Support scaffold

A support scaffold is a temporary support structure that safely transfers loads when load-bearing components are being built, modified, or systematically deconstructed. In practice, the support scaffold combines structural safety with a structured workflow: it holds what will later be removed, replaced, or processed. Especially for measures in concrete demolition and special deconstruction, in building gutting and cutting, in rock excavation and tunnel construction as well as in natural stone extraction, a professionally planned support scaffold creates the precondition for tools such as concrete pulverizers or rock and concrete splitters to be used in a controlled and low-vibration manner. This knowledge is aimed at site management, structural designers, and executing contractors who want to coordinate the planning, assembly, and use of support scaffolds safely and efficiently.

Definition: What is meant by support scaffold

A support scaffold is a time-limited structural aid for the transfer of vertical and horizontal loads while a new or existing component cannot (yet) fulfill its function. It differs from a working scaffold in that access is not the focus; instead, it is the load transfer into the ground. Typical materials are steel and aluminum; wood is used locally to level bearings. A support scaffold consists of posts, ledgers, diagonals, head screw jacks, and bearing timbers, supplemented by bracing and stiffeners. The design considers permanent loads, imposed and traffic loads, dynamic additional loads from demolition or splitting processes, as well as wind and, where applicable, vibration effects. Applicable standards and authority requirements must be observed; in case of doubt, a qualified structural analysis is required.

Configuration, components, and load-bearing behavior

The load-bearing behavior of a support scaffold relies on ensuring short buckling lengths, stiff nodes, and direct load paths. Posts take compressive forces, ledgers distribute loads over an area, and diagonals provide the necessary bracing. Head and base screw jacks enable millimeter-accurate adaptation to the existing structure and subgrade. Bearings are sized with load distribution plates or timber layers so that the subsoil is not overstressed. Essential is controlled pre-cambering (preloading) for slab supports to limit settlements and deflections and to prevent inadmissible stresses in adjacent components.

Fields of application: new construction, refurbishment, and deconstruction

Support scaffolds are used in bridge construction, slab renewals, underpinning of walls, tunnel construction, machine foundations, and industrial plants. During gutting and cutting, they support slab fields and beams that are removed in sections using concrete pulverizers. In concrete demolition and special demolition, they serve to redirect loads so that components can be selectively weakened with rock and concrete splitters and then removed without unwanted load redistributions. In rock excavation and tunnel construction, heavy-duty towers provide safe supports for extraction equipment or shielding. In natural stone extraction, auxiliary scaffolds stabilize work areas while rock splitting cylinders open bedding planes. For special operations in confined existing structures, modular support scaffolds allow tailored shoring when multi cutters, steel shears, or tank cutters are used for the controlled deconstruction of metallic plant components.

Support scaffold interacting with demolition and splitting technology

The interplay of shoring and separation technology determines safety, pace, and component protection. Concrete pulverizers benefit from a stiff, well-braced support because this makes crack lines more predictable. Rock and concrete splitters generate wedge-shaped splitting forces which—properly designed—reduce component strength without overloading the support scaffold. Hydraulic Power Units supply these tools; routing of hoses and the placement areas for the packs must therefore be considered in the scaffold layout. Combi shears, steel shears, and multi cutters free-cut reinforcement and steel sections, while the support scaffold posts carry the residual loads until the section is fully decoupled.

1. Define the shoring concept: load assumptions, load paths, subsoil verification, and clearances for tools.
2. Assemble, align, pre-camber/preload the support scaffold, and complete documented acceptance.
3. Weaken the component using rock and concrete splitters; monitor crack propagation.
4. Release component pieces with concrete pulverizers; cut reinforcement with multi cutters.
5. Secure the section, remove it, re-adjust the posts, and begin the next cycle.

Example: slab opening in an existing structure

First, the slab is propped and the load transfer is guided into zones with sufficient capacity. Then rock splitting cylinders locally weaken the concrete so that the concrete pulverizer can remove smaller pieces with less force. Rebars are cut with multi cutters. The support scaffold remains in service until the new load transfer is established and is subsequently dismantled in stages.

