Fine dust

Fine dust is generated during numerous activities in concrete demolition, strip-out, rock excavation and tunnel construction, as well as in natural stone extraction. In these fields of application, proper handling of dust plays a central role in occupational safety, environmental compatibility, and execution quality. Hydraulic tools from Darda GmbH—such as concrete demolition shears or rock and concrete splitters—are often used where precise, controlled, and ideally lower-dust methods are required. This article classifies the term fine dust in technical terms, describes generation mechanisms on the construction site, and presents practical measures to reduce particle exposure.

Definition: What is meant by fine dust

Fine dust refers to airborne particles with a small aerodynamic diameter. A common categorization is PM10 (particles ≤ 10 µm), PM2.5 (≤ 2.5 µm), and ultrafine particles. In construction practice, mineral dusts from concrete, mortar, brick, and natural stone are relevant, often containing quartz (respirable crystalline silica). The particles are generated by crushing, milling, grinding, sawing, drilling, breaking, and mechanical abrasion. The smaller the particles, the longer they remain suspended in the air and the deeper they can penetrate into the respiratory tract. Fine dust is therefore not only a matter of cleanliness but a key aspect of occupational hygiene and environmental protection.

Generation of fine dust in concrete demolition, strip-out and rock excavation

When processing mineral construction materials, particles are generated through crack propagation, aggregate fracture, and friction wear. Particularly dust-intensive are abrasive methods with a high proportion of cutting or grinding. Hydraulic separating and splitting methods—such as with concrete demolition shears or rock and concrete splitters—create fracture surfaces through controlled introduction of pressure. Compared to continuous abrasive processes, this can generate relatively less fine dust, because the material is preferentially separated into larger fragments. The actual dust load nevertheless depends on many factors: material (e.g., concrete strength, reinforcement ratio), moisture, tool geometry, contact pressure, working speed, and boundary conditions such as ventilation or enclosure.

Particle sizes, material properties and health aspects

Particle size determines residence time in the air and deposition in the respiratory tract. Coarse splinters settle quickly, while PM10 and especially PM2.5 remain airborne longer. Concrete and natural stone release mineral particles when fractured and crushed; contained quartz fractions can increase occupational health relevance. Dust exposures should therefore be minimized in principle—through method selection, technical and organizational measures, and personal protective equipment. Statements on permissible limit values are based on the applicable legal requirements and recognized rules of practice; they must be assessed on a project-specific basis.

Concrete demolition shears and rock and concrete splitters in the context of dust generation

Concrete demolition shears grip the component and crush it using high, locally introduced compressive forces. Rock and concrete splitters expand previously created drilled holes or apply splitting wedges to initiate controlled cracks. Both approaches promote fracture rather than abrasion. As a result, the release of very fine particles can be reduced, while coarser fragments are removed in a targeted manner. Additionally, dust generation can be further reduced by wetting surfaces, minimizing drop heights when placing material down, and using well-considered sequences (split first, then separate).

Fine dust in Darda GmbH application areas

Concrete demolition and special demolition

In selective deconstruction, dust emissions occur at separating points, when removing components, and during secondary breaking. Concrete demolition shears support step-by-step, controlled removal, thereby limiting dust sources locally. When loosening slabs, foundations, or walls, pre-cracking with shears can prepare subsequent processing with less abrasion. Hydraulic power units provide the required energy, while measures such as local dust extraction, water wetting, and enclosure further reduce emissions.

Strip-out and cutting

In interior spaces, the residence time of fine dust is increased. Therefore, point-source extraction, negative pressure containment in work areas, and strict separation of clean and dirty zones are crucial. When selectively removing concrete webs or chasing, prioritizing splitting or shear operations can reduce the amount of dust-intensive cutting. Metallic inserts can be separated with shears; this typically produces less mineral fine dust, though other emissions may occur that must be considered separately.

Rock excavation and tunnel construction

In rock, rock type, grain bonding, and moisture determine dust behavior. In projects focused on rock demolition and tunnel construction, limited volume and airflow affect dust distribution. Rock splitting cylinders and rock and concrete splitters create controlled crack patterns in the rock mass and can limit dust peaks such as those that occur during intensive impact work. At the same time, powerful ventilation, near-source dust extraction, and clean material logistics are indispensable.

Natural stone extraction

In the extraction and shaping of natural stone, dust is primarily released during sawing, grinding, and sorting. Splitting along natural or predefined discontinuities can reduce fine dust generation compared to abrasive cutting processes. Decisive are adapted process chains that favor fracture and minimize fines, supplemented by wet operating modes and low-dust transport routes.

Special application

In sensitive environments—such as occupied buildings, industrial facilities, or protected surroundings—dust control is particularly important. There, work with concrete demolition shears and splitters is often combined with enclosures, air cleaning (e.g., with suitable filters), and close-meshed monitoring to limit emissions and protect neighboring areas.

