Literatura académica sobre el tema "Direct heat meter"
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Artículos de revistas sobre el tema "Direct heat meter"
Magonski, Zbigniew. "Combustion Heat Meter". Journal of Microelectronics and Electronic Packaging 14, n.º 3 (1 de julio de 2017): 100–107. http://dx.doi.org/10.4071/imaps.0531.
Texto completoMagonski, Zbigniew. "Meter for the measurement heat of combustion". International Symposium on Microelectronics 2011, n.º 1 (1 de enero de 2011): 000938–46. http://dx.doi.org/10.4071/isom-2011-tha2-paper4.
Texto completoFeng Wei, Ji, Li Qun Sun, Kai Zhang, XiaoYang Hu y Shan Zhou. "Heat exchange model in absorption chamber of water-direct-absorption-typed laser energy meter". Optics & Laser Technology 67 (abril de 2015): 65–71. http://dx.doi.org/10.1016/j.optlastec.2014.09.015.
Texto completoPereselkov, A. y O. Kruglyakova. "EXPERIMENTAL STUDY OF ELEMENTARY ACTS OF HYDRODYNAMICS AND HEAT TRANSFER DURING THE INTERACTION BETWEEN WATER DROPS AND FILM AND CASTING ROLLER SURFACE". Integrated Technologies and Energy Saving, n.º 4 (12 de diciembre de 2022): 3–12. http://dx.doi.org/10.20998/2078-5364.2022.4.01.
Texto completoTirado-Conde, Joel, Peter Engesgaard, Sachin Karan, Sascha Müller y Carlos Duque. "Evaluation of Temperature Profiling and Seepage Meter Methods for Quantifying Submarine Groundwater Discharge to Coastal Lagoons: Impacts of Saltwater Intrusion and the Associated Thermal Regime". Water 11, n.º 8 (9 de agosto de 2019): 1648. http://dx.doi.org/10.3390/w11081648.
Texto completoUusikivi, Jari, Jens Ehn y Mats A. Granskog. "Direct measurements of turbulent momentum, heat and salt fluxes under landfast ice in the Baltic Sea". Annals of Glaciology 44 (2006): 42–46. http://dx.doi.org/10.3189/172756406781811150.
Texto completoUsoltseva, Liliya O., Dmitry S. Volkov, Evgeny A. Karpushkin, Mikhail V. Korobov y Mikhail A. Proskurnin. "Thermal Conductivity of Detonation Nanodiamond Hydrogels and Hydrosols by Direct Heat Flux Measurements". Gels 7, n.º 4 (3 de diciembre de 2021): 248. http://dx.doi.org/10.3390/gels7040248.
Texto completoMintorogo, Danny Santoso. "THE AQUATIC-POLYCARBONATE SKYLIGHT FOR SURABAYA INDONESIA". DIMENSI (Journal of Architecture and Built Environment) 35, n.º 1 (9 de julio de 2007): 100–106. http://dx.doi.org/10.9744/dimensi.35.1.100-106.
Texto completoKassai, Miklos. "Energy Performance Investigation of a Direct Expansion Ventilation Cooling System with a Heat Wheel". Energies 12, n.º 22 (8 de noviembre de 2019): 4267. http://dx.doi.org/10.3390/en12224267.
Texto completoKong, Zhenyi, Yonghui Li, Shuichi Hokoi y Shi Hu. "The rising damp in two traditional clay-brick masonry walls and influence on heat transfer performance". MATEC Web of Conferences 282 (2019): 02097. http://dx.doi.org/10.1051/matecconf/201928202097.
Texto completoCapítulos de libros sobre el tema "Direct heat meter"
Rohling, Eelco J. "ENERGY BALANCE OF CLIMATE". En The Climate Question. Oxford University Press, 2019. http://dx.doi.org/10.1093/oso/9780190910877.003.0006.
Texto completoSpiel, Christiane, Petra Gradinger y Dagmar Strohmeier. "Cyberpesten: definitie, metingen en bevindingen". En Boos! Over agressie, opvoeding en ontwikkeling, 101–14. 2a ed. Uitgeverij SWP, 2016. http://dx.doi.org/10.36254/978-90-8850-292-7.08.
Texto completoVerschuur, Gerrit L. "Solar System Debris". En Impact! Oxford University Press, 1996. http://dx.doi.org/10.1093/oso/9780195101058.003.0006.
