Carrier safety

Carrier safety describes the safe control of loads, forces, and movements that arise when using hydraulic demolition and splitting technology—both on the carrier machine (e.g., crawler excavator, demolition robot, or handheld tool) and on the load-bearing structural element itself (beams, girders, columns, bracing). In the typical fields of application of Darda GmbH—from concrete demolition and special demolition through gutting and cutting to rock breakout, tunnel construction, natural stone extraction, and special operations—carrier safety determines stability, process quality, and personal protection. The focus is on equipment such as concrete pulverizers, rock and concrete splitters (hydraulic wedge splitter), hydraulic power packs, hydraulic demolition shear, Multi Cutters, steel shear, cutting torch, as well as specific rock wedge splitter. Forward-looking work planning, traceable load transfer, and controlled handling of shear force, compressive, and splitting forces form the basis for a safe and efficient workflow.

Definition: What is meant by carrier safety

Carrier safety is understood as the sum of all measures and technical prerequisites that ensure safe work on the carrier machine and on load-bearing structures. This includes the correct selection, installation, and operation of attachments such as concrete pulverizers, rock and concrete splitters, or steel shears, the stable hydraulic supply via suitable hydraulic power packs, a statically clear dismantling and splitting sequence, controlled load transfer, as well as shoring or temporary securing of components. Carrier safety is therefore both organizational (hazard analysis, instruction, communication) and technical (load capacity, tipping stability, pressure/flow rate, cutting forces, splitting forces). Legal requirements and technical rules must be observed in general; binding assessments in individual cases always require expert evaluation.

Fundamentals of carrier safety in deconstruction and demolition

Carrier safety arises when all forces in the system are balanced and the reactions on the carrier machine, the subsoil, and the processed structural element are controlled. When using concrete pulverizers, high shear and crushing forces act, which perform rebar cutting and break concrete; rock and concrete splitters and specific rock wedge splitters generate radial splitting forces that open the structure along crack lines. Both methods have low vibration levels and are non-explosive, but require precise guidance, continuous monitoring of crack formation, and safe removal of loosened masses. Hydraulic power packs provide the required pressure and volume flow. Overturning moments, dynamic load changes (load spectrum (structural)), vibrations, and hydraulic temperature are relevant in planning because they affect the stability of the carrier machine and the condition of the structure.

Carrier safety on the carrier machine: selection, installation, and operation

Safe work with attachments and handheld tools requires a suitable carrier machine. Key aspects are load capacity, tipping stability, hydraulic supply, visibility, and freedom of movement—particularly in confined environments such as gutting works, tunnel construction, or special operations.

Load capacity, center of gravity, and overturning moment

• Tool weight and geometry: concrete pulverizers, hydraulic demolition shears, Multi Cutters, and steel shears influence the carrier machine’s center of gravity. Longer booms or add-ons increase the overturning moment.
• Working position: overhead or extended front work increases risk. A low, wide stance improves tipping reserve.
• Subsoil: bearing capacity of the subsoil, possible voids, and vibrations must be checked; temporary load distribution (e.g., timber or steel mats underneath) increases stability.

Hydraulic supply and hydraulic power packs

• Operating pressure and volume flow must match the concrete pulverizer, rock and concrete splitter, rock wedge splitter, cutting torch, hydraulic demolition shears, Multi Cutters, or steel shears; over- or undersupply impairs performance and safety.
• Return line, filtration, oil temperature, and leak-tightness of lines must be checked regularly; pressure testing and bleeding prevent cavitation and loss of performance.
• Leakage and burst protection: protective sleeves, retaining chains, and neatly routed lines minimize crushing and tear-off hazards.

Mounting, locking, and operation

• Secure coupling: quick coupler locking systems must close completely; visual and tug test before starting work.
• Operating logic: slowly ramp up pressure, continually follow through, controlled release under load.
• Communication: unambiguous signals, clear lines of sight, and coordinated procedures between operator and safety watch.

Carrier safety on the structure: safe handling of beams, girders, and columns

The load-bearing system remains effective until the last cut. Therefore, load transfer and dismantling sequence must be defined, temporary shoring planned, and self-weight as well as residual stresses reduced in a controlled manner. Components may only be released once their stability and the removal path of masses are secured.

Particularities when using concrete pulverizers

• Crack control: apply closing motion in a controlled manner; observe reinforcement layout to avoid uncontrolled spalling.
• Cutting against support: counter-held areas reduce impact load and prevent unintended redirection of loads.
• Residual connections: do not underestimate remaining reinforcement and hangers; release only when shoring is prepared.

Rock and concrete splitters in existing elements

• Borehole pattern and spacing: even load distribution of the splitting wedges; maintain edge distance to avoid breakout.
• Splitting sequence: work from relieved to loaded zones; monitor crack propagation and set intermediate securing if needed.
• Rock wedge splitter: high splitting forces require robust reaction abutments; consider voids and reinforcement layout.

