Anchors

Anchors are key components when structural elements of concrete, masonry, or rock need to be held, braced, or safeguarded against loosening, either permanently or temporarily. In deconstruction, rock demolition, and tunneling they provide load transfer and stabilization—often to make controlled separation and splitting methods safe in the first place. In practice, planning and execution interlock closely: the selection and arrangement of anchors influence how efficiently tools such as concrete pulverizer, stone and concrete splitters, steel shears or combination shears work and in which sequence components can be released safely.

Definition: What is meant by anchors

An anchor is a fastening element that transfers tensile and/or shear forces from components into a suitable substrate—usually concrete, natural stone, rock, or stabilized soil. Structurally, solutions range from mechanical expansion anchors through bonded or injection anchors to rock anchors and prestressed permanent anchors. They are used temporarily (e.g., for the construction stage during deconstruction) or permanently. The objective is a reliable load path to stabilize components, fix geometries, or enable controlled separation and splitting operations. Substrate, embedment depth, edge distances, load types, and the cracking state govern both design and execution.

Function and operating principle at a glance

Anchors work via frictional contact (clamping, e.g., with expansion anchors), mechanical interlock (e.g., with undercut anchors), or material bond (e.g., with bonded anchors using mortar or resin). Loads are transferred into the steel of the anchor and into the surrounding substrate. Failure modes include steel fracture, pullout/strip-out, concrete cone failure (cone-shaped breakout), splitting failure at insufficient edge distances, and failure of the bonding agent. For deconstruction, understanding these mechanisms is crucial in order to release anchors deliberately or to crack the concrete cover around anchors with concrete pulverizer or relieve them with stone and concrete splitters.

Variants and logic of use

The choice of anchor system follows the requirements of the construction stage: load level, duration of action, substrate quality, and environmental conditions. In deconstruction and demolition projects, later removability is also a criterion.

Mechanical expansion anchors

Expansion anchors create clamping pressure against the borehole wall via tightening torque. Advantages are quick installation and immediate loadability. Limitations exist at small edge distances and in cracked concrete. In deconstruction, expansion anchors can raise local stresses; before breaking open the concrete with concrete pulverizer, unloading the component or deliberately releasing the prestress is advisable. Documented tightening and controlled edge distances reduce the risk of concrete splitting.

Bonded and injection anchors

Bonded anchors transfer loads via a bond line between the anchor rod and the substrate. They are suitable for high tensile forces, variable embedment depths, and small edge distances. Prerequisites are clean, dust-free boreholes and curing appropriate to the ambient temperature. For temporary securing in deconstruction, removable bonded systems are of interest if anchors are to be cut flush or unscrewed later. When exposing bonded anchors, stepwise removal of the concrete cone with concrete pulverizer has proven effective to avoid uncontrolled cracking.

Undercut and undercut-type anchors

Undercut anchors achieve mechanical interlock and reduce expansion pressures. They are advantageous for high loads and demanding edge conditions. In deconstruction, releasing them is more involved; the area around the anchor is often chiselled open or opened with hydraulic work using a concrete pulverizer before rods are cut with steel shears.

Rock anchors and permanent anchors

In rock demolition and tunneling, rock anchors and strand anchors stabilize loosely bedded rock or face areas. For controlled release of individual rock bodies, knowledge of anchoring direction and length is essential. Only after unloading or defined deconstruction of the securing should stone and concrete splitters be applied for low-stress removal to keep energy input low.

Design and verification in the deconstruction context

Design in the construction stage differs from permanent design: loads are often eccentric, dynamic, or present only briefly; components may already be cracked or partially stripped out. Therefore, robust edge distances, sufficient embedment depth, clear load paths to supports, and documented installation are the focus.

Relevant load cases

• Tension from suspensions, temporary supports, and lifting operations
• Shear forces from bearing arrangements or horizontal bracing
• Coupled loads from cutting and splitting processes, including moments
• Fatigue-like actions during repeated lifting cycles

Typical failure modes

• Steel failure when the capacity of the anchor rod is exceeded
• Pullout or strip-out of the thread/bond
• Concrete cone breakout due to high tensile forces near edges
• Splitting failure due to insufficient edge or spacing distances

Fields of application and practical workflows

Anchors are used across all relevant fields. Planning and sequence determine when to secure, unload, cut, and split.

