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Moving particle simulation-aided soil plasticity analysis for earth pressure balance shield tunnelling [ScienceDaily]

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Understanding the relationship between plasticity of muddy soil and earth pressure can be crucial to maintaining tunnel stability and predicting ground behavior during earth pressure balance (EPB) shield tunnelling, a common underground excavation method. Researchers from Shibaura Institute of Technology developed small-scale model experimentation combined with moving particle simulation-based computer-aided engineering analysis that reliably predicted soil’s plasticity and its correlating factors without having to deal with the cost and time of on-ground field analysis.

Infrastructures often suffer severe damage due to geotechnical hazards of both natural kinds such as floods or earthquakes and human-made ones like underground construction work and excavations. The fields of civil engineering and disaster risk management have extensively studied methods to prevent these risks and are still looking for more effective ways of avoiding large-scale deformations associated with said hazards. The advent of computer-aided simulations has provided researchers with particle-based methods such as moving particle simulation (MPS) which is a valuable tool for independent deformation analysis even in larger regions. While the method has gained popularity over the last few years, they are yet to be applied for predicting ground behavior during design or construction work.

By bringing together small-scale model experimentation and a computer-aided engineering (CAE) analysis through MPS a team of researchers from Shibaura Institute of Technology led by Professor Shinya Inazumi from the College of Engineering investigated a few mysteries around earth pressure balance (EPB) shield tunnelling in their recent study published in Tunnelling and Underground Space Technology on 21 August 2024.

EPB is a widely used method for creating tunnels that utilize the excavated muddy soil to provide support for the tunnel face which is done by using foam, slurry, or other additives to plasticize the excavated material to ensure it is impermeable to water and easily transportable.

The team recognized that despite being a popular technique not much is known about how the plasticity of muddy soil adjusted by mixing excavated soil with plasticizing additives like bentonite solution affects the earth pressure inside a tunnelling chamber. Insights into these factors can not only significantly increase the chances of avoiding ground deformations but also ensure efficient sediment management during the tunnelling process.

“Urban centres are increasingly getting reliant on underground infrastructures therefore we wanted a prediction tool that can improve the resilience of urban infrastructure while lowering the costs associated with delays and structural damage due to unstable tunnel operations by ensuring efficient management of soil plasticity,” Prof. Inazumi adds, explaining the motivation behind this study. He also highlighted that since the research lab associated with the study aligns itself with the UN’s sustainable development goals, they also explored the environmental footprint arising from large volumes of excavated material and the use of chemical additives such as bentonite in search of ways to improve the sustainability of construction projects.

The experimental setup consisted of a sealable soil tank simulating a chamber and descending and ascending stages of an agitation blade model that was performed by installing a twin-pair earth pressure gauge in a shield tunnelling machine. This system along with the calculations by a computer-aided analysis system based on a moving particle simulation (MPS) was able to precisely simulate the tunnelling process which included measuring the variations in earth pressure in response to plasticity variation induced by the agitation of muddy soil.

The researchers found earth pressure a trustworthy reliable indicator for analyzing soil’s plasticity and correlating factors such as vane shear strength and slump value which together impact the stability of the tunnel and the operation of machinery. Backed by MPS, the CAE analysis system proposed by the team precisely reflects the experimental data, confirming its suitability for assessing and visualizing the plasticity and fluidity of muddy soil during tunnelling.

Evaluating the value of earth pressure in actual field conditions by analyzing the plasticity state of the muddy soil in different soil conditions can be both time-consuming and an expensive affair. The small-scale model experiment when combined with the computation power demonstrated in this study can be a valuable asset for optimizing EPB shield tunnelling operations and improving sediment management strategies. Thus, opening new possibilities for innovating strategies that can significantly improve the safety and efficiency of underground civil construction works especially in the urban environments.

“The results of this study can directly influence the construction of subway systems, underground utilities, and roads in densely populated urban areas by enabling controlled operations that cause less disturbance to the surrounding ground. We also hope that our proposed strategy is applied to optimize the environmental impact of the tunnelling process and improve safety protocols in areas prone to earthquakes or other geotechnical hazards,” concludes Prof. Inazumi.



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