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Heat transfer – a review of 2005 literature. (English) Zbl 1197.80002
Summary: The present review is intended to encompass the heat transfer literature published in 2005. While of a wide-range in scope, some selection is inevitable. We restrict ourselves to papers published in English through a peer-review process, with selected translations from journals published in other languages. Papers from conference proceedings generally are not included, though the Proceeding itself may be cited in the introduction. A significant fraction of the papers reviewed herein relates to the science of heat transfer, including experimental, analytical and numerical studies. Other papers cover applications where heat transfer plays a major role, not only in man-made devices but in natural systems as well. The papers are grouped into major subject areas and then into subfields within these areas. In addition to reviewing the literature, we mention major conferences held in 2005, major awards related to heat transfer presented in 2005, and books on heat transfer published during the year.

MSC:
80-00 General reference works (handbooks, dictionaries, bibliographies, etc.) pertaining to classical thermodynamics
80-02 Research exposition (monographs, survey articles) pertaining to classical thermodynamics
80-03 History of classical thermodynamics
01A90 Bibliographic studies
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References:
[1] Gubarev, V. Y.; Shatskikh, Y. V.: Heat transfer between a gas-droplet medium and a high-temperature surface, High temperature 43, No. 5, 775-780 (2005)
[2] Heichal, Y.; Chandra, S.: Predicting thermal contact resistance between molten metal droplets and a solid surface, Journal of heat transfer 127, No. 11, 1269-1275 (2005)
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[30] Huang, C. H.; Tsai, Y. L.: A transient 3-D inverse problem in imaging the time-dependent local heat transfer coefficients for plate fin, Applied thermal engineering 25, No. 14 – 15, 2478-2495 (2005)
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[38] Fukuyo, K.: Power-series method for two-dimensional heat conduction PROBLEMS, Numerical heat transfer, part B: fundamentals 47, No. 3, 239-255 (2005)
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[40] Kholpanov, L. P.; Zakiev, S. E.: Fractional integro-differential analysis of heat and mass transfer, Journal of engineering physics and thermophysics 78, No. 1, 33-46 (2005)
[41] Sadat, H.: A general lumped model for transient heat conduction in one-dimensional geometries, Applied thermal engineering 25, No. 4, 567-576 (2005)
[42] Strub, F.: Second law analysis of periodic heat conduction through a wall, International journal of thermal sciences 44, No. 12, 1154-1160 (2005)
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[48] Huang, C. H.; Lo, H. C.: A three-dimensional inverse problem in predicting the heat fluxes distribution in the cutting tools, Numerical heat transfer; part A: applications 48, No. 10, 1009-1034 (2005)
[49] Kennedy, T. C.; Traiviratana, S.: Transient effects on heat conduction in sliding bodies, Numerical heat transfer; part A: applications 47, No. 1, 57-77 (2005)
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[53] Lyra, P. R. M.: An axisymmetric finite volume formulation for the solution of heat conduction problems using unstructured meshes, Journal of the Brazilian society of mechanical sciences and engineering 27, No. 4, 407-414 (2005)
[54] Mishra, S. C.; Lankadasu, A.: Transient conduction-radiation heat transfer in participating media using the lattice Boltzmann method and the discrete transfer method, Numerical heat transfer; part A: applications 47, No. 9, 935-954 (2005)
[55] Simoes, N.; Tadeu, A.: 3D transient heat transfer by conduction and convection across a 2D medium using a boundary element model, CMES - computer modeling in engineering and sciences 9, No. 3, 221-233 (2005)
[56] Tsourkas, P.; Rubinsky, B.: A parallel genetic algorithm for heat conduction problems, Numerical heat transfer, part B: fundamentals 47, No. 2, 97-110 (2005)
[57] Beh, S. L.: Steady and unsteady thermal analysis of a triple stack cold plate with heat losses, International journal of numerical methods for heat and fluid flow 15, No. 1, 96-112 (2005) · Zbl 1162.76389
[58] Chen, C. K.; Wu, L. W.; Yang, Y. T.: Estimation of unknown outer-wall heat flux in turbulent circular pipe flow with conduction in the pipe wall, International journal of heat and mass transfer 48, No. 19 – 20, 3971-3981 (2005) · Zbl 1188.76216 · doi:10.1016/j.ijheatmasstransfer.2005.04.022
[59] Cheng, C. H.; Chang, M. H.: Identification of unknown heating elements embedded in a rectangular package, Journal of heat transfer 127, No. 8, 918-930 (2005)
[60] Dai, T.: Thermal analysis of a conduction-cooled HTS coil with heat disturbances, IEEE transactions on applied superconductivity 15, No. 2 PART II, 1679-1682 (2005)
