Analysis of concrete slab and ground settlement due to reach stacker and container load at Labuan Bajo Port Terminal

Analysis of concrete slab and ground settlement due to reach stacker and container load at Labuan Bajo Port Terminal

Authors

  • S Sihombing Department of Civil Engineering, Universitas Krisnadwipayana, Bekasi, Indonesia
  • A P Rodji Department of Civil Engineering, Universitas Krisnadwipayana, Bekasi, Indonesia
  • I Indriasari Department of Civil Engineering, Universitas Krisnadwipayana, Bekasi, Indonesia
  • Y P Rodji Department of Civil Engineering, Universitas Krisnadwipayana, Bekasi, Indonesia
  • G Pribadi Department of Civil Engineering, Universitas Krisnadwipayana, Bekasi, Indonesia
  • L Darmiyanti Department of Civil Engineering, Universitas Krisnadwipayana, Bekasi, Indonesia

Keywords:

Concrete slab settlement, reach stacker, container load, Labuan Bajo Port Terminal

Abstract

The container yard is one part of the dock terminal that stores containers. The busier a dock is linear the higher the need for a container yard. So good planning is needed with a long service life. Stackers and containers reach the influential loads in container yard concrete slab planning. The weight of the reach stalker which reaches 71.8 tons and the weight of the container reaches 6 tons /m2 is an important reason to analyze how thick the safe pavement is for these loads which continue to increase along with the increase in the busyness of a pier. This study analyzed the thickness of the concrete slab and the subsidence that occurred in a container yard of 1.36 Ha with a container area of 20 feet. The analysis was carried out with a concrete quality of 30Mpa and the calculation of soil subsidence was analyzed using a geogrid that helped maintain soil stability. The results of this study obtained a safe pavement thickness of 35cm with a safe decline following SNI 8460: 2017 standards regarding soil settlement.

References

Ayu, N. (2019). Perkerasan Rigid di Wilayah Container Distribution Center Pelabuhan Trisakti untuk Tipe Kontainer 20 feet dan Alat Berat Reach Stacker tipe Kalmar DRT450. Buletin Profesi Insinyur, 2(1), 1–6. https://doi.org/10.20527/bpi.v2i1.29

[2] Faulkner, D. W. S. (2010). Electrokinetics and Iron Precipitation for Ground Engineering and Metal Removal. 389. https://cris.brighton.ac.uk/ws/portalfiles/portal/4753158/Corrections1.pdf

[3] Henesey, L. (2005). A Simulation Model for Analysing Terminal Management Operations. Proceeding of the 4th International Conference on Computer Applications and Information Technology in the Maritime Industries (COMPIT’05), May, 8–11. http://www.ipd.bth.se/lhe/Compit05/COMPIT2005 Final.pdf

[4] Marcobal-Barranco, J. R., Lara-Galera, A. L., & Camarero-Orive, A. (2019). Functional assessment of port pavements: The case of container terminals. Journal of Testing and Evaluation, 49(3). https://doi.org/10.1520/JTE20180729

[5] Prabowo, W. A., Studi, P., & Profesi, P. (2021). Penggunaan Container Pad pada Container Yard Ex . Semen Tonasa di Wilayah Pelabuhan Trisakti untuk Tipe Kontainer 20 feet dan 40 feet. 10(1), 28–35.

[6] Rachardi, R. K. (2018). Analisis Tebal Perkerasan Jalan Rigid Di Kecamatan Sinar Peninjauan. Jurnal Deformasi, 3–2, 74–83.

Downloads

Published

2024-11-10

Conference Proceedings Volume

Vol. 1 (2024): The 5th BIS-STE 2023 in conjunction with The 1st INTERCONNECTS 2023

Section

Articles

License

Creative Commons License

This work is licensed under a Creative Commons Attribution-NonCommercial 4.0 International License.

How to Cite

Analysis of concrete slab and ground settlement due to reach stacker and container load at Labuan Bajo Port Terminal. (2024). Proceedings Series of Borobudur International Symposium on Energy and Engineering, 1, V124041. https://doi.org/10.31603/biseeng.51

Similar Articles

You may also start an advanced similarity search for this article.