Improving design and application method of screening bucket excavators

The purpose of the study is to increase the productivity and economic efficiency of mining operations using screening bucket excavators on the basis of the introduction of a new technical and technological solution that expands equipment functionality. The study involves the analysis of known designs of screening buckets installed on excavators that ensure material separation to be carried out simultaneously with excavation and loading works. It is noted that a promising development direction of screening buckets is a design with working drums. The article presents an excavator with a modernized screening bucket and its operation technology, which allows to start rock mass sorting in the bucket while the excavator is turning to the place of unloading. The improved screening bucket is equipped with a hinged movable bottom controlled by hydraulic cylinders to accumulate fine fractions screened through the working drums. Fine fractions accumulated in the moving bottom are unloaded into a dump truck, after which screening continues directly into the body of the dump truck. Screening finished, the movable bottom closes and the excavator unloads the coarse fractions remaining in the bucket into another vehicle. Unloading is carried out by bucket turning. The combination of screening and excavator turning reduces the operation cycle time, which increases the performance of both the excavator and dump trucks. The use of a modernized screening bucket with a moving bottom eliminates the loss of valuable fine material as a result of spilling when the excavator turns for unloading. The movable bottom can be installed on the screening buckets of known designs and does not require their significant alteration. Application of the proposed technical and technological solution will reduce unit costs and increase the efficiency of work.

1. Trubetskoy KN, Vladimirov DYa, Pytalev IA, Popova TM. Robotic systems for open pit mineral mining. Gornyi zhurnal. 2016;5:21–27. (In Russ.) https://doi.org/10.17580/gzh.2016.05.01

2. Jarvie-Eggart ME. Responsible mining: case studies in managing social & environmental risks in the developed world. Englewood: Society for Mining, Metallurgy and Exploration; 2015. 804 р.

3. Adams MD. Gold ore processing: project development and operations. Amsterdam: Elsevier; 2016. 980 p.

4. Frank U. Multi-perspective enterprise modeling: foundational concepts, prospects and future research challenges. Software & Systems Modeling. 2014;13(3):941– 962. https://doi.org/10.1007/s10270-012-0273-9

5. Cheban AYu. Engineering of complex structure apatite deposits and excavating-sorting equipment for its implementation. Zapiski Gornogo instituta = Journal of Mining Institute. 2019;238:399–404. (In Russ.) https://doi.org/10.31897/PMI.2019.4.399

6. Khopunov EA. Problems of ore preparation in the “fourth industrial revolution”. Izvestiya vysshikh uchebnykh zavedenii. Gornyi zhurnal = News of the Higher Institutions. Mining Journal. 2019;5:54–62. (In Russ.) https://doi.org/10.21440/0536-1028-2019-5-54-62

7. Cheban AYu. Improvement of geotechnology of extraction of thin ore minerals with the use of the arrow combine. Izvestiya Tul'skogo gosudarstvennogo universiteta. Nauki o Zemle = News of the Tula state university. Sciences of Earth. 2020;1:340–348. (In Russ.) https://doi.org/10.46689/2218-5194-2020-1-1-340-348

8. Starke L. Breaking new ground: mining, minerals and sustainable development. London: IIED; 2016. 480 p.

9. Brown C. Autonomous vehicle technology in mining. Engineering and Mining Journal. 2012;213(1):30–32.

10. Cheban AYu. Technology of development of complex structural deposit with application of improved mining aggregate. Izvestiya Tul'skogo gosudarstvennogo universiteta. Nauki o Zemle = News of the Tula state university. Sciences of Earth. 2020;3:209–219. (In Russ.)

11. Improving production performance of the mine using an economically efficient method with the help of ALLU. Gornaya promyshlennost' = Russian Mining Industry Journal. 2020;1:68–69. (In Russ.)

12. Cheban AYu. Method for exploding explosed rock mass by excavator when developing complex deposits. Marksheiderskii vestnik = Mine Surveying Bulletin. 2020;2:66–70. (In Russ.)

13. Burtsev SV, Levchenko YaV, Talanin VV, Voroshilin KS. Blastless technologies for rock mass conditioning for conveyor transportation. Ugol'. 2018;10:8–17. (In Russ.) https://doi.org/10.18796/0041-5790-2018-10-8-17

14. Cheban AYu. Production complex for open-cast mining of solid minerals. Gornoe oborudovanie i elektromekhanika = Mining Equipment and Electromechanics. 2017;3:8–11. (In Russ.)

15. Bokunov YuV, Kochetkov VS, Dudinskii FV. Dragline excavator bucket. Patent RF, no. 2029031; 1995. (In Russ.)

16. Mirkin SN, Levchenko SA, Meshcheryakov AA. Excavator bucket. Patent RF, no. 2204657; 2003. (In Russ.)

17. Modig K. A bucket with a sieving attachment. Patent RF, no. 2042015; 1995. (In Russ.)

18. Paski E. A ladle and its application method. Patent RF, no. 2622058; 2017. (In Russ.)

19. Nagornov DO, Kremtcheev EA, Mikhaylov AV, Bol'shunov AV. The hinged modular mechanized complex for extraction and primary processing of peat. Gornyi informatsionno-analiticheskii byulleten' (nauchno-tekhnicheskii zhurnal) = Mining informational and analytical bulletin (scientific and technical journal). 2013;2:243–248. (In Russ.)

20. Mennikko A. Screening, crushing or mixing bucket. Patent RF, no. 2530730; 2014. (In Russ.)