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Steel making
Название Calculation of bulk density of steel scrap in scrap chutes using 3D camera
Автор E. N. Ishmetyev, D. V. Chistyakov, A. N. Panov, E. E. Bodrov, D. V. Rabadzhi
Информация об авторе

“KonsOM SKS” JSC (Magnitogorsk, Russia):

Ishmetyev E. N., Dr. Eng., Director on Strategic Development
Chistyakov D. V., Cand. Soc., Executive Director
Panov A. N., Cand. Eng., Ass. Prof., Head of Dept. of Innovations

 

Nosov Magnitogorsk State Technical University (Magnitogorsk, Russia):
Bodrov E. E., Cand. Eng., Ass. Prof., Chair of Electronics and Microelectronics,

 

Magnitogorsk Iron and Steel Works (Magnitogorsk, Russia):
Rabadzhi D. V., Prof

E-mail (common): fortheartist@mail.ru

Реферат

At present time, an oxygen converter process is one of the most widespread steel making processes. Often it uses steel scrap as a refrigerant. This occur because of the facts that chemically pure steel scrap has high technological properties and is a production waste which requires recycling. One of the important technological parameters of the steel scrap metal used in basic oxygen furnace is its bulk density. It can affect the steel production yield and process stability in the furnace. That is why there is a need to control the bulk density of the steel scrap in a peel before putting it into the furnace. The bulk density can be calculated using information about its volume and weight. Finding the weight of the scrap-metal does not cause any difficulties because converter shop is equipped with a scale designed to weight peel with scrap-metal in it. On the other hand, finding the volume of the steel scrap that had been placed in the peel is a much more difficult problem. In order to solve that problem specialists of CJSC “KonsOM SKS” conducted experiments directed to measure the steel scrap volume using 3D-camera with time-of-fl ight sensor in oxygen converter shop at OJSC “Magnitogorsk Iron and Steel Works”. The camera allows to measure the distance between camera itself and a surface of scrapmetal in the peel. Then that distance can be used to calculate scrap-metal surface height above the peel bottom that in turn also is a surface with known distance from it to the camera. This paper presents calculation of steel scrap-metal volume in the peel using the distances obtained during the experiment. Comparison of different values of the volume obtained for the same peel in various time points showed that error caused by 3D-camera’s measurement inconstancy lies within 5% limits. The obtained volume values can further be used to calculate bulk density of the scrap.

Ключевые слова Metallurgical industry, basic oxygen furnaces, bulk density, scrap metal, volume measurement, 3D-camera.
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