Dust protection

Dust protection is a central topic in demolition, deconstruction and the extraction of mineral raw materials. Wherever concrete, natural stone or reinforced concrete are separated, crushed, split or cut, fine particles are generated that burden health, wear out machines, impair visibility and precision, and can affect the surroundings and neighbors. A systematic, well-planned dust protection increases occupational safety, improves work quality and reduces consequential costs—especially in areas such as concrete demolition and deconstruction, gutting works and cutting, rock breakout and tunnel construction, natural stone extraction as well as special assignments. Tools and methods by Darda GmbH—such as concrete demolition shears or stone and concrete splitters—can be integrated into low-dust workflows when technology, organization and personal protective measures are sensibly combined.

Definition: What is meant by dust protection

Dust protection comprises all measures that prevent or minimize the generation, release and spread of mineral and metallic dust on the construction site. This includes technical solutions (for example water mist, point extraction, enclosures), organizational measures (workflow planning, zoning, cleaning regimes) as well as personal protective measures (respiratory protection, safety glasses). The goal is to reduce dust emissions at the source, prevent spread, and keep immissions at the workplace and in the surroundings as low as possible. In the context of concrete and natural stone, especially fine, alveoli-penetrating particles are relevant, which can arise during breaking, crushing, separating and drilling.

Fundamentals of dust protection on demolition and construction sites

Dust protection starts at the source. The less material is mechanically removed, ground or sawn, the lower the dust load. Methods that rely on controlled splitting or crushing—such as stone and concrete splitters or concrete demolition shears by Darda GmbH—generally produce less fine dust than rotating or grinding tools. Nevertheless, even low-dust methods need additions such as water mist directly at the attack point, local dust extraction and consistent guidance of airflows. An effective strategy follows the principle Avoid – Reduce – Bind – Extract – Clean – Protect and thus combines technical, organizational and personal measures.

Causes, particle types and risks of construction dust

Construction dust is generated when separating, breaking, drilling, milling, grinding, sawing and sorting. It varies in composition and particle size—from coarse material abrasion to the finest “concrete flour” or quartz-bearing fine dust. The smaller the particles, the deeper they can penetrate into the respiratory tract. Corrosion and abrasion on steel or reinforcement also generate metallic dust, which—besides spark formation—must be taken into account from a safety perspective.

• Generation processes: Crushing and pressing (e.g., with concrete demolition shears), splitting (e.g., stone and concrete splitters), separating and cutting (e.g., during gutting works), drilling ahead of splitting operations.
• Materials: Concrete, reinforced concrete, natural stone, masonry, asphalt, metals (reinforcement/steel sections).
• Particle sizes: Visible coarse dust (deposited), inhalable dust (PM10) and fine dust (PM2.5 and smaller).

Dust protection in concrete demolition and special demolition

In concrete demolition, the choice of method decisively influences dust generation. Concrete demolition shears operate impact-free and often produce less widespread dust than percussive or grinding methods, especially in selective deconstruction. Water mist at the shear jaws effectively binds released particles. For massive components, combinations of predrilling, controlled splitting and subsequent downsizing can realize a lower-dust sequence.

Concrete demolition shears: targeted downsizing with a smaller dust plume

During crushing, the concrete matrix opens and reinforcement is exposed. Dust arises locally at the fracture edges. Recommended are short working strokes with frequent material changes, water mist near the fracture zone, and point extraction at the breakout edge. Clean material logistics (separate placement for concrete and reinforcement) reduces rework and thus further dust sources.

Stone and concrete splitters: split rather than grind

Hydraulic splitting separates material along defined cracks without abrasive grinding; hydraulic rock and concrete splitters significantly reduce fine dust. Preparatory steps such as drilling the holes can, however, generate relevant dust quantities—here, borehole extraction and water addition are crucial. Rock wedge splitters support controlled opening of the crack; removal of the split segments should be organized as low-dust as possible (short drop heights, wetted impact areas).

Technical measures: water, extraction, enclosure

Technical solutions act at the emission source and along the air pathways. They form the backbone of effective dust protection and should be combined to suit the project.

Water mist and wet methods

• Source-near wetting: Fine mist directly at the shear, splitting wedge or cutting edge binds particles without soaking the component.
• Dosage: As much as necessary, as little as possible—avoid puddles to minimize slurry and slipping hazards.
• Seasons: Watch for icing in winter; plan tempered water or flexible hoses.
• Disposal: Collect slurry and drill cuttings as damp material and dispose of them properly—avoid dry sweeping.

Point extraction and air cleaning

Source-close extraction with high volume flow and suitable filter grade retains particles before they disperse. Air cleaners with multi-stage filters can maintain enclosures at slight negative pressure so that dust does not escape into adjacent areas. Decisive are short intake paths, aerodynamically favorable hoods and clear guidance of exhaust air (preferably out of the work area).

