Road construction

Road construction combines geometry, geotechnics, materials science, and construction methods into infrastructure that enables traffic to be safe, high-performing, and durable. It encompasses the complete chain from planning and alignment through earth and rock works, layer construction and drainage, all the way to maintenance and deconstruction. In all phases, precise, controllable methods play a central role—for example, in selective concrete demolition with concrete pulverizers or in low-vibration rock break-out using rock and concrete splitters, as deployed in the road corridor, on bridge structures, and in tunnels.

Definition: What is meant by road construction

Road construction refers to the construction, preservation, and deconstruction of traffic surfaces for rolling traffic. This includes unbound and bound base layers, asphalt and concrete surfacings, paver pavements, drainage systems, edge and safety elements, as well as engineering structures such as bridges, retaining walls, and tunnels. Road construction covers the entire life cycle: from subsoil investigation and structural dimensioning through execution to preservation. Deconstruction and rehabilitation works are also part of it, such as the selective removal of concrete components using concrete pulverizers or the break-up of rock along the alignment with rock and concrete splitters, particularly where vibrations, noise, and flying debris must be minimized.

Layer structure and design principles in modern road construction

The layer structure follows the principle of transferring loads step by step into the subgrade while shielding against weather influences. Typical are frost protection layers and unbound base layers, above which are bound base layers or a concrete pavement or asphalt structure. The choice of structure depends on traffic loading, subgrade, and climatic conditions. For concrete pavements, joint layout, load transfer, and edge zones are decisive; for asphalt surfacings, binder selection, aggregate grading, and laydown temperatures determine durability. At tie-ins, bridge transitions, and drainage elements, precision and material compatibility influence service life.

Construction process: From alignment to opening to traffic

The typical process starts with surveying and alignment, followed by subsoil exploration, earth and rock works, and the construction of drainage and utilities. The layers are then placed, compacted, and tested. Finally, the surface is installed, markings are applied, and safety elements are fitted. For existing roads, phases of maintenance, rehabilitation, or selective deconstruction are added, such as removing foundations, curb stones, or pavement slabs. In practice, concrete pulverizers, hydraulic power packs, and rock and concrete splitters are used to separate components in a controlled manner and protect the surroundings.

Building materials and material selection in road construction

Material selection is guided by requirements for load-bearing capacity, durability, noise reduction, and ease of maintenance. Key materials are:

• Unbound layers: frost protection layer, unbound base course made from aggregates with defined gradation
• Bound layers: asphalt base, binder, and surface courses; hydraulically bound base courses
• Concrete: concrete pavements, concrete slabs, components in bridge and edge zones
• Pavers and slabs: for traffic areas of low to medium loading and in urban design contexts
• Edge restraints and drainage elements: curb stones and channel stones, swales, infiltration trenches

For deconstruction and material separation, mechanical-hydraulic methods are suitable. Concrete pulverizers enable targeted separation of concrete, while rock and concrete splitters open rock without blasting. Both methods support source-separated sorting, which facilitates recycling.

Earth and rock works: foundation, slopes, alignment

Earthworks establish the location and shape of the alignment. They include excavation, grading, soil improvement, and compaction. In rocky sections or tight urban settings, low-vibration methods are required. Rock and concrete splitters, as well as rock splitting cylinders, are used for rock break-outs, trenches for utilities, or in tunnel heading as a complement when vibrations and noise must be reduced. In special situations, for example near sensitive structures, controlled splitting can help protect adjacent structures.

Drainage and frost protection

Effective drainage protects the structure from water and frost damage. This includes crossfall, longitudinal gradients, channels, swales, and discharge into infiltration systems. During deconstruction of manhole covers, channels, or concrete swales, concrete pulverizers facilitate selective removal without placing undue load on adjacent surfacings.

Structural details: joints, edges, transitions

Joints in concrete pavements control cracking and ensure load transfer. Edge zones with curbs, channels, and upstands must be dimensionally stable and watertight. Transitions at bridges are highly stressed: precise installation positions, material-compatible sealing, and maintainability are crucial here. For renewals in existing structures, gentle opening of existing edges is advisable. Concrete pulverizers can release concrete components in segments, while steel shears cut reinforcement, for example at bridge caps or abutment edges.

