Deep drainage

Deep drainage forms the underground backbone for conveying wastewater and stormwater from buildings, industrial facilities, and traffic areas. It comprises pipelines, shafts, and structures below finished grade as well as the associated construction and rehabilitation methods in the ground. In planning, construction, and repair, classical civil engineering (underground works), sewer construction works, and selective concrete demolition intersect. Where existing shafts must be opened, foundation breakthroughs created, or rock formations along the alignment loosened, controlled, low-vibration methods are used — for example with concrete pulverizers or rock and concrete splitters from Darda GmbH in combination with suitable hydraulic power units. This interplay is particularly relevant in sensitive environments, in densely built inner-city areas, and when working on existing structures.

Definition: What is meant by deep drainage

Deep drainage refers to the entirety of all underground drainage facilities for the orderly conveyance of wastewater and stormwater. These include base pipelines, connection lines, inspection shafts and control shafts, drop shafts, backwater valves, sump pumps, and drainage systems. The systems are installed at sufficient depth to remain frost-free, operate with a defined gradient, and stay watertight over the long term. Materials range from concrete and reinforced concrete to vitrified clay and plastic pipes; selection is based on hydraulic, structural, and chemical requirements as well as the subsoil and the tie-in elevation to the public sewer. In addition, the procedures for execution and quality assurance — earthworks, shoring, bedding, compaction, leakage tests, and channel/invert testing — are part of the deep drainage domain.

Interfaces between deep drainage and selective deconstruction

Where deep drainage ties into existing structures, an interface to concrete demolition and special demolition arises. Typical examples include opening and enlarging inspection shafts, creating foundation breakthroughs for new base lines, removing damaged manhole rings, trimming channel inverts, or the controlled opening of sewer crowns. In these situations, concrete pulverizers prove their worth for precise removal of reinforced components, and hydraulic wedge splitters for low-vibration opening of massive cross-sections or for loosening rock in the pipe trench. The gentle working method protects existing utilities, reduces low vibration levels in the neighborhood, and lowers the risk of secondary damage — crucial in inner-city projects, for sensitive infrastructure, and in special deployments.

Planning and configuration of deep drainage systems

Robust deep drainage follows hydraulic design, geotechnical boundary conditions, and recognized rules of practice. Central building blocks are the gradient, pipe sizing, choice of materials, shaft spacing, bedding, and the ability to inspect and maintain.

Alignment, gradient, and hydraulics

Base lines are laid with a continuous, consistent gradient to avoid deposits and ensure reliable conveyance during rainfall events. A load-bearing, low-settlement subsoil with coordinated bedding and compaction is just as important as adequate pipe stiffness. At gradient drops, drop shafts provide energy-dissipating guidance; at shallow depths, modest bends and accessible shafts are crucial for future cleaning and rehabilitation.

Shafts and structures

Inspection shafts enable changes in direction, gradient drops, and control. Shaft bases with shaped inverts ensure self-cleansing flow. When modifying existing systems, manhole rings are often selectively removed or openings retrofitted — here, concrete pulverizers are used for ring-by-ring removal and hydraulic wedge splitters for dimensionally accurate enlargement of breakthroughs. In confined excavations with adjacent buildings, the low-vibration approach is particularly advantageous.

Construction methods in the ground: excavation, shoring, and installation

Installation is carried out in open trenches or — for undisturbed surfaces — using trenchless methods. In open trenches, subsoil, groundwater, and traffic conditions determine the choice of shoring. The goal is a stable excavation with a dry working area and a defined formation.

Trench shoring and groundwater

Depending on depth and soil, lightweight shoring systems, slide rail shoring, or soldier pile walls are used. With groundwater present, temporary groundwater lowering is required with the least possible impact on the surroundings. In rocky or boulder-rich soils, hydraulic wedge splitters facilitate controlled loosening without blasting works — an advantage in densely built areas and in rock excavation and tunnel construction where sensitivity to noise and vibration is high.

