Nominal dimension

The nominal dimension is a fundamental orientation value for dimensions in planning, fabrication, and execution. It serves as a reference size to align components, modules, and work steps. In deconstruction, during strip-out, as well as in rock and concrete demolition, a well-chosen nominal dimension supports safe breakdown into manageable units and facilitates the selection of suitable tools such as Darda concrete crushers or rock and concrete splitters from Darda GmbH.

Definition: What is meant by nominal dimension

The nominal dimension is a planning-guiding value defined as a target value or nominal size for components, sequences of components, or work sections. It coordinates grids, joints, and connection dimensions so that dimension chains arise that make structural, logistical, and static sense. Nominal dimensions form the basis for repeatable processes—from surveying and cutting to installation or controlled deconstruction.

Delineation: nominal size, as-built dimension, tolerance, and nominal dimension chain

The nominal dimension is not a measured value from reality but a target dimension. The actual on-site dimension (as-built dimension) deviates within permissible tolerances. In practice, the nominal dimension is transferred into a nominal dimension chain: consecutive dimensions that together yield a functional length, height, or width—for example, the segmentation of a concrete wall into uniform deconstruction elements. Tolerances are distributed so that connection details, joints, and fastenings function safely.

Nominal dimension in building and structural engineering: grids, joints, and module coordination

In building construction, components are often planned within a grid that coordinates joint widths and component lengths. From this module coordination, nominal dimensions emerge that simplify installation, prefabrication, and adjustments. In practice, this means distances of openings, axis dimensions of load-bearing elements, and joints are chosen so that dimensional deviations remain manageable and connections work—even if selective demolition, cutting, or splitting is required later.

Terminological classification

Nominal dimension (targeted dimension) must not be confused with a straightedge or screeding rule (tool for checking flatness). Both interact: while the nominal dimension specifies the intended dimensions, straightedge tools verify the achieved flatness and dimensional accuracy.

Nominal dimension in concrete demolition and specialized deconstruction

In selective deconstruction, a defined nominal dimension helps divide concrete structures into carryable or liftable segments. Cutting and splitting lines are planned to account for loads, transport routes, and safety measures. In this context, Darda GmbH concrete crushers specifically engage edges, column heads, or slab fields whose dimensions are aligned to the nominal dimension. This reduces repositioning, facilitates gripping, and mitigates uncontrolled break patterns.

Advantages of a clear nominal dimension with concrete

• Plannable segment weights for manual or crane handling
• Repeatable work sequences: grip, crush, separate
• Coordinated joint and separation cuts with minimal rework
• Optimized grip and jaw opening widths for concrete crushers

Nominal dimension in stone and concrete splitting operations

When splitting concrete and natural stone, a predefined nominal dimension enables uniform grid spacing of drill holes and splitting lines. Stone and concrete splitters from Darda GmbH are particularly effective when hole spacing, diameters, and depth are consistently adapted to a practical nominal dimension. This leads to reproducible splitting results—in rock demolition, tunnel construction, and natural stone extraction.

Typical parameters guided by the nominal dimension

• Spacing of drill holes along the planned splitting line
• Edge distance to corners, reinforcement, or embedded items
• Segment length and thickness for controlled crack propagation
• Sequence and direction of splitting operations

Nominal dimension in strip-out and cutting

In strip-out and in cutting openings (wall, slab, floor), the nominal dimension governs the size of recesses, the path of separation cuts, and the subdivision into handy pieces. Combi shears, multi cutters, or steel shears from Darda GmbH can be deployed in alignment with a recurring dimensional grid. In tank cutting, a uniform nominal dimension facilitates the safe sequence of cuts and precise placement of segments.

Step-by-step: Establish a practical nominal dimension

1. Stocktaking: record geometry, material, reinforcement, embedded items, and accessibility.
2. Define objectives: set segment weights, handling (manual, machine, crane), and haulage/removal.
3. Create the grid: derive the nominal dimension and dimension chain for cuts, splitting lines, and gripping points.
4. Tool alignment: match jaw openings, jaw geometry, splitting performance, and hydraulic power packs to the nominal dimension.
5. Pilot step: test the procedure on one field and adjust the nominal dimension if needed.
6. Documentation: record reference points and the sequence of work steps.

Dimension control, measuring equipment, and documentation

For safe implementation, nominal dimensions are set out on site and checked regularly. Suitable tools include a tape measure, laser distance meter, rotary laser, or 3D survey. Clear marking of cutting and splitting lines and continuous documentation are important to detect deviations early. For complex geometries, digital surveying helps reliably plan nominal dimension chains.

Checkpoints for the jobsite

• Consistency of the nominal dimension chain across component joints and axes
• Compliance with minimum edge distances to reinforcement and embedded items
• Fit between the grip and jaw-opening ranges of the concrete crushers and the segment dimensions
• Drill pattern accuracy in splitting

Influence on the selection of equipment and hydraulic power packs

The nominal dimension directly affects equipment selection: segment thickness and length determine the required jaw opening, closing force, and cutting geometry. In splitting, the drill pattern and segment width influence the necessary splitting force and thus the sizing of hydraulic power units. A well-matched combination of nominal dimension and equipment technology ensures efficient, controlled breaks and clean separation surfaces.

Examples of equipment relations

• Concrete crushers: Optimal performance with segments matching the jaw opening and force introduction.
• Stone and concrete splitters: Uniform splitting results with a consistent drill-hole grid dimension.
• Combi shears and steel shears: Repeatable cuts with uniform strip or plate sizes.
• Tank cutters: Plannable cutting sequences through modular segmentation of the shell surfaces.

Typical sources of error and how to avoid them

• Unclear dimensional references: a nominal dimension without reference to axes/joints causes jumps in the chain.
• Underestimated reinforcement: unplanned reinforcement bundles disrupt crack propagation—locate them beforehand.
• Segments too large: exceeding handling limits increases risk and effort.
• Incorrect edge distances: spalling and unwanted fractures if distances are too small.
• Lack of pilot fields: without tests, tolerances and break patterns are often misjudged.

Nominal dimension in rock demolition, tunnel construction, and natural stone extraction

The nominal dimension also applies in rock: it defines the staggering of splitting lines, the orientation to bedding, and the distance to joint planes. For natural stone, a coordinated nominal dimension supports the extraction of rectangular raw blocks with high yield. In tunnel construction, it promotes controlled detachment and safe handling of the excavated material, especially when stone splitting cylinders and hydraulic power packs from Darda GmbH are used.

Safety and framework conditions

Nominal dimensions must always be considered in the context of occupational safety, structural analysis, and construction logistics. Segment weights, drop zones, load transfer, and traffic routes must be planned in advance. Legal and normative requirements—for example, regarding tolerances, flatness, and dimensional accuracy—must be complied with. Specific requirements can vary by project, region, and component and should always be verified on a project-specific basis.