Influence of particles size and concentration in particles cloud radiation by Mie theory

1739 Ogledov
1726 Prenosov
Izvoz citacije: ABNT
TRIVIC, Dusan N.;DJORDEVIC, Bojan .
Influence of particles size and concentration in particles cloud radiation by Mie theory. 
Strojniški vestnik - Journal of Mechanical Engineering, [S.l.], v. 47, n.8, p. 417-423, july 2017. 
ISSN 0039-2480.
Available at: <https://www.sv-jme.eu/sl/article/influence-of-particles-size-and-concentration-in-particles-cloud-radiation-by-mie-theory/>. Date accessed: 20 dec. 2024. 
doi:http://dx.doi.org/.
Trivic, D., & Djordevic, B.
(2001).
Influence of particles size and concentration in particles cloud radiation by Mie theory.
Strojniški vestnik - Journal of Mechanical Engineering, 47(8), 417-423.
doi:http://dx.doi.org/
@article{.,
	author = {Dusan N. Trivic and Bojan  Djordevic},
	title = {Influence of particles size and concentration in particles cloud radiation by Mie theory},
	journal = {Strojniški vestnik - Journal of Mechanical Engineering},
	volume = {47},
	number = {8},
	year = {2001},
	keywords = {particles size; Mie theory; mathemathic models; },
	abstract = {The effects of mean diameter of particles and of particles concentration, for particles cloud, on the radiative heat flux have been analyzed by a mathematical model. The mathematical model for the radiation of particulate media on the surrounding walls, for 3-D rectangular geometry has been developed. The model is based on the Hottel-Cohen Zone Method for the analysis of radiative heat transfer. Total View Factors for radiative exchange have been evaluated by the Monte Carlo Method. Mie Theory has been used for the determination of the radiative properties of particles cloud in the enclosure. Parameters defining the radiative properties by Mie equations arch particles shape, mean diameter of particles, complex refractive index of particles material, density of material, particles concentration and the wave length of incident radiation. The particles considered have been of spherical shape. In the zone method, the enclosure and its surrounding surfaces are divided into a number of volume and surface zones, each of which is assumed to have uniform properties. A radiative energy balance is written on each zone giving the net radiative heat transfer between that zone and every other volume and surface zone in the system. The Monte Carlo Method is based an probability and statistics. The concept of energy bundles is introduced to simulate the actual physical process of radiation. A statistically meaningful number of energy bundles are followed from initial points of emission through randomly determined paths until the final points of absorption on the system. The mathematical and physical background of the interaction between incident radiation and a single solid particle is the solution of Maxwell's wave equations. Gustav Mie solved Maxwell's wave equations with the appropriate boundary conditions for single cylindrical and spherical particles and the resulting equations are called the Mie equations. The main objectives of the study are: To link numerically Hottel-Cohen zone method and Monte Carlo Method with Mie equations and to create an original 3-D computer code for the prediction of heat flux distribution. Using the code, as the results, the distribution of net radiative heat flux on the surfaces of a cube have been predicted for various values of mean diameter of particles and of particles concentration. The parametric study has been carried out keeping constant: complex refractive index of particles material and density of material. The wavelength of incident radiation was varied as well. It has been concluded, inter alia, that the larger is the mass concentration of particles the higher is the radiative heat flux transferred to the surfaces. The influence of particles diameter on the heat flux is not straight forward and it depends on the wavelength of incident radiation.},
	issn = {0039-2480},	pages = {417-423},	doi = {},
	url = {https://www.sv-jme.eu/sl/article/influence-of-particles-size-and-concentration-in-particles-cloud-radiation-by-mie-theory/}
}
Trivic, D.,Djordevic, B.
2001 July 47. Influence of particles size and concentration in particles cloud radiation by Mie theory. Strojniški vestnik - Journal of Mechanical Engineering. [Online] 47:8
%A Trivic, Dusan N.
%A Djordevic, Bojan 
%D 2001
%T Influence of particles size and concentration in particles cloud radiation by Mie theory
%B 2001
%9 particles size; Mie theory; mathemathic models; 
%! Influence of particles size and concentration in particles cloud radiation by Mie theory
%K particles size; Mie theory; mathemathic models; 
%X The effects of mean diameter of particles and of particles concentration, for particles cloud, on the radiative heat flux have been analyzed by a mathematical model. The mathematical model for the radiation of particulate media on the surrounding walls, for 3-D rectangular geometry has been developed. The model is based on the Hottel-Cohen Zone Method for the analysis of radiative heat transfer. Total View Factors for radiative exchange have been evaluated by the Monte Carlo Method. Mie Theory has been used for the determination of the radiative properties of particles cloud in the enclosure. Parameters defining the radiative properties by Mie equations arch particles shape, mean diameter of particles, complex refractive index of particles material, density of material, particles concentration and the wave length of incident radiation. The particles considered have been of spherical shape. In the zone method, the enclosure and its surrounding surfaces are divided into a number of volume and surface zones, each of which is assumed to have uniform properties. A radiative energy balance is written on each zone giving the net radiative heat transfer between that zone and every other volume and surface zone in the system. The Monte Carlo Method is based an probability and statistics. The concept of energy bundles is introduced to simulate the actual physical process of radiation. A statistically meaningful number of energy bundles are followed from initial points of emission through randomly determined paths until the final points of absorption on the system. The mathematical and physical background of the interaction between incident radiation and a single solid particle is the solution of Maxwell's wave equations. Gustav Mie solved Maxwell's wave equations with the appropriate boundary conditions for single cylindrical and spherical particles and the resulting equations are called the Mie equations. The main objectives of the study are: To link numerically Hottel-Cohen zone method and Monte Carlo Method with Mie equations and to create an original 3-D computer code for the prediction of heat flux distribution. Using the code, as the results, the distribution of net radiative heat flux on the surfaces of a cube have been predicted for various values of mean diameter of particles and of particles concentration. The parametric study has been carried out keeping constant: complex refractive index of particles material and density of material. The wavelength of incident radiation was varied as well. It has been concluded, inter alia, that the larger is the mass concentration of particles the higher is the radiative heat flux transferred to the surfaces. The influence of particles diameter on the heat flux is not straight forward and it depends on the wavelength of incident radiation.
%U https://www.sv-jme.eu/sl/article/influence-of-particles-size-and-concentration-in-particles-cloud-radiation-by-mie-theory/
