Diaphragm Wall Construction: Procedure And Equipment

By Author: Kalpesh
Total Articles: 5
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1. Introduction to Diaphragm Walls
A diaphragm wall is a reinforced concrete wall constructed in situ, usually using a slurry-supported trench excavation method. With typical thicknesses ranging from 600 mm to 1500 mm and depths reaching 20 m to over 60 m, diaphragm walls offer high rigidity and minimal deformation under earth pressure. Since they are constructed before excavation, diaphragm walls act as permanent structural elements, reducing the need for temporary systems and enhancing long-term performance.

The process involves trench excavation supported by bentonite or polymer slurry, placing reinforcement cages into the trench, and concreting using tremie methods. This sequence ensures continuous, stable, and high-quality wall panels capable of withstanding substantial vertical and lateral loads.

2. Applications of Diaphragm Walls
Diaphragm walls are widely used in situations where deep excavation is necessary and soil conditions demand robust support. Key applications include:

Deep basements for commercial towers and residential buildings
In densely populated urban areas, land constraints ...
... require structures to extend downward. Diaphragm walls serve both as temporary excavation support and permanent basement walls.
Metro rail stations and tunnels
Modern metro systems rely heavily on diaphragm walls to form the side walls for cut-and-cover stations and shafts for tunnel boring machines (TBMs).
Underpasses, flyover ramps, and subways
Diaphragm walls provide stable and watertight enclosures for underpasses or road tunnels built below existing infrastructure.
Hydraulic structures
Their low permeability and strength make diaphragm walls suitable for dams, barrages, and flood protection systems.
Foundations in soft or saturated soils
In coastal or riverine areas, diaphragm walls act as vertical foundations where driven or bored piles are less effective.
These varied applications highlight the versatility and importance of diaphragm walls in modern civil engineering.

3. Advantages of Diaphragm Wall Construction
Diaphragm walls provide several critical advantages over other deep excavation support systems:

3.1 Structural Strength and Rigidity
The reinforced concrete panels deliver high stiffness, reducing lateral deformation during excavation. This is particularly beneficial when working adjacent to existing buildings or transportation networks.

3.2 Groundwater Control
The continuous and nearly impermeable wall prevents water ingress, eliminating the need for extensive dewatering systems in many projects.

3.3 Space Efficiency
Since the wall is constructed before excavation and forms a permanent structural element, the site footprint is minimized—an essential requirement in urban construction.

3.4 Deep Construction Capability
Diaphragm walls can be constructed to depths exceeding 60 meters, making them suitable for mega-projects such as deep basements and transport interchanges.

3.5 Reduced Noise and Vibration
Unlike driven piles or sheet piles, diaphragm wall construction produces minimal vibrations, making it ideal in sensitive or densely built environments.

3.6 Long-Term Durability
Diaphragm walls offer excellent durability against soil pressure, groundwater, and environmental effects, ensuring a long service life.

4. Components of a Diaphragm Wall
A typical diaphragm wall consists of:

Primary and Secondary Panels: Constructed in alternating sequences to maintain continuity and stability.
Reinforcement Cages: Fabricated to match panel dimensions and provide structural strength.
Guide Walls: Shallow concrete walls that guide excavation machinery and maintain alignment.
Slurry System: Usually bentonite or polymer slurry that supports trench walls during excavation.
Tremie Concrete: Ensures high-quality concreting from bottom to top, preventing segregation.
Each of these components contributes to the overall integrity and performance of the wall.

5. Construction Methodology
Diaphragm wall construction follows a systematic sequence to ensure precision and safety. The major steps are outlined below.

5.1 Site Preparation
Before construction begins, the site is cleared, utilities are relocated if necessary, and temporary access roads are built. Surveying and layout marking are performed to define panel boundaries and alignment. The slurry plant, reinforcement fabrication yard, and storage areas are also established.

5.2 Construction of Guide Walls
Guide walls are typically 1 m high and 0.2–0.3 m thick. They serve three purposes:

Guiding the trench cutter or grab
Providing a working platform
Retaining the slurry at ground level
Guide walls ensure accuracy and prevent collapse of the trench opening during excavation.

