Concrete curing

The curing of concrete determines the strength, impermeability, and durability of a structure—and it influences how components can later undergo concrete cutting, be split, or be selectively deconstructed. In construction practice and deconstruction, for example in concrete demolition and selective deconstruction, gutting works and concrete cutting, or in tunnel construction, the precision and safety of the work steps depend on the quality of curing. This applies in particular where a concrete pulverizer or a concrete splitter is used and controlled cracks, defined break lines, and minimal edge spalling are required.

Definition: What is meant by concrete curing

Concrete curing encompasses all measures taken after placing and compaction to control moisture and temperature in the concrete so that cement hydration can proceed undisturbed. The aim is to avoid early shrinkage, capillary cracking, harmful temperature gradients, and drying of the surface zone, to build up sufficient surface tensile strength, and to achieve the specified compressive strength as well as resistance to actions (e.g., freeze–thaw with de-icing salts, concrete carbonation, chloride contamination). Curing begins as soon as the surface is workable and continues until the concrete has reached a sufficient level of hydration and moisture.

Fundamentals of hydration and target parameters of curing

Cement hydration is a chemical process that requires water and a suitable temperature. Evaporation that is too rapid prevents complete hydration in the surface zone; excessive cooling slows the reaction, while elevated temperatures in massive components can lead to harmful temperature gradients. Key targets of curing are a sufficiently low evaporation rate at the surface, controlled temperature management, early assurance of surface tensile strength, and a defined moisture profile across the cross-section. These parameters largely determine how the concrete can later be mechanically processed—whether it can, for example, be broken with a concrete pulverizer with stable edges or split in a controlled manner using rock and concrete splitters.

Influencing factors: weather, concrete composition, and component geometry

The curing strategy is based on external conditions and the properties of the concrete.

• Weather: Wind, solar radiation, air temperature, and humidity govern evaporation. High evaporation rates require more intensive moisture-protection measures.
• Concrete composition: Water-to-binder ratio, cement type, additives, and admixtures influence heat development, setting behavior, and shrinkage.
• Component geometry: Thin elements dry out faster; massive components tend to develop temperature stresses. Edges, upstands, and exposed surfaces are particularly sensitive.
• Constraints from follow-on trades: Planned concrete cutting, core drilling, deconstruction, or later splitting with a hydraulic wedge splitter require a robust surface zone and areas with as few cracks as possible.

Methods of curing: moisture and temperature control

Moisture-retaining coverings

Immediately after initial set, surfaces are covered with wet cloths, mats, or films. The covering minimizes evaporation and keeps moisture within the component. For exposed concrete, it reduces uneven color changes and fine surface cracking.

Misting and sprinkling

Regular, gentle wetting prevents the surface zone from drying out. Ensure uniform water films; spot “watering” at high pressure can damage fresh surfaces.

Membrane-forming curing compounds

Liquid agents that create a temporary evaporation barrier are particularly practical for large areas. Later coatings or bonded layers must be considered when selecting products, as residual films can affect adhesion.

Leaving the formwork in place

Keeping the formwork in place longer provides physical moisture and temperature protection. Edges and exposed surfaces require additional safeguarding.

Temperature management

In hot conditions, shading, evaporation control, and work during night-time hours are useful. In cold seasons, suitable minimum temperatures, protective covers, or heated enclosures help to avoid interrupting hydration.

Curing duration and release criteria

The duration depends on cement type, exposure conditions, component thickness, and ambient climate. Practical release criteria include adequately developed surface tensile strength, attainment of defined early strengths, and a moisture content that permits subsequent work steps. In general: The more critical the boundary conditions (strong wind, sun, low temperatures), the longer and more intensive the curing must be.

Summer and winter conditions: special measures

Hot, dry, windy

• Early covering, shading, and evaporation control before drying starts.
• Moisture-retaining mats or membrane compounds immediately after initial set.
• Use cooler placement times; observe mix temperatures.

Cold, damp, frost-prone

• Protection against cooling with coverings or enclosures.
• Prevent frost in the early phase; do not allow water accumulations to freeze.
• Sufficiently long curing, since hydration proceeds more slowly at low temperatures.

Impact of curing on concrete demolition and special demolition

The quality of curing shapes later fracture and splitting behavior. Well-cured surface zones exhibit higher surface tensile strength and fewer microcracks. This facilitates controlled removal methods and reduces unwanted spalling.

