Heavy-duty scaffold

A heavy-duty scaffold is a temporary load-bearing system for the safe support and load transfer of heavy structural elements. It is used wherever structures need to be temporarily held, lifted, relieved, or bridged during conversion, deconstruction, or new construction. In the application areas of concrete demolition and special deconstruction, strip-out and cutting, rock excavation and tunnel construction, natural stone extraction as well as special operations, the heavy-duty scaffold often provides the structural basis so that hydraulic tools such as concrete demolition shears, stone and concrete splitters, hydraulic shears or steel shears can operate in a controlled and low-vibration manner.

Definition: What is meant by heavy-duty scaffold

A heavy-duty scaffold (also support scaffold, heavy-duty shoring tower, or shoring scaffold) is understood to be a modular, temporary construction made of steel or aluminum components that safely transfers high vertical and horizontal loads into the subsoil. Typical tasks include supporting slabs and beams at openings, carrying bridge elements during concrete repair or deconstruction, propping machines or components during load redistribution, and creating provisional bridging. Characteristic features are the high load-bearing capacity combined with flexible adaptability to geometry, construction sequence, and accessibility.

Structure and load-carrying principle of heavy-duty scaffolds

Heavy-duty scaffolds consist of standardized or system-specific components optimized for compression, bending, and bracing. The load paths run from the bearing area of the intercepted component via beams and yokes into support towers, then via screw jacks, load distribution plates and, where applicable, substructure into the subsoil. Decisive factors are a continuous force line, sufficient bracing against overturning and buckling, and a load-bearing, low-deformation base.

• Support towers/heavy-duty props: modular tower elements with high compressive capacity and defined buckling length
• Yokes and beams: cross members for load distribution and for taking point or line loads
• Head and base screw jacks: fine adjustment, leveling, compensation of structural deformations
• Bracing: diagonals, frame bracing and couplers to resist horizontal actions
• Load distribution plates/sleepers: reduction of ground pressure and protection of sensitive surfaces

Materials and connection technology

Heavy-duty scaffolds are predominantly made of high-strength steel; aluminum is used where weight, handling, and corrosion resistance are paramount. Connections are made via system nodes, bolts, wedge heads, or tube couplers. Assembly must be force- and form-fit, free of play, and documented in a traceable manner, as connectors significantly influence the actual reserve of load capacity.

Types, systems, and load ranges

Different system types are used depending on the task. The selection is based on load capacity, structure geometry, accessibility, project duration, and assembly conditions.

• Heavy-duty towers and props: high point loads, small footprint, often stackable and linkable
• Frame and modular systems: grid-shaped support of large areas, good adaptability
• Yoke-beam and lattice girder solutions: long spans over obstacles, bridge support scaffolds
• Catch structures/load towers with superstructures: temporary underpinning of beams and edge girders
• Hybrid solutions: combination with steel beams, temporary foundations, or needling

Planning, structural analysis, and design

Planning a heavy-duty scaffold starts with determining all loads and load cases, verifying components, joints, and global stability, and assessing subsoil quality. In addition to permanent and variable actions, assembly states, construction stages, and possible interim steps must be considered. Design is based on established rules for support scaffolds and takes building code requirements into account. Project- and site-specific particularities must be assessed separately.

• Load assumptions: self-weight, imposed loads, machine loads, material storage, dynamic components from demolition and cutting operations
• Structural stability: verification against overturning, sliding, and buckling, bracing in all planes
• Deformations: limitation of settlements and deflections, compensation via screw-jack travel
• Fire protection and environmental influences: temperature, humidity, corrosion, vibrations

Substrates and load transfer

Safe load transfer requires load-bearing substrates. For sensitive soils or existing slabs, load distribution via sleepers, steel plates, or auxiliary foundations must be planned. Monitoring (for example, settlement points) supports the assessment of load-bearing behavior during the construction phase.

Use in concrete demolition and special demolition

In controlled deconstruction, components are often separated, released, and removed in segments. A heavy-duty scaffold serves for temporary shoring and controlled load redistribution. It creates the structural conditions to separate components with low vibrations, for example using concrete demolition shears, stone and concrete splitters, hydraulic shears, or concrete demolition shears in combination with cutting techniques.

1. Preparation: determine residual load-bearing capacity, define load redistributions, set up the heavy-duty scaffold
2. Expose and separate: make separation cuts, introduce predetermined breaking lines, use concrete demolition shears or rock splitters
3. Removal: segment-wise lifting off or controlled lowering, coordination with lifting equipment or internal haulage logistics
4. Dismantling the scaffold: after load redistribution and securing the structure

Interaction with concrete demolition shears

Concrete demolition shears reduce components with low vibration. In combination with a heavy-duty scaffold, slab fields, beams, or bridge cantilevers can first be shored and then reduced section by section with the concrete demolition shear. This minimizes unwanted crack formation and prevents uncontrolled load redistributions.

