Ground improvement is a critical component of construction engineering, addressing challenging soil conditions such as miscellaneous fill, soft soil, collapsible loess, liquefiable sand, and expansive clay. Traditional methods often fall short in handling problematic soils with corrosive media, high groundwater levels, thick layers of construction waste, or rock-filled embankments, leading to cost overruns and safety risks.
Environmental concerns also arise from inorganic solid pollutants like soil, brick fragments, industrial waste, and construction debris, which contaminate waterways and urban/rural areas. Xi’an Great Wall Geotechnical Engineering Co., Ltd., under the leadership of Mr. Si Bingwen, has pioneered two groundbreaking solutions: Down-hole Dynamic Compaction (DDC) and Super Down-hole Dynamic Compaction (SDDC). These methods effectively resolve complex geotechnical issues while promoting sustainable practices.
DDC is a deep foundation treatment method involving:
Drilling: Creating a hole to the desired depth.
Layered Compaction: Filling and compacting materials from the bottom up using a high-energy hammer.
Composite Foundation: Forming dense columns and tightly compacted surrounding soil.
DDC is suitable for:
Fill soils (engineered/miscellaneous)
Sandy, silty, and clayey soils
Collapsible loess and soft clay
Non-corrosive, eco-friendly fillers include:
Soil, sand, gravel
Construction waste (e.g., crushed concrete, bricks)
Industrial byproducts (e.g., fly ash, slag)
High Energy Efficiency: Delivers 3–9x higher bearing capacity than natural soil.
Deep Treatment: Effective up to 30m depth (vs. 10m for conventional dynamic compaction).
Versatility: Accommodates diverse fillers, reducing material costs.
Eco-Friendly: Recycles waste materials, minimizing environmental impact.
Manual operation affects consistency.
Dependent on operator skill and site conditions.
Optimal Depth: ≤50m; target bearing capacity ≤600kPa.
Equipment: Uses 400mm drills to create 550mm diameter piles.
Automation: Emerging automated systems improve precision and reduce labor intensity.
SDDC builds on DDC with:
Higher Kinetic Energy: 15-ton hammer with 2000–2500 kN·m impact force.
Larger Piles: 1500–1800mm diameter, achieving 3000–3600 kN ultimate bearing capacity.
Double Compaction: Secondary soil densification for superior stability.
In Xi’an, SDDC combined with cast-in-situ piles to support 33-story buildings:
Challenge: 10–24m thick heterogeneous fill with debris.
Solution: SDDC pre-treated soil, eliminating negative skin friction and enhancing pile performance.
Result: All piles exceeded design load requirements (≥6600kN).
Cost-Effective: 30–50% savings vs. conventional piling.
Waste Utilization: Consumes construction debris and industrial waste.
Speed: Rapid hole formation with olive-shaped hammers.
Remote-Controlled Hammer: Automated release system improves safety and efficiency.
Noise/Vibration Control: Advanced dampening for urban projects.
Sustainability: Reduces landfill dependency and carbon footprint.
Social Value: Cleaner sites with no slurry pollution.
DDC and SDDC technologies revolutionize ground improvement by:
Resolving “unmanageable” soil conditions.
Cutting costs via waste reuse.
Supporting high-capacity foundations for skyscrapers, bridges, and industrial plants.
For projects in loess, liquefaction-prone, or contaminated sites, SDDC/DDC offers unmatched technical and economic advantages.
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