Plaster base

The term plaster base connects fit-out, refurbishment works and deconstruction: it means the load-bearing substrate on which plaster systems adhere, as well as the preparatory measures to create a suitable bonding surface. For planning, execution and especially selective deconstruction, the plaster base influences how components are exposed, separated and downsized. This is essential for work in the application areas of concrete demolition and special deconstruction, building gutting and cutting, as well as for structures made of masonry, concrete and natural stone.

Definition: What is meant by plaster base

Plaster base refers on the one hand to the substrate for plaster and skim coats (e.g. concrete, brick, calcium silicate brick, autoclaved aerated concrete, natural stone, metal lath or wire mesh, plaster carrier boards). On the other hand, colloquially the bonding bridge or primer is also referred to as plaster base. A suitable plaster base is load-bearing, sufficiently strong, largely even, free of separating layers, and has absorbency matched to the plaster type. It provides the basis for durable plaster systems and at the same time determines the effort required when exposing load-bearing structures during deconstruction.

Structure and properties of the plaster base

Plaster systems often consist of several layers: bonding bridge or dash coat, base coat, optional reinforced layer with mesh, and finish coat. In external thermal insulation composite systems, adhesive, insulation boards and a reinforced skim system are added. The plaster base is the component or carrier layer to which this system bonds. Its characteristic values—strength, absorption behavior, moisture content, salt and dust loading, flatness and absence of cracks—determine pull-off adhesion and durability. In existing buildings there are also plaster carriers such as metal lath or wooden slats that influence later dismantling. Voids, spalling and separating layers (old coatings, bitumen, oil, dirt) are considered critical findings because they reduce bond strength and can lead to uncontrolled detachment during deconstruction.

Relevance of the plaster base in demolition and special demolition

In selective deconstruction, the condition of the plaster base determines when and how plaster and thin layers are removed before load-bearing areas are processed. On dense concrete surfaces with strongly bonded cement plaster, preliminary mechanical removal is often useful in order to allow concrete crushers to incise reinforced concrete in a targeted manner and expose reinforcement. With masonry carrying brittle gypsum or lime plasters, large-area, controlled detachment can be used to gently expose the masonry for subsequent steps, such as the low-vibration use of stone and concrete splitters.

Influence on tool and method selection

The layer sequence determines the choice of method: thin, cracked finish coats are usually knocked off or milled off in advance. Reinforced skim layers and metal lath can be separated section by section; for embedded steel, steel shears or combi shears are suitable. Once the load-bearing concrete is exposed, precision work with concrete crushers enables controlled biting of component edges and the opening of cross-sections. Massive or thick-walled components can, after exposure, be separated with low-vibration stone and concrete splitters. Hydraulic power packs provide the energy supply for compact, hand-held tools, especially in the confined conditions of building gutting and interior deconstruction.

Plaster types, substrates and typical damage patterns

Gypsum, lime, lime-cement and cement plasters behave differently: gypsum is soft and common indoors, lime plasters are vapor-open, lime-cement and cement are strong and moisture-resistant. Substrates range from concrete and reinforced concrete to brick and calcium silicate brick, to autoclaved aerated concrete and natural stone. Common damage patterns are voids, map and shrinkage cracks, moisture and salt damage, as well as segregation in old plasters. Reinforcement meshes, metal lath and embedded profiles act as hidden separation zones that must be cut into smaller sections during deconstruction—e.g. with Multi Cutters or steel shears—before concrete crushers or split cylinders engage the load-bearing structure.

Identification and testing on site

• Sounding (tapping) to locate voids and non-load-bearing areas.
• Scratch test and scribe hardness to roughly classify the plaster type.
• Wetting test to assess the absorbency of the plaster base.
• Pull-off adhesion or cross-cut tests (given a suitable test method) to estimate bond strength.
• Probing and small exposures to identify reinforcements, rails, meshes and plaster carriers.

Selective deconstruction: from plaster to the load-bearing component

An orderly sequence reduces damage and emissions: first coatings, wallpapers and weak plaster layers are removed. Reinforced layers are released section by section, inserts are separated and sorted by type. Once the plaster base is exposed, the structural interventions follow. In concrete and reinforced concrete, concrete crushers can create openings, reduce cross-sections or precisely trim edges. In masonry or massive blocks, the use of stone and concrete splitters offers a low-vibration approach, especially in sensitive environments. Combi shears and Multi Cutters support at interfaces with mixed materials, while steel shears are used for reinforcement, wires and profiles.

Interior areas: interior demolition and cutting

In interior demolition, plaster, light facing shells and installations meet load-bearing components. After removing plaster layers on walls and ceilings, anchors, dowels and rails can be separated. Multi Cutters and combi shears cut profiles, reinforcement and light components before concrete crushers expose or remove load-bearing areas. In confined spaces, a compact hydraulic system is recommended to work in a controlled manner, with low emissions and minimal vibration input.

Plaster base in rock and tunnel construction as well as with natural stone

In tunnel and gallery construction, shotcrete functions as “plaster” in the broadest sense. The plaster base here is rock or existing shotcrete. Delaminated or weakened areas are removed in a targeted manner; edges can be reworked with concrete crushers. Where rock is to be exposed or enlarged, stone and concrete splitters are used to create controlled fracture lines. In natural stone masonry, plaster layers are often part of historical systems. Here, gentle removal is paramount to avoid damaging the stone and then further process the structure with suitable tools.

Occupational safety, emissions and boundary conditions

Removing plaster and separating at the plaster base generate dust, noise and vibration. Suitable dust extraction, water spraying, personal protective equipment and a coordinated cutting sequence reduce emissions. When potentially hazardous layers occur (e.g. certain old coatings or insulating materials), the relevant rules and regulatory requirements must be observed. Methods with low vibration input and precise force application—such as splitting massive components or targeted biting with crushers—help protect adjacent components and plastered surfaces.

Planning, documentation and disposal

Before starting, there is an inventory, investigations and a deconstruction concept. Layer build-ups, fixings, services and the condition of the plaster base are documented. For disposal, source-separated sorting should be pursued: mineral plaster residues, masonry, concrete, metallic inserts and insulation materials are handled separately. A forward-looking sequence—first plaster and surfaces, then separation of load-bearing structures—simplifies logistics, material flow and quality assurance.

Practical guide: sequence of steps for projects involving a plaster base

1. Investigate: determine plaster type, layer sequence, plaster base, voids and inserts.
2. Plan: define work steps, access, shoring and emission control.
3. Expose: remove coatings and weak layers, make meshes/inserts visible.
4. Separate: cut metallic inserts with steel shears, combi shears or Multi Cutters.
5. Deconstruct: process load-bearing components with concrete crushers or separate massive elements in a low-vibration manner with stone and concrete splitters.
6. Downsize and sort: produce manageable piece sizes, separate material streams.
7. Document: record procedure, findings, deviations and results.

References to products and application areas of Darda GmbH

In the context of plaster base, interfaces arise with several tool groups: Concrete Crushers for structural partial deconstruction on concrete components after exposure; Stone and Concrete Splitters for low-vibration separation of massive elements; Combi Shears and Multi Cutters for mixed materials, profiles and inserts in the plaster and edge area; Steel Shears for reinforcement, meshes and wire carriers. These applications primarily concern concrete demolition and special demolition as well as building gutting and cutting; in rock excavation and tunnel construction, splitting comes into play after removing shotcrete. Hydraulic power packs reliably supply the tools mentioned with hydraulic pressure and enable flexible operations in existing structures.