Plaster facade

The plaster facade is the outermost functional and design layer of many buildings. It protects the wall structure from weather, absorbs loads from temperature and moisture fluctuations, and shapes the appearance. In new construction and existing buildings, the correct selection, execution, and maintenance of the facade plaster determine durability, energy efficiency, and building physics. In projects that intervene in the existing structure — from gutting works through selective deconstruction to concrete demolition — the plaster facade is often removed, separated, or renewed in sections. Depending on the build-up of the exterior wall and adjacent components, concrete pulverizers or hydraulic rock and concrete splitters are also used, for example when plaster systems on solid concrete or masonry surfaces have to be structurally separated from adjoining concrete components.

Definition: What is meant by a plaster facade

A plaster facade is understood to be a multi-layer exterior wall build-up whose outer layer consists of plaster. The facade plaster is a mortar applied to the exterior surface that provides mechanical protection, controls moisture, and contributes to architectural design. It can be applied directly to masonry or concrete or be part of an external thermal insulation composite system (ETICS). A typical sequence consists of substrate preparation, base coat, reinforcement layer, and finish coat. Depending on binder and function, a distinction is made between mineral plasters (e.g., lime, lime-cement, cement plasters) and organically bound plasters (e.g., silicone resin or dispersion plasters). The plaster facade performs building-physics tasks such as driving rain protection and vapor diffusion control and must be adapted to climatic, structural, and usage-related boundary conditions.

Structure, layers, and facade plaster systems

A plaster facade typically consists of coordinated layers. Each layer has a clear role and influences durability and maintenance over the life cycle — including later interventions such as refurbishment, gutting works, or deconstruction.

Typical layer sequence

• Substrate: Load-bearing masonry (e.g., brick, calcium silicate brick, autoclaved aerated concrete) or concrete. Surface strength, flatness, and moisture content are decisive for bond and crack resistance.
• Key coat/bonding bridge: Thin layer to improve adhesion, especially on dense or smooth concrete.
• Base coat: Levels irregularities, buffers moisture and temperature; contributes to crack distribution.
• Reinforcement layer: Mortar with embedded mesh to limit cracking; system-relevant in ETICS.
• Finish coat: Weather-exposed layer with texture (e.g., scraped, rubbed, or felt finishes). Optional coatings for additional hydrophobization or coloration.

Material variants and properties

• Mineral plasters (lime, lime-cement, cement): vapor-permeable, capillary-active, robust against UV; sensitive to early frost exposure and require appropriate curing.
• Silicate and silicone resin plasters: increased water repellency with good vapor permeability; suitable for locations exposed to driving rain.
• Lightweight and renovation plasters: optimized for thermal protection or salt exposure in moisture- and salt-laden areas.

Building physics: moisture protection, thermal protection, and crack behavior

The plaster facade acts as a regulating layer between the outdoor climate and the wall structure. In planning, a coherent relationship of diffusion resistance, water absorption, and drying must be ensured. Cracks occur when restraints from temperature, shrinkage, or settlement are not sufficiently relieved. Expansion joints in the load-bearing structure must be continued in the plaster layer. In ETICS, the choice and thickness of insulation influence the temperature distribution in the wall, which in turn affects algae growth, condensation risk, and drying behavior.

Influence of the substrate

Concrete surfaces often have higher densities and lower roughness than masonry. Here, pretreatment (cleaning, roughening, bonding bridge) determines tensile bond strength. On hard, smooth concrete, mechanical roughening may be necessary. In the course of repairs and deconstruction work, concrete edges are sometimes exposed or components are cut back — here, concrete pulverizers can reduce edges in a controlled manner without transmitting high vibrations into adjacent plaster areas.

Typical damage to plaster facades and diagnostics

Damage is usually due to moisture pathways, insufficient bond, movement, or execution errors. A systematic diagnosis leads to the appropriate repair strategy — and determines whether plaster must be removed partially or entirely.

Common damage patterns

• Voids and delamination: inadequate bond; identifiable through tapping and pull-off tests.
• Cracks: network-like, shrinkage-related microcracks; vertical/diagonal cracks over openings; joint cracks where expansion joints were not continued.
• Moisture and frost damage: spalling, efflorescence, salt loading in the plinth/base zone.
• Biological growth: algae and moss due to prolonged surface moisture.

Investigation methods

• Visual inspection, tapping test, pull-off tests.
• Moisture measurements, drill dust analysis, salt determination in base zones.
• Exploratory openings to identify layer thicknesses and system build-up (plaster, reinforcement, and any insulation).

Repair: preparation, measures, and execution

The choice of measure depends on the cause of damage and system compatibility. Basic principle: eliminate causes before cosmetics. This includes establishing or maintaining a functional moisture balance, securing bond, and correctly dimensioned reinforcement.

