You are building a new subway line through a dense city center. The station excavation is 15 meters deep. The buildings on both sides are old and cannot move. The water table is high. You need a retaining wall that is strong, watertight, and can be installed without damaging adjacent structures.
Sheet pile retaining walls are widely used in subway excavation. They provide a continuous, interlocking barrier that holds back soil and water, allowing safe excavation. For deep subway stations, anchored walls with tiebacks or braced walls with internal struts are used. Press-in piling minimizes vibration for sensitive urban sites.
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I have supplied sheet piles for subway projects across Southeast Asia and the Middle East. A metro project in Singapore used press-in sheet piles next to a historic mosque. A subway project in Dubai used braced sheet piles for a 15-meter deep station. Let me walk you through how sheet pile retaining walls1 work in subway excavation.
Can sheet piles be used as a retaining wall?
Yes, sheet piles are commonly used as retaining walls for subway excavations, basements, and waterfront structures. They are one of the most common retaining wall systems1 in construction.
Sheet piles are ideal for retaining walls because they are strong, watertight, and can be installed quickly. The interlocking design creates a continuous barrier that holds back soil and water. For subway excavations, sheet piles are driven around the perimeter before digging begins. As excavation proceeds, bracing or tiebacks are installed to support the wall.
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Types of Retaining Walls for Subway Excavation
Let me explain the different types of retaining walls used in subway projects.
- Description: Interlocking steel sections driven into ground
- Advantages: Fast installation, watertight, reusable
- Depth range: Up to 20 m with bracing
- Best for: Urban sites, high water table
- Description: Interlocking concrete piles drilled in place
- Advantages: Very stiff, no vibration during installation
- Disadvantages: Slower, more expensive
- Best for: Very sensitive sites
- Description: Cast-in-place concrete walls
- Advantages: Very deep, very stiff
- Disadvantages: Expensive, slow
- Best for: Deepest excavations
Comparison for Subway Excavation
| Feature | Sheet Piles | Secant Piles | Slurry Walls4 |
|---|---|---|---|
| Installation speed | Fast | Moderate | Slow |
| Cost | Low to moderate | High | Very high |
| Water tightness | Good | Excellent | Excellent |
| Vibration | Low (vibratory) | None | None |
| Reusable | Yes | No | No |
My Experience
For a subway project in Southeast Asia, we used sheet pile retaining walls for the station excavation. The piles were driven with press-in equipment to minimize vibration. The wall held the soil and water perfectly, and the station was built on schedule.
What is sheet piling1 in excavation?
Sheet piling in excavation is the use of interlocking steel sheet piles to support the sides of an excavation, preventing soil collapse and water inflow.
Sheet piling in excavation involves driving steel sheet piles around the perimeter of the excavation before digging begins. The piles form a continuous wall that holds back the soil. As excavation proceeds, bracing (struts or tiebacks) is installed to support the wall. After the permanent structure is built, the piles may be extracted (temporary) or left in place (permanent).
[^1] in [excavation process](https://kv-build.com/7-components-of-the-excavation-process/)[^2] diagram](https://placehold.co/600x400 "Sheet Piling in Excavation")](https://cnsteelplant.com/wp-content/uploads/2026/03/Article-Application-City-3.webp)
Excavation Process with Sheet Piles
Let me walk you through the excavation process2 for a subway station.
Step 1: Sheet Pile Installation
- Drive sheet piles around the station perimeter
- Use vibratory or press-in hammers
- Drive to depth below final excavation
Step 2: First Excavation
- Excavate to first brace level (typically 2-3 m depth)
- Install walers and struts or tiebacks
Step 3: Second Excavation
- Excavate to second brace level
- Install additional bracing
Step 4: Continue to Final Depth
- Repeat until final excavation depth is reached
- Final brace level may be at or near the bottom
Step 5: Station Construction
- Build the subway station (slab, walls, roof)
- Remove bracing as permanent structure gains strength
Step 6: Pile Extraction (if temporary)
- Extract sheet piles using vibratory hammer
- Reuse on another project
Excavation Depth and Bracing
| Excavation Depth | Typical Bracing Levels |
|---|---|
| Up to 5 m | Cantilever (no bracing) or 1 level |
| 5-10 m | 1-2 levels |
| 10-15 m | 2-3 levels |
| 15-20 m | 3-4 levels |
My Experience
For a 15 m deep subway station, we used four levels of bracing. The first level was at 2 m depth, the second at 6 m, the third at 10 m, and the fourth at 13 m. The excavation proceeded in stages, with bracing installed before digging deeper.
