Wall thickness is a key parameter in construction practice, in concrete demolition and in separation and splitting technology. It influences the selection of methods, the sizing of tools and the sequence of work steps. Whether concrete wall, masonry, pipe wall, retaining wall, steel tank or natural stone slab: The component thickness largely determines which forces, interventions and safety measures are required. For Darda GmbH, wall thicknesses are crucial for deploying rock and concrete splitters, concrete pulverizers, hydraulic power packs or tank cutters in a technically meaningful way—always targeted and material-appropriate, without unnecessary vibrations.
Definition: What is meant by wall thickness
Wall thickness means the perpendicular thickness of a wall component between its two relevant surfaces. It can refer to reinforced concrete, masonry, natural stone, steel sheet or composite assemblies. A distinction is made between nominal thickness (design dimension) and the effective on-site thickness, which can deviate due to tolerances, plaster and facing layers, voids or reinforcement layers. In reinforced concrete, the position of the reinforcement and the concrete cover are relevant, as they influence the effective cross-sectional thickness as well as the separation and splitting behavior.
Importance of wall thickness in deconstruction and cutting technology
In concrete demolition and specialized deconstruction, wall thickness determines the choice of gripping, cutting and splitting techniques. Thin members can often be separated with lower forces and finer tools, while massive cross-sections require a multi-stage approach. For concrete pulverizers, thickness influences the suitable jaw opening, kinematics and staged removal. With rock and concrete splitters, it controls borehole diameter, grid pattern and splitting direction. In strip-out and cutting, member thickness dictates the cut path, number of passes and the need for auxiliary shoring. The goal is a controlled, low-vibration process with a predictable fracture line.
Wall thickness and tool selection
Tool selection follows member thickness, material and accessibility. It is about a well-tuned interaction of hydraulic performance, kinematics, edge guidance and tool life. A sound assessment of wall thickness reduces risks such as uncontrolled spalling, jamming or unnecessary loads.
Concrete pulverizers
With concrete pulverizers, wall thickness is decisive for jaw opening, tool orientation and removal strategy. Slender walls are removed in a controlled bite sequence to avoid edge breakouts and cracks. For massive elements, a sequential removal with pre-relief and, if necessary, the introduction of relief openings is recommended. Reinforcement density and concrete strength influence cutting forces; wall thickness determines how many gripping and crushing cycles are required to reach the target contour.
Rock and concrete splitters
Splitters generate a defined splitting impulse along predrilled grids. Wall thickness governs borehole spacing, edge distances and the staging of the splitting process. Thin cross-sections can often be released with few splitting points; for thick walls, a multi-stage break from the edge towards the center is advisable to guide the intended fracture joint. This controls load redistribution and minimizes vibrations.
Other tools and systems
- Hydraulic power packs: The required working pressure and flow rate depend on wall thickness, material and tool size. Greater thicknesses often mean longer load cycles and adapted hydraulic supply.
- Combination shears and multi cutters: Sensible for composite assemblies and varying thicknesses, for example in combined concrete–steel deconstruction.
- Steel shears: Decisive is the steel wall thickness (e.g., on sections and tanks), which defines the necessary cutting force and staging.
- Tank cutters: Plate thickness and any double walls define feed, cutting strategy and safety distances during the cutting process.
Determining wall thickness on site
Before using concrete pulverizers or rock and concrete splitters, the actual member thickness must be established. The more precise the data, the safer the planning of splitting points, cut edges and the demolition sequence.
- Visual inspection and measurement: Expose edges; measure at openings and interfaces.
- Trial openings or core samples: Targeted exploration of thickness, concrete quality and reinforcement content.
- Endoscopy/inspection: Insight into voids, layers and composite joints.
- Rebar locating: Detection of bar diameters, layers and concrete cover as an indication of effective cross-sectional thickness.
- Low-destructive testing methods: Acoustic or ultrasonic methods can indicate thickness variations and inhomogeneities.
Documentation and tolerances
Recorded thicknesses, measurement points and particularities (e.g., layers, facing shells, voids) should be documented and integrated into work planning. Usual construction tolerances and local deviations must be considered, as well as possible material changes. Information on standards and codes must be verified in general; project-specific decisions are always made after expert evaluation.
Influencing factors: concrete strength, reinforcement and voids
Beyond thickness alone, material properties affect separation and splitting behavior. High concrete densities and compressive capacity often require higher forces or finer staging. Reinforcement deflects cracks and locally strengthens cross-sections; its position relative to the wall surface influences fracture propagation. Voids, lost formwork or facing shells alter the effective wall thickness and can favor irregular breaks. A combination of concrete pulverizer and splitting technology often enables controlled progress: pre-relieve first, then split or crush in a targeted manner.
