Crane track

A crane track is the precisely aligned runway on which bridge, semi-gantry, or gantry cranes move loads safely. It links the supporting structure, rail, and power supply into a system that reliably transfers high wheel loads, horizontal forces, and dynamic actions. In existing facilities, tasks such as refurbishment, adaptation, or deconstruction frequently arise. In these cases, low-vibration, controlled separation of concrete and steel plays a decisive role—especially when crane tracks are modified in operating industrial plants, power plant areas, or tunnel construction sites. Tools from Darda GmbH such as concrete crushers as well as rock and concrete splitters are used situationally when components on crane track girders, brackets, or bearings must be released with precision.

Definition: What is meant by a crane track

A crane track refers to the entirety of crane rails, fastening components, grout/underpour, crane track girders, and their support on the primary structure. It forms the runway for crane trolleys in buildings and outdoors. In practice, the term also includes end stops, buffers, rail expansion joints, alignment tolerances, and the interfaces to power feeds.

The crane track transfers vertical and horizontal loads as well as starting, braking, and skewing forces into the structure. In addition to static actions, vibrations, wheelset frequencies, temperature effects, and fatigue are decisive. Proper planning and maintenance ensure that gauge, the difference in elevation between the two rails, and straightness remain within permissible tolerances.

Historical development and current fields of application

Early crane tracks were simple rails on masonry or steel girders. With increasing capacities and travel speeds, standardized rail profiles, elastic interlayers, adjustable clamping systems, and high-strength grout were developed. Today, crane tracks are found in production halls, steel mills, power plants, port facilities, tunnel tubes, and quarries. During conversions and special demolition, crane track components are often partially exposed and selectively removed—such as brackets, concrete bearing areas, steel inserts, or worn rail sections. Depending on boundary conditions, concrete crushers or rock and concrete splitters are suitable means to release components in a material-appropriate manner with minimal impact on the surroundings.

Structure and key components of a crane track

The configuration varies according to crane type, hall geometry, and load spectrum. Typical components are:

• Crane rail: Special profiles that take concentrated wheel loads; often with elastic interlayer for damping.
• Rail fastening: Clamps, bolts, rib plates, and leveling plates for adjustment and force transfer.
• Grout/underpour: Flatness compensation, load-bearing bedding, corrosion and vibration protection.
• Crane track girders: Steel, concrete, or composite girders, often as cross-girders with brackets or as continuous trusses.
• Supports/substructure: Columns, walls, brackets, or cantilevers; decisive for settlements and torsion.
• End stops and buffers: Mechanical limitation of travel, energy dissipation during emergency stops.
• Power supply: Conductor rails or cable carriers for the crane system, to be routed with clearance to the rail.

Loads, actions, and tolerances

Crane tracks must safely carry vertical wheel loads, horizontal transverse and longitudinal forces (starting/braking, skewing), as well as impact and vibration components. Key aspects are:

• Gauge and straightness: Limited deviations prevent skewing, uneven wheel load distribution, and increased wear.
• Elevation/cross-level: Permissible differences between the rails; impermissible differences induce additional forces.
• Vibrations and fatigue: Repeated loads affect the service life of rail fastenings, welds, and girder details.
• Temperature: Length changes require joints and compliant fastenings.

Precise surveying and regular inspections are the basis for operational safety and service life. If deviations occur, adjustments, grout repairs, or rail replacements are required.

Construction types: steel, concrete, and composite

Different systems are used depending on the structural concept:

• Steel girders with mounted rail: High load-bearing capacity, good adjustability, proven in industrial halls.
• Concrete cantilevers and brackets: Rail mounted directly on grout over concrete supports; advantageous for massive frame structures.
• Composite solutions: Combination of steel girders, composite sections, and elastic interlayers for vibration behavior and sound insulation.

In refurbishment of existing structures, reinforcement layouts, shear connectors, and potential crack zones must be known to plan interventions in a controlled manner. Concrete crushers are well-suited to remove cover concrete, expose reinforcement, and shape bearing zones. Rock and concrete splitters enable the creation of cracked separation planes without impact energy—useful in vibration-sensitive environments.

