12
Schaffer, A. A. (2019). Low temperature upregulates
cwp expression and modifies alternative splicing pat-
terns, increasing the severity of cwp- induced tomato
fruit cuticular microfissures. Horticulture Research, 6.
[23] Chen, W., &Fryrear, D. W. (2001). Aerodynamic
and geometric diameters of airborne particles. Journal
of Sedimentary Research, 71(3), 365–371.
[24] Chen, Y., &Zhang, X. (2021). Study on the cutting
mechanism of SiCp/Al considering particle size and
distribution. The International Journal of Advanced
Manufacturing Technology, 115(4), 1211- 1225.
[25] Cheng, W., Zhou, G., Chen, L., WANG, G., NIE,
W. and. ZHZNG, Q., 2020. Research progress and
prospect of dust control theory and technology in
China’s coal mines in the past 20 years. Coal science
and technology, 48(2).
[26] Chugh, Y. P., &Gillies, A. D. S. (2018). Advanced
Bit Management Strategies to Enhance Tool Life
and Performance in Coal Mining. International
Journal of Coal Geology, 194, 45–55. doi: 10.1016
/j.coal.2018.06.011.
[27] Claiborn, C. S., Finn, D., Larson, T. V., &Koenig,
J. Q. (2000). Windblown dust contributes to high
PM25 concentrations. Journal of the Air &Waste
Management Association, 50(8), 1440–1445.
[28] Colinet, J., Halldin, C. N., &Schall, J. (2021). Best
practices for dust control in coal mining.
[29] Copur, H., Bilgin, N., Balci, C., Tumac, D. and
Avunduk, E., 2017. Effects of different cutting pat-
terns and experimental conditions on the perfor-
mance of a conical drag tool. Rock Mechanics and
Rock Engineering, 50, pp.1585–1609.
[30] Dahneke, B. (1971). The capture of aerosol particles
by surfaces. Journal of colloid and interface science,
37(2), 342- 353.
[31] Derickson, A. (2013). “Nuisance Dust”: unprotective
limits for exposure to coal mine dust in the United
States, 1934– 1969. American journal of public health,
103(2), 238–249.
[32] Després, V., Huffman, J. A., Burrows, S. M., Hoose,
C., Safatov, A., Buryak, G., ...&Jaenicke, R. (2012).
Primary biological aerosol particles in the atmosphere:
a review. Tellus B: Chemical and Physical Meteorology,
64(1), 15598.
[33] Dewangan, S. and Chattopadhyaya, S., 2016.
Characterization of wear mechanisms in distorted
conical picks after coal cutting. Rock Mechanics and
Rock Engineering, 49, pp.225–242.
[34] Diniz, A. E., Machado, Á. R., &Corrêa, J. G. (2016).
Tool wear mechanisms in the machining of steels and
stainless steels. The International Journal of Advanced
Manufacturing Technology, 87, 3157–3168.
[35] Donoghue, A. M. (2004). Occupational health haz-
ards in mining: An overview. Occupational Medicine,
54(5), 283–289. doi: 10.1093/occmed/kqh072.
[36] Ehara, K., Hagwood, C., &Coakley, K. J. (1996).
Novel method to classify aerosol particles according
to their mass-to- charge ratio—aerosol particle mass
analyser. Journal of Aerosol Science, 27(2), 217–234.
[37] Fanebust, I. M. (2019). Study of the influence of
particle size and moisture on the explosibility of dusts
(Master’s thesis, Høgskolen på Vestlandet).
[38] Finkelman, R. B., Orem, W., &Castranova, V. (2019).
Health Impacts of Coal Mining and Combustion:
Advancing Coal Mining Practices for Public Health
Protection. International Journal of Coal Geology,
202, 37–52. doi: 10.1016/j.coal.2018.12.003.
[39] Gao, R., Flower, M., &Brown, M. (2020). Predictive
Maintenance for Mining Tools: Real-time Monitoring
and Wear Prediction. Mining Engineering, 72(4),
61–67. doi: 10.19150/me.9260.
[40] Garcia, M.C.A., 2024. Predictive Model for Coal
Workers Pneumoconiosis (CWP) Risk in the US
(Master’s thesis, New Mexico Institute of Mining and
Technology).
[41] Ghasemi, R., Rezaei, B., &Mardani, H. (2021).
Adhesive Wear Mechanisms in Mining Equipment: A
Comprehensive Study. Tribology International, 158,
106877. doi: 10.1016/j.triboint.2021.106877.
[42] Gonen, A., 2018. Ventilation requirements for today’s
mechanized underground metal mines. International
Journal of Advanced Research in Engineering, 4(1),
pp.7- 10.
[43] Gromyka, D. and Kremcheev, E., 2020. High tem-
perature wear assessment of mining machines oper-
ating tools. In E3S Web of Conferences (Vol. 174,
p. 03013). EDP Sciences.
[44] Gurley, W. A., Davis, J. W., &Moncrief, H. L. (2021).
Innovative Dust Control Measures in Underground
Coal Mining: Evaluation of New Technologies. Mining
Engineering, 73(8), 31–37. doi: 10.19150/me.9612.
[45] Han, L., Han, R., Ji, X., Wang, T., Yang, J., Yuan,
J., Wu, Q., Zhu, B., Zhang, H., Ding, B. and Ni,
C., 2015. Prevalence characteristics of coal workers’
pneumoconiosis (CWP) in a state- owned mine in
Eastern China. International journal of environmental
research and public health, 12(7), pp.7856–7867.