[61] Gerstenmaier, Y. C.; Wachutka, G. K. M.: Transient temperature fields with general nonlinear boundary conditions in electronic systems, IEEE transactions on components and packaging technologies 28, No. 1, 23-33 (2005)
[62] Ha, S. H.; Cho, S.: Topological shape optimization of heat conduction problems using level set approach, Numerical heat transfer, part B: fundamentals 48, No. 1, 67-88 (2005)
[63] Ho, C. I.; Hung, T. C.; Hung, C. I.: Thermal analysis and optimization for a ball grid array package, Proceedings of the institution of mechanical engineers, Part C: Journal of mechanical engineering science 219, No. 4, 381-393 (2005)
[64] Iesan, D.; Nappa, L.: On the theory of heat for micromorphic bodies, International journal of engineering science 43, No. 1 – 2, 17-32 (2005) · Zbl 1211.74071 · doi:10.1016/j.ijengsci.2004.09.003
[65] Kuznetsov, G. V.; Sheremet, M. A.: Spatial simulation of heat transfer through protective structures in conditions of heterogeneous heat exchange on the boundaries, Heat transfer research 36, No. 8, 631-639 (2005)
[66] Rozniakowska, M.; Yevtushenko, A. A.: Influence of laser pulse shape both on temperature profile and hardened layer depth, Heat and mass transfer/waerme- und stoffuebertragung 42, No. 1, 64-70 (2005)
[67] Siakavellas, N. J.; Georgiou, D. P.: 1D heat transfer through a flat plate submitted to step changes in heat transfer coefficient, International journal of thermal sciences 44, No. 5, 452-464 (2005)
[68] Su, S.: Comparison of the solutions of a phase-lagging heat transport equation and damped wave equation, International journal of heat and mass transfer 48, No. 11, 2233-2241 (2005) · Zbl 1189.80029 · doi:10.1016/j.ijheatmasstransfer.2004.12.024
[69] Su, Y. X.: Revised CFB wall-to-suspension heat transfer model, Journal of dong hua university (English edition) 22, No. 1, 97-101 (2005)
[70] Teertstra, P.; Yovanovich, M. M.; Culham, J. R.: Modeling transient conduction in enclosed regions between isothermal boundaries of arbitrary shape, Journal of thermophysics and heat transfer 19, No. 3, 382-387 (2005)
[71] Veselovskii, V. B.: Mathematical modeling of heat transfer in enhancement of the heating processes of solid bodies, Heat transfer research 36, No. 8, 691-696 (2005)
[72] Xiao, D.: Transient conduction analytical solutions for testing of building energy simulation programs, Building services engineering research and technology 26, No. 3, 229-247 (2005)
[73] Yang, C. Y.: Estimation of multiple heat sources in two-dimensional heat conduction problems, Journal of thermophysics and heat transfer 19, No. 3, 388-394 (2005)
[74] Zhou, H.; Li, D.: Modeling and simulation of heat transfer for Glass bulb mold, Progress in natural science 15, No. 7, 650-655 (2005)
[75] Yevtushenko, A.; Matysiak, S. J.: On approximate solutions of temperature and thermal stresses in an elastic semi-space due to laser heating, Numerical heat transfer; part A: applications 47, No. 9, 899-915 (2005)
[76] Aizaz, A.; Mcmasters, R. L.: Detection of hot spot through inverse thermal analysis in superconducting RF cavities, International journal of heat and mass transfer 48, No. 21 – 22, 4562-4568 (2005) · Zbl 1189.80035 · doi:10.1016/j.ijheatmasstransfer.2005.05.034
[77] Deng, H.: Combination of inverse and neural network methods to estimate heat flux, Numerical heat transfer; part A: applications 47, No. 6, 593-607 (2005)
[78] Keanini, R. G.; Ling, X.; Cherukuri, H. P.: A modified sequential function specification finite element-based method for parabolic inverse heat conduction problems, Computational mechanics 36, No. 2, 117-128 (2005) · Zbl 1101.80003 · doi:10.1007/s00466-004-0644-3
[79] Luo, J.; Shih, A. J.: Inverse heat transfer solution of the heat flux due to induction heating, Journal of manufacturing science and engineering, transactions of the ASME 127, No. 3, 555-563 (2005)
[80] Wang, H. M.: Adaptive-weighting input-estimation approach to nonlinear inverse heat-conduction problems, Journal of thermophysics and heat transfer 19, No. 2, 209-216 (2005)
[81] Zueco, J.; Alhama, F.; Fernández, C. F. González: Numerical nonlinear inverse problem of determining wall heat flux, Heat and mass transfer/waerme- und stoffuebertragung 41, No. 5, 411-418 (2005) · Zbl 1061.65093
[82] Absi, J.: Thermal response of two-layer systems: numerical simulation and experimental validation, Journal of the European ceramic society 25, No. 4, 367-373 (2005)
[83] Battaglia, J. L.; Puigsegur, L.; Cahuc, O.: Estimated temperature on a machined surface using an inverse approach, Experimental heat transfer 18, No. 1, 13-32 (2005)
[84] Ignaczak, J.: The second law of thermodynamics for a two-temperature model of heat transport in metal films, Journal of thermal stresses 28, No. 9, 929-942 (2005)
[85] Kargarnovin, M. H.; Zarei, A. Rezai; Darijani, H.: Wall thickness optimization of thick-walled spherical vessel using thermo-elasto-plastic concept, International journal of pressure vessels and piping 82, No. 5, 379-385 (2005)
[86] Chao, J.: Effect of conjugate heat transfer on MEMS-based thermal shear stress sensor, Numerical heat transfer; part A: applications 48, No. 3, 197-217 (2005)