Tie-in to existing systems and connection works

Connecting to existing pipelines requires precise opening and creation of pipe connections. When penetrating foundation beams or girders, selective demolition methods are needed: concrete pulverizers for reinforced components, supplemented by hydraulic shear (demolition shear) for reinforcing steel. Hydraulic power packs provide the necessary force in a compact package — helpful in narrow shafts.

Inspection, rehabilitation, and deconstruction in deep drainage

Regular inspections, condition classification, and a coordinated rehabilitation strategy ensure durability. Depending on the damage pattern, trenchless methods (e.g., liners) or open-cut replacement are used. When structures below grade are selectively deconstructed, protecting the surroundings takes priority.

Selective concrete demolition below finished grade

For removing manhole heads, enlarging access openings, or taking out defective inverts, concrete pulverizers are well-suited thanks to their controlled, low-splinter working principle. Hydraulic wedge splitters create defined crack patterns in massive components and enable non-destructive release of large blocks. In combination with combination shears, multi cutters, or steel shear, reinforcement and mixed materials can be separated efficiently — a typical use case in building gutting and concrete cutting as well as in concrete demolition and special demolition.

Challenges: confined spaces, protection of existing assets, and safety

Work in shafts and trenches entails specific requirements for occupational safety, rescue routes, ventilation, and handling potential hazardous substances (e.g., biogases). In addition, neighboring buildings, utility lines, and traffic must be protected. Low-vibration methods, low-dust working practices, and careful handling of arising material support environmental protection and construction quality. The use of compact, hydraulically powered tools eases access in tight conditions.

Technology overview: tools and methods for underground deconstruction

In practice, the following tool categories have proven themselves where deep drainage and selective demolition coincide:

• Concrete pulverizers for precise deconstruction of shaft walls, covers, and foundation breakthroughs with controlled material removal.
• Hydraulic wedge splitters for inducing cracks and releasing massive components or rock, particularly suitable in sensitive neighborhoods.
• Hydraulic power packs as mobile power units for operating tools in shafts, trenches, and tunnels.
• Combination shears, Multi Cutters, and steel shear for cutting reinforcement, grating, and built-in components.

Selection depends on component thickness, degree of reinforcement, accessibility, and the requirements for vibration, noise, and dust. The goal is a reproducible, safe working method with minimal impact on the surroundings.

Typical use cases across application areas

1. Concrete demolition and special demolition: Opening inspection shafts, removing manhole heads, selective removal of defective inverts — preferably with concrete pulverizers.
2. Building gutting and concrete cutting: Creating foundation breakthroughs for new base lines and removing inserts; a combination of concrete pulverizer, steel shear, and supplementary cutting methods.
3. Rock excavation and tunnel construction: Clearing alignments in rocky subsoil using hydraulic wedge splitters — low-vibration and dimensionally accurate.
4. Natural stone extraction: Extracting and sizing natural stone for manhole covers or surrounding construction tasks; controlled splitting supports dimensional accuracy.
5. Special deployments: Work in sensitive areas such as hospitals, laboratories, or heritage sites where emissions and vibrations are strictly limited.

Quality assurance and documentation

Durability depends on careful bedding, defined compaction, and tight joints. In addition, condition reports, measurement logs, and photo documentation create transparency — from the excavation through installation to the closed trench. For selective deconstruction below finished grade, continuous barricading, checking the stability of the shoring, and tracking material flows (concrete, soil, reinforcement) are essential.

Practical recommendations for planning and execution

• Plan early interface coordination between sewer construction works and deconstruction technology; size access routes and work areas.
• On-site component assessment: material, reinforcement ratio, thickness, and stress state determine the tool choice.
• Evaluate vibration, noise, and dust in advance; prioritize low-emission methods such as dust suppression and low vibration levels.
• Plan for safe handling of groundwater and soil; document installation and removal of shoring elements with regard to settlements.
• Review work and rescue concepts for working in shafts and trenches comprehensively within the team, focusing on occupational safety.