TY - JOUR
T1 - Railway ballast performance
T2 - Recent advances in the understanding of geometry, distribution and degradation
AU - Shi, Can
AU - Fan, Zheng
AU - Connolly, David P.
AU - Jing, Guoqing
AU - Markine, Valeri
AU - Guo, Yunlong
PY - 2023
Y1 - 2023
N2 - Railway ballast performance is dictated by a complex mix of mechanical properties. These effect its performance at the particle level for example in terms of particle degradation, but also at the track system level in terms of settlement and stability. Therefore this paper seeks to develop new understandings of ballast behaviour and identify opportunities for future research directions. First, ballast particle size and size distribution curves are discussed, considering opportunities to improve breakage, settlement and drainage characteristics. Next, particle geometry is discussed, with a focus on form, angularity and surface texture. This is followed by a discussion on the degradation mechanisms of ballast particles and the effect of fouling on permeability. Next, techniques to assess and improve ballast bulk density are discussed, such as ground penetration radar and dynamic track stabilisation. Testing methods for studying ballast are also reviewed, first considering both smaller-scale tests such as direct shear tests and the Los Angeles abrasion test. Then larger-scale laboratory testing is discussed, including large-diameter dynamic triaxial testing and the use of full-scale laboratory tracks. Finally, conclusions are drawn and suggestions for future research directions are given.
AB - Railway ballast performance is dictated by a complex mix of mechanical properties. These effect its performance at the particle level for example in terms of particle degradation, but also at the track system level in terms of settlement and stability. Therefore this paper seeks to develop new understandings of ballast behaviour and identify opportunities for future research directions. First, ballast particle size and size distribution curves are discussed, considering opportunities to improve breakage, settlement and drainage characteristics. Next, particle geometry is discussed, with a focus on form, angularity and surface texture. This is followed by a discussion on the degradation mechanisms of ballast particles and the effect of fouling on permeability. Next, techniques to assess and improve ballast bulk density are discussed, such as ground penetration radar and dynamic track stabilisation. Testing methods for studying ballast are also reviewed, first considering both smaller-scale tests such as direct shear tests and the Los Angeles abrasion test. Then larger-scale laboratory testing is discussed, including large-diameter dynamic triaxial testing and the use of full-scale laboratory tracks. Finally, conclusions are drawn and suggestions for future research directions are given.
KW - Ballast fouling index
KW - Ballast mechanical behaviour
KW - Ballast particle size distribution
KW - Bulk density
KW - Parent rock
KW - Railroad dynamic performance
KW - Railway ballast
KW - Railway track degradation
UR - http://www.scopus.com/inward/record.url?scp=85161534698&partnerID=8YFLogxK
U2 - 10.1016/j.trgeo.2023.101042
DO - 10.1016/j.trgeo.2023.101042
M3 - Review article
AN - SCOPUS:85161534698
SN - 2214-3912
VL - 41
JO - Transportation Geotechnics
JF - Transportation Geotechnics
M1 - 101042
ER -