The soft rock quarry connects geology, process engineering, and occupational safety: it is about the controlled loosening, splitting, and extraction of slightly to moderately lithified rocks such as chalk, marl, gypsum, mudstone, or soft sandstone. In practice, precise, low-vibration methods are at the forefront—such as hydraulic splitting. This is precisely where hydraulic rock and concrete splitters and suitable hydraulic power units show their strengths. They enable finely metered energy input in natural stone cutting and in rock excavation and, in tunnel construction, special operations, and special demolition, contribute to greater control, occupational safety, and gentle handling of materials. Concrete demolition shears come into play where soft rock meets concrete structures or where mineral composite materials need to be separated selectively during deconstruction.
Definition: What is meant by soft rock quarry
Soft rock quarry refers to the extraction, loosening, and controlled fragmentation of rocks with low to medium compressive strength and a pronounced bedding, joint, or pore fabric. These include, among others, chalk, gypsum and anhydrite rocks, tuffs, marls, mudstones, as well as weakly cemented sandstones. Characteristic are lower tear-off resistance, higher sensitivity to water, and frequently distinct bedding and depositional structures. The soft rock quarry covers the entire process chain from geotechnical exposure through primary loosening (e.g., by borehole drilling and hydraulic splitting) to secondary crushing, sorting, and loading. The aim is safe, low-emission extraction with reproducible block or grain qualities—in the quarry, in tunnel and adit construction, as well as in excavation pits with soft rock faces.
Geological fundamentals and material behavior
Soft rocks show deformation and fracture behavior that strongly depends on water content, porosity, bed thickness, and binder. Clayey and marly rocks tend to soften and lose strength when wetted; gypsum-bearing layers react sensitively to water ingress. Chalk and fine-grained calcareous marls often exhibit a homogeneous yet brittle structure that can be split in a controlled manner. In weakly cemented sandstones, grain size, cementation, and bedding control crack propagation. These properties favor low-noise and low-vibration methods: hydraulic wedge splitters or stone splitting cylinders exploit existing planes of weakness and create defined separation joints, while concrete demolition shears selectively separate at transitions to structures or in composite zones. For process reliability, the orientation of the borehole axes to the bedding, the wedge geometry, and a uniform pressure build-up by appropriate hydraulic power packs are decisive.
Methods in the soft rock quarry: controlled, low-vibration, selective
In soft rock, methods that combine precision with low emissions are the focus. The goal is clean separation joints, minimal edge damage, and safe workflows—especially in sensitive environments.
Hydraulic splitting with stone and concrete splitters
Stone and concrete splitters generate, by means of wedge splitters or stone splitting cylinders, high, locally confined tensile stresses in the borehole. In soft rocks, cracks propagate preferentially along bedding planes, clay seams, or finely jointed structures. Advantages include reproducible crack guidance, low vibrations, and the ability to size blocks in a targeted manner. Hydraulic power packs provide the required, finely adjustable pressure and support continuous cycles. This enables the extraction of natural stone for further processing and the controlled loosening of rock sections in tunnel heading or at excavation pit faces.
Concrete demolition shears at the interface between soft rock and structure
When soft rock approaches structures—such as at retaining constructions, slabs, or linings—concrete demolition shears enable selective removal of concrete portions without unnecessarily weakening the rock. In refurbishment and special demolition projects, this facilitates material removal, exposure of contact joints, and the safe trimming of edges with splitters. The combination of both tools improves process quality and reduces mis-breaks in sensitive zones.
Multi-stage process chain
- Preparation: Geotechnical description, determination of bedding, jointing, and water ingress.
- Primary loosening: Grid drilling, orientation to bedding, splitting with stone splitting cylinders.
- Secondary crushing: Re-splitting along the created separation planes; in composite zones, use of concrete demolition shears.
- Handling: Securing, lifting, loading of blocks; sorting by quality and size fraction.
- Documentation: Recording of parameters such as borehole spacing, splitting sequence, and result quality.
Material and bedding effects in the soft rock quarry
Aligning the method to the bedding is key to success. Bedding planes, clayey interbeds, disturbances, and moist zones determine splitting direction and tool choice. Uniform pressure build-up, suitable wedge geometry, and short splitting paths promote clean crack formation. For water-sensitive rocks, protection against wetting is important to avoid softening, laminations, and uncontrolled breaks.
Typical soft rocks and specific features
- Chalk, calcareous marl: brittle, uniform texture; well splittable, low edge spalling with correct borehole guidance.
- Gypsum/anhydrite: moisture-sensitive; controlled cycles and swift processing prevent strength loss.
- Mudstone/marl: tends to soften; short splitting spacings and moderate pressure increases are advantageous.
- Soft sandstone: splitting behavior depends on cementation; observe orientation along bedding and lenses.
Application areas related to the soft rock quarry
Soft rock appears in many projects—sometimes purely geological, sometimes at the interface with structures. The methods can be adapted to the respective application areas.
Rock excavation and tunnel construction
In tunnels and adits through soft rock, controlled loosening with minimal vibrations is crucial in rock demolition and tunnel construction. Hydraulic splitting reduces loosening at the tunnel face and preserves the rock mass. During fitting-out works or cross-section enlargements, concrete demolition shears are suitable for selectively removing concrete or shotcrete portions and subsequently continuing to work the rock.
Natural stone extraction
For high block quality, clean separation joints and minimal edge damage are central. Stone and concrete splitters allow loosening along planes of weakness, while splitting cylinders define block dimensions. Consistent results support further processing and sorting by quality grades.
Concrete demolition and special demolition
For structures in soft rock—such as slabs on marl or retaining structures in chalk—concrete demolition shears are used for controlled deconstruction. Subsequently, exposed rock sections can be trimmed with splitters without endangering surrounding structures.
Strip-out and cutting
In projects with composite materials or transitions from concrete to soft natural stones, concrete demolition shears facilitate selective separation. This keeps rock bodies stable while installations are removed and contact joints are exposed.
Special operations
In sensitive zones—such as near protected buildings, in confined inner-city areas, or where vibration limits apply—blasting-free, low-vibration methods are in demand. The combination of hydraulic splitting, adapted drilling techniques, and selective fragmentation with shears minimizes emissions and supports requirements for immission control.
Planning, safety, and environmental aspects
Careful planning is the basis: geotechnical investigation, assessment of water inflows, and analysis of bedding define the splitting strategy. Safety distances, stable working slopes, and controlled load paths must be observed. Emission control—dust, noise, vibrations—is supported by adapted working methods, controlled pressure stages, and short splitting intervals. Legal and approval-relevant requirements depend on project, location, and use; they must be observed within the applicable regulations.
Tool use: hydraulic power packs, splitting cylinders, and shears
Hydraulic power packs provide constant, finely adjustable system pressure. Stone splitting cylinders and wedge splitters transfer energy locally into the rock. Decisive factors are the design of borehole diameter, wedge geometry, and splitting spacing in relation to bedding. Concrete demolition shears complement the chain when composite components, reinforcement in concrete, or connections to soft rock need to be separated cleanly. In combination, this enables continuous and safe process control.
Parameters with practical relevance
- Drilling pattern and orientation to bedding
- Splitting sequence and pressure stage profile
- Block dimensions, edge lengths, and target quality
- Moisture conditions and weather window
- Occupational safety: stability, retreat lines, communication
Quality assurance and documentation
Documenting splitting parameters, block quality, and edge damage creates transparency and improves reproducibility. Visual inspections of separation surfaces, checks for unwanted cracks, and complete recording of process steps facilitate optimizations. This keeps the soft rock quarry stable and efficient—from development through primary loosening to further processing.