Recycled concrete

recycled concrete combines resource conservation with technical performance. It is produced from recycled aggregates obtained during selective deconstruction of structures. Quality and suitability stand and fall with a clean process chain: precise demolition, single-grade separation, professional processing, reliable quality monitoring, and an adapted mix design. Tools such as concrete demolition shears and hydraulic rock and concrete splitters from Darda GmbH make a decisive contribution because they gently release material, separate reinforcement, and minimize contaminants—an essential prerequisite for high-quality RC aggregates in load-bearing applications.

Definition: What is meant by recycled concrete

Recycled concrete (RC concrete) is concrete in which natural aggregates are wholly or partially replaced by recycled aggregates from mineral construction and demolition waste. Common are aggregates from concrete debris, possibly with defined proportions of masonry debris. The term covers both concretes for structural components and for non-load-bearing components, traffic areas, or sub-bases, provided that proof of suitability is furnished. Execution follows recognized rules of technology (e.g., national implementations of DIN EN 206 and DIN 1045-2). Key parameters include origin and purity of the RC aggregate, grading curve, water absorption, bulk density, foreign substance content, and durability criteria.

Recovery and processing of recycled aggregates

The quality of RC concrete begins with deconstruction. The more single-grade the separation, the higher the material recyclability. Selective methods using concrete demolition shears and hydraulic wedge splitters from Darda GmbH produce large, clean pieces with a low fines content. Reinforcement is exposed and can be separated with precision steel shears or combination shears; hydraulic power units supply all tools reliably.

Crushing and screening technology

After the initial size reduction come crushing (e.g., jaw, impact, or cone crushers), screening, and removal of impurities (magnetic separators, air classifiers). The goal is a target-compliant grading curve with defined size classes. Carefully prepared chunks from shear or splitter processes can be crushed more energy-efficiently and deliver lower mortar adhesions—a plus for density, strength, and durability of RC concrete.

Purity and contaminants

Foreign substances such as wood, plastics, gypsum, bitumen, asbestos, or chloride-bearing adhesions must be avoided. Clean strip-out and controlled separation of attachments—using, for example, Multi Cutters or steel shears from Darda GmbH—reduces contamination. For high-end applications, RC aggregate obtained from concrete debris is preferred; mixed aggregates require particularly careful suitability testing.

Selective deconstruction: Influence of the demolition method on RC quality

Deconstruction with concrete demolition shears allows targeted breaking of components, separation of reinforcement, and minimization of fines. Hydraulic wedge splitters and splitting cylinders act in a controlled manner, generate low vibrations, and reduce cracking in adjacent components—a benefit in sensitive environments of concrete demolition and special demolition as well as during gutting works and cutting. Compared to impact-intensive methods, dust and noise emissions are reduced, and RC aggregate achieves higher purity. This process quality directly benefits the subsequent concrete properties.

Mix design, properties, and durability

Recycled aggregates often have higher water absorption and lower bulk density than natural aggregate. The mix design accounts for this through adjusted water addition, pre-wetting of the RC aggregate if necessary, the use of high-performance admixtures, and an optimized grading curve. For durability, freeze–thaw deicing-salt resistance, chloride diffusion, carbonation, and avoidance of an alkali–silica reaction (ASR) must be taken into account. Systematic suitability verification ensures that the required exposure and strength classes are achieved.

Typical replacement rates and particle size ranges

Partial replacement rates in the coarse fraction have proven effective; fine RC fractions are used cautiously to control water demand and workability. The cleaner and denser the RC aggregate, the higher the replacement rates that can be used in load-bearing applications—subject to project-specific suitability verification.

Influence on fresh and hardened concrete

Fresh concrete with RC aggregate often shows increased water demand and altered viscosity. With suitable superplasticizers and a stable grading curve, good workability can be achieved. In hardened concrete, compressive strengths of comparable classes can be reached; the modulus of elasticity and density are typically somewhat lower. Durability parameters depend strongly on the purity and mortar adhesion of the RC aggregate.

Standards, quality assurance, and quality monitoring

The use of recycled concrete takes place within recognized rules of technology (including national regulations of DIN EN 206 and DIN 1045-2). Project stakeholders define requirements for strength, exposure classes, freeze–thaw deicing-salt resistance, and maximum contents of foreign substances. Continuous quality monitoring of the RC aggregate is recommended.

• Incoming goods inspection: origin, delivery note, batch traceability
• Verification of the grading curve and fines content
• Determination of water absorption and bulk density
• Foreign substance content and mortar adhesion
• Suitability verification for the intended application
• Documentation, if applicable Environmental Product Declaration (EPD) from the supplier

Specifications for normative limit values and test procedures must be verified on a project- and country-specific basis. The guidance described here is general and non-binding.

Fields of application and design notes

Recycled concrete is used in building and structural engineering, for example in walls, slabs, foundations, retaining structures, and traffic areas—depending on exposure and proof of suitability. For components with high durability requirements, the RC aggregate and the mix must be selected particularly carefully. Concrete demolition and special demolition with precise tools from Darda GmbH create the conditions for RC concretes even in demanding projects. During gutting works and cutting, Multi Cutters and steel shears facilitate single-grade separation; this reduces contaminants in the RC cycle.

Life cycle assessment, CO2, and transport distances

RC concrete can reduce the carbon footprint, primarily through avoided primary raw materials and shorter transport routes. In the LCA, several levers interact:

• Substitution rate and quality of the RC aggregate
• Energy and emissions profile of the processing plant
• Transport distances from demolition site, processing facility, and concrete plant
• Cement content and binder strategy
• Construction logistics and efficient site processes

Project-specific assessments—ideally with EPD data—show the actual effect. Short, well-coordinated material cycles are ecologically advantageous.

Process chain: From deconstruction to RC concreting

1. Survey of the existing structure and planning of selective deconstruction
2. Strip-out, single-grade separation of installations and inserts
3. Primary size reduction with concrete demolition shears or hydraulic wedge splitters from Darda GmbH
4. Separation of reinforcement with steel shears or combination shears
5. Crushing, screening, separation, and quality control of the RC aggregate
6. Mix design, suitability verification, trial concretes
7. Production, placement, curing, and documentation

Site organization, occupational safety, and special deployment

Controlled methods reduce dust, noise, and vibrations—important in inner-city locations, hospitals, or heritage environments. Hydraulic wedge splitters operate virtually vibration-free and are also suitable for special deployments and sensitive sections in rock excavation and tunnel construction. Good logistics with clear material flows and separate storage areas ensure the purity of the RC aggregate.

Typical sources of error and how to avoid them

• Insufficient separation during deconstruction: select early, separate installations with Multi Cutters, separate reinforcement with steel shears
• High fines content: use shear- or splitter-based primary size reduction, optimize crushing stages
• Lack of moisture control: pre-wet RC aggregate or dynamically adjust water addition
• Unsuitable grading curve: monitor grading curves and ensure target size ranges
• Unclear suitability: testing, suitability verification, and documentation before production start

Contractual and documentation aspects

Specifications should clearly define the origin and quality of the RC aggregate, test intervals, exposure classes, and documentation obligations. Agreements on transport routes, intermediate storage, and traceability increase planning reliability. Legal requirements and standards must be checked on a project-specific basis; the statements here are non-binding and do not replace a case-by-case review.