Assessment of Infrastructures Assets Induced by Water Level Fluctuation along the Bengawan Solo River

Satrya, Trihanyndio Rendy; Soemitro, Ria Asih Aryani; Maulana, Mahendra Andiek; Warnana, Dwa Desa; Soetanto, Robby

doi:10.12962/jifam.v1i2.5973

Cited by 6 publications

(6 citation statements)

References 4 publications

Supporting

Mentioning

Contrasting

Order By: Relevance

“…where: Qult = ultimate bearing capacity Qs = friction piles Qp = end bearing piles Wp = weight of the pile Then, to obtain the allowable single pile capacity, it is determined using the following formula: Qa = Qult/SF … (11) where: Qa = bearing capacity of single pile SF = 2,5 -3 safety factor The frictional resistance or the skin friction resistance of a pile can be calculated using the formula:…”

Section: Bearing Capacity Of Pile On Vertical Forcesmentioning

confidence: 99%

“…The landslide is suspected to occur due to the contact between clay shale soil and water entering the road body through cracks on the surface, transforming the soil condition beneath the road body as if it were sandy. The Mechanism of water infiltration could decrease the strength of soil rapidly (Satrya et al, 2019). Clay shale soil is highly sensitive to weather changes or exposure to air and water.…”

Section: Introductionmentioning

confidence: 99%

See 1 more Smart Citation

Analysis of Existing Slope Reinforcement Design on Clay Shale Soil and Its Alternative Modifications: A Case Study of the Awunio – Lapuko Road Section Sta 4+955 – 5+015 in the Southeast Sulawesi Province

Azhari,

Khoiri,

Siagian

2024

Journal of Infrastructure &Amp; Facility Asset Management

View full text Add to dashboard Cite

On the Awunio -Lapuko road section, there was a landslide from STA 4+955 to STA 5+015, causing the roadside to collapse. The probable cause is water infiltration into the soil, affecting the clay shale properties. An analysis of the existing slope stability and its planning needs to be carried out. Water management planning and alternative reinforcement are necessary if the stability does not meet the requirements. Slope stability analysis is conducted on the existing slope and existing design using manual calculation methods and the GEO5 program. The stability considered includes shear stability, tilting, and overall stability.The analysis reveals that the existing slope stability is safe from landslides. However, this contradicts the field observations. Therefore, a crack soil approach is used in this study to assess the landslide conditions in the field, resulting in a safety factor (SF) of 0.95 for the road slope. The existing design, a 2.5 m high retaining wall with bored piles of 50 cm diameter and a depth of 8 m, yields slope stability with an SF of 7.91, indicating safety but being excessively costly. The water management system planning indicates that the drainage channel capacity can handle the water discharge from rainfall. Introducing subdrains improves the slope stability from SF 0.95 to 1.38, but additional reinforcement is still needed. An alternative design with a 2.5 m high retaining wall and bored piles of 40 cm diameter and 3 m depth yields a slope stability 3.29. Replacing the retaining wall structure with natural stone using bored piles of 30 cm diameter and 3 m depth results in an SF of 2.18. If an alternative subdrain with additional gabion reinforcement is implemented, the slope stability becomes 2.23. Additionally, an alternative design using geotextiles results in slope stability with an SF of 1.77. All alternative reinforcements are deemed safe and meet stability requirements

show abstract

Section: Bearing Capacity Of Pile On Vertical Forcesmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

Analysis of Existing Slope Reinforcement Design on Clay Shale Soil and Its Alternative Modifications: A Case Study of the Awunio – Lapuko Road Section Sta 4+955 – 5+015 in the Southeast Sulawesi Province

Azhari,

Khoiri,

Siagian

2024

Journal of Infrastructure &Amp; Facility Asset Management

View full text Add to dashboard Cite

show abstract

“…Measure of infrastructure stability is determined by safety factor which compares resistance and load (Satrya et al, 2019). Therefore, CW must be designed to remain safe against overturning stability, slip stability and soil bearing capacity.…”

Section: Cantilever Wall Reinforcementmentioning

confidence: 99%

Existing Design Analysis of Slope Reinforcement on Clayey Soil and Its modified Alternatives (Case Study : Awunio – Lapuko National Road, Southeast Sulawesi)

