STUDY ON SOIL STABILIZATION WITH CEMENT AND ADDITIVES AS BASE LAYER FOR ROAD PAVEMENT (CASE STUDY : SOIL FROM NUSANTARA CAPITAL CITY AREA)
The massive construction of the Nusantara Capital City (IKN) has led to a significant increase in the demand for aggregates. To ensure the continuous development of IKN, aggregates are being supplied from outside the island, which increases construction costs, including road construction costs. T...
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| Format: | Theses |
| Language: | Indonesia |
| Online Access: | https://digilib.itb.ac.id/gdl/view/81072 |
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| Institution: | Institut Teknologi Bandung |
| Language: | Indonesia |
| Summary: | The massive construction of the Nusantara Capital City (IKN) has led to a
significant increase in the demand for aggregates. To ensure the continuous
development of IKN, aggregates are being supplied from outside the island, which
increases construction costs, including road construction costs. To reduce
aggregate demand and construction costs, one potential solution is to use
alternative base layer materials such as soil cement base (SCB). Local soil
materials have good bearing capacity and are widely available, making SCB a
viable option for road pavement. A mixture of soil and cement alone may not always
provide the necessary properties for a base layer for road pavement. Adding
additives to the soil-cement mixture can improve its properties to meet the
requirements for a base layer. This research aims to study the stabilization of soil
from the Nusantara Capital City with cement and additives for use as a base layer
for road pavement.
Soil samples from the Nusantara Capital City are dark brown coarse-grained soils
dominated by the sand fraction (75.92%). They are classified as SM (Silty Sand)
with a fine content of less than 50% (23.30%), low acidity (pH 6.32), low sulfate
content (0.007356%), and free of organic matter. These properties make the soil
suitable for use as a soil-cement mixture. The mixture was designed using 13-15%
cement and 1-3% additives. Unconfined Compressive Strength (UCS) and Wetting-
Drying tests were conducted on all variations of the soil-cement mixture, both with
and without additives. The test results were used to evaluate the strength and
durability of all mixture variations according to the technical requirements for a
base layer. Pavement structure and construction cost analysis were performed to
evaluate the construction cost per vehicle axle to obtain an economical mixture.
Based on the strength analysis, all variations of the mixture, both soil-cement
mixtures (13-15%) without additives and with additives (1-3%), showed 7-day
compressive strength values higher than the target compressive strength value
(2400 kPa). This indicates that they meet the strength requirements for a base layer
for road pavement. At curing ages of 3 and 7 days, the soil-cement mixture without
additives had higher compressive strength than the soil-cement mixture with
additives. However, at 28 days of curing, the soil-cement mixture with additives had higher compressive strength than the soil-cement mixture without additives.
The soil-cement mixture with 1%, 2%, and 3% additives showed 9.6%, 6.7%, and
12.9% higher 28-day compressive strength, respectively, compared to the soilcement
mixture without additives.
Based on the durability analysis, the soil-cement mixture without additives showed
high weight loss, indicating that it does not meet the durability requirements for a
base layer for road pavement. The soil-cement mixture without additives had low
resistance to wet-dry cycles, with the highest weight loss of 15.90% at a cement
content of 13% and the lowest of 13.74% at a cement content of 15%. On the other
hand, the soil-cement mixture with additives showed a weight loss of around 7%,
meeting the durability requirements for a base layer for road pavement. The soilcement
mixture with 1%, 2%, and 3% additives showed 55%, 46%, and 57% lower
weight loss, respectively, compared to the soil-cement mixture without additives.
The minimum cement content that resulted in a target compressive strength of more
than 2400 kPa was 13%. The minimum additive content that resulted in a weight
loss of less than 7% was 1%. Therefore, the optimum cement content and optimum
additive content were 13% and 1%, respectively.
Based on the cost analysis per vehicle axle, the mixture of 13% cement and 1%
additive was the optimum mixture as it resulted in the lowest cost per axle, which
was 0.033 Rp/m2/ESA. This mixture provides the best combination of low cost and
adequate performance. The use of a 13% cement and 1% additive soil mixture as a
base layer for road pavement can save up to 53.4% of the road construction cost
compared to pavements using granular base layers.
Soil-cement base (SCB) can serve as a viable alternative to granular base layers
in road pavements. SCB offers several advantages, including lower cost, increased
strength, and enhanced durability, which can reduce aggregate requirements and
construction costs. The implementation of SCB in road pavements can promote
more economical construction and lead to lower maintenance costs. This aligns
with the goal of sustainable development for the Nusantara Capital City. |
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