Lightweight construction method

The lightweight construction method describes the targeted reduction of mass while maintaining equal or higher functionality. In construction, deconstruction, and demolition technology it enables lower loads, better handling, and more efficient processes. Especially when working in existing buildings, on slabs with critical load-bearing capacity, or in confined areas, light yet robust tools facilitate safe and controlled operations. This applies in particular to hydraulic attachments and handheld tools such as concrete demolition shears as well as hydraulic rock and concrete splitters which, in combination with compact hydraulic power units, perform a wide range of tasks in concrete demolition and specialized deconstruction, in strip-out, and in rock excavation.

Definition: What is meant by the lightweight construction method

The lightweight construction method comprises the totality of approaches used to design components, machines, and systems with mass optimized for given requirements in load-bearing capacity, stiffness, and fatigue strength. The goal is a favorable ratio of weight, performance, and service life. The lightweight construction method includes material lightweighting (material selection), structural lightweighting (geometry and structure), and system lightweighting (functional integration, assembly and process optimization). In demolition and deconstruction technology, lightweighting pays off in better ergonomics, reduced bearing loads, lower energy demand, and increased mobility.

Lightweighting in demolition technology and mobile hydraulic systems

Light yet durable tools reduce the loading of carrier machines and structures. On slabs with limited residual load-bearing capacity or in sensitive zones, lower masses help maintain safety distances. In addition, reduced dead weight eases transport and positioning, shortens setup times, and lowers the required drive power of the hydraulic power packs. Using precise, low-vibration methods such as splitting or pressing/crushing of concrete, dust and noise emissions can often be minimized.

Relevance for concrete demolition shears and stone and concrete splitters

Concrete demolition shears benefit from lightweighting because a favorable mass-to-performance ratio increases control during selective deconstruction. Lightweight designs make it easier to engage at separation joints, open slab openings, and detach reinforced components. Stone and concrete splitters are often used where impact or blasting methods are not permitted. Their compact, lightweight design enables use in narrow shafts, on scaffolds, and in tunnel heading. Both tool groups support controlled, low-vibration work with low load on adjacent structures.

• Lower bearing loads on slabs and work platforms
• Easy handling and rapid relocation times
• Reduced energy demand at the same splitting or shear force
• Gentle, controlled separation on sensitive components
• Advantages in noise-sensitive areas due to low-vibration methods

Design principles of the lightweight construction method

Material selection and material lightweighting

In heavy-duty applications, tough, high-strength steels dominate, resisting peak loads, abrasion, and impact loading. Lightweighting here does not mean “thin-walled at any cost,” but rather targeted use of high yield strengths, suitable heat treatments, and wear-resistant contact surfaces. Components with functional surfaces are designed so that material is concentrated where loads are introduced.

Geometry, load paths, and topology

Structural lightweighting optimizes ribs, webs, and transitions along real load paths. Rounded contours reduce notch effects. Hollow sections and cellular structures save mass while maintaining high bending stiffness. Modern calculation methods support topology optimization so that only “load-bearing material” remains. For concrete demolition shears, jaw geometry influences not only mass but also the clean guidance of the fracture line. For splitters, wedge angles, cylinder housings, and supports are designed to generate high splitting forces in a compact form.

System lightweighting and functional integration

Hydraulic power packs, valve blocks, hose routing, and connections can be integrated in a space-saving manner. Short hose runs reduce pressure losses; a compact design lowers inertia and improves balance when engaging. Functional integration can reduce maintenance effort, provided wear parts remain easily accessible.

Application areas: requirements and opportunities of lightweighting

Concrete demolition and specialized deconstruction

On existing slabs with limited load-bearing capacity, lightweight tools are a factor for safety and productivity. Concrete demolition shears enable selective detachment of components in controlled load steps. With less mass on the carrier machine, requirements for supports and cranes are reduced. Stone and concrete splitters create defined crack lines so components can break down into manageable segments.

Strip-out and cutting

In strip-out, low emissions and rapid redeployability are key. Lightweight tools accelerate cycle times in multi-story buildings because they can be moved without large lifting equipment. In combination with cutting methods (e.g., combination shears (e.g., HCS8) or multi cutters), openings are created before concrete demolition shears or splitters complete the separation.

