Diaphragm wall construction method

The diaphragm wall construction method is a core construction technique for deep, watertight excavation pits, basements, and transportation structures in constrained urban environments. It combines geotechnical stability, groundwater protection, and high dimensional accuracy. In practice, the construction and subsequent processing of diaphragm walls often intersect with tasks from concrete demolition and special demolition: wall heads are trimmed, obstacles in the trench are resolved, reinforcement is locally exposed, or openings are created with precision. Depending on boundary conditions, low-noise and low-vibration tools such as concrete pulverizers or hydraulic rock and concrete splitters are used, frequently powered by compact hydraulic power packs from Darda GmbH. This creates clean interfaces between special foundation engineering and controlled demolition, building gutting and cutting, as well as rock excavation at the transition to the in-situ rock.

Definition: What is meant by diaphragm wall construction method

The diaphragm wall construction method refers to the sectional construction of a continuous, structurally effective and usually watertight reinforced-concrete wall (diaphragm wall) in the ground. A trench is excavated to final depth with a trench grab or a diaphragm wall cutter under support fluid (bentonite or polymer slurry). The cleaned trench, reinforcement cages and embedded components are then prepared, and the concrete is placed via tremie pipes (tremie concreting). The wall performs enclosure, sealing, and load transfer functions. Diaphragm walls are constructed in panels (diaphragm wall panels) and connected through joints with sealing profiles or inserts.

Manufacturing sequence and key process steps

Production follows a standardized, quality-assured sequence. Essential steps are:

1. Setup and guide walls: Alignment and elevation control using guide walls; they guide the grab/cutter and confine the upper trench zone.
2. Excavation under support fluid: Trench grab or cutter loosens the soil; the slurry hydraulically stabilizes the trench walls.
3. Cleaning and end-profile control: Sediment is removed, the final profile is checked; slurry properties are monitored.
4. Lowering the reinforcement: Reinforcement cages with spacers and embedded items (e.g., sealing profiles) are positioned.
5. Concreting by tremie method: Concrete is placed via tremie pipes; the support fluid is displaced and recovered.
6. Joint and connection: Adjacent panels interlock via joint solutions; watertightness and structural composite are ensured.
7. Wall head trimming: After excavation of the pit, the wall head is trimmed to the target elevation; connection with bracing or slabs follows.

Geotechnical basics

Stability during excavation is ensured by the density and viscosity of the support fluid. The load-bearing and sealing functions of the diaphragm wall are based on embedment in competent and, where applicable, low-permeability soil layers; where rock is encountered or layers are irregular, the toe design requires particular attention. When the diaphragm wall cutter or grab encounters boulders, old foundation elements, or rock spurs, low-vibration hydraulic splitters for stone and concrete can be used locally to loosen or precondition the material, preserving the trench geometry and protecting adjacent structures.

Equipment, tools, and interfaces to demolition

The core process uses special foundation equipment such as grabs, cutters, mixing and recycling systems for slurry, and lifting gear. At the interfaces to demolition and adjustment work, tools and units from Darda GmbH come into play. They provide support wherever precise, low-vibration, and controlled interventions are required, for example near sensitive existing buildings or at connections.

• Concrete pulverizers: For targeted trimming of the wall head, breaking guide walls after completion, or creating openings in diaphragm walls. The pulverizers enable defined edges and protect the surrounding element.
• Hydraulic splitters (for stone and concrete): For loosening hard obstacles in the trench (boulders, old concrete) and for low-vibration deconstruction of head areas or capping beams, particularly under strict emission requirements.
• Hydraulic power packs: Compact units for powering the tools, flexibly positionable within the site layout and suitable for operations with limited access.
• Combination shears and Multi Cutters: For mixed tasks involving cutting and breaking, for example when locally exposing anchor heads, frame webs, or for detailed work on joint areas.
• Steel shears: For cutting reinforcement during wall head trimming or when creating openings, where rebar projections must be shortened in a controlled manner.
• Rock wedge splitters: For pinpoint splitting of natural stone or highly overconsolidated soils at the trench toe without inducing vibrations in adjacent structures.
• Tank cutters: In brownfield projects, when old tanks or steel bodies are uncovered along the alignment and must be dismantled in a controlled way before the diaphragm wall is constructed or extended.