Interaction with stone and concrete splitters

Stone and concrete splitters generate controlled splitting along defined lines. If a component is first offloaded by a support scaffold, restraints decrease and the split joint remains predictable. This facilitates lifting individual blocks, for example in bridge bearing zones or massive foundation blocks.

Strip-out and cutting: stable working and protection scaffolds

During strip-out in existing buildings, preserving the exterior shell and minimizing vibrations are often the priorities. Heavy-duty scaffolds secure slab fields during core drilling, wire sawing, or wall sawing and carry machine and material loads. mobile hydraulic power units supply concrete demolition shears, hydraulic shears, or multi cutters; the scaffold also serves as an organized logistics spine for dust- and noise-reduced work.

Openings in existing slabs

Before creating stair or MEP openings, slabs are shored using modular towers. After the separation cut, the remaining structure can be reduced in a controlled manner with concrete demolition shears, and the cut material can be divided into manageable units.

Rebar and steel separation

After concrete breakout, reinforcement is often cut with hydraulic shears or steel shears. The heavy-duty scaffold keeps loads stable during the cutting process, prevents vibrations, and facilitates safe handling.

Rock excavation, tunnel construction, and natural stone extraction

In underground environments and during rock removal, temporary load-bearing systems are required as work platforms, material carriers, or catch structures. Heavy-duty scaffolds can bridge stationary lining elements, carry service structures, or secure fall zones. In combination with stone and concrete splitters, defined wedges can be detached from natural stone without resorting to blasting technology. The low vibration protects linings, anchors, and supports.

Particularities underground

Low headroom, restricted logistics, and ventilation requirements shape the planning. Lightweight, high-capacity modules with a clear assembly sequence are advantageous; settlement and deformation measurements must be closely accompanied.

Special operations and temporary auxiliary structures

Heavy-duty scaffolds are also used as temporary supports for tank cutting operations, as carriers for pipeline modifications, or as auxiliary structures during machine changeouts. In industrial plants they are suitable for shoring heavy aggregates while peripheral equipment is separated, cut, or repositioned.

Safety, assembly, and operation

Safety has top priority in planning, assembly, and operation. A well-thought-out assembly concept, defined releases, and regular inspection are essential. Ergonomic handling of components, clear traffic routes, and a dust- and noise-conscious site organization support smooth operations.

• Assembly sequence: start from load-bearing bearing points upward, early bracing, continuous elevation control
• Inspection: visual checks of components and connectors, documentation, release before loading
• Operation: comply with permissible loads, prohibit uncontrolled redistributions, protect against vehicle impact and vibrations
• Dismantling: step-by-step and symmetrical, verify loads before each step

Interactions with hydraulic tools

Hydraulic tools can generate variable loads and local shocks. The support scaffold must be designed for such actions; work areas must be safeguarded against falling objects, crush and shear points. Hydraulic power packs must be positioned so that hoses are routed without tension and tripping hazards are avoided.

Normative and legal framework

For the planning, construction, and operation of support scaffolds, relevant technical rules and standards apply, including those for support and working scaffolds. Depending on the project, requirements from building code, occupational safety, and structural design must also be considered. The application of appropriate standards, the preparation of structural verifications, and a qualified operating manual must be defined on a project-specific basis. Legal requirements must always be reviewed in general and adapted to the specific boundary conditions.

Practice-oriented notes for collaboration with hydraulic demolition tools

The integration of support scaffold and equipment technology increases efficiency and safety. In combination with concrete demolition shears, stone and concrete splitters, hydraulic shears, multi cutters, steel shears, or tank cutters, consistent interface planning proves its worth.

• Anticipate: shore components before the separation cut, provide continuous load paths, avoid restraints
• Segment: define manageable sizes, keep crane or lifting paths clear, exclude drop zones
• Minimize vibrations: prefer low-vibration methods, cushioned bearings, and short force paths
• Make measurable: document settlements, screw-jack travel, and deformations, define thresholds
• Communication: uniform signals, clear responsibilities, coordinated emergency routines

Material selection, logistics, and cost-effectiveness

The choice between steel and aluminum systems depends on load requirements, transport routes, and assembly cycles. Lightweight modules score in confined existing buildings; on open areas, tall tower systems with large load reserves are convincing. Early logistics planning—from inbound transport via intermediate storage to return—reduces idle times and increases the productivity of downstream work with hydraulic tools.

Quality assurance

Regular maintenance, component marking, and complete documentation ensure proper condition. Inspection intervals depend on frequency of use, environmental conditions, and manufacturer specifications. Visible damage, deformation, or corrosion lead to the exclusion of affected parts.