Planning, design, and monitoring

Robust planning defines load cases (permanent loads, traffic loads, equipment loads, dynamic components), safety factors, and allowable deflections. Support reactions must be checked against the subsoil; where bearing capacity is non-uniform, distribution structures are required. For demolition operations, monitoring is recommended: settlement control marks, dial gauges at critical nodes, and regular visual inspections. For operations with splitting and cutting forces, reserves against buckling and overturning must be provided because loads can change direction.

Set-up areas and subsoil

The subsoil must be level, load-bearing, and secured against sliding. Load distribution plates reduce ground pressures. Elevated areas require verification of transfer into substructures. In wet areas, slip protection and corrosion protection must be considered.

Clearances for tools and power packs

The scaffold geometry must account for the gripping paths of concrete pulverizers, installation spaces for rock splitting cylinders, and hose and cable routing to hydraulic power packs. Sufficient working clearances, splash protection, and safe set-up locations for power packs must be provided.

Safety, work organization, and communication

A sound safety concept structures responsibilities, exclusion zones, and releases. Load-altering operations take place only after coordination between site management, structural engineering, and the equipment operators. Changes to the support scaffold (relocation, re-adjustment, removal of diagonals) are made exclusively after written release.

• Keep the stability verification and assembly instructions available; document the acceptance protocol.
• Check deformations regularly; define threshold values.
• Mark exclusion zones and load paths; coordinate craning and lifting operations.
• Secure hydraulic lines; collect dripped oil; avoid ignition sources in sensitive areas.
• Plan for dust and noise reduction measures; prevent material drop.

Material selection, system types, and corrosion protection

Steel support scaffolds offer high stiffness and load reserves; aluminum convinces with low self-weight and rapid assembly. System types range from modular and frame scaffolds to heavy-duty towers and single telescopic posts with head jacks. Corrosion protection (hot-dip galvanized, coated) and cleanability play a role in tunnel or industrial applications. For elevated temperature exposure (e.g., hot work on steel), material limits and protective measures must be defined in advance.

Special applications in tunneling, natural stone, and industry

In tunnel construction, support scaffolds serve as temporary abutments to support tunnel face support or excavation edges while rock and concrete splitters or concrete pulverizers remove components section by section. In natural stone extraction, shoring creates safe working positions in quarries when rock splitting cylinders open layers. In industrial special operations, support scaffolds stabilize tanks, pipelines, and steel platforms until cuts with steel shears, multi cutters, or tank cutters are fully completed and the residual loads are safely removed.

Assembly, conversion, and dismantling

Assembly begins with surveying the bearing points, followed by placing posts, ledgers, diagonals, and preloading. Each construction phase is documented. Conversions are carried out in controlled cycles so that load paths are never interrupted. Dismantling starts only when the permanent load-bearing structure is completed or the deconstruction section is completely unloaded.

Dismantling the support scaffold after demolition

After releasing and removing the component pieces—e.g., using concrete pulverizers and cutting reinforcement with multi cutters—the shoring is gradually unloaded. Back off the screw jacks in a controlled manner, remove diagonals last, clean the bearings, and inspect the condition of the components. Components are inspected for damage and released for the next use.

Typical mistakes and how to avoid them

Errors often occur at interfaces: insufficient bracing, unclear load paths, or lack of communication. With clear rules, adequate reserves, and a layout tailored to the tools used, these risks can be minimized.

• Insufficient diagonal bracing leads to overturning: close the cross bracing consistently.
• Too small a bearing area causes settlements: plan load distribution plates and subsoil verification.
• Equipment weights underestimated: account for the self-weight of concrete pulverizers, hydraulic power packs, and material transport.
• Preloading forgotten: limit deflections and observe settlements.
• Bracing released prematurely: make changes only after approval and with substitute securing.

Terminological classification and interfaces

Support scaffolds must be distinguished from working and protective scaffolds. They can carry formwork girders (formwork scaffold) or independently redirect loads (supporting scaffold, heavy-duty tower). In deconstruction projects, they form the structural link between component and ground, while separation and splitting technology—such as concrete pulverizers, rock and concrete splitters, combi shears, or steel shears—divides components into manageable sections. Darda GmbH provides specialist knowledge that enables clean integration of shoring, separation, and logistics without abandoning a neutral, safety-oriented approach.