Khoiri,

Siagian

2024

Journal of Infrastructure &Amp; Facility Asset Management

View full text Add to dashboard Cite

The slopes of the Awunio -Lapuko national road section are prone to landslides, which pose a threat to the road asset management. Hard soil layer with an NSPT value >60 is found at a depth of 4 metres. The slope has been reinforced with cantilever walls (CW) and caisson as well as retaining walls and bored pile. In this research, the problem that needs to be studied is the stability of the existing slope with and without reinforcement using the cracked soils approach to obtain the factor of safety (FS) for critical conditions with the Limit Equilibrium Method (LEM). The CW is calculated for overturning stability, shear stability, foundation bearing capacity and overall stability. In addition, bored pile should also be evaluated when considered as a lateral pile based on NAVFAC, bearing capacity within the group, max & min stress and deflection capacity. The result of LEM program analysis shows the slope failure mechanism due to the existence of slip plane between weak soil layer and strong soil layer. Furthermore, the stability of existing reinforcement such as CW only or CW combined with caisson is insufficient. While the stability of reinforcement CW combined with bored pile or alternative modification such as subdrain combined with geotextile meets the requirements.

show abstract

“…During the design process, the stability of infrastructure is often assumed to be static and is considered by applying factors of safety generated by extreme condition analysis. Nevertheless, there has been a lack of consideration for the variability of natural factors, and notably, the growing risk posed by extreme environmental conditions resulting from global climate change (Satrya et al, 2019). At the construction of the serang-panimbang toll road, it is necessary to consider changes in soil characteristics in climate change in Indonesia.…”

Section: Introductionmentioning

confidence: 99%

Correlation of Initial Soil Density and Maximum Soil Density Under Drying-Wetting Cycles and Their Soil Erodibility

Evriana,

Satrya,

Maulana

et al. 2024

Journal of Infrastructure &Amp; Facility Asset Management

View full text Add to dashboard Cite

The Serang -Panimbang Toll Road plan area of Banten province in regional stratigraphy from the starting station to the end consists of sedimentary rock sediments of the Bojongmanik Formation in the form of sandstone intersections with clayey limestone inserts that have been precipitated by the products of Karang volcano consisting of breccia and lava. This volcanic material exhibits a coarse soil texture, high water absorption capacity, and susceptibility to erosion. Soil erosion levels can be determined by measuring soil erodibility. Erosion often occurs in Indonesia because Indonesia has a tropical climate which has two seasons, the rainy and dry seasons. This climatic pattern contributes to the soil vulnerability to erosion, impacting its density. Therefore, it is important to know the effect of drying-wetting cycle on erodibility along the slope of Serang-Panimbang Toll Road. Soil samples will be modeled under two density variations: initial density and maximum density. Drying-wetting tests will determine the physical, mechanical, suction, and erodibility properties of soil. The results showed that there was an increase in the degree of saturation of 8.31% for the initial density soil and 17.12% for the maximum density soil. Unconfined compressive strength of the soil with initial density and maximum density also decreased in consistency which decreased from very stiff and stiff to very soft. However, erodibility values for both density conditions remained constant at 0.19 despite the drying-wetting cycles and is classified as low.

show abstract

Assessment of Infrastructures Assets Induced by Water Level Fluctuation along the Bengawan Solo River

Cited by 6 publications

References 4 publications

Analysis of Existing Slope Reinforcement Design on Clay Shale Soil and Its Alternative Modifications: A Case Study of the Awunio – Lapuko Road Section Sta 4+955 – 5+015 in the Southeast Sulawesi Province

Analysis of Existing Slope Reinforcement Design on Clay Shale Soil and Its Alternative Modifications: A Case Study of the Awunio – Lapuko Road Section Sta 4+955 – 5+015 in the Southeast Sulawesi Province

Existing Design Analysis of Slope Reinforcement on Clayey Soil and Its modified Alternatives (Case Study : Awunio – Lapuko National Road, Southeast Sulawesi)

Correlation of Initial Soil Density and Maximum Soil Density Under Drying-Wetting Cycles and Their Soil Erodibility

Contact Info

Product

Resources

About