Defect and Diffusion Forum, volume 370, pages 113-119
The Thermophysical Bases of Monitoring of the Fireproof Lining Wear in the Blast Furnace Hearth
Publication type: Journal Article
Publication date: 2017-01-24
Journal:
Defect and Diffusion Forum
Quartile SCImago
Q4
Quartile WOS
—
Impact factor: —
ISSN: 10120386, 16629507
Condensed Matter Physics
General Materials Science
Radiation
Abstract
This paper presents a two-dimensional description of the temperature field in refractory lining of the hearth in the blast furnace. The mathematical model is based on Fourier differential heat conduction equation. Different solutions of this equation are presented and the optimal quantity and location of thermosensors in the hearth is proposed. This paper also presents a methodology to obtain the heat conductivity of refractory materials.
Citations by journals
|
1
|
|
|
Ironmaking and Steelmaking
|
Ironmaking and Steelmaking
1 publication, 33.33%
|
|
Ferrous Metallurgy Bulletin of Scientific Technical and Economic Information
|
Ferrous Metallurgy Bulletin of Scientific Technical and Economic Information
1 publication, 33.33%
|
|
Lecture Notes in Computer Science
|
Lecture Notes in Computer Science
1 publication, 33.33%
|
|
1
|
Citations by publishers
|
1
|
|
|
Taylor & Francis
|
Taylor & Francis
1 publication, 33.33%
|
|
South Ural State University
|
South Ural State University
1 publication, 33.33%
|
|
Springer Nature
|
Springer Nature
1 publication, 33.33%
|
|
1
|
- We do not take into account publications that without a DOI.
- Statistics recalculated only for publications connected to researchers, organizations and labs registered on the platform.
- Statistics recalculated weekly.
{"yearsCitations":{"type":"bar","data":{"show":true,"labels":[2019,2020,2021],"ids":[0,0,0],"codes":[0,0,0],"imageUrls":["","",""],"datasets":[{"label":"Citations number","data":[1,1,1],"backgroundColor":["#3B82F6","#3B82F6","#3B82F6"],"percentage":["33.33","33.33","33.33"],"barThickness":null}]},"options":{"indexAxis":"x","maintainAspectRatio":true,"scales":{"y":{"ticks":{"precision":0,"autoSkip":false,"font":{"family":"Montserrat"},"color":"#000000"}},"x":{"ticks":{"stepSize":1,"precision":0,"font":{"family":"Montserrat"},"color":"#000000"}}},"plugins":{"legend":{"position":"top","labels":{"font":{"family":"Montserrat"},"color":"#000000"}},"title":{"display":true,"text":"Citations per year","font":{"size":24,"family":"Montserrat","weight":600},"color":"#000000"}}}},"journals":{"type":"bar","data":{"show":true,"labels":["Ironmaking and Steelmaking","Ferrous Metallurgy Bulletin of Scientific Technical and Economic Information","Lecture Notes in Computer Science"],"ids":[6116,30906,1022],"codes":[0,0,0],"imageUrls":["\/storage\/images\/resized\/5YZtvLvkPZuc2JHOaZsjCvGSHFCuC3drUwN3YAc5_medium.webp","\/storage\/images\/resized\/QmBKdvQR66juwTKToKoBN7jk0mRjGh8wAeLwZ5fQ_medium.webp","\/storage\/images\/resized\/voXLqlsvTwv5p3iMQ8Dhs95nqB4AXOG7Taj7G4ra_medium.webp"],"datasets":[{"label":"","data":[1,1,1],"backgroundColor":["#3B82F6","#3B82F6","#3B82F6"],"percentage":[33.33,33.33,33.33],"barThickness":13}]},"options":{"indexAxis":"y","maintainAspectRatio":false,"scales":{"y":{"ticks":{"precision":0,"autoSkip":false,"font":{"family":"Montserrat"},"color":"#000000"}},"x":{"ticks":{"stepSize":null,"precision":0,"font":{"family":"Montserrat"},"color":"#000000"}}},"plugins":{"legend":{"position":"top","labels":{"font":{"family":"Montserrat"},"color":"#000000"}},"title":{"display":true,"text":"Journals","font":{"size":24,"family":"Montserrat","weight":600},"color":"#000000"}}}},"publishers":{"type":"bar","data":{"show":true,"labels":["Taylor & Francis","South Ural State University","Springer Nature"],"ids":[18,7216,8],"codes":[0,0,0],"imageUrls":["\/storage\/images\/resized\/5YZtvLvkPZuc2JHOaZsjCvGSHFCuC3drUwN3YAc5_medium.webp","\/storage\/images\/resized\/QmBKdvQR66juwTKToKoBN7jk0mRjGh8wAeLwZ5fQ_medium.webp","\/storage\/images\/resized\/voXLqlsvTwv5p3iMQ8Dhs95nqB4AXOG7Taj7G4ra_medium.webp"],"datasets":[{"label":"","data":[1,1,1],"backgroundColor":["#3B82F6","#3B82F6","#3B82F6"],"percentage":[33.33,33.33,33.33],"barThickness":13}]},"options":{"indexAxis":"y","maintainAspectRatio":false,"scales":{"y":{"ticks":{"precision":0,"autoSkip":false,"font":{"family":"Montserrat"},"color":"#000000"}},"x":{"ticks":{"stepSize":null,"precision":0,"font":{"family":"Montserrat"},"color":"#000000"}}},"plugins":{"legend":{"position":"top","labels":{"font":{"family":"Montserrat"},"color":"#000000"}},"title":{"display":true,"text":"Publishers","font":{"size":24,"family":"Montserrat","weight":600},"color":"#000000"}}}}}
Metrics
Cite this
GOST |
RIS |
BibTex
Cite this
GOST
Copy
DMITRIEV A. N. et al. The Thermophysical Bases of Monitoring of the Fireproof Lining Wear in the Blast Furnace Hearth // Defect and Diffusion Forum. 2017. Vol. 370. pp. 113-119.
GOST all authors (up to 50)
Copy
DMITRIEV A. N., Zolotykh M. O., Chen K., Vitkina G. Yu. The Thermophysical Bases of Monitoring of the Fireproof Lining Wear in the Blast Furnace Hearth // Defect and Diffusion Forum. 2017. Vol. 370. pp. 113-119.
Cite this
RIS
Copy
TY - JOUR
DO - 10.4028/www.scientific.net/ddf.370.113
UR - https://doi.org/10.4028%2Fwww.scientific.net%2Fddf.370.113
TI - The Thermophysical Bases of Monitoring of the Fireproof Lining Wear in the Blast Furnace Hearth
T2 - Defect and Diffusion Forum
AU - DMITRIEV, ANDREY N.
AU - Zolotykh, M O
AU - Chen, K.
AU - Vitkina, Galina Yu
PY - 2017
DA - 2017/01/24 00:00:00
PB - Trans Tech Publications
SP - 113-119
VL - 370
SN - 1012-0386
SN - 1662-9507
ER -
Cite this
BibTex
Copy
@article{2017_DMITRIEV,
author = {ANDREY N. DMITRIEV and M O Zolotykh and K. Chen and Galina Yu Vitkina},
title = {The Thermophysical Bases of Monitoring of the Fireproof Lining Wear in the Blast Furnace Hearth},
journal = {Defect and Diffusion Forum},
year = {2017},
volume = {370},
publisher = {Trans Tech Publications},
month = {jan},
url = {https://doi.org/10.4028%2Fwww.scientific.net%2Fddf.370.113},
pages = {113--119},
doi = {10.4028/www.scientific.net/ddf.370.113}
}
Profiles