organic liquids, specified by conductive-radiative heat transfer of ultrathin heated up to high temperature sample layer, under conditions consistent with the implementation of the laser pulse method, when exposed to the surface of the collimated laser pulse of finite duration was made. The influence to the error of the radiation absorption process was discovered.

Multi-parameter estimation in semitransparent graded-index media based on coupled optical and thermal information

An inverse conduction-radiation analysis is presented for estimating multi-parameter in semitransparent graded-index media from measured coupled optical and thermal information. The boundary radiative signals (optical information) and temperature distribution within the media (thermal information) are served as measurement data. The direct coupled conduction-radiation heat transfer problems are solved by the Chebyshev collocation spectral method. The stochastic particle swarm optimization (SPSO) was employed to estimate the multi-parameter including graded refractive index, absorption coefficient and conduction-radiation parameter. Only using the optical information is enough in estimation of graded refractive index and simultaneous estimation of graded refractive index and absorption coefficient when the conduction-radiation parameter is known. It was found that an increase of measurement noise significantly deteriorated the estimation accuracy of multi-parameter by using single optical or thermal information. To address this issue, coupled optical and thermal information was suggested to be adopted as input to estimate multi-parameter simultaneously. All the simulation results show that SPSO can estimate the multi-parameter of semitransparent graded-index media accurately based on coupled optical and thermal information even with noise. The results obtained show that the proposed methodology is a promising approach for accurate estimation of multi-parameter in semitransparent graded-index media.

An advanced model of heat and mass transfer in the protective clothing - verification

The paper presents an advanced mathematical and numerical models of heat and mass transfer in the multi-layers protective clothing and in elements of the experimental stand subjected to either high surroundings temperature or high radiative heat flux emitted by hot objects. The model included conductive-radiative heat transfer in the hygroscopic porous fabrics and air gaps as well as conductive heat transfer in components of the stand. Additionally, water vapour diffusion in the pores and air spaces as well as phase transition of the bound water in the fabric fibres (sorption and desorption) were accounted for. The thermal radiation was treated in the rigorous way e.g.: semi-transparent absorbing, emitting and scattering fabrics were assumed a non-grey and all optical phenomena at internal or external walls were modelled. The air was assumed transparent. Complex energy and mass balance as well as optical conditions at internal or external interfaces were formulated in order to find exact values of temperatures, vapour densities and radiation intensities at these interfaces. The obtained highly non-linear coupled system of discrete equation was solve by the in-house iterative algorithm which was based on the Finite Volume Method. The model was then successfully partially verified against the results obtained from commercial software for simplified cases.

Simultaneous estimation of thermal conductivity and specific heat of thermal protective fabrics using experimental data of high heat flux exposure

In the present study, ant colony optimization algorithm is used for an inverse heat transfer problem of parameter estimation. Temperature dependent thermal conductivity and specific heat are estimated simultaneously. Performance of the present algorithm is first analyzed by using the temperature data obtained from the solution of direct problem. Effect of measurement error on the property estimation is then analyzed. Accuracy of estimated properties is found to be good in both the cases. Experiments are then conducted on a cotton duck fabric exposed to 40kW/m2 radiant heat flux using a bench top test according to ISO 6942. Temporal variation of sensor temperature is used to estimate the thermal conductivity and specific heat of the fabric sample. The estimated values are in agreement with the results available in the literature. Property values estimated in the study are included in a coupled conduction-radiation heat transfer model for fabrics. Performance of the fabric sample is further analyzed with the numerical model for high heat fluxes. The simulation results compare quite well with experimental data at 80kW/m2 radiant heat and 70kW/m2 flame exposures. Flame exposure experiment is conducted according to ISO 9151. Good agreement between the numerical and experimental results are found for both the exposures.

Calculation of combined conduction-radiation heat transfer reduction using thick concentric spheres with temperature-dependent emissivity as radiation shields

In this study, the rate of conduction-radiation heat transfer between two thick concentric spheres is analytically investigated because of the ever-increasing importance of radiation shield applications. The heat transfer rate, the percentage of reduction in heat transfer, temperature and emissivity of surfaces are calculated when one and two thick radiation shields are placed between two thick spheres. The calculations show that the use of a radiation shield with a lower emissivity is better than two radiation shields with a higher emissivity to reduce the heat transfer rate. In addition, optimal combinations of radiation shields with different materials are proposed.