What are the disadvantages of using sheet piles?
Sheet piles are excellent for subway excavation, but they have limitations that engineers must consider.
The main disadvantages of sheet piles for subway excavation are noise and vibration during installation (mitigated by press-in piling), potential for ground movement if not installed carefully, difficulty driving through cobbles or rock, and the need for bracing that can obstruct the excavation. In urban areas, noise restrictions may limit working hours.
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Addressing the Disadvantages
Let me discuss each disadvantage and how to mitigate it for subway projects.
- Disadvantage: Pile driving is loud and creates vibration
- Mitigation: Use press-in (silent piling) for sensitive areas
- Mitigation: Use vibratory hammers with noise blankets
- Mitigation: Work during permitted hours only
- Disadvantage: Pile driving can displace soil, causing settlement
- Mitigation: Use press-in piling (minimal ground movement)
- Mitigation: Pre-drilling to reduce displacement
- Mitigation: Monitor adjacent structures during installation
- Disadvantage: Cobbles, boulders, or rock make driving difficult
- Mitigation: Pre-drilling through hard layers
- Mitigation: Use impact hammers for hard driving
- Mitigation: Consider alternative wall types if rock is near surface
Bracing Obstructions
- Disadvantage: Internal struts block access inside excavation
- Mitigation: Use tiebacks instead of internal struts
- Mitigation: Design struts to allow equipment access
- Mitigation: Use rakers (diagonal braces) that take less space
- Disadvantage: Steel corrodes in groundwater
- Mitigation: Use corrosion allowance (extra thickness)
- Mitigation: Use marine grade steel for aggressive conditions
- Mitigation: Apply protective coatings
My Experience
For a subway project adjacent to a hospital, we used press-in piling to eliminate noise and vibration. The installation was silent, and the hospital experienced no disruption. The press-in method cost more, but it was essential for that site.
What is a pile retaining wall?
A pile retaining wall is a structure that holds back soil and water using vertical piles driven into the ground. Sheet piles are the most common type of pile retaining wall.
A pile retaining wall consists of vertical piles (steel sheet piles, concrete piles, or timber piles) that are driven into the ground to form a continuous or semi-continuous barrier. Sheet pile walls are the most common because the piles interlock to create a watertight barrier. Other types include soldier pile walls (piles with lagging between them) and secant pile walls (interlocking concrete piles).
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Types of Pile Retaining Walls
Let me compare the different types of pile retaining walls used in subway excavation.
- Piles: Interlocking steel sections
- Water tightness: Excellent (interlocks)
- Installation: Driven or pressed
- Best for: Urban sites, high water table
- Cost: Low to moderate
- Piles: Steel H-piles with timber or concrete lagging
- Water tightness: Poor (gaps between piles)
- Installation: Drilled or driven
- Best for: Dry sites, temporary excavations
- Cost: Low
- Piles: Interlocking concrete piles
- Water tightness: Excellent (interlocking)
- Installation: Drilled
- Best for: Very deep excavations, sensitive sites
- Cost: High
- Piles: Concrete piles with gaps between
- Water tightness: Poor
- Installation: Drilled
- Best for: Dry sites, temporary works
- Cost: Moderate
Comparison for Subway Excavation
| Wall Type | Water Tightness | Vibration | Cost | Best Depth |
|---|---|---|---|---|
| Sheet pile | Good | Low (press-in) | Low-moderate | Up to 20 m |
| Soldier pile | Poor | Low | Low | Up to 10 m |
| Secant pile | Excellent | None | High | Over 20 m |
My Experience
For most subway excavations, sheet pile walls are the best choice. They provide good water tightness, can be installed with low vibration using press-in methods, and are cost-effective. For the deepest stations (over 20 m) or extremely sensitive sites, secant piles may be used.
Conclusion
Sheet pile retaining walls1 are ideal for subway excavation. They are strong, watertight, and can be installed with minimal vibration using press-in methods. For deep stations, anchored or braced walls2 are used. Disadvantages include noise, vibration, and bracing obstructions, but these can be mitigated.
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Explore the advantages of sheet pile retaining walls, including their strength and watertight properties, essential for subway projects. ↩ ↩ ↩ ↩ ↩ ↩
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Learn about the specific applications of anchored or braced walls in deep station construction and their benefits. ↩ ↩ ↩ ↩ ↩
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Discover how Secant Pile Walls function and their advantages for deep excavations in sensitive areas. ↩ ↩ ↩
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Find out about Contiguous Pile Walls, their installation process, and when they are suitable for use. ↩ ↩ ↩ ↩