Installation, maintenance, and refurbishment

For a durable crane track, clean bearing surfaces, continuous bedding, correct clamp preload, and documented alignment are key. In maintenance, the focus is on cleaning, visual inspections, retightening, lubrication (where permitted), and periodic surveying.

Typical damage patterns

• Edge spalling and scaling on concrete bearing areas
• Wear and corrugation on rail running surfaces
• Loose clamps, corroded fasteners, settlements in the grout/underpour
• Cracks in brackets and connection details due to transverse forces and torsion
• Impermissible gauge deviations as a result of deformations or settlements

Refurbishment steps in existing structures

1. Survey of gauge, elevation, and straightness; documentation of findings
2. Planned release of fastenings and sections of the rail
3. Controlled removal of grout and damaged concrete areas
4. Reprofiling/strengthening of the bearing zone; re-grouting and adjustment
5. Installation and final alignment; functional test and acceptance

When removing concrete bearing areas in the immediate vicinity of the rail, concrete crushers reduce dust and vibrations compared to percussive tools. Where massive components must be split (e.g., cantilevers or stub brackets), rock and concrete splitters allow a defined crack path without damaging adjacent components.

Crane track in deconstruction: controlled separation and removal

In the concrete demolition and special demolition of crane tracks, the sequence is crucial: first securing, then dismantling the rails, followed by selective removal of grout and bearing components. For steel components such as rail sections, rib plates, or brackets, steel shears and multi cutters are suitable. Combination shears are used for releasing reinforcement and exposing anchor zones. Where high material thicknesses are present, the use of high-performance cutting devices may be required. For adjacent concrete structures, concrete crushers and rock and concrete splitters are the tools of choice to separate components with low vibration—especially for special operations in sensitive environments or under ongoing production. Hydraulic power units from Darda GmbH supply the tools with the required drive power.

Crane track in tunneling and power plant construction

In caverns, shafts, and tunnel tubes, temporary or permanent crane tracks are used to move installations. The substructure may consist of steel yokes, composite plates, or bearing areas integrated into rock. When creating such bearings—such as fitting seating surfaces into rock or removing defects in concrete—rock and concrete splitters assist through controlled crack formation. For later adjustments or deconstruction, concrete crushers enable dimensionally accurate removal of concrete without excessive vibration, which is particularly important in hydraulic installations and tunnels.

Planning aspects and interfaces

A crane track is always an interface between structure, crane, and operations. For new construction as well as refurbishment, consider:

• Load assumptions and crane duty cycles, including braking and acceleration phases
• Vibration and noise protection in sensitive areas
• Corrosion protection, drainage, and cleaning options
• Accessibility for inspection and adjustment
• Deconstruction concept for later life-cycle phases

During strip-out and cutting of hall areas around the crane track, coordination with utility runs, cable trays, and fire protection is essential. Selective separation with concrete crushers and rock and concrete splitters supports orderly construction sequencing and reduces consequential damage.

Measurement and testing practice

The quality of a crane track is reflected in the adherence to gauge, elevation, straightness, and parallelism. Common practices include:

• Geometric measurements by leveling, tacheometry, or laser scans
• Visual and functional inspections of fastening systems
• Checking the grout/underpour for voids and bond
• Inspection of end stops and buffers

Results feed into maintenance plans. If deviations are found, adjustments, grout repairs, or the replacement of rail sections are scheduled. For preparatory work—such as exposing anchor heads or locally removing concrete in bearing areas—concrete crushers provide precise performance.

Material-appropriate working methods in existing structures

The choice of method depends on the goal, the component, and the environment:

• Low vibration: Rock and concrete splitters for defined cracks without impact energy
• Selective: Concrete crushers for edge-near removal, opening reinforcement cages, and exposing embedded parts
• Metalworking: Shears and cutters for rails, rib plates, anchors, and web plates

These methods support an orderly deconstruction of the crane track in the spirit of concrete demolition and special demolition and reduce impacts on adjacent production areas.