%0 Journal Article
%R 
%& 417
%P 7
%J Strojniški vestnik - Journal of Mechanical Engineering
%V 47
%N 8
%@ 0039-2480
%8 2017-07-07
%7 2017-07-07
Trivic, Dusan, & Bojan  Djordevic.
"Influence of particles size and concentration in particles cloud radiation by Mie theory." Strojniški vestnik - Journal of Mechanical Engineering [Online], 47.8 (2001): 417-423. Web.  20 Dec. 2024
TY  - JOUR
AU  - Trivic, Dusan N.
AU  - Djordevic, Bojan 
PY  - 2001
TI  - Influence of particles size and concentration in particles cloud radiation by Mie theory
JF  - Strojniški vestnik - Journal of Mechanical Engineering
DO  - 
KW  - particles size; Mie theory; mathemathic models; 
N2  - The effects of mean diameter of particles and of particles concentration, for particles cloud, on the radiative heat flux have been analyzed by a mathematical model. The mathematical model for the radiation of particulate media on the surrounding walls, for 3-D rectangular geometry has been developed. The model is based on the Hottel-Cohen Zone Method for the analysis of radiative heat transfer. Total View Factors for radiative exchange have been evaluated by the Monte Carlo Method. Mie Theory has been used for the determination of the radiative properties of particles cloud in the enclosure. Parameters defining the radiative properties by Mie equations arch particles shape, mean diameter of particles, complex refractive index of particles material, density of material, particles concentration and the wave length of incident radiation. The particles considered have been of spherical shape. In the zone method, the enclosure and its surrounding surfaces are divided into a number of volume and surface zones, each of which is assumed to have uniform properties. A radiative energy balance is written on each zone giving the net radiative heat transfer between that zone and every other volume and surface zone in the system. The Monte Carlo Method is based an probability and statistics. The concept of energy bundles is introduced to simulate the actual physical process of radiation. A statistically meaningful number of energy bundles are followed from initial points of emission through randomly determined paths until the final points of absorption on the system. The mathematical and physical background of the interaction between incident radiation and a single solid particle is the solution of Maxwell's wave equations. Gustav Mie solved Maxwell's wave equations with the appropriate boundary conditions for single cylindrical and spherical particles and the resulting equations are called the Mie equations. The main objectives of the study are: To link numerically Hottel-Cohen zone method and Monte Carlo Method with Mie equations and to create an original 3-D computer code for the prediction of heat flux distribution. Using the code, as the results, the distribution of net radiative heat flux on the surfaces of a cube have been predicted for various values of mean diameter of particles and of particles concentration. The parametric study has been carried out keeping constant: complex refractive index of particles material and density of material. The wavelength of incident radiation was varied as well. It has been concluded, inter alia, that the larger is the mass concentration of particles the higher is the radiative heat flux transferred to the surfaces. The influence of particles diameter on the heat flux is not straight forward and it depends on the wavelength of incident radiation.
UR  - https://www.sv-jme.eu/sl/article/influence-of-particles-size-and-concentration-in-particles-cloud-radiation-by-mie-theory/
@article{{}{.},
	author = {Trivic, D., Djordevic, B.},
	title = {Influence of particles size and concentration in particles cloud radiation by Mie theory},
	journal = {Strojniški vestnik - Journal of Mechanical Engineering},
	volume = {47},
	number = {8},
	year = {2001},
	doi = {},
	url = {https://www.sv-jme.eu/sl/article/influence-of-particles-size-and-concentration-in-particles-cloud-radiation-by-mie-theory/}
}
TY  - JOUR
AU  - Trivic, Dusan N.
AU  - Djordevic, Bojan 
PY  - 2017/07/07
TI  - Influence of particles size and concentration in particles cloud radiation by Mie theory
JF  - Strojniški vestnik - Journal of Mechanical Engineering; Vol 47, No 8 (2001): Strojniški vestnik - Journal of Mechanical Engineering
DO  - 
KW  - particles size, Mie theory, mathemathic models, 
N2  - The effects of mean diameter of particles and of particles concentration, for particles cloud, on the radiative heat flux have been analyzed by a mathematical model. The mathematical model for the radiation of particulate media on the surrounding walls, for 3-D rectangular geometry has been developed. The model is based on the Hottel-Cohen Zone Method for the analysis of radiative heat transfer. Total View Factors for radiative exchange have been evaluated by the Monte Carlo Method. Mie Theory has been used for the determination of the radiative properties of particles cloud in the enclosure. Parameters defining the radiative properties by Mie equations arch particles shape, mean diameter of particles, complex refractive index of particles material, density of material, particles concentration and the wave length of incident radiation. The particles considered have been of spherical shape. In the zone method, the enclosure and its surrounding surfaces are divided into a number of volume and surface zones, each of which is assumed to have uniform properties. A radiative energy balance is written on each zone giving the net radiative heat transfer between that zone and every other volume and surface zone in the system. The Monte Carlo Method is based an probability and statistics. The concept of energy bundles is introduced to simulate the actual physical process of radiation. A statistically meaningful number of energy bundles are followed from initial points of emission through randomly determined paths until the final points of absorption on the system. The mathematical and physical background of the interaction between incident radiation and a single solid particle is the solution of Maxwell's wave equations. Gustav Mie solved Maxwell's wave equations with the appropriate boundary conditions for single cylindrical and spherical particles and the resulting equations are called the Mie equations. The main objectives of the study are: To link numerically Hottel-Cohen zone method and Monte Carlo Method with Mie equations and to create an original 3-D computer code for the prediction of heat flux distribution. Using the code, as the results, the distribution of net radiative heat flux on the surfaces of a cube have been predicted for various values of mean diameter of particles and of particles concentration. The parametric study has been carried out keeping constant: complex refractive index of particles material and density of material. The wavelength of incident radiation was varied as well. It has been concluded, inter alia, that the larger is the mass concentration of particles the higher is the radiative heat flux transferred to the surfaces. The influence of particles diameter on the heat flux is not straight forward and it depends on the wavelength of incident radiation.
UR  - https://www.sv-jme.eu/sl/article/influence-of-particles-size-and-concentration-in-particles-cloud-radiation-by-mie-theory/
Trivic, Dusan, AND Djordevic, Bojan.
"Influence of particles size and concentration in particles cloud radiation by Mie theory" Strojniški vestnik - Journal of Mechanical Engineering [Online], Volume 47 Number 8 (07 July 2017)