[87] Gross, S.: Identification of boundary heat fluxes in a falling film experiment using high resolution temperature measurements, International journal of heat and mass transfer 48, No. 25 – 26, 5549-5562 (2005)
[88] Ootao, Y.; Tanigawa, Y.: Three-dimensional solution for transient thermal stresses of functionally graded rectangular plate due to nonuniform heat supply, International journal of mechanical sciences 47, No. 11, 1769-1788 (2005) · Zbl 1192.74090 · doi:10.1016/j.ijmecsci.2005.06.003
[89] Alyaev, V. A.; Karchevskii, M. M.; Panfilovich, V. K.: Aircraft and rocket engine theory: a method for determining the conductive heat conduction coefficient of absorbing and radiating fluids, Russian aeronautics 48, No. 1, 61-65 (2005)
[90] Attetkov, A. V.; Volkov, I. K.; Tverskaya, E. S.: Optimum thickness of a cooled wall in local pulse-periodic heating, Journal of engineering physics and thermophysics 78, No. 2, 216-224 (2005)
[91] Girault, M.; Petit, D.; Conduction, Identification Methods In Nonlinear Heat: Part II: Inverse problem using a reduced model, International journal of heat and mass transfer 48, No. 1, 119-133 (2005) · Zbl 1098.80004 · doi:10.1016/j.ijheatmasstransfer.2004.06.033
[92] Girault, M.; Petit, D.: Identification methods in nonlinear heat conduction, part I: Model reduction, International journal of heat and mass transfer 48, No. 1, 105-118 (2005) · Zbl 1098.80003 · doi:10.1016/j.ijheatmasstransfer.2004.06.032
[93] Gupta, R.; Tuli, S.: Electro-thermal modelling and analysis for estimation of defect parameters by stepped infrared thermography, NDT and E international 38, No. 1, 11-19 (2005)
[94] Ibrahem, F. S.; Hassanien, I. A.; Bakr, A. A.: Nonclassical thermal effects in Stokes second problem for micropolar fluids, Journal of applied mechanics, transactions ASME 72, No. 4, 468-474 (2005) · Zbl 1111.74450 · doi:10.1115/1.1875412
[95] Kossecka, E.; Kosny, J.: Three-dimensional conduction z-transfer function coefficients determined from the response factors, Energy and buildings 37, No. 4, 301-310 (2005)
[96] Lee, J. F.: Complete heat transfer solutions of an insulated regular polyhedron by using an RPSWT model, Energy conversion and management 46, No. 13 – 14, 2232-2257 (2005)
[97] Sablani, S. S.: Non-iterative estimation of heat transfer coefficients using artificial neural network models, International journal of heat and mass transfer 48, No. 3 – 4, 665-679 (2005) · Zbl 1121.80312 · doi:10.1016/j.ijheatmasstransfer.2004.09.005
[98] Abidi, L.; Saghir, M. Z.; Labrie, D.: Use of an axial magnetic field to suppress convection in the solvent of ge0.98si0.02 grown by the travelling solvent method, International journal of materials and product technology 22, No. 1 – 3, 2-19 (2005)
[99] Emelianov, V. M.: Convection and heat transfer experiments in supercritical fluid under microgravity: from MIR to ISS, Microgravity science and technology 15, No. 1, 164-169 (2005)
[100] Helal, M. M.; Abd-El-Malek, M. B.: Group method analysis of magneto-elastico-viscous flow along a semi-infinite flat plate with heat transfer, Journal of computational and applied mathematics 173, No. 2, 199-210 (2005) · Zbl 1161.76605 · doi:10.1016/j.cam.2004.03.007
[101] Teamah, M. A.; Dawood, M. M. K.: Effect of angle of approach of the forced flow on the mixed convection heat transfer in air from an infinite isothermal horizontal cylinder, AEJ - Alexandria engineering journal 44, No. 2, 141-155 (2005)
[102] Wang, C. C.; Chen, C. K.: Mixed convection boundary layer flow on inclined wavy plates including the magnetic field effect, International journal of thermal sciences 44, No. 6, 577-586 (2005)
[103] El-Sayed, M. F.; Mohamed, A. A.; Metwaly, T. M. N.: Thermohydrodynamic instabilities of conducting liquid jets in the presence of time-dependent transverse electric fields, Physica A: statistical mechanics and its applications 345, No. 3 – 4, 367-394 (2005)
[104] Elaissi, S.: Electric discharge fluid modelling with the contribution of convective and drift energy effects, EPJ applied physics 32, No. 1, 37-44 (2005)
[105] Tashtoush, B.; Duwairi, H. M.; Al-Salaymeh, A.: Hydromagnetic flow on a power law stretching surface with suction and injection of non-Newtonian fluid, International journal of heat and technology 23, No. 1, 55-60 (2005)
[106] Yakut, K.: Effects of tapes with double-sided delta-winglets on heat and vortex characteristics, Applied energy 80, No. 1, 77-95 (2005)
[107] Zdanski, P. S. B.; Ortega, M. A.; Jr., N. G. C.R. Fico: Heat transfer studies in the flow over shallow cavities, Journal of heat transfer 127, No. 7, 699-712 (2005)
[108] Wiberg, R.; Lior, N.: Heat transfer from a cylinder in axial turbulent flows, International journal of heat and mass transfer 48, No. 8, 1505-1517 (2005)
[109] Webb, R. L.: Next generation devices for electronic cooling with heat rejection to air, Journal of heat transfer 127, No. 1, 2-10 (2005)
