Crane control

Crane control is a central component of many workflows on construction sites for concrete demolition, interior demolition, tunnel construction, and natural stone extraction. Precise, sensitive, and safe crane movements are required to guide components, secure loads, and deploy tools such as concrete demolition shears, hydraulic wedge splitters or hydraulic power packs ergonomically and purposefully. Especially in special demolition, the quality of crane operation determines occupational safety, cycle times, and the quality of the cutting or splitting result.

Definition: What is meant by crane control

Crane control refers to the entirety of operating elements, control algorithms, and safety functions used to initiate, meter, and monitor the hoisting, slewing, and traveling motions of a crane. This includes manual inputs (e.g., joysticks), electrical and hydraulic control loops, as well as assistance systems that limit load moments and working areas. The goal is safe load handling with reproducible precision—from coarse positioning and lifting to micro-movements at the target point. In demolition and extraction work, crane control is often coordinated with the control of hydraulic tools, for example when components are preloaded, held, or lowered during cutting, crushing, or splitting.

Fundamentals of crane control on demolition and extraction sites

On sites involving concrete demolition, interior demolition, rock excavation, and natural stone extraction, crane control must govern load movements while supporting the work process of the tools used. When using concrete demolition shears, components are often held under slight preload to relieve the cut. Hydraulic wedge splitters generate forces in the material that can affect load position; crane control compensates for these influences with calm, finely metered movements. Critical factors are sway-reduced acceleration ramps, low terminal speeds, precise angle corrections, and clear working area limits—especially in tight building structures, at edges, shafts, or in tunnels.

Control types and operating elements

Manual operation at the control station

Manual crane operation is performed via joysticks or levers for the hoist, trolley travel, and slewing gear. Proportional valves and sensitive characteristic curves enable gentle starts and stops. For demolition and cutting work, micrometer-precise metering is important to support components with minimal stress without deforming them. A clear separation of axis movements (lift first, then slew) helps minimize load sway.

Radio remote control and assistance functions

Radio remote controls improve situational awareness and allow work with direct line of sight to the tool and the cutting interface. Assistance functions such as working area limits, load-moment monitoring, wind warnings, or sway-reduced motion profiles increase process safety. For tandem lifts or parallel load handling (e.g., lowering large slabs after using concrete demolition shears), synchronization functions are helpful. Emergency stop, limit switches, and gentle speed profiles support safe operation.

Interfaces to hydraulic tools and power units

Hydraulic tools are often supplied by hydraulic power packs that are positioned separately and remote-controlled. Crane control must always consider the position of hoses, power units, and tools. Hose routing should be planned to avoid kinks, crushing, and tensile loads. When switching between tension and compression situations (e.g., after a splitting operation), movements should be cushioned smoothly to prevent hydraulic pressure spikes and load shocks.

Concrete demolition shears under the hook

In practice, concrete demolition shears are often combined with load-bearing devices; crane control then assumes the load handling of the component to be separated. Typical steps include slight preloading before biting, controlled following during the cut, and targeted setting down of the segment. Preventing jamming is important: crane motion opens the cutting gap minimally so the shear can cut or crush evenly. Slewing movements must be performed very slowly to limit load sway under changing resistance.

Hydraulic wedge splitters in combination with cranes

When using hydraulic wedge splitters at height or over obstacles, the crane positions the splitting cylinders precisely in boreholes or joints. During splitting, the load geometry changes: the crane holds the target position, compensates for the material’s slight give, and prevents uncontrolled movement. In natural stone extraction, blocks are released from the bed after splitting with minimal dynamics to avoid cracks. In rock demolition and tunnel construction, crane control maintains a safe distance to the tool operation and protects personnel through calm, predictable movements.

Workflows: From planning to execution

• Work preparation: Determine load data, center of gravity, hitch points, and the structure’s residual load-bearing capacity. Define the working area and access/egress routes.
• Tool logistics: Plan the position of the hydraulic power pack, specify hose lengths, keep start/stop and emergency stop within reach.
• Communication: Assign a signaller, agree on hand signals and radio discipline. Clearly separate responsibilities for crane and tool operation.
• Trial movements: Test slow start and stop profiles, dampen sway, determine deadband.
• Processing: During cutting, crushing, or splitting, apply slight preload to the load, correct movement only as needed, monitor tool pressure.
• Removal and set-down: Stabilize the load, protect edges, keep set-down areas clear. Check hose routing and tool position.