Applications and typical scenarios

Carrier safety is essential in all fields of application, but the focus varies.

• Concrete demolition and special demolition: concrete pulverizers and hydraulic demolition shears enable controlled dismantling. Load-bearing cross-sections are only processed after shoring or relief.
• Gutting and cutting: in buildings with limited space, handheld tools in combination with hydraulic power packs are common. Cutting and splitting sequences must preserve building stability.
• Rock breakout and tunnel construction: rock and concrete splitters as well as rock wedge splitters work without explosives. Supporting the crown, controlled crack guidance, and stability of the tunnel face secure operations.
• Natural stone extraction: splitting technology enables precise separation. Define fall direction and transport route in advance so that released blocks move in a controlled manner.
• Special operations: cutting torch is used on tanks, pipes, and in sensitive environments. Media-free condition, degassing, and grounding must be verified before cutting.

Planning and hazard assessment

Systematic planning is the basis of carrier safety and aligns technology, personnel, and process.

1. Survey of existing conditions: record structural system, material, reinforcement, prestressing, utilities, media, and access.
2. Method selection: choose concrete pulverizer, rock and concrete splitter, hydraulic demolition shears, Multi Cutters, steel shear, or cutting torch according to structure and boundary conditions.
3. Structural analysis and shoring: secure load paths, size temporary beams and shoring prop, define demolition or splitting sequence.
4. Hydraulic concept: specify hydraulic power packs, line routing, pressure/volume flow, cooling, and leakage precautions.
5. Work and communication routes: plan sight lines, exclusion zones, pick-up and lay-down areas.
6. Emergency and shutdown concept: provide redundancy, orderly pressure relief, and retreat paths.

Legal and normative requirements are to be considered in general; binding individual assessments are carried out by qualified planners.

Technical parameters influencing carrier safety

• Equipment specifications: tool force, jaw opening, splitting force, cutting performance, dead weight.
• Hydraulics: operating pressure, volume flow, return pressure, oil quality, temperature.
• Structure: cross-section, reinforcement ratio, material strength, crack condition, prestressing.
• Dynamics: vibrations, load changes, shock factors, rebound.
• Environment: space constraints, subsoil bearing capacity, weather, visibility, dust, and noise.

Workflows and best practices

• Preparation: visual inspection of concrete pulverizer, rock and concrete splitter, rock wedge splitter, hydraulic demolition shears, Multi Cutters, steel shear, and cutting torch; function test of hydraulic power packs.
• Positioning: align the carrier machine securely, clear exclusion zones, install shoring.
• Smooth start: increase pressure gradually, observe crack formation or cutting path and follow through.
• Controlled release: secure loads, do not allow components to swing or tip unsecured.
• Step-by-step dismantling: prefer small, manageable partial cross-sections; synchronize removal and haulage logistics.
• Regular inspection breaks: check temperature, leaks, and wear; interrupt work if anomalies occur.

Cutting and splitting methods with regard to carrier safety

The choice between shearing, cutting, and splitting depends on material, installation situation, and safety objectives.

• Concrete pulverizers/hydraulic demolition shears: suitable for reinforced concrete; allow selective separation with low vibrations.
• Rock and concrete splitters/rock wedge splitters: non-explosive alternative; crack control and controlled force dosing are crucial.
• Steel shears/Multi Cutters: for sections, reinforcement, tanks, and pipelines; consider cutting sequence and residual stresses.
• Cutting torch: for hollow bodies and vessels; ensure emptying, cleaning, and gas-free condition beforehand.

Material and environmental influences

Moisture, temperature, aging, and corrosion change load-bearing capacity and fracture pattern. Dust, noise, and vibrations affect perception and communication. In tunnels and shafts, ventilation and lighting are critical to safety (tunnel ventilation). Uncertainties are mitigated by measurable checks (e.g., visual inspection, temperature, pressure) and by conservative approaches to force application.

Documentation and evidence

Continuous documentation increases carrier safety and the reproducibility of processes. Recommended are equipment data sheets, hydraulic logs, dismantling sequence plans, shoring concepts, handover and inspection checklists, as well as photo documentation of key steps. Changes on site must be recorded in a traceable manner.

Maintenance, testing, and upkeep

The safe function of concrete pulverizers, rock and concrete splitters, rock wedge splitters, hydraulic demolition shears, Multi Cutters, steel shears, cutting torches, and hydraulic power packs depends on regular care. Wear on blades, jaws, and wedges, hydraulic tightness, completeness of locks, and the condition of hoses and couplings must be checked at regular intervals. Components with safety relevance must be replaced in good time.

Competence and organization

Well-trained teams recognize load paths, correctly assess splitting and cutting behavior, and respond prudently to changes. Instruction, clear responsibilities, and practiced communication are essential elements of carrier safety. General specifications and recognized rules of technology serve as a framework; decisions on site are made situationally and by experts.