[110] Velayati, E.; Yaghoubi, M.: Numerical study of convective heat transfer from an array of parallel bluff plates, International journal of heat and fluid flow 26, No. 1, 80-91 (2005)
[111] Uzol, O.; Camci, C.: Heat transfer, pressure loss and flow field measurements downstream of staggered two-row circular and elliptical pin fin arrays, Journal of heat transfer 127, No. 5, 458-471 (2005)
[112] Thole, K. A.; Knost, D. G.: Heat transfer and film-cooling for the endwall of a first stage turbine vane, International journal of heat and mass transfer 48, No. 25 – 26, 5255-5269 (2005)
[113] Stripf, M.; Schulz, A.; Wittig, S.: Surface roughness effects on external heat transfer of a HP turbine vane, Journal of turbomachinery 127, No. 1, 200-208 (2005)
[114] Polley, G. T.; Abu-Khader, M. M.: Interpreting and applying experimental data for plate-fin surfaces: problems with power law correlation, Heat transfer engineering 26, No. 9, 15-21 (2005)
[115] Peles, Y.: Forced convective heat transfer across a pin fin micro heat sink, International journal of heat and mass transfer 48, No. 17, 3615-3627 (2005) · Zbl 1189.76502
[116] Naterer, G. F.: Surface micro-profiling for reduced energy dissipation and exergy loss in convective heat transfer, Microscale thermophysical engineering 9, No. 3, 213-236 (2005)
[117] Nowak, W.; Stachel, A. A.: Convective heat transfer in air flow around a cylinder at low Reynolds numbers, Journal of engineering physics and thermophysics 78, No. 6, 1214-1221 (2005)
[118] Nithiarasu, P.; Massarotti, N.; Mathur, J. S.: Forced convection heat transfer from solder balls on a printed circuit board using the characteristic based split (CBS) scheme, International journal of numerical methods for heat and fluid flow 15, No. 1, 73-95 (2005) · Zbl 1162.76392 · doi:10.1108/09615530510571967
[119] Mahmood, G. I.; Gustafson, R.; Acharya, S.: Experimental investigation of flow structure and Nusselt number in a low-speed linear blade passage with and without leading-edge fillets, Journal of heat transfer 127, No. 5, 499-512 (2005)
[120] Mishra, D. P.; Desai, T.: Numerical study of mixed convection heat transfer from thermal sources on a vertical surface, Modelling, measurement and control B 74, No. 1, 31-44 (2005)
[121] Medic, G.; Durbin, P. A.: Unsteady effects on trailing edge cooling, Journal of heat transfer 127, No. 4, 388-392 (2005)
[122] Maguire, L.; Behnia, M.; Morrison, G.: An experimental and computational study of heat transfer in high power amplifiers, Heat transfer engineering 26, No. 2, 81-92 (2005)
[123] Liu, I. C.; Kong, C. H.: Heat transfer of an electrically conducting viscoelastic fluid over a stretching sheet, Journal of mechanics 21, No. 1, 5-13 (2005)
[124] Lin, S. C.; Chuang, F. S.; Chou, C. A.: Experimental study of the heat sink assembly with oblique straight fins, Experimental thermal and fluid science 29, No. 5, 591-600 (2005)
[125] Khan, W. A.; Culham, J. R.; Yovanovich, M. M.: Fluid flow around and heat transfer from elliptical cylinders: analytical approach, Journal of thermophysics and heat transfer 19, No. 2, 178-185 (2005)
[126] Khan, W. A.; Culham, J. R.; Yovanovich, M. M.: Fluid flow around and heat transfer from an infinite circular cylinder, Journal of heat transfer 127, No. 7, 785-790 (2005)
[127] Khan, S. K.; Sanjayanand, E.: Viscoelastic boundary layer flow and heat transfer over an exponential stretching sheet, International journal of heat and mass transfer 48, No. 8, 1534-1542 (2005) · Zbl 1189.76139 · doi:10.1016/j.ijheatmasstransfer.2004.10.032
[128] Kanna, P. R.; Das, M. K.: Conjugate forced convection heat transfer from a flat plate by laminar plane wall jet flow, International journal of heat and mass transfer 48, No. 14, 2896-2910 (2005) · Zbl 1189.76488 · doi:10.1016/j.ijheatmasstransfer.2005.01.033
[129] Harahap, F.; Rudianto, E.: Measurements of steady-state heat dissipation from miniaturized horizontally-based straight rectangular fin arrays, Heat and mass transfer/waerme- und stoffuebertragung 41, No. 3, 280-288 (2005)
[130] Gawad, A. F. A.; Nassief, M. M.; Guirguis, N. M.: Numerical and neural study of flow and heat transfer across an array of integrated circuit components, Journal of engineering and applied science 52, No. 5, 981-1000 (2005)
[131] Dhiman, A. K.; Chhabra, R. P.; Eswaran, V.: Flow and heat transfer across a confined square cylinder in the steady flow regime: effect of Péclet number, International journal of heat and mass transfer 48, No. 21 – 22, 4598-4614 (2005) · Zbl 1189.76112 · doi:10.1016/j.ijheatmasstransfer.2005.04.033
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[817] Moawed, M.: Experimental investigation of natural convection from vertical and horizontal helicoidal pipes in HVAC applications, Energy conversion and management 46, No. 18 – 19, 2996-3013 (2005)
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[826] Burns, J. R.; Jachuck, R. J. J.: Determination of liquid – solid mass transfer coefficients for a spinning disc reactor using a limiting current technique, International journal of heat and mass transfer 48, No. 12, 2540-2547 (2005)
