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Correlations between Refractive Index and Retroreflectance of Glass Beads for Use in Road-marking Applications under Wet Conditions

  • Shin, Sang Yeol (Department of Materials Science and Engineering, Korea Aerospace University) ;
  • Lee, Ji In (Department of Materials Science and Engineering, Korea Aerospace University) ;
  • Chung, Woon Jin (Division of Advanced Materials Engineering, Kongju National University) ;
  • Choi, Yong Gyu (Department of Materials Science and Engineering, Korea Aerospace University)
  • Received : 2019.06.18
  • Accepted : 2019.08.20
  • Published : 2019.10.25

Abstract

Visibility of road-surface markings is one of the critical issues that should be secured for self-driving cars as well as human drivers. Glass beads are taking on the role of retroreflectors, and therefore are considered a necessity in modern pavements. In this context, retroreflectance is sensitively dependent not only on the refractive index of glass beads but also on that of the surrounding medium. This implies that the optimum refractive index of glass beads immersed in water, i.e. under wet conditions, is different from that of glass beads surrounded by air, i.e. under dry conditions. A refractive index of approximately 1.9, which is known to maximize retroreflectance under dry conditions, actually exhibits much poorer retroreflectance under wet conditions. This suggests that glass beads with optimal refractive index for wet conditions need to be installed together with those for dry conditions. We propose a facile but practical model capable of calculating retroreflectance of glass beads surrounded by an arbitrary medium, here water in particular, and experimentally verify its capability of assessing the refractive index of commercial glass beads. Changes in retroreflectance according to the mixing ratio of glass beads with different refractive indices are also discussed, in an effort to propose the proper use of glass beads produced for dry and wet conditions.

Keywords

References

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