Control measurement

Control measurements are indispensable in demolition, deconstruction, and the processing of concrete and rock to reliably document the target–actual comparison throughout all project phases. Whether openings are cut precisely, components are separated to exact dimensions, or borehole patterns for splitting are adhered to with precision: systematic verification creates safety, reduces risks, and increases execution quality. Especially when using hydraulic tools from Darda GmbH – from concrete demolition shears and rock and concrete splitters to combination shears, multi cutters, or steel shears – control measurement provides the basis for predictable results in concrete demolition and special deconstruction, strip-out and cutting, rock excavation and tunnel construction, as well as natural stone extraction.

Definition: What is meant by control measurement

A control measurement is the targeted, documented verification of geometric dimensions, conditions, and process-relevant parameters in order to detect and correct deviations from the target at an early stage. This includes dimensional and positional checks on components, crack and deformation monitoring, borehole depth and position checks, the recording of cut edge quality, and the monitoring of impacts such as vibration, noise, or dust. In combination with hydraulic tools — for example concrete demolition shears or rock and concrete splitters — control measurement also includes checking tool-side variables such as hydraulic pressure, cut or split stroke, opening width, and tool wear. The goal is demonstrable quality assurance throughout the entire workflow.

Measurement objectives and use cases in concrete demolition and special demolition

Depending on the task, control measurements address different objectives: dimensional accuracy of openings and separation cuts, flatness, plumb, and level, adherence to borehole patterns for splitting, control of cutting depths and remaining thicknesses, monitoring of crack widths and settlements, as well as the surveillance of process-induced impacts. In practice, use cases range from preparation (as-built survey, reference measurement) through ongoing control (intermediate measurements to steer the intervention) to acceptance (evidence of target values and surface quality).

Control measurements with concrete demolition shears and rock and concrete splitters

Before starting: baseline survey and measurement planning

A reliable starting point is created by a structured baseline survey. For work with concrete demolition shears or rock and concrete splitters, the following points are particularly relevant:

• Component geometry: wall and slab thicknesses, axis and grid dimensions, concrete cover.
• Material and reinforcement detection: locating reinforcement and inserts in cutting or splitting zones.
• Borehole planning for splitting: diameter, depth, center-to-center spacing, and edge distances as the basis for the splitting process.
• Reference points: defining fixed points/zeros for later target–actual comparisons.
• Tool parameters: checking the hydraulic power units, baseline setting of the concrete demolition shear (opening width) and the splitter cylinder (stroke).

During the intervention: process-near control

Ongoing control serves to steer and document intervention quality:

• Concrete demolition shear: measurement of achieved cutting depth, residual thickness, edge quality, and the opening dimensions of the created opening; checking tool opening and pressure level.
• Rock and concrete splitters: checking borehole depth and position, verifying split stroke, observing crack propagation (crack width measurement), readjusting the borehole pattern if necessary.
• Component response: flatness/deformation, settlements, vibration impact on adjacent components.

After the intervention: acceptance and verification

Acceptance includes complete documentation of target–actual values:

• Geometry: opening dimensions, flatness, plumb, cut and split quality, edge radii.
• Remaining load-bearing areas: minimum clearances to reinforcement, remaining wall/slab thicknesses.
• Process evidence: hydraulic pressures, tool inserts used, calibration certificates of measuring instruments.
• Impacts: vibration, noise, and dust logs, if required.

Measurement methods and measuring equipment

The choice of method depends on accuracy, accessibility, surface condition, and documentation requirements. Proven approaches include:

• Geometric measurement: tape measure, steel ruler, feeler gauges, calipers; laser distance measurement and rotating laser (level); total station; 3D laser scanning or photogrammetry for complex geometries.
• Component diagnostics: rebound hammer for indicative concrete strength; concrete cover measurement (rebar locator); borehole endoscopy; drilling dust evaluation for splitting.
• Crack and deformation monitoring: crack width gauges, strain measurement points, inclinometers for tilt control.
• Process parameters: hydraulic pressure and flow measurement at the hydraulic power pack; stroke/opening checks on shears and splitter cylinders; wear measurement on blades and jaws.
• Impact measurement: vibration monitors, sound level meters, dust measurement (as needed), temperature and humidity sensors on sensitive components.