[827] Lock, G. D.: Heat transfer measurements using liquid crystals in a preswirl rotating-disk system, Journal of engineering for gas turbines and power 127, No. 2, 375-382 (2005)
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[832] Jin, L. F.; Tou, K. W.; Tso, C. P.: Effects of rotation on natural convection cooling from three rows of heat sources in a rectangular cavity, International journal of heat and mass transfer 48, No. 19 – 20, 3982-3994 (2005) · Zbl 1188.76252 · doi:10.1016/j.ijheatmasstransfer.2005.04.013
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[857] Lin, J. L.; Yang, C. S.: Heat transfer analysis of charring ablators under aerodynamic heating, Aircraft engineering and aerospace technology 77, No. 3, 214-221 (2005)
[858] Lin, W. S.: Steady ablation on the surface of a two-layer composite, International journal of heat and mass transfer 48, No. 25 – 26, 5504-5519 (2005) · Zbl 1188.76270 · doi:10.1016/j.ijheatmasstransfer.2005.06.040
[859] Bellettre, J.: Studies of the transpiration cooling through a sintered stainless steel plate, Experimental heat transfer 18, No. 1, 33-44 (2005)
[860] Celere, M.; Gostoli, C.: Heat and mass transfer in osmotic distillation with brines, glycerol and glycerol-salt mixtures, Journal of membrane science 257, No. 1 – 2, 99-110 (2005)
[861] Fujita, I.; Hihara, E.: Heat and mass transfer coefficients of falling-film absorption process, International journal of heat and mass transfer 48, No. 13, 2779-2786 (2005) · Zbl 1189.76062 · doi:10.1016/j.ijheatmasstransfer.2004.11.028
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[863] Garcia, R. A.; Cloutier, A.: Characterization of heat and mass transfer in the mat during the hot pressing of MDF panels, Wood and fiber science 37, No. 1, 23-41 (2005)
[864] Kurpaska, S.: Simulation of heat and moisture transfer in the greenhouse substrate due to a heating system by buried pipes, Biosystems engineering 90, No. 1, 63-74 (2005)
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[869] Kaeser, M.; Pritchard, C. L.: Heat transfer at the surface of sieve trays, Chemical engineering research and design 83, No. 8A, 1038-1043 (2005)
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[873] Yuen, C. H. N.; Martinez-Botas, R. F.: Film cooling characteristics of rows of round holes at various streamwise angles in a crossflow: part II. Heat transfer coefficients, International journal of heat and mass transfer 48, No. 23 – 24, 5017-5035 (2005)
[874] Bourouis, M.: Absorption of water vapour in the falling film of water-(LiBr + lii + lino3 + licl) in a vertical tube at air-cooling thermal conditions, International journal of thermal sciences 44, No. 5, 491-498 (2005)
[875] Bunker, R. S.: A review of shaped hole turbine film-cooling technology, Journal of heat transfer 127, No. 4, 441-453 (2005)
[876] Gambaryan-Roisman, T.; Alexeev, A.; Stephan, P.: Effect of the microscale wall topography on the thermocapillary convection within a heated liquid film, Experimental thermal and fluid science 29, No. 7 SPEC. ISS, 765-772 (2005)
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[886] Zhang, J.; Chang, H.: The interior heat transfer characteristics of gas turbine blade due to sparse film cooling holes, Heat transfer - asian research 34, No. 3, 197-206 (2005)
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[894] Thielen, L.: Predictions of flow and heat transfer in multiple impinging jets with an elliptic-blending second-moment closure, International journal of heat and mass transfer 48, No. 8, 1583-1598 (2005) · Zbl 1189.76279 · doi:10.1016/j.ijheatmasstransfer.2004.10.025
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[1151] Liu, J.: Experimental study of pool boiling heat transfer of water-based magnetic fluid on a horizontal heater, Heat transfer - asian research 34, No. 3, 180-187 (2005)
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[2073] Talib, R. Abu: Detailed investigation of heat flux measurements made in a standard propane-air fire-certification burner compared to levels derived from a low-temperature analog burner, Journal of engineering for gas turbines and power 127, No. 2, 249-256 (2005)
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[2083] Fiedler, T.: Numerical and analytical calculation of the orthotropic heat transfer properties of fibre reinforced materials, Materialwissenschaft und werkstofftechnik 36, No. 10, 602-607 (2005)
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[2090] Kuosa, M.: Numerical and experimental modelling of gas flow and heat transfer in the air gap of an electric machine. Part II: Grooved surfaces, Journal of thermal science 14, No. 1, 48-55 (2005)
[2091] Mhaisekar, A.; Kazmierczak, M. J.; Banerjee, R.: Three-dimensional numerical analysis of convection and conduction cooling of spherical biocrystals with localized heating from synchrotron X-ray beams, Journal of synchrotron radiation 12, No. 3, 318-328 (2005)
[2092] Chen, L.; Sun, F.; Wu, C.: Thermoelectric-generator with linear phenomenological heat-transfer law, Applied energy 81, No. 4, 358-364 (2005)