• Concrete pulverizer: Homogeneous, moisture-cured surfaces break with more stable edges; corners remain more defined. Insufficient curing more often leads to breakouts, complicating precise separation during selective deconstruction.
• Concrete splitter: The splitting pattern depends largely on fracture toughness and moisture content. Evenly cured concrete enables predictable crack paths and clean split joints, for example for openings in existing structures.
• Hydraulic power pack and hydraulic demolition shear: During gutting works and concrete cutting, follow-on tasks must be aligned with the achieved early strength so that clamping, gripping, and cutting can proceed without damage to adjacent components.

Practical effect: Careful curing reduces rework during removal, lowers dust exposure due to less brittle surface zones, and supports controlled load transfer during selective deconstruction.

Gutting works and cutting: surface condition and surface-zone strength

Interior components are often needed early for gutting works, core drilling, and concrete cutting. Sufficient surface tensile strength is essential so that grippers, shears, or cutting devices create defined edges. Properly cured concrete can be cut more cleanly; tool wear may decrease because breakouts and rework are reduced. For edge openings, chases, and precision drillings, a moisture-cured surface has a positive effect due to reduced microcracking.

Rock breakout, tunnel construction, and shotcrete

In tunnel construction, shotcrete is frequently used as a stabilization measure. Curing is also relevant here: moisture retention and temperature control are critical to avoid early shrinkage, particle dusting, and weak surface zones. For downstream activities—such as the controlled removal of shotcrete linings or creating openings—well-cured layers improve the predictability of fracture behavior, which supports the targeted use of a concrete pulverizer. In rock breakout itself, curing is naturally not applicable; however, moisture and temperature in the surroundings still play a role where concrete members connect to rock and need to be selectively separated later.

Exposed concrete, edges, and detail points

For exposed concrete, curing is part of the surface quality. Uniform moisture control reduces mottling and fine cracking. This is not only relevant visually: edges, upstands, and façade elements benefit during deconstruction, as defined break lines are more likely to be preserved with a concrete pulverizer. For repair mortars and reprofiling, coordinated curing is important so that transitions are load-bearing and cut-resistant, supporting high-quality concrete repair.

Environmental, safety, and organizational aspects

• Water management: Excess water from curing must be drained in a controlled way; discharges into soil or bodies of water are to be avoided.
• Curing compounds: Residues can affect the adhesion of later coatings or bonds; plan selection and removal accordingly.
• Occupational safety: Moist surfaces reduce dust exposure during early processing steps. At the same time, beware of slip hazards and ensure safe access routes.
• Process coordination: Integrate curing times into work planning, e.g., prior to gutting works, concrete cutting, or the use of hydraulic equipment.

Documentation and quality assurance

Simple documentation of boundary conditions (temperature, wind, humidity), the methods used, and curing duration increases execution reliability. Practical checks—such as assessing surface tensile strength or verifying the attainment of defined early strengths—help to reliably release follow-on activities like cutting, splitting, or gripping. Note: Applicable standards and guidelines (e.g., DIN standard) are authoritative; project-specific requirements may go beyond them.

Typical mistakes and their consequences in deconstruction

• Drying too early: Capillary cracks and weak surface zones make it harder to achieve clean break lines with a concrete pulverizer.
• Insufficient edge protection: Spalling and breakouts at upstands; increased rework during selective removal.
• Uneven temperature control: Cracking due to temperature gradients, problematic for precise concrete cutting and splitting.
• Unsuitable curing compounds: Adhesion issues for later coatings or bonded layers; additional removal steps required.

Practice-oriented approach for site execution and deconstruction planning

1. Check boundary conditions before concreting: evaporation risk, component geometry, cement type, follow-on trades.
2. Organize curing immediately: have coverings ready, plan moisture retention, and provide for temperature management.
3. Monitor surface condition: ensure uniform moisture, protect edges additionally.
4. Release follow-on work based on suitable criteria: adequate early strengths and surface tensile strength, especially before gutting works or using a concrete pulverizer and a concrete splitter.
5. Align the deconstruction and cutting concept with the curing plan: the goals are defined break lines, minimal edge spalling, and safe crack guidance.

Tool selection in the context of curing

For selective separation of concrete after sufficient curing, equipment with controllable force transmission is recommended:

• Concrete pulverizer for edge-near, precise removal during gutting works and selective deconstruction.
• Concrete splitter for targeted crack initiation along predetermined breaking lines.
• Hydraulic power pack as the power source for mobile, low-noise, and low-vibration applications in sensitive areas.
• Hydraulic demolition shear and steel shears for follow-on work on reinforcement, embedded parts, and attachments once concrete sections have been removed.

The effectiveness of these methods increases when proper concrete curing has produced a homogeneous, load-bearing, and low-crack surface zone.