Procedure and documentation

1. Objective definition: Which dimensions, conditions, and impacts are critical for the task? Prioritize by risk and consequence.
2. Measurement planning: selection of measuring equipment, definition of measuring points, references, and tolerance ranges; set measuring intervals (before, during, after the works).
3. Calibration and functional check: plausibility check of measuring devices; documentation of calibration status.
4. Execution: reproducible methodology, clear measurement logs, photos/sketches for spatial context.
5. Evaluation: target–actual comparison, trend observation for series measurements (e.g., crack or settlement), actions in case of deviations.
6. Proof of compliance: compilation of results for acceptance/quality assurance; secure, traceable archiving.

Tolerances and guide values in context

Tolerances arise from planning, structural analysis, specification, and, where applicable, relevant standards (e.g., tolerances for flatness/position in structural engineering or guidance for assessing vibrations). Such requirements must be interpreted in context; evaluation should be based on the intended usage and safety level. Legal requirements can vary by project and location and should always be carefully reviewed on a project-specific basis.

Typical sources of error and how to avoid them

• Unclear reference points: missing fixed points lead to systematic deviations. Remedy: establish and protect stable references.
• Unsuitable measuring equipment: wrong accuracy class or contact measurement on rough surfaces. Remedy: choose method-appropriate measuring tools and fixtures.
• Edge and environmental influences: temperature, vibration, or dust affect measurements. Remedy: plan measurement times and shielding, perform repeat measurements.
• Incomplete logs: without photo sketches and serial numbers, traceability is limited. Remedy: use standardized log modules.
• Tool wear: blade or jaw wear changes cutting/splitting results. Remedy: regular wear inspection and measurement.

Control measurement across application areas

Concrete demolition and special demolition

In selective deconstruction with concrete demolition shears and combination shears, dimensional accuracy of separations and control of impacts are paramount.

• Opening dimensions, residual thicknesses, edge quality, and flatness of cut surfaces.
• Monitoring adjacent components (crack formation, vibrations).
• Hydraulic and tool parameters for reproducibility.

Strip-out and cutting

In interior areas, precise cuts and minimal impacts are crucial.

• Exact position of penetrations, door and window openings; plumb and level.
• Cutting depth, remaining material, reinforcement exposure.
• Noise and dust logs as required by the project.

Rock excavation and tunnel construction

When splitting rock or massive concrete bodies, borehole and crack control are central.

• Borehole position, depth, and pattern as prerequisites for the splitting process.
• Crack propagation, split stroke, stability of adjacent areas.
• Vibration and settlement in sensitive environments.

Natural stone extraction

Extraction requires predictable splitting patterns and high-quality separation faces.

• Pattern fidelity, splitting pattern, surface quality.
• Volume and dimensional control of raw blocks.
• Tool wear and hydraulic parameters for consistent results.

Special applications

For specialized tasks — such as selective separation cuts with steel shears or tank cutters — control measurement is adapted to the project.

• Dimensional and positional measurements in confined spaces.
• Material separation with documented process parameters.
• Impact monitoring according to the boundary conditions.

Practice-oriented measurement criteria for shears and splitters

• Geometry: opening dimension (L x W), flatness, plumb, residual thickness, edge radius.
• Drilling/splitting parameters: borehole diameter and depth, center spacing, edge distance, split stroke.
• Tool data: opening width of the shear, hydraulic pressure and flow, wear dimension on blades/jaws.
• Component behavior: crack width, deformation, settlement.
• Impacts: vibration level, sound level, dust concentration (if project-relevant).

Guideline for reliable results

For reproducible quality, a three-stage approach with clear measurement windows is recommended: before (create a reference), during (steer via intermediate measurements), and after (acceptance and evidence). In all phases: choose measuring instruments suited to the task, document calibration status, validate results for plausibility, and address deviations promptly. Especially for work with concrete demolition shears and rock and concrete splitters, the combination of geometry measurement, process parameter control, and observation of component behavior leads to robust, traceable results.