Load handling, sway damping, and micro-movements

Load sway arises from abrupt accelerations, wind, or asymmetrical load distribution. Crane control counters this with soft ramps, short path impulses, and preferably separated axis movement. Tag lines can reduce tendencies to rotate. With concrete demolition shears, a slight preload on the component helps support the opening of the cutting gap. During splitting, micro-movements are performed only when the stress conditions in the material change—otherwise the load remains still so the tool can work.

Fine loads in interior demolition and cutting

During interior demolition, cranes often move small, delicate loads, for example partition walls, building services, or bundles of lines that were previously separated with Multi Cutters, steel shears, or a cutting torch. The key is to work with minimal speeds and short dwell points to avoid vibrations and prevent damage at interfaces.

Safety and protective functions

Crane control includes protective functions such as load-moment and working area limits, limit switches, emergency stop, as well as alerts for unfavorable environmental conditions. For concrete demolition and special demolition, conservative speeds, clear communication rules, and defined retreat zones have proven effective. Legally binding requirements arise from the applicable standards, operating manuals, and company regulations; these must be observed for each project.

1. Daily functional check of emergency stop, signals, and limit switches.
2. Inspection of slings, hooks, and safeties before each lift.
3. Keep the working area clear; coordinate with all involved trades.
4. Check wind, visibility, ground, and load-bearing capacity; adjust speeds.
5. Stress-free set-down and controlled release of slings.

Application-specific considerations

Concrete demolition and special demolition

In the deconstruction of reinforced concrete, varying forces act. Crane control holds components in a defined position while concrete demolition shears or hydraulic demolition shears separate reinforcement and concrete. Preventing binding and unloading in time before the final cut are crucial to exclude uncontrolled load movement.

Rock excavation and tunnel construction

In underground areas, visibility, space, and ventilation are limited. Crane control must feed tools precisely and slowly. When using hydraulic wedge splitters, sudden give must be expected; movements are therefore anticipated and performed at very low speeds.

Natural stone extraction

After splitting blocks, sway-reduced lifting operations lead to less material loss and better surfaces. Slight corrections in tilt and rotation prevent edge damage. Setting down on soft interlayers reduces impact loads.

Interior demolition and cutting

Under confined conditions, radio remote control improves the view of cutting interfaces. After using Multi Cutters, steel shears, or a cutting torch, crane control ensures metered lowering of lines, tanks, or sections without unwanted rotation.

Special operations

In sensitive areas (e.g., at historic structures), low vibration levels and millimeter-accurate positioning take priority. Motion profiles are reduced further; micro-movements occur in short pulses with longer rest phases.

Practical checklists

• Before the lift: Verify load data, attachment points, working area, and escape routes; check the tool, hydraulic power packs, and hose routing.
• During the lift: Actively apply sway damping, separate axis movements, keep speeds low, maintain line of sight.
• During cutting/splitting: Apply slight preload, no jerks; monitor tool pressure and component behavior; only targeted micro-movements.
• After the lift: Set down without stress, release slings, secure tools, relieve and inspect lines.

Typical error sources and countermeasures

• Overcontrol and sway build-up: Countermeasure—start gently, separate axes, use short correction impulses.
• Lack of communication: Countermeasure—assign a signaller, clear hand signals, radio discipline.
• Jamming during cutting: Countermeasure—crane control applies slight preload, keep the cutting gap open.
• Unplanned load shift during splitting: Countermeasure—micro-movements only as needed, keep the load under control at all times.
• Hose damage: Countermeasure—defined hose routes, kink protection, no torsion.

Terminology and system boundaries

Crane control denotes the technical and operational implementation of motions and protective functions. It is to be distinguished from operative crane operation (work planning, communication, slinging). In practice, both areas interlock. The limits of crane control are reached where structural conditions, wind, visibility, and load-bearing capacity require adjustments. Tools and equipment from Darda GmbH such as concrete demolition shears or hydraulic wedge splitters are complemented by forward-looking crane control: calm movements, defined preload, and clear working area limits provide the basis for safe, clean, and efficient workflows.