Groundwater lowering

Groundwater lowering – also called dewatering – creates dry and stable work areas when excavations, shafts, tunnel headings, or deconstruction works take place below the groundwater level. It forms the interface between geotechnical engineering, environmental engineering, and work preparation. In practice, it touches numerous application areas of Darda GmbH: from concrete demolition and special demolition through building gutting and cutting to rock demolition and tunnel construction. Wherever components must be separated in a controlled manner after reducing pore water pressure, concrete demolition shear as well as stone and concrete splitters are used – with low vibration, precision, and a focus on neighborhood-compatible methods.

Definition: What is meant by groundwater lowering

Groundwater lowering encompasses all technical measures that temporarily or – more rarely – permanently reduce the groundwater level in a defined area. The goal is to control water inflows, decrease pore water pressure, and thus ensure the stability of excavations, foundations, or demolition fields. Typical methods include open dewatering, Wellpoint vacuum filters, dewatering wells with deep-well pumps, or ejector wells. The resulting drawdown forms a so-called cone of depression around the extraction points. Planning and operation are based on subsurface stratigraphy, permeability (kf-value), expected inflows, and the requirements for environmental and neighborhood protection.

Methods of groundwater lowering

The choice of method depends on soil type, permeability, required drawdown depth, space constraints, and environmental requirements. In complex situations, methods are combined, for example cut-off walls with wells or vacuum systems with localized open dewatering.

Open dewatering (sump pits)

Suitable for well-stable soils and small inflows. Water collects in excavation sumps and is pumped out. Advantages are simple setup and quick availability. Limits arise in fine-grained, erosion-prone soils and at greater drawdown depths, where scouring and base heave are a risk.

Vacuum wellpoint arrays (Wellpoint)

Rows of small, filter-equipped wellpoints are operated via a vacuum pump. Efficient in sandy to fine-sandy layers for drawdowns up to about 5–6 m. The vacuum reduces pore water pressure and stabilizes the excavation perimeter. Important factors include filter gravel, correct spacing, and uniform load distribution.

Dewatering wells with deep-well pumps

For greater drawdown depths and higher inflows. Wells are sunk into permeable strata; submersible motor pumps continuously abstract the water. Design is governed by the kf-value, thickness of permeable layers, required drawdown, and acceptable impacts on the surroundings.

Ejector wells

Operate with jet pumps and are suitable for fine sand and silt when conventional filter wells fail. They create local negative pressure and enable drawdowns even in less permeable soils, albeit with higher energy demand.

Cut-off walls and complementary measures

Sheet pile walls, cut-off walls, or ground freezing limit inflow and reduce the cone of depression. They are often combined with wells. This reduces impacts on neighboring foundations and can simplify water treatment.

Objectives and applications in construction and deconstruction

Groundwater lowering becomes relevant wherever work is carried out below the natural groundwater level. In the application areas of Darda GmbH, controlled separation and low-vibration procedures are often the focus.

• Concrete demolition and special demolition: Exposing foundations, grade beams, or basins; controlled separation with concrete demolition shear under reduced pore water pressures.
• Building gutting and cutting: Dry kerfs and clean work surfaces for sawing and cutting operations in basement and shaft areas.
• Rock excavation and tunnel construction: Reducing inflows at the tunnel face and crown; orderly load redistribution for stone and concrete splitters as well as stone splitting cylinders.
• Natural stone extraction: Reduction of seepage water in benches and slopes, improvement of stability and occupational safety.
• Special applications: Infrastructure junctions, underpasses, shafts, tank renovations with high environmental relevance and stringent water treatment.

Geotechnical fundamentals and design

Design is based on permeability (kf-value), layer boundaries, aquifers and aquitards, storage capacities, and Darcy flow. The cone of depression depends on abstraction rate, well spacing, and boundary conditions. Settlements can occur in fine-grained soils; in sandy layers, insufficient safeguards may lead to base heave. Monitoring using gauges, flow and turbidity measurements is common to verify effectiveness and environmental impacts.

Effects on the structure and surroundings

Groundwater lowering affects pore water pressure and effective stresses. Possible effects include settlements, rearrangements in the subsoil, and impacts on neighboring buildings or utilities. In the presence of hydrostatic pressure, uplift must be considered. Noise, aerosols, and vibrations should be minimized. In existing structures, controlled drawdown creates the basis for precise cutting and splitting with minimal edge damage – an advantage for procedures using concrete demolition shear or stone and concrete splitters.

Water quality, treatment, and discharge

Pumped water often contains suspended solids, fine sediments, or fine concrete particles. Depending on the situation, settling stages, filters, or separators are appropriate. pH and solids content should be monitored. Discharge to a receiving water body or the sewer generally requires a permit; regional requirements vary. Where feasible, water is infiltrated or allowed to percolate on site to limit impacts on the surroundings.

Interfaces to demolition: tools and workflow

After successful dewatering, components are exposed and residual moisture is limited. Dimensional accuracy and break control during separation increase as a result. In this phase – depending on member thickness and boundary conditions – concrete demolition shear, stone and concrete splitters, hydraulic power packs, combination shears, stone splitting cylinders, multi cutters, steel shears, or tank cutters are used. Coordination between pump operation, material logistics, and occupational safety is decisive.

Concrete demolition shear in partially flooded structures

In basements or shafts, residual water may remain. Concrete demolition shear enables controlled detachment of foundation ribs, upstands, and wall bases without generating additional vibration. Advantages include defined fracture lines and minimal secondary damage.

Stone and concrete splitters in water-affected rock

In tunnel and shaft construction, drawdown reduces inflow and stabilizes the tunnel face. Splitters and stone splitting cylinders transmit high forces quietly into boreholes. This is particularly suitable when sensitive neighbors or utility networks are close to the extraction area.

Hydraulic power packs in wet areas: protective measures

When working near water, ensure splash-proof setup, stable footing, and safe hose routing. Regular leak checks prevent undesirable entries into the pumped water.

Project planning and sequence

1. Investigation: Geology, kf-values, layer boundaries, existing structures, receptors requiring protection.
2. Concept: Selection of method (e.g., Wellpoint, wells), drawdown depth, filter completion, energy and power supply.
3. Permitting and verification: Required notifications and permits, protective measures for neighboring foundations.
4. Execution: Construction of wells/wellpoints, trial operation, adjustment of pumping rate.
5. Monitoring: Level control, flow, turbidity, pH, and where applicable, noise and vibration.
6. Demolition/separation: Coordinated use of concrete demolition shear as well as stone and concrete splitters under reduced pore water pressure.
7. Decommissioning of the dewatering system: Gradual shutdown, backfilling, monitoring of rebound.

Legal and organizational aspects

Water law requirements, discharge permits, and ancillary provisions vary regionally. Requirements for emission limits, noise and dust control, as well as for deconstruction and reclamation must be assessed on a project-specific basis. Notes provided here are general and non-binding; relevant codes and official stipulations are decisive in each individual case.

Selection of materials and tools under dewatering

Lowered pore water pressure facilitates targeted cutting and splitting. For massive members, stone and concrete splitters or stone splitting cylinders are often selected; for reinforced concrete, concrete demolition shear are suitable, if necessary in combination with steel shears for reinforcing steel. Hydraulic power packs provide the required energy. Selection depends on member thickness, reinforcement ratio, accessibility, and requirements for low vibration.

Quality assurance and documentation

Continuous documentation of groundwater levels, flow rates, water quality, and settlement measurements increases execution reliability. For separation work in the lowered area, cutting and splitting records, photo and material evidence are kept. This substantiates process stability, traceability, and environmental compatibility.