Pushpa Publishing House

Journal Menu

Content

Volume 38 (2025)

Volume 37 (2024)

Volume 24 (2021)

Volume 23 (2021)

	Volume 23, Issue 2 Pg 189 - 388 (August 2021)
	Volume 23, Issue 1 Pg 1 - 188 (June 2021)

Volume 22 (2021)

Special Issue II (2020)

Volume 21 (2020)

Volume 20 (2020)

Volume 19 (2020)

Volume 18 (2019)

Special Issue (2019)

Volume 17 (2019)

Volume 16 (2019)

Volume 15 (2018)

Volume 14 (2017)

Volume 13 (2016)

Volume 12 (2015)

Volume 11 (2015)

Volume 10 (2014)

Volume 9 (2014)

Volume 8 (2013)

Volume 7 (2013)

Volume 6 (2012)

Volume 5 (2011)

Volume 4 (2010)

Volume 3 (2009)

Volume 2 (2008)

Volume 1 (2007)

Notice: All new articles and volumes will be published only on our new website — www.pphmjopenaccess.com

JP Journal of Heat and Mass Transfer

JP Journal of Heat and Mass Transfer
Volume 23, Issue 2, Pages 189 - 200 (August 2021)
http://dx.doi.org/10.17654/HM023020189

EXPERIMENTAL CONFIRMATION OF THE LAWS OF THERMAL RADIATION OF GAS VOLUMES

Anatoliy Nikolaevich Makarov

Abstract:

The energy of the fuel during flare combustion is converted into a stream of thermal radiation. The energy of an electric arc burning in metal vapors in arc steel-making furnaces is converted into a flux of thermal radiation. The laws of thermal radiation of gas volumes of torches and electric arcs discovered by the author are described. The results of experimental confirmation of the laws of thermal radiation of gas volumes of torches and electric arcs are presented. The difference between the fluxes of thermal radiation of gas volumes, calculated by the formula of the law and measured, does not exceed 10%, which confirms the correctness of the open law of thermal radiation of gas volumes. It is shown that in mathematical modeling, the thermal radiation of a cylindrical gas volume of a larger diameter can be equivalently replaced by the thermal radiation of its axis of symmetry.

Keywords and phrases:

thermal radiation, gas volumes, laws of thermal radiation, electric arc, torch.

Received: March 1, 2021; Accepted: April 5, 2021; Published: July 31, 2021

How to cite this article: Anatoliy Nikolaevich Makarov, Experimental confirmation of the laws of thermal radiation of gas volumes, JP Journal of Heat and Mass Transfer 23(2) (2021), 189-200. DOI: 10.17654/HM023020189

This Open Access Article is Licensed under Creative Commons Attribution 4.0 International License

References:

[1] Anatoliy Makarov, Calculations of heat radiation from gas volume of the torch (Part II). Calculations of radiation from the torch on the burner, JP Journal of Heat and Mass Transfer 16(1) (2019), 43-52.
http://dx.doi.org/10.17654/HM016010043.
[2] Anatoliy Makarov, Calculations of heat transfer in torch furnaces, JP Journal of Heat and Mass Transfer 18(1) (2019), 145-165.
http://dx.doi.org/10.17654/HM018010145.
[3] Anatoliy Nikolaevich Makarov, Calculations of heat transfer in furnaces of steam boilers under laws of radiation of gas volumes, JP Journal of Heat and Mass Transfer 18(2) (2019), 423-436.
http://dx.doi.org/10.17654/HM018020423.
[4] A. N. Makarov, Heat exchange in arc and torch metallurgical furnaces and power station: studies, A Grant for Students of Higher Education Institutions, St. Petersburg, Lan’, Russia, 2014.
[5] A. N. Makarov, Calculation and analysis of energy parameters of meltings in EAFs of conventional and consteel design, Metallurgist 62(9-10) (2019), 974-978. doi:10.1007/s11015-017-0492-y.
[6] A. N. Makarov, Calculation and analysis of the relationship between the efficiency and position of electric arcs and power consumption in electric arc furnaces (EAF) of smaller and larger capacity, Part 2. Calculation and analysis of the relationship between position of arcs, walls and power consumption, Metallurgist 63(5-6) (2019), 441-450. doi:10.1007/s11015-019-00844-5.
[7] A. N. Makarov, Radiation from large gas volumes and heat exchange in steam boiler furnaces, Power Technology and Engineering 49(3) (2015), 196-201.
doi:1570-145x/15/4903-0196.
[8] A. N. Makarov, Flare temperature and nitrogen oxide emission reduction and heat transfer in the TGMP-314I steam boiler firebox, Power Technology and Engineering 50(2) (2016), 200-203. doi:1570-145x/16/5002-0200.
[9] A. N. Makarov, Regularities of heat exchange in gas layers of a torch and screens of fire chambers of boilers, Part II. Laws of radiations of gas layers and the method of calculation of heat exchange developed on their basis in furnaces, fire chambers, combustion chambers, Thermal Engineering 10 (2014), 24-31.
doi:10.1134/s0040601514100073.
[10] A. N. Makarov, Regularities of heat exchange in gas layers of a torch and screens of fire chambers of boilers, Part III. Examples of calculations of heat exchange in torch furnaces and fire chambers of boilers, Thermal Engineering 11 (2014), 46-54. doi:10.1134/s0040601514110056.
[11] R. Sigel and Y. Howell, Thermal Radiation Heat Transfer, Moscow, Mir, Russia, 1975.
[12] M. N. Ozisik, Radiative Transfer and Interaction with Conduction and Convection, Moscow, Mir, Russia, 1976.
[13] S. S. Kutateladre, Heat Transfer and Hydraulic Resistance: Reference Manual, Energoatomizdat, Moscow, Russia, 1990.
[14] A. G. Blokh, Y. A. Zhuravlev and L. N. Ryzhkov, Radiant Heat Transfer: A Handbook, Energoatomizdat, Moscow, Russia, 1991.
[15] A. S. Nevskii, Radiant Heat Transfer in Furnaces, Metallurgiya, Moscow, Russia, 1971.
[16] A. N. Makarov, Regulation of gas volumes and calculations of the torch in furnaces, Electric Generating Station 4 (2018), 42-50.