[2093] De Miguel, A.; Bilbao, J.: Test reference year generation from meteorological and simulated solar radiation data, Solar energy 78, No. 6, 695-703 (2005)
[2094] Verevochkin, Y. G.; Startsev, S. A.: Effect of absorption of solar radiation by water of different optical types on convection and heat transfer just under the air-water interface: the case of zero wind speed, Journal of fluid mechanics 523, 109-120 (2005) · Zbl 1081.76595 · doi:10.1017/S0022112004001971
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[2096] Lund, P. D.: Sizing and applicability considerations of solar combisystems, Solar energy 78, No. 1, 59-71 (2005)
[2097] Joshi, S. V.; Bokil, R. S.; Nayak, J. K.: Test standards for thermosyphon-type solar domestic hot water system: review and experimental evaluation, Solar energy 78, No. 6, 781-798 (2005)
[2098] Jordan, U.; Furbo, S.: Thermal stratification in small solar domestic storage tanks caused by draw-offs, Solar energy 78, No. 2, 291-300 (2005)
[2099] Johannes, K.: Comparison of solar water tank storage modelling solutions, Solar energy 79, No. 2, 216-218 (2005)
[2100] Huang, B. J.; Lee, J. P.; Chyng, J. P.: Heat-pipe enhanced solar-assisted heat pump water heater, Solar energy 78, No. 3, 375-381 (2005)
[2101] Furbo, S.: Performance improvement by discharge from different levels in solar storage tanks, Solar energy 79, No. 5, 431-439 (2005)
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[2103] Ito, S.; Miura, N.; Takano, Y.: Studies of heat pumps using direct expansion type solar collectors, Journal of solar energy engineering, transactions of the ASME 127, No. 1, 60-64 (2005)
[2104] Furbo, S.: Smart solar tanks for small solar domestic hot water systems, Solar energy 78, No. 2, 269-279 (2005)
[2105] Esen, M.; Esen, H.: Experimental investigation of a two-phase closed thermosyphon solar water heater, Solar energy 79, No. 5, 459-468 (2005)
[2106] Xiaowu, W.; Ben, H.: Exergy analysis of domestic-scale solar water heaters, Renewable and sustainable energy reviews 9, No. 6, 638-645 (2005)
[2107] Wang, Y.; Davidson, J.; Francis, L.: Scaling in polymer tubes and interpretation for use in solar water heating systems, Journal of solar energy engineering, transactions of the ASME 127, No. 1, 3-14 (2005)
[2108] Umurzakova, M. A.: Calculation of the efficient heat-transfer coefficient of solar turbulator receivers, Applied solar energy (English translation of geliotekhnika) 41, No. 1, 84-86 (2005)
[2109] Smyth, M.: Experimental comparison of alternative convection suppression arrangements for concentrating integral collector storage solar water heaters, Solar energy 78, No. 2, 223-233 (2005)
[2110] Morrison, G. L.; Budihardjo, I.; Behnia, M.: Measurement and simulation of flow rate in a water-in-Glass evacuated tube solar water heater, Solar energy 78, No. 2, 257-267 (2005)
[2111] Li, M.: Study on intermittent refrigeration phenomenon for solar solid adsorption refrigeration, Applied thermal engineering 25, No. 11 – 12, 1614-1622 (2005)
[2112] Hernandez, J. I.: Study of a solar booster assisted ejector refrigeration system with r134a, Journal of solar energy engineering, transactions of the ASME 127, No. 1, 53-59 (2005)
[2113] Mers, A. A.; Mimet, A.: Numerical study of heat and mass transfer in adsorption porous medium heated by solar energy: boubnov-Galerkin method, Heat and mass transfer/waerme- und stoffuebertragung 41, No. 8, 717-723 (2005)
[2114] Janarthanan, B.; Chandrasekaran, J.; Kumar, S.: Evaporative heat loss and heat transfer for open- and closed-cycle systems of a floating tilted Wick solar still, Desalination 180, No. 1 – 3, 291-305 (2005)
[2115] Angeli, C.; Leonardi, E.: The effect of thermodiffusion on the stability of a salinity gradient solar pond, International journal of heat and mass transfer 48, No. 21 – 22, 4633-4639 (2005) · Zbl 1189.76570 · doi:10.1016/j.ijheatmasstransfer.2005.05.021
[2116] Akhatov, Z. S.: Heat balance of a hotbed-type solar distiller with regenerative heat utilization, Applied solar energy (English translation of geliotekhnika) 41, No. 2, 25-28 (2005)
[2117] Abakr, Y. A.; Ismail, A. F.: Theoretical and experimental investigation of a novel multistage evacuated solar still, Journal of solar energy engineering, transactions of the ASME 127, No. 3, 381-385 (2005)
[2118] Tanaka, H.; Nakatake, Y.: A simple and highly productive solar still: a vertical multiple-effect diffusion-type solar still coupled with a flat-plate mirror, Desalination 173, No. 3, 287-300 (2005)
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[2120] Kerdchang, P.: Development of a new solar thermal engine system for circulating water for aeration, Solar energy 78, No. 4 SPEC. ISS., 518-527 (2005)
[2121] Sharma, S. D.: Thermal performance of a solar cooker based on an evacuated tube solar collector with a PCM storage unit, Solar energy 78, No. 3, 416-426 (2005)
[2122] Gupta, R.; Tiwari, G. N.: Thermal modelling of a greenhouse having a north wall using periodic analysis and its experimental validation, International journal of ambient energy 26, No. 3, 115-128 (2005)
