Spraying methods

Spraying methods are indispensable in deconstruction, structural repair, and rock processing. Whether dust suppression during demolition, corrosion protection after exposing reinforcement, or applying shotcrete to secure voids: the targeted atomization and metered application of liquid or pasty media deliver safe, predictable, and reproducible results. In combination with mechanical tools—such as concrete pulverizers as well as hydraulic rock and concrete splitters—spraying methods support a clean separation of work steps, minimize emissions, and prepare surfaces of defined quality for subsequent trades.

Definition: What is meant by spraying method

Spraying method refers to the atomizing application of media such as water, binders, coatings, impregnations, or mortars onto substrates. The input of pressure energy (air, hydraulic or piston pumps), the nozzle geometry, and the material properties (viscosity, solids content) determine droplet size, spray pattern, impact energy, and ultimately the layer thickness or wetting. In construction practice, besides classic coatings, this includes in particular the wet and dry spraying of shotcrete, dust suppression during deconstruction, spraying curing compounds for concrete hardening, as well as applying corrosion protection to exposed metal surfaces.

Classification and delineation in the construction and deconstruction context

Spraying methods are not an end in themselves. They serve as a complementary technique to make mechanical processing—for example with concrete pulverizers, splitting cylinders, or steel shears—safer, cleaner, and quality-assured. While cutting and splitting tools separate material, spray media help bind particles, improve bond, protect surfaces, or temporarily secure excavations and voids. Spraying methods are to be distinguished from brushing or pouring techniques as well as from spinning and dipping processes; common interfaces exist in material preparation and surface cleaning.

Fields of application across use cases

The spectrum ranges from low-dust operations to structural stabilization. The following sections assign typical spraying tasks to the application areas and identify interfaces with relevant tools and devices from Darda GmbH.

Concrete demolition and specialized deconstruction

In selective deconstruction, concrete pulverizers are used to open slab edges, expose reinforcement, and separate components. Water or binder sprays used in parallel reduce the dust load directly in the intervention area. After deconstruction, curing compounds or corrosion protection can be sprayed onto concrete and steel surfaces to control drying or provide temporary passivation. Where concrete cover has been partially removed, repair mortars can be applied by spray to achieve a structural bond.

Strip-out and cutting

When cutting reinforcement and sections with steel shears, multi cutters, or combination shears, spraying methods support fire and spark control (e.g., water mist) and surface preparation for subsequent coatings. Spray primers and adhesion promoters improve the bonding of leveling compounds or fire protection layers. After wet cutting operations, spray equipment aids cleaning, neutralization, and removal of cooling slurries.

Rock demolition and tunneling

Rock loosened by blasting or splitting is often stabilized with shotcrete. The spray application (wet or dry) is matched to geology, moisture, and the desired early load-bearing capacity. Preparatory spray mist suppresses fine dust, while adhesion sprays increase bonding on weathered surfaces. Hydraulic splitters create defined fractures and bearing surfaces that are subsequently secured by the spraying method.

Natural stone extraction

In the extraction and shaping of natural stone, spray mist improves visibility, tool life, and dimensional accuracy. Hydrophobizing or consolidating sprays can temporarily protect edges. When blocks are separated with splitting cylinders, controlled pre-wetting helps reduce spalling and minimize dust generation.

Special operations

In sensitive areas—such as with strict emission control or in occupied existing buildings with the public—finely dosed spray patterns cushion noise and dust peaks when working with compact hydraulic tools. During work on tanks and vessels, the surface can be sprayed with suitable protective layers after cutting to limit corrosion until final finishing.

Types of spraying technology

Different technologies are used depending on the medium and objective. Selection and parameterization directly influence quality, cost-effectiveness, and occupational safety.

• Low-pressure spraying: universal for water, cleaning agents, and curing compounds; large droplets, low rebound tendency, limited reach.
• Airless spraying: high material throughput, fine spray pattern, suitable for coatings and impregnations with higher solids content.
• Air-assisted spraying (Airmix): combination of pressure and air for fine control of droplet size; useful for uniform layer thicknesses.
• Two-component spraying: reactive systems (e.g., mineral or polymer-modified coatings) are mixed only at the nozzle; requires precise dosing.
• Wet and dry spraying of concrete: transport as mortar/concrete mass (wet) or as dry mix with water added at the nozzle (dry); essential for tunnel and slope stabilization.