Enclosures and dust locks

Temporary enclosures separate dust-intensive zones from sensitive areas. Film walls, frame constructions and dust locks enable material transport without “opening” the area. The interplay of enclosure, negative pressure and regular cleaning is particularly effective for gutting works and cutting in existing buildings.

Organizational measures and personal protective equipment

Technology is effective only in conjunction with well-designed workflows and suitable PPE. Responsibilities, traffic routes and cleaning intervals should be defined before work begins.

Zoning, logistics and cleaning

• Control access: Only essential personnel in the dust-exposed area.
• Separate material flows: Remove demolition debris, reinforcement and fine fractions separately.
• Clean wet or with a suitable vacuum; avoid dry sweeping and compressed air.
• Keep routes and egress paths low-dust; use mats or tacky films at transitions to minimize carryover.

PPE and training

• Respiratory protection with suitable protection level, worn with a proper fit.
• Eye and hand protection, robust work clothing; consider skin protection for wet work.
• Training on hazards, equipment operation, change intervals for filters and behavior in case of malfunctions.

Dust protection in gutting works and cutting

Interior work requires special care: low air volume, sensitive environments and frequent personnel movement increase the risk of dust transfer. When separating masonry, deconstructing floor buildups or cutting lines, enclosures, negative pressure, point extraction and consistent wet suppression help. Tank cutters, steel shears, combination shears and multi cutters are mainly used on metallic components; here, less mineral fine dust typically occurs, but sparks and metal particles can arise—therefore protect the surroundings and create zones with low fire load.

Rock breakout, tunnel construction and natural stone extraction

In rock breakout and tunnel construction, dust is especially critical due to limited air volumes. Stone and concrete splitters as well as rock wedge splitters enable controlled separation with low fine dust generation. Consistent dust management during drilling (extraction, wetting) and air exchange with clear flow direction remain necessary. In natural stone extraction, splitting reduces fine particle formation compared to grinding methods; organize transport and dumping with reduced heights and wetted impact areas.

Material separation: reinforced concrete and reinforcement

When exposing reinforcement, fracture edges and particles are created—this is where concrete demolition shears play to their strengths, especially in combination with water mist and short drop heights of the chunks. Steel shears or combination shears are suitable for cutting reinforcement; metal chips are heavier and settle faster, but should still not be blown off dry—instead vacuumed or picked up damp. A clear sequence (first separate mineral material, then cut metal) reduces cross-contamination and secondary dust.

Planning and sequence of measures

A low-dust workflow can be planned. Even during work preparation, risks can be identified and measures defined.

1. Analysis: Components, materials, strength, reinforcement, accessibility, sensitive existing fabric.
2. Choice of method: Split where possible, otherwise crush/separate; use rotating grinding methods only if no alternative exists.
3. Technology package: Source-near wetting, point extraction, enclosure/negative pressure, airflow control.
4. Logistics: Material routes, intermediate storage, disposal of slurry and drill cuttings.
5. PPE and training: Selection, fit, wearing times, spare parts/filters.
6. Control: Indicative measurements, visual inspections, documentation and adjustment.

Measurement, control and documentation

Indicative measurements and visual inspections help assess the effectiveness of dust protection measures. In sensitive areas, continuous monitoring of air quality (for example, particle counting for coarse trend analysis) has proven itself. Results should be documented and linked to the measures used. Legal requirements can vary by country, region and activity; compliance with applicable rules should generally be verified and, in case of doubt, professionally assessed.

Typical mistakes and how to avoid them

• Relying only on end-of-job cleaning instead of minimizing emissions at the source.
• Too much water without a binding concept: slurry replaces dust but creates new risks.
• Extraction without aerodynamic capture—too far from the source.
• Enclosure without negative pressure: dust escapes at joints and doors.
• Dry cleaning with brooms or compressed air instead of vacuuming/wetting.
• Unclear responsibilities and missing training on equipment and PPE.

Practice-oriented reference to Darda GmbH equipment

The choice of method has a decisive impact on dust. Stone and concrete splitters as well as concrete demolition shears by Darda GmbH can be integrated into low-dust strategies because they work without rotating grinding abrasion. In addition, water mist at the fracture zone, short gripping paths, targeted point extraction and orderly material handling are sensible. In combination with power units, ensure tight, intact hydraulic hose lines so that moisture and dust do not enter the couplings. Tools such as steel shears, combination shears, multi cutters and tank cutters are used in subsequent or parallel operations; here, sparks, chips and achieving clean cut edges are in focus—the dust protection strategy accounts for these specifics with shielding, extraction and suitable cleaning.

Terms and distinctions

Dust protection includes dust avoidance (choice of method), dust reduction (water, reduced process energy), dust binding (mist/wet methods), dust capture (extraction), dust retention (filters) and prevention of dust transfer (enclosure, negative pressure, zoning). In practice these elements interlock. What is crucial is to start at the source, deliberately guide airflows and organize work areas so that downstream activities do not generate new dust.