Typical work steps

1. Demarcate: mark damage areas, consider joints and component edges.
2. Selective deconstruction: remove loose and detached plaster zones; on hard substrates or adjacent concrete components, work with low vibration. Hydraulic splitters can, for example, help relieve stress in a controlled manner in thick, high-strength edge zones.
3. Substrate preparation: clean, roughen, apply bonding bridges; minimize moisture ingress.
4. Rebuild: compatible mortars and reinforcement; continue expansion joints; match finish coat and any coating to surroundings.
5. Quality assurance: waiting times, curing, spot checks (pull-off, flatness).

Selective deconstruction in ETICS

In ETICS, the reinforcement layer is often bonded over the area with the insulation. Partial areas can be separated with precisely guided separation cuts. Where plaster or ETICS surfaces abut concrete bands, parapets, or cantilevering components, concrete pulverizers enable low-crack nibbling of concrete edges, so the plaster system in the remaining structure is not unnecessarily stressed.

Deconstruction and gutting: methods and tools in the context of the plaster facade

In the course of gutting, cutting work, and special deconstruction, the plaster facade is frequently removed in sections, for example for new openings, structural strengthening, or the demolition of facade bands. The goal is controlled separation of layers and components with minimal impact on the existing structure.

Working with low vibration and low emissions

• Hydraulic splitting: hydraulic splitters create controlled cracks in thicker, high-strength zones and reduce impact and vibration loads. This is particularly advantageous near sensitive plaster and stucco surfaces.
• Grabbing and nibbling: low-vibration concrete crushers allow step-by-step deconstruction of concrete reveals, cornices, and parapets without extensive hammering. Adjacent plaster surfaces thus tend to remain intact.
• Shearing and cutting: For metal substructures, railings, or attachments fastened to the facade, depending on the material, steel shears or hydraulic shears may be suitable. Steel components can thus be released before plaster surfaces are repaired.
• Hydraulic power pack: properly sized hydraulic power units supply the tools mentioned with energy reliably; correct sizing influences progress and precision.

Sequence in existing structures

1. Set up dust and splinter protection, protect adjacent plaster surfaces.
2. Mark and make separation cuts; locate hidden reinforcement.
3. Remove edges and projections with concrete pulverizers, if necessary locally hydraulically split instead of chiseling.
4. Remove residual plaster, mechanically prepare the substrate.
5. Install the new plaster build-up in sections, continue joints, allow for movements.

Interfaces to concrete and masonry components

Connections between plaster and components such as lintels, reveals, parapets, or cantilevering cornices are prone to cracking and moisture issues. Expansion joints, drip edges, and clean connection details are crucial. If concrete-related adaptations become necessary (e.g., cutting back a concrete parapet during facade refurbishment), controlled methods are proven: concrete pulverizers for removing material in grippable pieces; hydraulic splitters for creating defined fracture lines before surfaces are replastered.

Design, surface, and durability

The plaster texture (fine, medium, coarse) influences water runoff, tendency to soil, and visual homogeneity. Lighter, hydrophobic surfaces dry faster. Base zones are particularly stressed; robust mortars and splash-water-repellent details are important here. On large facade areas, panel limits, controlled cracking joints, and careful mesh placement reduce the risk of uncontrolled cracking.

Maintenance and care

• Regular visual inspection for cracks, voids, and coating damage.
• Gentle cleaning; aggressive blasting methods only after compatibility checks.
• Early repair of small defects prevents consequential moisture damage.

Occupational safety, environmental protection, and regulatory framework

Work on plaster facades generates dust, noise, and vibrations. Low-emission approaches are advantageous, especially in densely built areas or with sensitive existing buildings. Hydraulic splitting and nibbling with concrete pulverizers is often quieter and lower in vibration than conventional hammering. Protective measures such as dust suppression, dust extraction, protective enclosure, and personal safety equipment are mandatory. For existing plasters, it must be checked whether coatings or legacy materials relevant to hazardous substance management are present; applicable regulations and occupational safety requirements must be observed. The information in this text is general and does not replace project-specific assessment.

Sustainability and circular aspects

The plaster facade affects energy efficiency, service life, and maintenance effort. Durable, compatible layer build-ups reduce refurbishment cycles. During deconstruction, mineral plaster residues — separated from insulation and coatings — can often be processed as recycled construction material. Selective separation and splitting methods facilitate construction waste separation of layers and attachments. This conserves resources and keeps disposal costs transparent.

Planning and quality assurance

A coherent concept includes an existing-condition analysis, the selection of compatible plaster systems, observance of weather windows, and the definition of details (joints, connections, base). For interventions in the existing structure, test areas and field trials are useful. In deconstruction or gutting works, forward-looking sequencing helps: separate first, then remove — ideally with tools that allow controlled force application. Concrete pulverizers and hydraulic splitters are used precisely where conventional chiseling could cause excessive collateral damage.