Identyfikatory
Warianty tytułu
Języki publikacji
Abstrakty
Many methods based on machine vision were used to estimate coarse particles size distribution in recent years, but comparison of accuracy parameters representing particle size has not been carried out and a related representing analysis has not been yet proposed. Nine parameters were investigated. The results indicated the minor axis of equivalent ellipse and breadth of the best-fit rectangle were the most suitable for representing particle size. The former accuracy ratio was 86.43% and the latter accuracy ratio was 85.39%, while the accuracy of other parameters was less than 70%. A related representing analysis was proposed to explain this phenomenon. This research is instructive and meaningful for the size distribution estimation by machine vision.
Rocznik
Tom
Strony
397--405
Opis fizyczny
Bibliogr. 24. poz., rys., wykr.
Twórcy
autor
- School of Chemical Engineering and Technology, China University of Mining and Technology, Xuzhou 221116, Jiangsu, China
autor
- School of Chemical Engineering and Technology, China University of Mining and Technology, Xuzhou 221116, Jiangsu, China
autor
- School of Chemical Engineering and Technology, China University of Mining and Technology, Xuzhou 221116, Jiangsu, China
autor
- School of Chemical Engineering and Technology, China University of Mining and Technology, Xuzhou 221116, Jiangsu, China
Bibliografia
- 1. AL-THYABAT S., MILES N.J., 2006. An improved estimation of size distribution from particle profile measurements. Powder Technology, 166, 152–160.
- 2. AL-THYABAT S., MILES N.J., KOH T.S., 2007. Estimation of the size distribution of particles moving on a conveyor belt. Minerals Engineering, 20, 72–83.
- 3. BANTA L., CHENG K., ZANIEWSKI J., 2003. Estimation of limestone particle mass from 2D images, Powder Technology, 132, 184–189.
- 4. CASALI A., GONZALEZ G., VALLEBUON G., PEREZ C., VARGAS R., 2001. Grindability Softsensors based on Lithological Composition and On-Line Measurements. Minerals Engineering, 14, 689-700.
- 5. DONALD C., KETTUNEN B.E., 1996. On-line size analysis for the measurement of blast fragmentation. In: J.A. Franklin, T. Katsabanis (Eds.), Measurement of Blast Fragmentation, Rotterdam, Balkema, 175–177.
- 6. GIRDNER K.K., KEMENY J.M., SRIKANT A., MCGILL R., 1996. The split system for analyzing the size distribution of fragmented rock. In: J.A. Franklin, T. Katsabanis (Eds.), Measurement of Blast Fragmentation, Rotterdam, Balkema, 101–108.
- 7. GRANNES S.G., 1986. Determine size distribution of moving pellets by computer image processing. In: R.V. Ramani (Ed.), Proceedings of the 19th Application of Computers and Operations Research in Mineral Industry, Soc. Mining Engineers, Inc., 545–551.
- 8. GUYOT O., MONREDON T., LAROSA D., BROUSSAUD A., 2004. VisioRock, an Integrated Vision Technology for Advanced Control of Comminution Circuits. Minerals Engineering, 17, 1227-1235.
- 9. KEMENY J., 1994. A practical technique for determining the size distribution of blasted benches, waste dumps, and heap-leach sites. Mining Engineering, 46, 1281–1284.
- 10. KWAN A.K.H., MORA C.F., CHAN H.C., 1999. Particle shape analysis of coarse aggregate using digital image processing. Cement and Concrete Research, 29 (9),1403–1410.
- 11. MAERZ N.H., FRANKLIN J.A., ROTHENBURG L., COURSEN D.L., 1987. Measurement of Rock Fragmentation by Digital Photoanalysis. 5th. Int. Cong. Int. Soc. Rock Mech., 1, 687–692.
- 12. MAERZ N.H., PALANGIO T.C., FRANKLIN J.A., 1996. WipFrag image based granulometry system. In: J.A. Franklin, T. Katsabanis (Eds.), Measurement of Blast Fragmentation, Rotterdam, Balkema, 91–99.
- 13. MCDERMOTT C., HUNTER G.C., MILES N.J., 1989. The application of image analysis to the measurement of blast fragmentation. Proceedings of the Surface Mining – Future Concepts, Nottingham University, Marylebone Press, Manchester, 103–108.
- 14. MORA C.F., KWAN A.K.H., CHAN H.C., 1998. Particle Size Distribution Analysis Of Coarse Aggregate Using Digital Image Processing. Cement and Concrete Research, 28, 921–932.
- 15. MORA C.F., KWAN A.K.H., 2000. Sphericity, shape factor, and convexity measurement of coarse aggregate for concrete using digital image processing. Cement and Concrete Research, 30, 351–358.
- 16. MONTORO J.J., GONZALEZ E., 1993. New analytical techniques to evaluate fragmentation based on image analysis by computer methods. Proceedings of the 4th Int. Symposium Rock Fragmentation by Blasting, Vienna, Austria, 309–316.
- 17. ORD A., 1989. Real time image analysis of size and shape distributions of rock fragments. Proc. Aust. Int. Min. Metall, 294, 28.
- 18. RHOLL S.A., 1993. Photographic assessment of the fragmentation distribution of rock quarry muckpiles. Proceedings of the 4th Int. Symposium Rock Fragmentation by Blasting, Vienna, Austria, 501–506.
- 19. TASDEMIR A., OZDAG H., ONAL G., 2011. Image analysis of narrow size fractions obtained by sieve analysis. An evaluation by log-normal distribution and shape factors. Physicochemical Problems of Mineral Processing, 46, 95–106.
- 20. TOBIAS A., THURLEY M.J., CARLSON J.E., 2012. A machine vision system for estimation of size distributions by weight of limestone particles. Minerals Engineering, 25, 38–46.
- 21. WANG, W.X., 2006. Image analysis of particles by modified Ferret method – best-fit rectangle. Powder Technology, 165, 1–10.
- 22. XIA W., YANG J., ZHAO Y., ZHU B., WANG Y. 2012a, Improving floatability of taixi anthracite coal of mild oxidation by grinding. Physicochem. Probl. Miner. Process. 48 (2), 393–401.
- 23. XIA W., YANG J., ZHU B., 2012b. Flotation of oxidized coal dry-ground with collector. Powder Technology, 228, 324–326.
- 24. ZHANG Z.L., YANG J.G., DING L.H., ZHAO Y.M., 2012. An improved estimation of coal particle mass using image analysis. doi:10.1016/j.powtec.2012.06.027.
Typ dokumentu
Bibliografia
Identyfikator YADDA
bwmeta1.element.baztech-410d7c2e-ccaf-4c7d-8d35-73c3f5528f96