Critical stress evaluation of rigid pavement due to the presence of water in expansive soil subgrade

Q3 Engineering
W. Wibowo, A. Setyawan, Y. Purwana, B. Setiawan
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Abstract

The use of various types of rigid pavement is widespread because of its superiority in resisting heavy load vehicles. However, traffic loading complexity and subgrade response cause uncertainty during the design process. The presence of water in expansive soil issue swelling affected the flexural behavior of a rigid pavement slab. Rigid pavement relies heavily on the support and stability of the subgrade. Plain concrete is very weak in resisting tensile stresses so that the failure of rigid pavement slab structures often occurs in the expansive subgrade zone. Therefore, this study aims to numerically analyze the relationship between variations in the thickness of rigid pavement slabs on the flexural behavior parameters, such as critical and tensile stresses that affected water in expansive soil. The concrete’s performance limit was determined, using its material’s constitutive equation curve, and the data were analyzed using the finite element method. The results showed that the presence of water in expansive soil caused a change in soil volume (swelling), a reduction in soil bearing capacity (shrinking), and consequently, a rigid pavement cracked due to water variations in the subgrade. Generally, increasing the thickness of rigid pavement is a common method for mitigating the detrimental effects of expansive soil swelling. It is possible to provide reinforcement in other forms, which provide an opportunity to improve the performance of the concrete slab as a rigid pavement. For example, stabilization of expansive soil with materials capable of reducing its expansive power can be done but it requires large resources to realize it. Another method is to provide reinforcement to the rigid pavement slab structure, so that the rigid pavement slab is able to withstand traffic loads and also the expansion and shrinkage behavior of the expansive soil
膨胀土路基含水刚性路面临界应力评价
各种类型的刚性路面因其在抗重载车辆方面的优越性而得到广泛的应用。然而,交通荷载的复杂性和路基的响应导致了设计过程中的不确定性。膨胀土中水的存在影响了刚性路面板的受弯性能。刚性路面在很大程度上依赖于路基的支撑和稳定性。素混凝土抗拉应力能力很弱,在膨胀路基区经常发生刚性路面板结构的破坏。因此,本研究旨在数值分析刚性铺装板厚度变化与影响膨胀土含水量的临界应力和拉应力等弯曲行为参数之间的关系。利用混凝土材料的本构方程曲线确定了混凝土的性能极限,并用有限元法对数据进行了分析。结果表明,膨胀土中存在水分会引起土体体积的变化(膨胀),土体承载能力的降低(收缩),从而导致路基中水分的变化导致刚性路面开裂。一般来说,增加刚性路面的厚度是减轻膨胀土膨胀不利影响的常用方法。提供其他形式的加固是可能的,这为改善混凝土板作为刚性路面的性能提供了机会。例如,用能够降低膨胀土膨胀力的材料来稳定膨胀土是可以做到的,但需要大量的资源来实现。另一种方法是对刚性铺装板结构进行加固,使刚性铺装板既能承受交通荷载,又能承受膨胀土的胀缩特性
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来源期刊
EUREKA: Physics and Engineering
EUREKA: Physics and Engineering Engineering-Engineering (all)
CiteScore
1.90
自引率
0.00%
发文量
78
审稿时长
12 weeks
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