Rock excavation and tunnel construction

In underground headings and drifts with restricted transport routes, lightweighting eases material flow. Hydraulic wedge splitters operate with low vibration, which is advantageous near sensitive infrastructure. The lower system weight supports safe use at faces with limited stand space.

Natural stone extraction

In natural stone extraction, controlled fracture is crucial. Lightweight splitters can be positioned precisely and redeployed quickly to free blocks along the cleavage plane. This supports the quality and geometry of the recovered raw blocks.

Special applications

In special situations with difficult access, heightened safety requirements, or limited energy supply, lightweighting increases flexibility. Compact hydraulic power packs and lightweight tools can be used where heavy equipment is impractical.

Selection criteria for lightweight tools and attachments

• Mass-to-performance ratio (dead weight per usable shear or splitting force)
• Compatibility with carrier machines and hydraulic power packs (working pressure, flow rate, connections)
• Jaw geometry of concrete demolition shears and wedge design of stone and concrete splitters matched to reinforcement and component thickness
• Stiffness and torsional rigidity of the structure under dynamic loads
• Wear protection on contact and guide surfaces; accessibility of wear parts
• Noise and vibration behavior in the intended method
• Transport logistics: carrying points, rigging points, balance when engaging

Work methodology: combine gentle methods with lightweighting

The benefits of the lightweight construction method unfold within a coordinated approach. Splitting and shear techniques are combined so that forces are introduced in a targeted manner and components are separated in planned partial steps. Short routes, clear load paths, and small batch sizes ensure controlled progress.

1. Structural analysis of concrete members or rock; definition of cut and split lines
2. Planning of load paths: supports, rigging points, protection zones
3. Preparation: drilling for stone and concrete splitters, exposing reinforcement
4. Selective separation with concrete demolition shears, combination shears, or multi cutters along the planned lines
5. Segmented removal and material-appropriate haulage in small units

Safety and ergonomics in the context of lightweighting

Less mass reduces handling risks but does not replace systematic hazard analysis. Load-bearing capacities, rigging gear, and stability must be verified before each use. Lightweight designs improve ergonomics when grip points, center of gravity, and visibility of the work zone are well matched. Personal protective equipment, secure coupling operations on hydraulic hose lines, and clear communication on site are indispensable. Legal requirements and recognized rules of technology must always be observed; case-specific professional advice remains necessary.

• Short, secure hose routing with mechanical protection
• Defined lifting and carrying points; marked centers of gravity
• Smooth tool ramp-up to avoid impact loads
• Regular visual and functional checks before the start of the shift

Sustainability and life-cycle considerations

Lightweighting reduces transport and lifting requirements and can lower energy demand in operation. This has a positive effect on emissions and noise balance, especially with low-vibration methods. High structural efficiency must go hand in hand with fatigue strength and repair-friendly design to extend service life and conserve resources. Replaceable wear parts and clear maintenance intervals extend use and improve circularity.

Practical examples and avoiding typical mistakes

Where lightweighting has particular impact

• Work on slabs with limited residual load-bearing capacity
• Strip-out on upper floors without a large crane
• Confined areas in tunnel and drift construction
• Noise-sensitive zones where low-vibration splitting offers advantages

Failure patterns and countermeasures

• Oversized attachments: select tools according to component thickness and reinforcement ratio
• Ignored load distribution: verify supports, shoring, and work platforms in advance
• Insufficient preparation for splitting: dimension and position pre-drilled holes correctly
• Unsuitable jaw geometry of concrete demolition shears: align the cut path with the reinforcement layout
• Poor maintenance: check wear surfaces in time; inspect hydraulic power packs for leaks

Technical characteristic values and assessment in lightweighting

Key metrics include density, yield strength, tensile strength, modulus of elasticity, impact toughness, and the ratio of mass to usable force or power. For concrete demolition shears and stone and concrete splitters, opening width, splitting or pressing force, cycle time, and the balance of the overall system with hydraulic power packs are also relevant. A balanced design considers safety margins, fatigue strength, and the actual load spectra in operation.