Shell construction / structural work

Shell construction / structural work is the load-bearing framework of a structure. It defines geometry, load transfer, and durability and forms the basis for fit-out and building services. In this phase, decisive course is set for quality, time, and costs. For adjustments during construction or in existing buildings, controlled separation and deconstruction methods are relevant — for example with concrete demolition shears as well as hydraulic wedge splitters from Darda GmbH — because they operate with low vibration, precision, and predictability.

Definition: What is meant by shell construction / structural work

Shell construction / structural work refers to the construction phase from the foundation to the completed load-bearing structure of walls, columns, slabs, stairs, shafts, and the roof structure. It usually ends with weather-tightness (e.g., sealed roof and closed building envelope), before interior works and finishes begin. It includes reinforced concrete and masonry, steel and timber structures, as well as necessary waterproofing and connections. It is relevant in new construction as well as in alterations and refurbishments when load-bearing structures are added, strengthened, or selectively deconstructed.

Core components and construction types in shell construction / structural work

Shell construction / structural work comprises foundations or the floor slab, vertical load transfer (walls, columns), horizontal members (slabs, roof structure), circulation elements (stairs, elevator shafts), and openings for doors, windows, and installations. The choice of construction type depends on use, spans, subsoil, fire protection, building acoustics, and cost-effectiveness.

Reinforced concrete construction

Reinforced concrete combines the compressive strength of concrete with the tensile strength of reinforcement. Critical factors include formwork quality, reinforcement layout, concrete cover, joint planning, and curing. Construction joints, movement joints, and stripping times influence watertightness, cracking behavior, and dimensional accuracy. Corrections to openings or cantilevering components can be executed precisely in the shell phase; where adjustments are needed, concrete demolition shears can be used for controlled removal of concrete, and hydraulic power packs provide the drive system.

Masonry

Masonry made of small-format units or large-format elements is used for load-bearing or non-load-bearing walls. Bed joints, head joints, bond patterns, and connection details determine load-bearing capacity and thermal performance. Openings are formed with lintels, transfer beams, or ring beams. Local corrections can be made by manual demolition work or low-vibration splitting techniques; rock wedge splitters are an option here, especially for natural stone or solid calcium silicate brick masonry.

Steel and timber structures

Steel frames and timber structures enable large spans and fast erection. Connections, bracing, and corrosion and moisture protection are decisive. When cutting or adapting steel sections during the construction stage or in conversions, steel shears or Multi Cutters are used, which cut profiles true to shape and ease construction logistics.

Construction sequence and interfaces in shell construction / structural work

The sequence follows a clear order so that geometry, load transfer, deadlines, and safety are maintained. Precise coordination of trades reduces rework and facilitates later fit-out.

Typical steps

1. Earthworks, excavation pit, if applicable rock excavation; construction of the foundation (foundations, floor slab)
2. Walls, columns, cores, shafts; installation of penetrations and embedded components
3. Slab and roof structures including edge beams and bearings
4. Stair flights, landings, parapets, bracing elements
5. Weather-tightness of the envelope; shell construction / structural work inspection, tolerance check, documentation

Interface management

Early coordination with fit-out, building services, and the façade prevents clashes (e.g., shafts, openings, attachment points). Change requests can be implemented in a targeted way in the shell — for example with concrete demolition shears for precise removal or hydraulic wedge splitters for low-vibration creation of openings when vibrations and noise must be minimized.

Formwork, reinforcement, and concreting

Formwork defines geometry and surface; reinforcement provides tensile capacity; concreting ties both into a durable load-bearing component. Quality arises from careful preparation, control, and curing.

Formwork and reinforcement

Clean formwork joints, correct spacers, and defined concrete cover are essential. Reinforcement is placed according to the drawings, tied or welded, observing lap splice lengths, bend radii, and placement. For corrections to reinforcement, steel shears and Multi Cutters can cut profiles and reinforcement bars without excessively loading adjacent members.

Concrete placement and curing

Concrete is placed with suitable consistency, compacted, and protected against drying out or cooling too quickly. Curing controls hydration and reduces the risk of cracking. Stripping times depend on strength development and environmental influences. For precise block-outs, accurate formwork planning is worthwhile; subsequent openings should, if required, be created using low-vibration methods.

