References

gscience

Mining Science and Technology (Russia)

Горные науки и технологии

2500-0632

The National University of Science and Technology MISiIS (NUST MISIS)

10.17073/2500-0632-2022-2-111-125

gscience-347

Research Article

SAFETY IN MINING AND PROCESSING INDUSTRY AND ENVIRONMENTAL PROTECTION

ТЕХНОЛОГИЧЕСКАЯ БЕЗОПАСНОСТЬ В МИНЕРАЛЬНО-СЫРЬЕВОМ КОМПЛЕКСЕ И ОХРАНА ОКРУЖАЮЩЕЙ СРЕДЫ

Forecasting PM2.5 emissions in open-pit minesusing a functional link neural network optimized by various optimization algorithms

Прогнозирование выбросов пыли (PM2.5) на угольных разрезах с помощью нейронной сети с функциональными связями, оптимизированной различными алгоритмами

https://orcid.org/0000-0001-5953-4902

Буи

С. -Н.

Bui

X. -N.

Суан-Нам Буи– доктор наук, профессор, департамент открытых горных работ; Исследовательская группа инноваций для устойчивой и ответственной добычи полезных ископаемых (ISRM)

Scopus ID 36892679300

Ханой

Huan-Nam Bui – Dr.-Ing, Professor, Department of Surface Mining, Mining Faculty; Research Group of Innovations for Sustainable and Responsible Mining (ISRM)

Scopus ID 36892679300

Hanoi

buixuannam@humg.edu.vn

https://orcid.org/0000-0001-6122-8314

Нгуен

Х.

Nguyen

Хоанг Нгуен – департамент открытых горных работ; Исследовательская группа инноваций для устойчивой и ответственной добычи полезных ископаемых (ISRM)

Scopus ID 57209589544

Ханой

Hoang Nguyen – Department of Surface Mining, Mining Faculty; Research Group of Innovations for Sustainable and Responsible Mining (ISRM)

Scopus ID 57209589544

Hanoi

nguyenhoang@humg.edu.vn

Ле

К. -Т.

Q. .-T.

Ки-Тао Ле – департамент открытых горных работ; Исследовательская группа инноваций для устойчивой и ответственной добычи полезных ископаемых (ISRM)

Scopus ID 57209279515

Ханой

Qui-Thao Le – Department of Surface Mining, Mining Faculty; Research Group of Innovations for Sustainable and Responsible Mining (ISRM)

Hanoi

lequithao@humg.edu.vn

Ле

Т. Н.

T. N.

Туан-Нгок Ле – заместитель генерального директора

Ханой

Tuan-Ngoc Le – Deputy General Director

Hanoi

letuanngoc@vimico.vn

Ханойский университет горного дела и геологииВьетнамHanoi University of Mining and GeologyViet Nam

Vinacomin – Minerals Holding CorporationВьетнамVinacomin – Minerals Holding CorporationViet Nam

2022

20072022

72111125

2022

Буи С.-., Нгуен Х., Ле К.-., Ле Т.Н.

Bui X.-., Nguyen H., Le Q..., Le T.N.

This work is licensed under a Creative Commons Attribution 4.0 License.

https://mst.misis.ru/jour/article/view/347

PM2.5 air pollution is not only a significant hazard to human health in everyday life but also a dangerous risk to workers operating in open-pit mines OPMs), especially open-pit coal mines (OPCMs). PM2.5 in OPCMs can cause lung-related (e.g., pneumoconiosis, lung cancer) and cardiovascular diseases due to exposure to airborne respirable dust over a long time. Therefore, the precise prediction of PM2.5 is of great importance in the mitigation of PM2.5 pollution and improving air quality at the workplace. This study investigated the meteorological conditions and PM2.5 emissions at an OPCM in Vietnam, in order to develop a novel intelligent model to predict PM2.5 emissions and pollution. We applied functional link neural network (FLNN) to predict PM2.5 pollution based on meteorological conditions (e.g., temperature, humidity, atmospheric pressure, wind direction and speed). Instead of using traditional algorithms, the Hunger Games Search (HGS) algorithm was used to train the FLNN model. The vital role of HGS in this study is to optimize the weights in the FLNN model, which was finally referred to as the HGS-FLNN model. We also considered three other hybrid models based on FLNN and metaheuristic algorithms, i.e., ABC (Artificial Bee Colony)-FLNN, GA (Genetic Algorithm)- FLNN, and PSO (Particle Swarm Optimization)-FLNN to assess the feasibility of PM2.5 prediction in OPCMs and compare their results with those of the HGS-FLNN model. The study findings showed that HGS-FLNN was the best model with the highest accuracy (up to 94–95 % in average) to predict PM2.5 air pollution. Meanwhile, the accuracy of the other models ranged 87 % to 90 % only. The obtained results also indicated that HGS-FLNN was the most stable model with the lowest relative error (in the range of −0.3 to 0.5 %).

