MODIFICATION OF HRS-WC ASPHALT CONCRETE MIXING USING ANTI STRIPPING AGENT

Authors

  • Rikki Sofyan Rizal Politeknik Negeri Jakarta
  • Anni Susilowati Politeknik Negeri Jakarta
  • Eko Wiyono Politeknik Negeri Jakarta

DOI:

https://doi.org/10.33197/jitter.vol9.iss1.2022.937

Keywords:

HRS-WC, anti stripping, marshall

Abstract

In road development, the main challenge is the pavement, especially asphalt concrete which breaks down quickly. The type of damage that is commonly found in Indonesia is premature surface damage, the visible symptoms of which are surface peeling, surface rutting, grain release and cracks. This typical damage for asphalt concrete pavement layers, is usually caused by low asphalt adhesion, this is marked by the release of grains due to no longer cohesion by asphalt which eventually gives water the opportunity to penetrate and destroy the asphalt concrete matrix. As a result, the mixture becomes loose and there is a lot of asphalt peeling on the surface layer. Based on this background, it is necessary to study the modification of the gap graded asphalt concrete mixture for Lataston HRS-WC by using anti-stripping materials. The purpose of conducting this research is to obtain the effect of anti-stripping materials in the gap graded asphalt concrete mixture on the properties of the Marshall test results in accordance with the 2018 Highways specifications. From the results of the tests carried out, the Optimum Asphalt Content (KAO) is 7.4%. With the KAO value, a test sample was made with the addition of Wetfix Be with a concentration of 0.2; 0.3 ; 0.4 and 0.5. The results obtained with the addition of Wetfix Be 0.30% increased the stability value to 1423.12 kg and Mashall quotient to 400.88 kg/mm. A high Marshall Quotent value indicates the mixture is stiff and has low flexibility.

Downloads

Download data is not yet available.

Published

2022-12-15

How to Cite

[1]
Rikki Sofyan Rizal, A. Susilowati, and E. Wiyono, “MODIFICATION OF HRS-WC ASPHALT CONCRETE MIXING USING ANTI STRIPPING AGENT”, JITTER, vol. 9, no. 1, Dec. 2022.

Issue

Section

Articles

Most read articles by the same author(s)