Measures to reduce fine dust on the construction site

Effective dust management combines method selection, technology, organization, and personal protective measures. The specific combination is planned and monitored on a project-specific basis.

• Method selection and sequence: Generate fracture where possible (e.g., concrete demolition shears, rock and concrete splitters) and minimize abrasive processing; pre-crack components, then separate in a targeted manner.
• Wet processing: Water wetting at the point of generation binds particles. Water quantity, droplet size, and point of application must be adapted to the material and method.
• Point extraction: Near-source capture with suitable filtration (e.g., for fine mineral dusts) and sufficient volumetric flow.
• Encapsulation and enclosure: Dust-tight partitions, airlocks, and negative pressure reduce spread—especially during strip-out.
• Ventilation: Targeted airflow, adequate air exchange, and avoidance of backflows improve air quality, for example in tunnel construction.
• Cleanliness and logistics: Wet clean instead of dry sweeping, no compressed air for blow-off, low-dust conveying and drop systems, short routes.
• Tool and process parameters: Adapted pressure, feed, and gripping positions on concrete demolition shears; controlled split widths and cycles during splitting—to avoid unnecessary fine comminution.
• Maintenance: Maintain seals, cutting edges, and bearings; operate hydraulic power packs cleanly to preserve efficiency and process stability.
• Organization and PPE: Zone work areas, limit exposure times, provide suitable respirators and use them correctly; refresh training regularly.
• Monitoring and documentation: Plan measurements, define reference values, log results, and adjust measures as needed.

Measurement, assessment and documentation of dust exposure

For a reliable assessment, PM10/PM2.5, respirable dusts, and material-typical components are considered depending on the task. In addition to gravimetric methods, portable particle counters can be used for trend observation. Important are representative measuring points, suitable measurement times (including peak loads), and interpretation of the values with respect to applicable requirements. Clear documentation supports verification for clients and authorities as well as the continuous improvement of processes.

Environmental protection: emissions, deposition and water balance

Fine dust leaves the construction site as diffuse emissions or settles on surfaces and vegetation. Measures such as windbreaks, closed containers, dampened routes, and gentle handling techniques reduce spread. Water-based processes require controlled collection and treatment of the resulting water to retain sediments and fines. Careful planning avoids secondary inputs into soil and water bodies.

Planning, occupational safety and communication

A low-dust approach begins with a hazard analysis and suitable work planning. The structure, materials, weather, neighborhood, and working times are taken into account. Communication with stakeholders—client, residents, users—supports acceptance. Legal requirements must be carefully reviewed in each project; binding information is provided by the responsible institutions. Operationally, the rule is: Plan, execute, measure, adjust.

Material and tool influence on dust formation

Concrete quality and reinforcement

High-strength concrete fractures more brittlely and can generate finer particles under unfavorable parameters. Concrete demolition shears can be positioned so that cracks run purposefully through the concrete while reinforcement is separated or exposed. This reduces rework with abrasive methods.

Rock types and moisture

Weakly bonded rocks generate more dust under friction than tough-brittle rocks. Material moisture has a dust-binding effect. During splitting or crushing, targeted humidification can dampen particle formation.

Tool geometry and process control

Cutting edges, shear jaws, pressure stages, and holding positions influence crack paths and fragment size. Calm process control with moderate speeds and controlled pressure favors large fragments and reduces abrasion.

Practical examples: low-dust approach for typical tasks

Column demolition in existing structures

1. Enclose the work area, create negative pressure, position near-source extraction.
2. Pre-crack the column with a concrete demolition shear, expose the reinforcement.
3. Separate the reinforcement, place fragments down wet and transport them with low dust.
4. Wet clean, check measurements, adjust measures.

Foundation splitting prior to disposal

1. Set drilled holes according to plan and insert rock or concrete splitters.
2. Split in a controlled manner to produce manageable blocks.
3. Moisten fracture surfaces, secure edges, use low-dust logistics.
4. Wet clean the area, bind dust deposits.

Breakout window in the tunnel

1. Plan airflow, size extraction and ventilation.
2. Pre-crack with shear or splitters, reduce abrasion-intensive steps.
3. Remove material quickly, cover dust sources, control drip water.
4. Control measurement and visual inspection, update documentation.

Maintenance and operation of hydraulic power packs in dusty environments

Low-dust construction sites benefit from reliably operating power packs and tools. Filters, coolers, and air paths must be protected from excessive contamination; keeping quick coupling connections clean reduces ingress into the hydraulic system. A well-maintained condition helps concrete demolition shears and rock and concrete splitters to work reproducibly and avoid unnecessary fine comminution.

Limits of dust prevention and realistic expectations

Fine dust cannot be completely avoided when processing concrete and rock. The goal is minimized exposure through smart method selection, consistent technology, and attentive execution. Tools such as concrete demolition shears and rock and concrete splitters can contribute as building blocks in an overall solution to limit fine dust generation—the effectiveness, however, is always determined by the interplay of all measures and the boundary conditions.