Material groups for spray applications

The choice of medium depends on substrate, objective, and boundary conditions. In the deconstruction environment, the following groups have proven effective:

• Water and binder solutions for dust suppression and cleaning.
• Curing compounds for concrete to control moisture release and minimize cracking.
• Corrosion protection and passivating layers for exposed reinforcement and steel profiles.
• Hydrophobizations and impregnations to reduce water uptake of surfaces.
• Spray mortars/shotcrete for leveling, securing, and load-bearing action.
• Fire protection and flame-retardant coatings on steel or concrete substrates where required by building codes.

Process parameters and quality assurance

A reproducible result arises from the interplay of material, technology, and execution. Key levers are:

• Viscosity and temperature of the medium: determine atomization and flow.
• Nozzle geometry and wear: influence spray fan, droplet size, and layer thickness.
• Distance and angle: control wetting, rebound, and overlap.
• Substrate preparation: cleanliness, roughness, and residual moisture are critical for adhesion.
• Ambient conditions: wind, humidity, temperature, and substrate temperature affect mist formation and curing.

Tests and measurement methods

For coatings, wet and dry film thickness measurement, pull-off adhesion tests, and cross-cut tests (depending on the system) are suitable. For shotcrete, rebound measurements, core extractions, strength tests, and layer thickness control are common. Documentation with test areas and process protocols supports reliable acceptance.

Interfaces with concrete pulverizers and hydraulic splitters

Mechanical separation and spray-based accompanying processes interlock. Sensible couplings are:

• Dust suppression directly at the point of attack of concrete pulverizers and during splitting: fine spray mist reduces aerosols and improves visibility.
• Surface preparation for repair mortar after removal: after using hydraulic splitters, cleaned, pre-wetted flanks ensure better adhesion of spray mortars.
• Corrosion protection sprays on exposed reinforcement after selective deconstruction: temporary passivation until final repair.
• Edge and joint stabilization: thin spray layers prevent spalling on newly created cut edges.

Selection criteria for the right spraying technology

The right technology results from the place of use, the medium, and the target quality. The following steps support the decision:

1. Define the objective: dust suppression, protection, adhesion improvement, structural load-bearing capacity, or surface finish.
2. Assess the substrate: strength, roughness, moisture and temperature behavior.
3. Determine the medium: chemical compatibility, emissions, reaction time, processing window.
4. Select the technology: low-pressure, airless, air-assisted, or shotcrete; with matching pump and nozzle parameters.
5. Plan boundary conditions: accessibility, hose lengths, energy and water availability, weather.
6. Secure quality: test areas, measurement points, protocols, and rework.

Typical defects and remedies

• Uneven layer thickness: check nozzle, align working distance and speed, plan overlap systematically.
• Beading/lack of adhesion: improve substrate cleaning, check moisture content, use a suitable adhesion promoter.
• Excessive spray mist: reduce nozzle size and pressure, provide wind protection, optimize spray angle.
• Rebound in shotcrete: adjust aggregate grading and water–cement ratio, correct impact energy and angle.
• Premature drying: plan curing, protect the layer from drafts and direct sunlight.

Process-oriented approach from preparation to follow-up

1. Set up the work area: cordon off, cover, and provide protection and collection devices for overspray and wastewater.
2. Mechanical pre-work: selective deconstruction with concrete pulverizers or splitters; define edges, remove loose material.
3. Prepare the substrate: clean, degrease, pre-wet, or dry depending on system requirements.
4. Equip the spraying technology: condition the medium, choose the nozzle, set pressure, perform a function check.
5. Create a test area: fine-tune parameters, check layer build and flow.
6. Production application: uniform pass guidance, defined overlap, continuous monitoring.
7. Quality control: measure layer thickness, check adhesion, keep records.
8. Follow-up work: carry out curing, clean edges, remove protection, dispose of residual materials properly.

Occupational safety, environment, and legal aspects

Spraying methods generate aerosols and may cause substance emissions. Appropriate protective measures—such as respiratory and eye protection, extraction, shielding, and exposure minimization—must be planned. The selection and use of media should follow applicable rules of occupational and environmental safety. This includes observing technical data sheets, proper waste disposal, possible VOC limitations, and coordination with permitting requirements, which can vary regionally.