Performance evaluation of dense-graded asphalt mixture for high-strength application
Sustaining an efficient transportation system in Singapore for a large population in a limited land area is a challenge. Cost-effective road construction is vital due to budget constraints. Road pavements typically comprise granite aggregates and pen 60/70 grade binders in Singapore. Hence, to o...
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| Format: | Final Year Project |
| Language: | English |
| Published: |
Nanyang Technological University
2023
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| Online Access: | https://hdl.handle.net/10356/172681 |
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| Institution: | Nanyang Technological University |
| Language: | English |
| Summary: | Sustaining an efficient transportation system in Singapore for a large population in a limited land area is a
challenge. Cost-effective road construction is vital due to budget constraints. Road pavements typically
comprise granite aggregates and pen 60/70 grade binders in Singapore. Hence, to optimize road
construction, it is essential to understand how aggregate gradation affects mechanical performance in high-strength applications.
In this study, PG-76 binder and granite aggregates were utilized in the creation of specimens for dense-graded Hot Mix Asphalt (HMA), aligning with the Land Transport Authority's (LTA) design mixes of
W3B, W3, and W1. PG 76 binder, a polymer-modified bitumen known for its higher viscosity and
suitability in high-stress environments, was selected for its commendable performance in Singapore's
variable climate. The study established the Optimum Binder Content (OBC) by evaluating various criteria
through four laboratory test: Marshall test, Creep Resistance, Moisture susceptibility, and Indirect Tensile
Strength test. Additionally, aggregates were classified according to the three gradations stipulated by LTA.
Given the limited research on performance distinctions within the three design mixes for wearing courses,
this research explores how aggregate gradation influences the mechanical properties of high-strength
wearing courses.
Following laboratory testing, optimal binder content (OBC) values of 4.5%, 5.5%, and 5.5% were
determined for W3B, W3, and W1, respectively. The findings indicate that W3B is the most promising
design mix, meeting the required stability standards, displaying excellent resistance to moisture-induced
damage, and exhibiting superior performance in resisting cracking and permanent deformation. In contrast,
W3 and W1 mixes encountered challenges related to flow and stiffness. Overall, W3B stands out as the
optimal choice for high-strength applications in road pavements among the three mixes. |
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