Effect of Water Film Thickness on skid Resistance of Tined Concrete Pavement

Seng, Chann; Kim, Young Kyu; Lee, Seung Woo

doi:10.34726/10621

DC Field

Value

Language

dc.contributor.author

Seng, Chann

dc.contributor.author

Kim, Young Kyu

dc.contributor.author

Lee, Seung Woo

dc.contributor.editor

Eberhardsteiner, Lukas

dc.contributor.editor

Hofko, Bernhard

dc.contributor.editor

Blab, Ronald

dc.date.accessioned

2025-09-12T07:12:30Z

dc.date.available

2025-09-12T07:12:30Z

dc.date.issued

2025

dc.identifier.citation

<div class="csl-bib-body"> <div class="csl-entry">Seng, C., Kim, Y. K., & Lee, S. W. (2025). Effect of Water Film Thickness on skid Resistance of Tined Concrete Pavement. In L. Eberhardsteiner, B. Hofko, & R. Blab (Eds.), <i>Advances in Materials and Pavement Performance Prediction IV : Contributions to the 4th International Conference on Advances in Materials and Pavement Performance Prediction (AM3P 2025), 7-9 May 2025, Vienna, Austria</i> (pp. 83–86). TU Wien, E230-03 Road Engineering. https://doi.org/10.34726/10621</div> </div>

dc.identifier.uri

http://hdl.handle.net/20.500.12708/219008

dc.identifier.uri

https://doi.org/10.34726/10621

dc.description.abstract

Wet pavement friction decreases with increased water film thickness (WFT), significantly raising the risk of vehicle crashes. The British Pendulum Test is used to measure wet pavement friction for design and management. The British Pendulum Number (BPN) in wet conditions varies with WFT. Following ASTM E303-93 standard procedures, WFT was simulated by spraying water on the pavement surface. However, the measurement of BPN did not include specific information about the thickness of the water film present during testing. To address these issues, WFTs and BPNs were measured using a rainfall simulator across various intensities, drainage lengths, slopes, and textures. This study examines WFT's impact on BPN for wet friction and determines WFT for each BPN on various surfaces. This study shows significant BPN decreases with increasing WFT for non-tined and 25mm tined surfaces, while 16mm tined surfaces decrease slightly. These insights improve friction values, enhancing road safety, better design, and reducing crash risks.

dc.language.iso

dc.relation.ispartofseries

Advances in Materials and Pavements Performance Prediction

dc.rights.uri

https://creativecommons.org/licenses/by/4.0/

dc.subject

Wet Pavement Friction

dc.subject

Water Film Thickness

dc.subject

Tined Concrete Pavement

dc.subject

British Pendulum Number

dc.subject

Pavement Geometry

dc.title

Effect of Water Film Thickness on skid Resistance of Tined Concrete Pavement

dc.type

Inproceedings

dc.type

Konferenzbeitrag

dc.rights.license

Creative Commons Attribution 4.0 International

dc.rights.license

Creative Commons Namensnennung 4.0 International

dc.identifier.doi

10.34726/10621

dc.contributor.affiliation

Gangneung–Wonju National University, Korea (the Republic of)

dc.contributor.affiliation

Gangneung–Wonju National University, Korea (the Republic of)

dc.contributor.affiliation

Gangneung–Wonju National University, Korea (the Republic of)

dc.relation.isbn

978-3-901912-99-3

dc.relation.doi

10.34726/9259

dc.description.startpage

dc.description.endpage

dc.rights.holder

TU Wien, E230-03 Road Engineering

dc.type.category

Full-Paper Contribution

tuw.booktitle

Advances in Materials and Pavement Performance Prediction IV : Contributions to the 4th International Conference on Advances in Materials and Pavement Performance Prediction (AM3P 2025), 7-9 May 2025, Vienna, Austria

tuw.container.volume

tuw.peerreviewed

true

tuw.book.ispartofseries

Advances in Materials and Pavements Performance Prediction

tuw.relation.publisher

TU Wien, E230-03 Road Engineering

tuw.relation.publisherplace

Wien

tuw.researchTopic.id

tuw.researchTopic.name

Surfaces and Interfaces

tuw.researchTopic.value

100

tuw.publication.orgunit

E000 - Technische Universität Wien

dc.identifier.libraryid

AC17637714

dc.description.numberOfPages

tuw.author.orcid

0009-0002-1208-4320

tuw.author.orcid

0000-0002-3459-9678

dc.rights.identifier

CC BY 4.0

dc.rights.identifier

CC BY 4.0

tuw.editor.orcid

0000-0003-2153-9315

tuw.editor.orcid

0000-0002-8329-8687

tuw.editor.orcid

0000-0003-4101-1964

tuw.event.name

Advances in Materials and Pavement Performance Prediction 2025 (AM3P 2025)

tuw.event.startdate

07-05-2025

tuw.event.enddate

09-05-2025

tuw.event.online

On Site

tuw.event.type

Event for scientific audience

tuw.event.place

Wien

tuw.event.country

tuw.event.institution

TU Wien/E230-03

tuw.event.presenter

Lee, Seung Woo

tuw.event.track

Multi Track

wb.sciencebranch

Bauingenieurwesen

wb.sciencebranch

Verkehrswesen

wb.sciencebranch.oefos

2011

wb.sciencebranch.oefos

2013

wb.sciencebranch.value

item.openaccessfulltext

Open Access

item.openairecristype

http://purl.org/coar/resource_type/c_5794

item.mimetype

application/pdf

item.fulltext

with Fulltext

item.cerifentitytype

Publications

item.grantfulltext

open

item.openairetype

conference paper

item.languageiso639-1

crisitem.author.dept

Gangneung–Wonju National University, Korea (the Republic of)

crisitem.author.dept

Gangneung–Wonju National University, Korea (the Republic of)

crisitem.author.dept

Gangneung–Wonju National University, Korea (the Republic of)

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