Openings, separation cuts, and adjustments in shell construction / structural work

In practice, subsequent adjustments are common: new door openings, shafts for building services, larger breakthroughs, or removal of protruding components. Controlled methods are needed that protect the load-bearing structure and do not damage surrounding areas.

• Concrete demolition shears enable the step-by-step, targeted removal of reinforced concrete — suitable for gutting works and concrete cutting as well as for concrete demolition and special deconstruction within the shell phase.
• Hydraulic wedge splitters — including rock wedge splitters — produce predictable cracks in concrete, natural stone, or engineered stone. Advantageous where strict requirements regarding vibration, noise, and dust apply, for example in densely built-up areas or existing buildings.
• Combination shears and Multi Cutters cut reinforcement, profiles, and composite members; they support separating steel and concrete for cleaner demolition sorting.
• Steel shears accelerate shortening of beams, bracing, or rebar bundles — important for conversions, vertical extensions, or when installing load-transfer systems.
• Hydraulic power packs provide the necessary power supply for the tools mentioned and ensure reproducible, finely metered performance.

Safe and low-vibration methods in shell construction / structural work

In sensitive environments — for example in the immediate vicinity of existing buildings, laboratories, or hospitals — methods with low dynamic loads are crucial. Hydraulic wedge splitters induce controlled crack formation; concrete demolition shears work with high precision and without impact loads. These methods reduce secondary damage, decrease rework, and facilitate stability verification during the intervention. In rock areas of excavation pits, they connect to rock demolition and tunnel construction by selectively releasing rock without generating blasting vibrations.

Sustainability and circular economy in shell construction / structural work

Resource-conscious shell planning considers material efficiency, separability by material type, and a future deconstruction strategy. Selective deconstruction facilitates recycling of concrete and steel, reduces waste volumes, and preserves components for reuse.

Selective deconstruction facilitates recycling

Through controlled separation — e.g., with concrete demolition shears and Multi Cutters — concrete and reinforcement can be collected separately. Splitting methods support dismantling close to fracture surfaces, which organizes the material flow. This is particularly relevant in concrete demolition and special demolition as well as in gutting works and concrete cutting.

Natural stone and excavation pit

In excavation pits with rocky subsoil, rock wedge splitters and hydraulic wedge splitters can precisely control rock removal. The technique originates from natural stone extraction and rock excavation and tunnel construction and transfers effectively to inner-city shell construction situations with sensitive boundary conditions.

Quality, tolerances, and documentation

Dimensional accuracy, flatness, plumb and alignment, concrete cover, and surface quality are systematically checked in shell construction / structural work. Inspection and acceptance records, concrete delivery notes, reinforcement documentation, and photo documentation form part of robust quality assurance. Tolerances and requirements follow the contractually agreed standards; they should be coordinated for the specific project and carefully documented.

Component accuracy and function

Early checks of grid/axis dimensions, opening positions, and embedded items prevent later clashes. Where rework is necessary, concrete demolition shears and splitting methods are often gentler on materials and surroundings than percussive methods because they introduce lower vibration.

Occupational safety and environmental protection in shell construction / structural work

Shell construction / structural work combines work at height, load handling, reinforcement, formwork, fresh concrete, and machine use. Safety has top priority: fall protection, lifting and load checks, stability verification for construction states, dust and noise reduction measures, and an orderly construction logistics concept are indispensable.

Keeping emissions low

Low-vibration methods — such as hydraulic wedge splitters or concrete demolition shears — reduce vibration, noise, and dust. This protects neighboring buildings and improves working conditions. The selection of the right tool should be based on member thickness, reinforcement ratio, accessibility, and environmental constraints.

Planning with a view to future alterations

Shells that anticipate adjustments remain more durable and economical: reserve shafts, predesigned openings, modular grids, and separable connections make later intervention easier. If an existing structure still needs to be modified, concrete demolition shears, hydraulic wedge splitters, and additionally combination shears and Multi Cutters enable targeted and controlled deconstruction — from small slab penetrations to large-format openings, including as a special demolition under tight scheduling or spatial constraints.