Abstract

Negative vacuum pressure hardly reaches deep soils due to the drain board bending and serious blockage with the existing vacuum preloading methods (VPMs), thus resulting in poor reinforcement relative to practical engineering applications. To address this issue, this paper proposes a vacuum preloading method with pumping and discharging (a new dredger filling foundation processing technique based on vacuum preloading). This new VPM is developed through technological improvement and plastic drain board innovations in traditional VPMs. The new VPM uses a plastic vertical drainage board with double drainage channels, and the core board is in a “tic‐tac‐toe” shape with a hollow centre and square pipeline channels. It can execute air and water drainage. Vacuum transfer holes were set at two grooves, every 2‐3 m from the central pipeline of the core board. Grooves at two sides of the core board and filter membrane were rolled together to improve drainage. In addition, the vacuum pipe, tube connector, and core board centre of the vertical plastic drainage board were connected directly and securely. A stereoscopic vacuum transmission system composed of a horizontal and vertical drainage system was built. In this vacuum transmission system, the transfer route was shortened, and the loss of vacuum along the route was decreased. The negative vacuum pressure was transferred to different soil depths through the central pipeline of the core board to accelerate the dissipation of pore pressure in soil mass and prevent vacuum pressure loss caused by drainage board bending, thus improving the reinforcement effect. Dredger filling silt foundation reinforcement by VPM and VPM with pumping and drainage were compared in laboratory simulations and field tests with different drainage boards. Test results show that the loss of vacuum pressure along the drainage path was relatively smaller in the new physical vapor deposition (PVD), and the pressure transfer efficiency was increased. Deep soil mass was reinforced effectively by using the new PVD. After reinforcement, the physical and mechanical properties of soil layers were improved. Moreover, soil strengths were remarkably improved, with sharp reductions in natural moisture content and porosity. Then, the transfer law of vacuum on different drainage boards and the reinforcement mechanism of VPM with pumping and drainage were analysed. Research conclusions show the superiority of VPM with pumping and drainage in terms of effectiveness and soft foundation reinforcement. This study provides a theoretical basis for the application and development of the new VPM.

Highlights

  • Sludge soils from seas, rivers, and lake beds are often used as dredger filling materials in reclamation projects in coastal and offshore areas in China

  • E vacuum pressure in the common plastic vacuum drainage (PVD) stabilized after 50 h, but in the new PVD, it stabilized after 10 h, which indicates that the loss of vacuum pressure along the drainage

  • In the new Vacuum preloading methods (VPMs), the PVC pipe was connected with the vacuum pump, which was subsequently connected to the central channel of the new PVD’s core board

Read more

Summary

Introduction

Sludge soils from seas, rivers, and lake beds are often used as dredger filling materials in reclamation projects in coastal and offshore areas in China. A plastic drainage board (Figure 1) is inserted into the soft foundation as a vertical drainage channel to transfer vacuum pressure to the soil; pore water is drained under the negative pressure difference between soil. E vacuum pressure was directly transferred along the pipeline in the centre of the PVD to different soil layer depths through vacuum transfer holes. In this manner, the vacuum transfer path was shortened, the vacuum degree loss was decreased, and pore pressure dissipation was accelerated. The vacuum pressure can still be transferred to deep soil layers through the central channel of the PVD after the external grooves have been blocked, increasing the utilization of vacuum pressure

Model Test
Test Results
Field Test
Analysis and Discussion
Conclusion

Talk to us

Join us for a 30 min session where you can share your feedback and ask us any queries you have

Schedule a call

Disclaimer: All third-party content on this website/platform is and will remain the property of their respective owners and is provided on "as is" basis without any warranties, express or implied. Use of third-party content does not indicate any affiliation, sponsorship with or endorsement by them. Any references to third-party content is to identify the corresponding services and shall be considered fair use under The CopyrightLaw.