[2123] Ghosal, M. K.: Modeling and comparative thermal performance of ground air collector and Earth air heat exchanger for heating of greenhouse, Energy and buildings 37, No. 6, 613-621 (2005)
[2124] Ozgener, O.; Hepbasli, A.: Experimental performance analysis of a solar assisted ground-source heat pump greenhouse heating system, Energy and buildings 37, No. 1, 101-110 (2005)
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[2129] Facao, J.; Oliveira, A. C.: The effect of condenser heat transfer on the energy performance of a plate heat pipe solar collector, International journal of energy research 29, No. 10, 903-912 (2005)
[2130] Gawlik, K.; Christensen, C.; Kutscher, C.; Numerical, A.; Unglazed, Experimental Investigation Of Low-Conductivity; Heaters, Transpired Solar Air: Journal of solar energy engineering, Transactions of the ASME 127, No. 1, 153-155 (2005)
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[2134] Yu, Z. T.: Investigation and analysis on a cellular heat pipe flat solar heater, Heat and mass transfer/waerme- und stoffuebertragung 42, No. 2, 122-128 (2005)
[2135] Riffat, S. B.; Zhao, X.; Doherty, P. S.: Developing a theoretical model to investigate thermal performance of a thin membrane heat-pipe solar collector, Applied thermal engineering 25, No. 5-6, 899-915 (2005)
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[2137] Schuler, A.: Potential of quarterwave interference stacks for colored thermal solar collectors, Solar energy 79, No. 2, 122-130 (2005)
[2138] Shah, L. J.; Furbo, S.; Absorbers, Modeling Shadows On Evacuated Tubular Collectors With Cylindrical: Journal of solar energy engineering, Transactions of the ASME 127, No. 3, 333-342 (2005)
[2139] Maneewan, S.: Heat gain reduction by means of thermoelectric roof solar collector, Solar energy 78 (4 SPEC. ISS.), 495-503 (2005)
[2140] Naphon, P.: On the performance and entropy generation of the double-pass solar air heater with longitudinal fins, Renewable energy 30, No. 9, 1345-1357 (2005)
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[2142] Abanades, S.; Flamant, G.: Production of hydrogen by thermal methane splitting in a nozzle-type laboratory-scale solar reactor, International journal of hydrogen energy 30, No. 8, 843-853 (2005)
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[2144] Wieckert, C.; Model, Design Studies For A. Solar Reactor Based On A. Simple Radiative Heat Exchange: Journal of solar energy engineering, Transactions of the ASME 127, No. 3, 425-429 (2005)
[2145] Meier, A.: Multitube rotary kiln for the industrial solar production of lime, Journal of solar energy engineering, transactions of the ASME 127, No. 3, 386-395 (2005)
[2146] Licht, S.: Solar water splitting to generate hydrogen fuel - a photothermal electrochemical analysis, International journal of hydrogen energy 30, No. 5, 459-470 (2005)
[2147] Sogut, O. S.; Durmayaz, A.: Performance optimization of a solar driven heat engine with finite-rate heat transfer, Renewable energy 30, No. 9, 1329-1344 (2005)
[2148] Roger, M.; Buck, R.; Muller-Steinhagen, H.: Numerical and experimental investigation of a multiple air jet cooling system for application in a solar thermal receiver, Journal of heat transfer 127, No. 8, 863-876 (2005)
[2149] Schlaich, J.: Design of commercial solar updraft tower systems - utilization of solar induced convective flows for power generation, Journal of solar energy engineering, transactions of the ASME 127, No. 1, 117-124 (2005)
[2150] Freid, A. P.: Solar blind pyrometer temperature measurements in high temperature solar thermal reactors: a method for correcting the system-sensor cavity reflection error, Journal of solar energy engineering, transactions of the ASME 127, No. 1, 86-93 (2005)
[2151] Sun, J.: Modeling and experimental evaluation of passive heat sinks for miniature high-flux photovoltaic concentrators, Journal of solar energy engineering, transactions of the ASME 127, No. 1, 138-145 (2005)
[2152] Kaushika, N. D.; Mishra, A.; Chakravarty, M.: Thermal analysis of solar biomass hybrid co-generation plants, International journal of sustainable energy 24, No. 4, 175-186 (2005)
[2153] Bozonnet, E.; Belarbi, R.; Allard, F.: Modelling solar effects on the heat and mass transfer in a street canyon, a simplified approach, Solar energy 79, No. 1, 10-24 (2005)
[2154] De La Flor, F. J. S.: Solar radiation calculation methodology for building exterior surfaces, Solar energy 79, No. 5, 513-522 (2005)
[2155] Martinez, P. J.; Velazquez, A.; Viedma, A.: Performance analysis of a solar energy driven heating system, Energy and buildings 37, No. 10, 1028-1034 (2005)
[2156] Oosthuizen, P. H.: The effect of coverings on heat transfer from a window to a room, Heat transfer engineering 26, No. 5, 47-65 (2005)
[2157] Shahid, H.; Naylor, D.: Energy performance assessment of a window with a horizontal venetian blind, Energy and buildings 37, No. 8, 836-843 (2005)