Загрязнение воздуха PM2.5 (твердые частицы размером 2,5 мк и менее) представляет собой не только значительную опасность для здоровья человека в повседневной жизни, но и опасный риск для рабочих при открытых горных работах, особенно на угольных разрезах. PM2.5 на угольных разрезах могут вызывать заболевания легких (например, пневмокониоз, рак легких) и сердечно-сосудистые заболевания из-за длительного воздействия вдыхаемой пыли. Поэтому точное прогнозирование PM2.5 имеет большое значение для минимизации загрязнения PM2.5 и улучшения качества воздуха на рабочих местах. В данном исследовании изучались метеорологические условия и выбросы PM2.5 на угольном разрезе во Вьетнаме с целью разработки новой интеллектуальной модели для прогнозирования выбросов и загрязнения PM2.5, применялась нейронная сеть с функциональными связями (FLNN) для прогнозирования загрязнения PM2.5 в зависимости от метеорологических условий (в частности, температуры, влажности, атмосферного давления, направления и скорости ветра). Вместо традиционных алгоритмов для обучения модели FLNN был использован алгоритм поиска методом голодных игр (HGS). Важнейшая роль HGS в данном исследовании заключается в оптимизации весов в модели FLNN, которая была названа моделью HGS-FLNN. Также были рассмотрены три другие гибридные модели, основанные на FLNN и метаэвристических алгоритмах, т.е. ABC (искусственная пчелиная колония)-FLNN, GA (генетический алгоритм)-FLNN и PSO (оптимизация роя частиц)-FLNN, для оценки возможности прогнозирования PM2.5 на угольных разрезах и сравнения их результатов с результатами модели HGS-FLNN. Исследования показали, что HGS-FLNN является лучшей моделью с самой высокой точностью прогнозирования загрязнения воздуха PM2.5 (в среднем до 94–95 %, при этом точность других моделей варьировалась от 87 до 90 %), а также наиболее стабильной моделью с наименьшей относительной ошибкой (в диапазоне от −0,3 до 0,5 %).

угольный разреззагрязнение воздухапыльPM2.5здоровье человекапоиск методом голодных игрнейронная сеть с функциональными связямиоптимизацияразрез Кок Саупровинция КуангниньВьетнам

open-pit coal mineair pollutiondustPM2.5human healthhunger games searchfunctional link neural networkoptimizationCoc Sau open-pit coal mineQuang Ninh provinceVietnam

Данное исследование было финансово поддержано Министерством образования и профессиональной подготовки (MOET) Вьетнама в рамках гранта № B2018-MDA-03SP. Авторы также благодарят Центр горных и электромеханических исследований Ханойского университета горного дела и геологии (HUMG), Вьетнам; инженеров и руководителей угольного разреза Кок Сау, провинция Куангнинь, Вьетнам, за помощь и сотрудничество.

This study was financially supported by the Ministry of Education and Training (MOET) of Vietnam under grant number B2018-MDA-03SP. The authors also thank the Center for Mining, Electro-Mechanical Research of Hanoi University of Mining and Geology (HUMG), Vietnam; the engineers and managers of the Coc Sau open-pit coal mine, Quang Ninh province, Vietnam for their help and cooperation.

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The authors declare that there are no conflicts of interest present.