Selecting work methods by wall thickness
Member thickness defines the demolition strategy: number of work steps, load sequence, grid and safeguards. The aim is a predictable process with the lowest possible dust and noise.
Slender members
For thin walls, a gentle intervention with lower forces, short lever arms and tight tool guidance is recommended. Concrete pulverizers work section by section with high precision; splitters are applied at selected points to define break edges and guide crack paths.
Medium member thicknesses
Here, a combination of pre-relief and sequential removal is proven. Splitting points are placed so that stresses are reduced step by step. Concrete pulverizers open the structure before further splitting cycles extend the fracture surface. Cutting or milling operations can protect edges.
Massive members
For high wall thicknesses, a stepped splitting plan is usually indispensable. Grid, borehole diameter and edge distances must be matched to member thickness. Intermediate reliefs and the use of load-bearing frames or shoring must be assessed. Hydraulic power packs should be configured for longer pressure-hold phases.
Planning drilling patterns for rock and concrete splitters
The drilling pattern guides the fracture and determines efficiency. It depends on wall thickness, material and the desired demolition edge. Principles include edge and center distances, staged activation of splitting points and safeguarding adjacent components.
- Edge distance: Sufficient distance reduces uncontrolled spalling and edge breakouts.
- Hole spacing: With increasing thickness, the required spacings and/or splitting phases grow.
- Sequence: Splitting sequences from outside to inside or vice versa—depending on support and free edge.
- Intermediate relief: Targeted pre-breaks lower overall forces and improve crack guidance.
Wall thickness in special applications
Concrete demolition and specialized deconstruction
Massive columns, shear walls or shafts require a coordinated approach of splitting, crushing and occasional relief cuts. Concrete pulverizers refine edges and reduce projections, splitters create predictable fracture joints. Adjacent components remain as undisturbed as possible.
Strip-out and cutting
In strip-out, wall thicknesses influence the selection of separation tools and the cutting sequence. Thinner facings are removed first, followed by load-bearing layers. Multi cutters and combination shears handle varying thicknesses in composite assemblies; concrete pulverizers create defined openings.
Rock excavation and tunnel construction
In rock, the effective thickness often corresponds to bed or slab thickness. Splitting cylinders transmit their force into existing joints or a drilled pattern. Greater thicknesses require adapted splitting sequences and hydraulic cycles to achieve the desired fracture surface.
Natural stone extraction
In natural stone, layer thickness, fabric and bedding control splitability. A finely tuned pattern facilitates clean separation faces. Wall thickness and grain structure determine how many splitting cycles are required for a dimensionally accurate slab.
Special applications
Special environments with large wall thicknesses—such as shielding, high-strength special concretes or composite constructions—require a conservative, stepwise approach. Remote-controlled hydraulic power packs support safe distances, while concrete pulverizers and splitters guide the fracture.
Calculation and estimation of required forces
With increasing wall thickness, the required splitting and cutting forces rise. Material properties (e.g., compressive strength), reinforcement ratio and construction details act as multipliers. A practical approach is an iterative approximation: trial splitting points, staged removal with the concrete pulverizer and fine-tuning of hydraulic parameters. For steel walls (e.g., tanks), plate thickness and geometry define the cutting sequence and the necessary shear or cutting capacity.
Cut-edge quality and reworking
Wall thickness influences the surface quality of fracture or cut edges. Thick members often exhibit coarser roughness and local spalls, especially at edges. A combination of preliminary relief cuts and subsequent edge finishing leads to reproducible results. Concrete pulverizers can precisely trim edges and expose protruding reinforcement.
Occupational safety in connection with wall thickness
Safe processes require stable support and controlled load paths. Larger wall thicknesses store higher stresses; accordingly, shoring, intermediate relief and secured demolition sequences must be provided. Notes on occupational and environmental protection must be checked on a project-specific basis; binding decisions are made by those responsible on site.
- Plan load transfer: Align the sequence with wall thickness, supports and connection details.
- Define exclusion zones: With increasing member thickness, enlarge fall-out zones.
- Control hydraulics: Operate pressure and flow within approved system values.
- Apply thermal cutting procedures (e.g., tank plates) with care: Consider ventilation, cleanliness and material thickness.
Typical sources of error and practical notes
- Underestimated wall thickness leads to jamming, uncontrolled fracture patterns or unnecessarily high forces.
- Unknown reinforcement layouts deflect cracks; combining rebar locating with trial openings reduces surprises.
- Edge distances that are too small at splitting points favor spalling; carefully adapt the pattern to thickness.
- Inhomogeneous zones (voids, facing shells) distort behavior; stepwise progress with intermediate checks is advantageous.