Texto completo"than its original energy. The ejected electron (Compton electron) has enough kinetic energy to cause excitations and ionizations in the absorber atoms. It thus interacts with the absorber in the same way as the ejected secondary electrons produced by an electron accelerator beam (Fig. 12b). Because Compton electrons are produced when gamma or x-ray photons interact with a medium, and because the Compton electrons cause ionizations and excitations in the same way as secondary electrons produced by accelerator beam electrons, the radiation-induced chemical changes in the irradiated medium are largely the same, regardless of the type of radiation used. The purpose of dose meters is to measure the amount of radiation energy absorbed by the irradiated product. The instrument that gives a reading of absorbed dose directly is the calorimeter. It measures the total energy dissipated or the rate of energy dissipation in a material in terms of the thermal properties of the absorbing body. This instrument, therefore, is considered to be an absolute dose meter that can be used for calibrating other dose meters. The principle of radiation calorime try is implicit in the definition of the radiation dose unit 1 Gy (gray) = 1 J (joule)/ kg. Ideally the temperature elevation should be measured in the irradiated food product itself— but in practice this is usually not done because the thermal properties of foodstuffs vary widely. A substance with known, reproducible thermal properties is taken instead, which serves as a heat-sensing calorimetric body, included in an adiabatic system (adiabatic = without transmission of heat). Water, graphite, aluminum, or a water-equivalent plastic is usually chosen, and the thermal change is determined by small calibrated thermocouples or thermis tors embedded in the calorimetric body. The practice of using radiation calorimetry is not simple, and ways to use it in a routine fashion have been developed only recently (24,25). Because the process of temperature elevation should run under adiabatic or quasi-adiabatic conditions, the dose has to be applied in a very short time. Calorimetry is therefore mostly used for measuring electron accelerator beam doses. The absorbed dose in the calorimetric body can be converted to that of the material of interest (foodstuff) by taking into consideration the different density and the different energy absorp tion coefficients of the two materials. The temperature elevation depends on radiation dose and on the specific heat of the material irradiated. A dose of 10 kGy causes a temperature elevation as follows: 2.3K in water (specific heat 4.2 kJ/kg • K) 6.2K in dry protein (specific heat 1.6 kJ/kg • K) 7.1K in dry carbohydrate (specific heat 1.4 kJ/kg • K) 12.5 K in glass (specific heat 0.8 kJ/kg • K)". En Safety of Irradiated Foods, 49. CRC Press, 1995. http://dx.doi.org/10.1201/9781482273168-38.
Texto completoActas de conferencias sobre el tema "Direct heat meter"
Bergin, Mike, Ettore Musu, Sage Kokjohn y Rolf D. Reitz. "Examination of Initialization and Geometric Details on the Results of CFD Simulations of Diesel Engines". En ASME 2009 Internal Combustion Engine Division Spring Technical Conference. ASMEDC, 2009. http://dx.doi.org/10.1115/ices2009-76053.
Texto completoXu, Feng, Qiusheng Liu, Satoshi Kawaguchi y Makoto Shibahara. "Experimental Study on Transient Heat Transfer for Helium Gas Flowing in a Minichannel". En 2020 International Conference on Nuclear Engineering collocated with the ASME 2020 Power Conference. American Society of Mechanical Engineers, 2020. http://dx.doi.org/10.1115/icone2020-16697.
Texto completoGallman, Benjamin, B. Terry Beck y Mohammad H. Hosni. "Direct Pressure Measurement and Flow Visualization of Cavitation in a Converging-Diverging Nozzle". En ASME 2019 International Mechanical Engineering Congress and Exposition. American Society of Mechanical Engineers, 2019. http://dx.doi.org/10.1115/imece2019-12236.
Texto completoKumar Juvva, Srihari Dinesh, Sathesh Mariappan y Abhijit Kushari. "Open Loop Active Control of Combustion Noise in Gas Turbine Combustor". En ASME 2015 Gas Turbine India Conference. American Society of Mechanical Engineers, 2015. http://dx.doi.org/10.1115/gtindia2015-1340.
Texto completoAnandram, V., S. Ramakrishnan, J. Karthick, S. Saravanan y G. LakshmiNarayanaRao. "Engine Analysis of Single Cylinder DI Diesel Engine Fuelled With Sunflower Oil, Sunflower Oil Methyl Ester and Its Blends". En ASME 2006 Internal Combustion Engine Division Fall Technical Conference. ASMEDC, 2006. http://dx.doi.org/10.1115/icef2006-1573.
Texto completoHermansson, Robert, Ville Närvänen, Jyrki Kajaste, Olof Calonius, Matti Pietola y Petri Kuosmanen. "Experimental Study on Energy Efficiency of Two-Cylinder Direct Driven Hydraulic System in a Large-Scale Test Bench". En ASME/BATH 2021 Symposium on Fluid Power and Motion Control. American Society of Mechanical Engineers, 2021. http://dx.doi.org/10.1115/fpmc2021-68797.
Texto completoMcKee, Robert J. "Mapping and Predicting Air Flows in Gas Turbine Axial Compressors". En ASME Turbo Expo 2003, collocated with the 2003 International Joint Power Generation Conference. ASMEDC, 2003. http://dx.doi.org/10.1115/gt2003-38745.
Texto completoMassini, D., T. Fondelli, B. Facchini, L. Tarchi y F. Leonardi. "Windage Losses of a Meshing Gear Pair Measured at Different Working Conditions". En ASME Turbo Expo 2018: Turbomachinery Technical Conference and Exposition. American Society of Mechanical Engineers, 2018. http://dx.doi.org/10.1115/gt2018-76823.
Texto completoMassini, D., T. Fondelli, A. Andreini, B. Facchini, L. Tarchi y F. Leonardi. "Experimental and Numerical Investigation on Windage Power Losses in High Speed Gears". En ASME Turbo Expo 2017: Turbomachinery Technical Conference and Exposition. American Society of Mechanical Engineers, 2017. http://dx.doi.org/10.1115/gt2017-64948.
Texto completoAlexandrescu, Aurora C., Simona Adina O. Alexandrescu y Constantin Adrian O. Alexandrescu. "Contributions Concerning the Power Optimization of the Pumping Stations". En ASME 2008 Fluids Engineering Division Summer Meeting collocated with the Heat Transfer, Energy Sustainability, and 3rd Energy Nanotechnology Conferences. ASMEDC, 2008. http://dx.doi.org/10.1115/fedsm2008-55007.
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