Avtorji

Inštitucije

  • Institute of Nuclear Sciences Vinca, Department of Thermal Engineering and Energy Research, Belgrade, Serbia
  • Faculty of Technology and Matallurgy, Belgrade, Serbia

Informacije o papirju

Strojniški vestnik - Journal of Mechanical Engineering 47(2001)8, 417-423
© The Authors, CC-BY 4.0 Int. Change in copyright policy from 2022, Jan 1st.

The effects of mean diameter of particles and of particles concentration, for particles cloud, on the radiative heat flux have been analyzed by a mathematical model. The mathematical model for the radiation of particulate media on the surrounding walls, for 3-D rectangular geometry has been developed. The model is based on the Hottel-Cohen Zone Method for the analysis of radiative heat transfer. Total View Factors for radiative exchange have been evaluated by the Monte Carlo Method. Mie Theory has been used for the determination of the radiative properties of particles cloud in the enclosure. Parameters defining the radiative properties by Mie equations arch particles shape, mean diameter of particles, complex refractive index of particles material, density of material, particles concentration and the wave length of incident radiation. The particles considered have been of spherical shape. In the zone method, the enclosure and its surrounding surfaces are divided into a number of volume and surface zones, each of which is assumed to have uniform properties. A radiative energy balance is written on each zone giving the net radiative heat transfer between that zone and every other volume and surface zone in the system. The Monte Carlo Method is based an probability and statistics. The concept of energy bundles is introduced to simulate the actual physical process of radiation. A statistically meaningful number of energy bundles are followed from initial points of emission through randomly determined paths until the final points of absorption on the system. The mathematical and physical background of the interaction between incident radiation and a single solid particle is the solution of Maxwell's wave equations. Gustav Mie solved Maxwell's wave equations with the appropriate boundary conditions for single cylindrical and spherical particles and the resulting equations are called the Mie equations. The main objectives of the study are: To link numerically Hottel-Cohen zone method and Monte Carlo Method with Mie equations and to create an original 3-D computer code for the prediction of heat flux distribution. Using the code, as the results, the distribution of net radiative heat flux on the surfaces of a cube have been predicted for various values of mean diameter of particles and of particles concentration. The parametric study has been carried out keeping constant: complex refractive index of particles material and density of material. The wavelength of incident radiation was varied as well. It has been concluded, inter alia, that the larger is the mass concentration of particles the higher is the radiative heat flux transferred to the surfaces. The influence of particles diameter on the heat flux is not straight forward and it depends on the wavelength of incident radiation.

particles size; Mie theory; mathemathic models;