Deconstruction, rehabilitation, and preservation

The life cycle of a road includes recurring maintenance as well as targeted rehabilitation. In deconstruction, the priorities are safety, noise control, dust minimization, and material separation. In the following situations, hydraulic tools are typically used:

• Selective concrete demolition and special deconstruction: separating caps, abutment sections, curb foundations, and concrete slabs with concrete pulverizers
• Strip-out and cutting: opening slabs, walls, and foundations in road and bridge areas, supported by combination shears and multi cutters
• Rock break-out and tunnel construction: rock exposure and profile corrections in tunnel heading using rock and concrete splitters
• Natural stone extraction: aggregates and curb stones—controlled splitting supports quality-compliant piece sizes
• Special applications: work in sensitive areas with stringent requirements for vibration and spall protection

Mobile hydraulic power units supply energy to the connected tools. A tuned hydraulic system facilitates controlled removal, reduces unnecessary peak loads, and supports occupational safety in the road corridor.

Preservation strategies

Preservation is guided by condition data (smoothness, skid resistance, structural condition). For concrete surfaces, crack repairs, slab replacement, and joint rehabilitation are options. For asphalt, measures range from thin overlays to renewal of the base course. If concrete must be removed locally, concrete pulverizers are suitable for controlled release of components; reinforcement can be cut with steel shears. This keeps loads on the remaining structure low.

Machinery and tools in road construction

Alongside large machines such as graders, rollers, and pavers, specialized tools for demolition and deconstruction are used in road construction:

• Concrete pulverizers: targeted gripping, crushing, and releasing of concrete components in existing structures
• Rock and concrete splitters: controlled splitting of rock and massive concrete, with low vibration and without impact
• Combination shears, multi cutters, and steel shears: cutting steel sections, reinforcement, and composite components, for example in bridge deconstruction
• Hydraulic power packs: mobile energy supply for tools on constrained job sites

By combining precise cutting and splitting techniques, components in the road corridor can be deconstructed piece by piece and in position. This protects adjacent utilities, surfacings, and structures, reduces closure times, and eases logistics on constrained construction sites.

Sustainability and circular economy in road construction

Resource conservation means using building materials as long as possible and separating them by type during deconstruction. Selective methods—separating concrete elements with concrete pulverizers or splitting rock and concrete without blasting—can facilitate reuse. Processed materials can serve as recycled construction material in base layers or concretes, provided applicable requirements are met. Holistic considerations also account for emissions, dust, and noise; low-dust cutting and splitting processes support protection of residents and the environment.

Quality assurance, testing, and documentation

Quality assurance covers compaction certificates in earthworks and base layers, smoothness and layer thicknesses, skid resistance, and bearing capacity. Testing is performed during placement and in the finished state. In deconstruction, documenting material flows is important: Which components were separated, how were steel and concrete removed, which recycling routes are intended? The use of precise tools, such as concrete pulverizers and steel shears, supports traceability because components can be dismantled in a defined manner.

Safety and traffic management

Work in the road corridor requires secured work zones, clear traffic management, and protection of personnel. Noise and vibration management must be planned, particularly in dense urban areas, on bridges, or in tunnels. Hydraulic splitting and cutting methods help limit impacts on adjacent components and sensitive systems. Legal and normative requirements must always be checked for currency; they can vary by country, state, and project and must be coordinated with the responsible authorities in each case.

Practical application examples

Typical tasks in road construction where hydraulic tools play a role:

1. Replacement of individual concrete slabs in pavements: open joints, release the slab with concrete pulverizers, cut reinforcement, prepare the bedding, install the new slab
2. Bridge rehabilitation: demolition of caps and edge zones with concrete pulverizers, cutting reinforcement with steel shears, followed by concrete repair
3. Rock break-out along alignments: opening the rock slope with rock and concrete splitters, profile adjustment without blasting-induced vibrations
4. Utility crossings in existing corridors: selective opening of concrete and curb foundations, securing the surroundings, targeted reinstatement
5. Strip-out before surface renewal: removing local concrete build-ups or foundations with combination shears and concrete pulverizers, preparation for new layers

Planning and execution: Good practice at a glance

Clear processes are crucial for long-lasting roads:

• Early subsoil and material analysis, appropriate layer selection, and a robust drainage concept
• Load-appropriate dimensioning of asphalt or concrete structures
• Precise installation with continuous compaction and quality control
• Targeted preservation instead of later major rehabilitation: treat small defects early
• Selective deconstruction with suitable tools, e.g., concrete pulverizers and rock and concrete splitters, to protect existing fabric and facilitate recycling

The result is roads that carry traffic safely, are economical to maintain, and whose materials remain in the cycle at the highest possible quality after service life. The combination of a well-thought-out layer structure, careful drainage, controlled demolition methods, and documented quality assurance forms the foundation for this—both in urban areas and on local roads, federal roads, and highways.