[2158] Weinlader, H.; Beck, A.; Fricke, J.: PCM-facade-panel for daylighting and room heating, Solar energy 78, No. 2, 177-186 (2005)
[2159] Zhai, X. Q.; Dai, Y. J.; Wang, R. Z.: Comparison of heating and natural ventilation in a solar house induced by two roof solar collectors, Applied thermal engineering 25, No. 5-6, 741-757 (2005)
[2160] Argiriou, A. A.: Numerical simulation and performance assessment of a low capacity solar assisted absorption heat pump coupled with a sub-floor system, Solar energy 79, No. 3, 290-301 (2005)
[2161] Filippin, C.: Response of conventional and energy-saving buildings to design and human dependent factors, Solar energy 78, No. 3, 455-470 (2005)
[2162] Lam, J. C.: Residential building envelope heat gain and cooling energy requirements, Energy 30, No. 7, 933-951 (2005)
[2163] Meillaud, F.; Gay, J. B.; Brown, M. T.: Evaluation of a building using the emergy method, Solar energy 79, No. 2, 204-212 (2005)
[2164] Saman, W.; Bruno, F.; Halawa, E.: Thermal performance of PCM thermal storage unit for a roof integrated solar heating system, Solar energy 78, No. 2, 341-349 (2005)
[2165] Cabeza, L. F.: Long term immersion corrosion tests on metal-PCM pairs used for latent heat storage in the 24 to 29Â^\(\circ C\) temperature range, Materials and corrosion 56, No. 1, 33-38 (2005)
[2166] Canbazoglu, S.: Enhancement of solar thermal energy storage performance using sodium thiosulfate pentahydrate of a conventional solar water-heating system, Energy and buildings 37, No. 3, 235-242 (2005)
[2167] Raab, S.; Mangold, D.; Müller-Steinhagen, H.: Validation of a computer model for solar assisted district heating systems with seasonal hot water heat store, Solar energy 79, No. 5, 531-543 (2005)
[2168] Brosseau, D.: Testing of thermocline filler materials and molten-salt heat transfer fluids for thermal energy storage systems in parabolic trough power plants, Journal of solar energy engineering, transactions of the ASME 127, No. 1, 109-116 (2005)
[2169] Nemchinsky, V.: Dissociation reactive thermal conductivity in a two-temperature plasma, Journal of physics D: Applied physics 38, No. 20, 3825-3831 (2005)
[2170] Cheng, K.: Effects of shroud gas on laminar argon plasma jets impinging on a substrate in ambient air, Kung cheng je Wu Li hsueh pao/journal of engineering thermophysics 26, No. 6, 1019-1021 (2005)
[2171] Kharchenko, V. N.; Zverev, V. N.: Heat and mass transfer in the model of a vortex plasmachemical reactor, Heat transfer research 36, No. 8, 697-702 (2005)
[2172] Wang, W.: Numerical simulation of fluid flow and heat transfer in a plasma spray gun, International journal of advanced manufacturing technology 26, No. 5-6, 537-543 (2005)
[2173] Wang, W. M.: Numerical simulation of fluid flow and heat transfer in a plasma sprayer, Jisuan wuli/chinese journal of computational physics 22, No. 1, 83-87 (2005)
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[2175] Xu, W. J.: A numerical simulation of temperature field in plasma-arc forming of sheet metal, Journal of materials processing technology 164-165, 1644-1649 (2005)
[2176] Gonzalez, J. J.: Numerical modelling of an electric arc and its interaction with the anode: part II. The three-dimensional model-influence of external forces on the arc column, Journal of physics D: Applied physics 38, No. 2, 306-318 (2005)
[2177] Yeh, F. B.; Wei, P. S.: Effects of plasma parameters on the temperature field in a workpiece experiencing solid-liquid phase transition, Journal of heat transfer 127, No. 9, 987-994 (2005)
[2178] Kersten, H.: Measurement of energy fluxes in plasma surface treatments, Die bestimmung von energieflüssen bei plasmaoberflächenprozessen 96, No. 12 (2005)
[2179] Nunomura, S.: Heat transfer in a two-dimensional crystalline complex (dusty) plasma, Physical review letters 95, No. 2, 1-4 (2005)
[2180] Borisov, Y. S.; Zatserkovny, A. S.; Krivtsun, I. V.: Convective-conductive and radiation heat exchange of plasma flow with particles of dispersed materials in plasma spraying, Avtomaticheskaya svarka, No. 6, 7-11 (2005)
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[2182] Golosnoy, I. O.; Tsipas, S. A.; Clyne, T. W.: An analytical model for simulation of heat flow in plasma-sprayed thermal barrier coatings, Journal of thermal spray technology 14, No. 2, 205-214 (2005)
[2183] Xiong, H. B.: Melting and oxidation behavior of in-flight particles in plasma spray process, International journal of heat and mass transfer 48, No. 25-26, 5121-5133 (2005) · Zbl 1188.76271 · doi:10.1016/j.ijheatmasstransfer.2005.07.019
[2184] Kumar, A.; Debroy, T.: Improving reliability of modelling heat and fluid flow in complex gas metal arc fillet welds - part II: Application to welding of steel, Journal of physics D: Applied physics 38, No. 1, 127-134 (2005)
[2185] Kumar, A.; Zhang, W.; Debroy, T.: Improving reliability of modelling heat and fluid flow in complex gas metal arc fillet welds - part I: An engineering physics model, Journal of physics D: Applied physics 38, No. 1, 119-126 (2005)
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