5.3 Trench Excavation
Excavation is carried out using:

Hydraulic grabs
Cable-operated grabs
Hydromill trench cutters (for hard soils or rocks)
As excavation progresses, slurry is continuously pumped into the trench to maintain stability. The slurry prevents soil collapse by exerting hydraulic pressure against the trench walls.

5.4 Slurry Circulation and Cleaning
The slurry used during excavation accumulates soil particles, which must be removed through desanders or desilters. Maintaining slurry properties—density, viscosity, and sand content—is critical to ensure wall stability and high-quality concrete.

5.5 Placement of Reinforcement Cage
Once the trench reaches the desired depth, prefabricated reinforcement cages are lowered into the slurry-filled trench using cranes. These cages are connected securely to ensure continuity between panels. Spacers are used to maintain the required concrete cover.

5.6 Concreting Using Tremie Method
Tremie pipes are inserted to the bottom of the trench, and concrete is poured continuously. As concrete flows in, it displaces the slurry upward without mixing. This bottom-up concreting ensures uniformity and prevents segregation or formation of voids.

The displaced slurry is collected, cleaned, and reused for subsequent panels.

5.7 Panel Sequencing
Panels are constructed in alternating sequence—usually primary panels first, followed by secondary panels. This ensures wall continuity, minimizes ground movement, and maintains trench stability. Joint formers or stop-end pipes are inserted at panel ends to create properly aligned joints.

5.8 Curing and Quality Control
After concreting, the panel is allowed to cure. Quality control tests such as slump tests, concrete cube tests, slurry density/viscosity tests, and verticality checks are conducted to ensure compliance with design requirements.

6. Quality Control in Diaphragm Wall Construction
Quality control is crucial for ensuring structural performance. Key elements include:

6.1 Verticality Checks
Verticality of the trench is verified using sonar or laser sensors during excavation. Deviations must be within allowable limits, typically 1% of wall depth.

6.2 Slurry Quality Monitoring
Before and after excavation, slurry properties must meet the specification for:

Density
Viscosity
pH
Sand content
Poor slurry quality can lead to trench collapse or poor concrete finish.

6.3 Concrete Quality Testing
Concrete must be workable, with high fluidity to allow smooth tremie operations. Standard tests include slump tests, cube compressive strength, and temperature monitoring.

6.4 Reinforcement Cage Inspection
Rebar spacing, cover blocks, and tied joints are inspected before lowering into the trench.

Consistent quality control minimizes defects such as honeycombing, segregation, or panel misalignment.

7. Challenges in Diaphragm Wall Construction
Despite its advantages, diaphragm wall construction faces several challenges:

7.1 Groundwater Pressure
High groundwater levels demand careful slurry management to prevent trench collapse.

7.2 Urban Constraints
Working in congested areas requires noise control, traffic management, and safety precautions for nearby structures.

7.3 Complex Soil Conditions
Hard strata, boulders, or mixed soil profiles can slow excavation or damage machinery.

7.4 Verticality and Alignment
Maintaining verticality in deep panels is difficult but essential for structural integrity.

7.5 Cost and Time
Diaphragm wall construction is more expensive and time-consuming than conventional shoring systems due to specialized equipment, skilled labor, and material requirements.

8. Conclusion
Diaphragm wall construction is a highly effective solution for deep excavation support and groundwater control in challenging engineering environments. Its strength, durability, and versatility make it indispensable for modern urban infrastructure such as metro systems, high-rise basements, tunnels, and underground facilities. While the process is complex and demands strict quality control, the resulting structure offers unmatched performance and long-term reliability.

Through precise execution—ranging from guide wall preparation to slurry management, trench excavation, reinforcement placement, and tremie concreting—a diaphragm wall provides a robust permanent solution that ensures structural safety and stability. As cities continue to grow vertically and underground, diaphragm wall technology will remain a cornerstone of advanced geotechnical engineering.