[46] Health. Division of Physical Sciences. (1994). NIOSH,
Manual of Analytical Methods. US Department of
Health and Human Services, Public Health Service,
Schaffer, A. A. (2019). Low temperature upregulates
cwp expression and modifies alternative splicing pat-
terns, increasing the severity of cwp- induced tomato
fruit cuticular microfissures. Horticulture Research, 6.
[23] Chen, W., &Fryrear, D. W. (2001). Aerodynamic
and geometric diameters of airborne particles. Journal
of Sedimentary Research, 71(3), 365–371.
[24] Chen, Y., &Zhang, X. (2021). Study on the cutting
mechanism of SiCp/Al considering particle size and
distribution. The International Journal of Advanced
Manufacturing Technology, 115(4), 1211- 1225.
[25] Cheng, W., Zhou, G., Chen, L., WANG, G., NIE,
W. and. ZHZNG, Q., 2020. Research progress and
prospect of dust control theory and technology in
China’s coal mines in the past 20 years. Coal science
and technology, 48(2).
[26] Chugh, Y. P., &Gillies, A. D. S. (2018). Advanced
Bit Management Strategies to Enhance Tool Life
and Performance in Coal Mining. International
Journal of Coal Geology, 194, 45–55. doi: 10.1016
/j.coal.2018.06.011.
[27] Claiborn, C. S., Finn, D., Larson, T. V., &Koenig,
J. Q. (2000). Windblown dust contributes to high
PM25 concentrations. Journal of the Air &Waste
Management Association, 50(8), 1440–1445.
[28] Colinet, J., Halldin, C. N., &Schall, J. (2021). Best
practices for dust control in coal mining.
[29] Copur, H., Bilgin, N., Balci, C., Tumac, D. and
Avunduk, E., 2017. Effects of different cutting pat-
terns and experimental conditions on the perfor-
mance of a conical drag tool. Rock Mechanics and
Rock Engineering, 50, pp.1585–1609.
[30] Dahneke, B. (1971). The capture of aerosol particles
by surfaces. Journal of colloid and interface science,
37(2), 342- 353.
[31] Derickson, A. (2013). “Nuisance Dust”: unprotective
limits for exposure to coal mine dust in the United
States, 1934– 1969. American journal of public health,
103(2), 238–249.
[32] Després, V., Huffman, J. A., Burrows, S. M., Hoose,
C., Safatov, A., Buryak, G., ...&Jaenicke, R. (2012).
Primary biological aerosol particles in the atmosphere:
a review. Tellus B: Chemical and Physical Meteorology,
64(1), 15598.
[33] Dewangan, S. and Chattopadhyaya, S., 2016.
Characterization of wear mechanisms in distorted
conical picks after coal cutting. Rock Mechanics and
Rock Engineering, 49, pp.225–242.
[34] Diniz, A. E., Machado, Á. R., &Corrêa, J. G. (2016).
Tool wear mechanisms in the machining of steels and
stainless steels. The International Journal of Advanced
Manufacturing Technology, 87, 3157–3168.
[35] Donoghue, A. M. (2004). Occupational health haz-
ards in mining: An overview. Occupational Medicine,
54(5), 283–289. doi: 10.1093/occmed/kqh072.
[36] Ehara, K., Hagwood, C., &Coakley, K. J. (1996).
Novel method to classify aerosol particles according
to their mass-to- charge ratio—aerosol particle mass
analyser. Journal of Aerosol Science, 27(2), 217–234.
[37] Fanebust, I. M. (2019). Study of the influence of
particle size and moisture on the explosibility of dusts
(Master’s thesis, Høgskolen på Vestlandet).
[38] Finkelman, R. B., Orem, W., &Castranova, V. (2019).
Health Impacts of Coal Mining and Combustion:
Advancing Coal Mining Practices for Public Health
Protection. International Journal of Coal Geology,
202, 37–52. doi: 10.1016/j.coal.2018.12.003.
[39] Gao, R., Flower, M., &Brown, M. (2020). Predictive
Maintenance for Mining Tools: Real-time Monitoring
and Wear Prediction. Mining Engineering, 72(4),
61–67. doi: 10.19150/me.9260.
[40] Garcia, M.C.A., 2024. Predictive Model for Coal
Workers Pneumoconiosis (CWP) Risk in the US
(Master’s thesis, New Mexico Institute of Mining and
Technology).
[41] Ghasemi, R., Rezaei, B., &Mardani, H. (2021).
Adhesive Wear Mechanisms in Mining Equipment: A
Comprehensive Study. Tribology International, 158,
106877. doi: 10.1016/j.triboint.2021.106877.
[42] Gonen, A., 2018. Ventilation requirements for today’s
mechanized underground metal mines. International
Journal of Advanced Research in Engineering, 4(1),
pp.7- 10.
[43] Gromyka, D. and Kremcheev, E., 2020. High tem-
perature wear assessment of mining machines oper-
ating tools. In E3S Web of Conferences (Vol. 174,
p. 03013). EDP Sciences.
[44] Gurley, W. A., Davis, J. W., &Moncrief, H. L. (2021).
Innovative Dust Control Measures in Underground
Coal Mining: Evaluation of New Technologies. Mining
Engineering, 73(8), 31–37. doi: 10.19150/me.9612.
[45] Han, L., Han, R., Ji, X., Wang, T., Yang, J., Yuan,
J., Wu, Q., Zhu, B., Zhang, H., Ding, B. and Ni,
C., 2015. Prevalence characteristics of coal workers’
pneumoconiosis (CWP) in a state- owned mine in
Eastern China. International journal of environmental
research and public health, 12(7), pp.7856–7867.
[46] Health. Division of Physical Sciences. (1994). NIOSH,
Manual of Analytical Methods. US Department of
Health and Human Services, Public Health Service,