Planning, design, and quality assurance

The planning phase includes ground investigation, hydraulic verifications, dimensioning of wall thickness, panel width and embedment depth, as well as defining the construction sequence. Design accounts for deformation requirements, water pressure, temporary stages with bracing or tie-back anchoring, and subsequent service loads. Quality assurance starts with slurry management (density, viscosity, sand content), continues with trench control (verticality, depth, cleanliness), and includes concreting and delivery documentation.

Joints, watertightness, and detail points

Diaphragm wall panels are connected via joint solutions. Sealing profiles, swelling tapes, or special joint pipes ensure watertightness. After the excavation phase, the wall head is systematically cut down to the target elevation. Here, concrete pulverizers prove their worth for precise wall head trimming; reinforcement is shortened with steel shears. In areas with existing buildings, hydraulic splitters for stone and concrete offer an option to keep vibrations low, for example when removing guide walls or capping elements.

Rework, wall head trimming, and openings

After the excavation pit reaches final depth, trimming and finishing works follow:

• Removal of guide walls and wall head down to the specified connection elevation.
• Creation of openings for utilities, shafts, or doors during structural work.
• Exposing anchoring zones, recesses for bracing, or local adaptations to existing structures.

For these tasks—depending on geometry, reinforcement density, and surrounding conditions—concrete pulverizers, combination shears, and steel shears are suitable. Where vibrations must be avoided, hydraulic splitters or rock wedge splitters provide a controlled alternative. Hydraulic power packs from Darda GmbH ensure reliable power supply, even in areas with restricted accessibility.

Applications: excavation pits, basements, and tunnels

Diaphragm walls serve as excavation pit enclosures for high-rise basements, underground garages, subway stations, and underpasses. In cut-and-cover tunneling, they secure the excavation pit and can be used as permanent exterior walls. In port or hydraulic engineering, diaphragm walls perform sealing and retaining functions. Transitions to rock excavation and tunnel construction arise when the diaphragm wall must be embedded in rock or portal areas are constructed in mixed ground. In such cases, pre-deploying hydraulic splitters for stone and concrete can produce the final contour in the rock with minimal material stress. When deconstructing temporary components and during building gutting of adjacent structures, concrete pulverizers, combination shears, and Multi Cutters are used. In special operations—such as in contaminated or highly constrained existing areas—precise, low-emission methods are particularly in demand.

Occupational safety, environment, and emissions

In diaphragm wall construction, safe construction logistics, proper handling of support fluids, and emissions control take priority. Noise and vibration protection are crucial in dense urban settings. Tools such as concrete pulverizers and hydraulic splitters for stone and concrete support low-vibration processing, reducing settlement risks and protecting sensitive neighboring buildings. Handling of slurry, spoil, and washouts requires regulated procedures for treatment and disposal. Notes in this text are of a general nature and do not replace project-specific planning or legal advice.

Typical challenges and practical solutions

Challenges include heterogeneous layers, subsurface obstacles, groundwater inflows, tight verticality tolerances, and difficult connection points to existing structures. Proven practical solutions are:

• Pre-investigation and trial slotting to identify obstacles; if necessary, local splitting of boulders.
• Consistent slurry control and cleaning prior to concreting to avoid voids and honeycombing.
• Precise wall head trimming with concrete pulverizers followed by cutting reinforcement with steel shears to produce connection faces.
• Use of combination shears/Multi Cutters for complex details where concrete and steel must be processed simultaneously.
• Low-vibration methods in sensitive locations, for example splitting technique instead of impact tools, to limit immissions.