Concrete demolition and specialized deconstruction

When deconstructing massive components, temporary anchors stabilize slabs, cantilevers, or brackets until cutting or jaw work is completed. Frequently, the concrete cover in the area of anchor heads is first opened with concrete pulverizer to access nut, washer, and plate. The rods can then be cut with steel shears or combination shears. For large cross-sections, stone and concrete splitters can be used to pre-release the concrete mass with low stress and to unload the anchors.

Strip-out and cutting

In strip-out, anchors secure temporary suspensions, beam bearings, or brackets. Small edge distances and thin components favor bonded solutions. Exposing connection zones is achieved using handy concrete pulverizer before multi cutters or combination shears cut reinforcement and anchors. This aligns with core removal and cutting approaches.

Rock demolition and tunneling

Rock anchors stabilize shells, benches, and discontinuities. For removing individual blocks, the anchoring is dismantled in a controlled manner. Afterwards, stone and concrete splitters enable low-vibration removal along natural or predrilled planes; jaw and shear tools help release anchor plates and cut exposed steel parts.

Natural stone extraction

When loosening raw blocks, temporary anchors can limit movements until splitting operations are completed. After splitting, anchors are released, steel is partially separated, and the block is further processed.

Special applications

In sensitive environments with strict vibration and emission requirements, small edge and spacing distances, well-documented installation, and stepwise unloading are crucial. Hydraulic pulverizer and splitting methods support a controlled approach.

Work preparation and safe execution

Structured preparation reduces risks and increases execution safety. A sequential approach that interlinks inspection, installation, control, and deconstruction has proven effective.

1. Survey of existing conditions: substrate, component thicknesses, crack patterns, reinforcement layout, existing anchors
2. Definition of load paths and construction stages, including reserve capacities
3. Drilling and installation plan with edge/spacing distances and embedment depths
4. Borehole creation and careful hole cleaning (brushing, blowing out)
5. Installation in accordance with the system manufacturer’s specifications; document tightening torques
6. Inspection and proof pull, if specified; continuous visual inspection during the construction stage
7. Define the sequence for cutting, pulverizer work, and splitting operations
8. Orderly dismantling: open the concrete cone, cut the steel, properly close voids

Particularities when releasing and removing anchors

Removal depends on the system and accessibility. Exposed rods are usually cut flush; concealed ends can be accessed by locally opening the concrete. Concrete pulverizer enables controlled removal of the concrete cover without overloading adjacent areas. Protruding rods are cut with steel shears or combination shears. For bonded anchors, surrounding material can be removed until the rod can be unscrewed or cut. Finally, voids are closed with a suitable mortar and surfaces are smoothed.

Tools and methods in interaction with anchors

Method selection is based on component thickness, reinforcement ratio, accessibility, and the required low-emission approach.

• Concrete pulverizer: Local opening of anchor heads, controlled removal of concrete cones, exposing plates and nuts
• Stone and concrete splitters: Low-stress pre-release of massive areas to unload anchored zones, breaking along drill rows
• Steel shears and combination shears: Cutting anchor rods, head plates, and accessories
• Multi cutters: Flexible cutting in confined areas
• Hydraulic power units: Energy supply for the above tools in various power classes
• Tank cutters: Special applications when securing anchors must be released and plates cut during tank deconstruction

Quality assurance and documentation

For traceability, positions, drilling parameters, embedment depths, systems used, tightening values, and tests are documented. Photos before/after installation and visual inspection records help assess construction stages. This supports a safe sequence, especially when several anchor stages are activated and released one after another.

Resource conservation and material separation

During deconstruction, concrete and anchor steel can be collected separately. Steel from anchors, plates, and nuts is sent to metal recycling; broken concrete can be returned to the construction materials cycle after appropriate processing. A controlled, low-vibration approach reduces damage to adjacent components and minimizes rework.

Terminology and common misconceptions

Anchors must be distinguished from reinforcement connections, temporary suspension points, or mere assembly aids. Likewise, personal fall-arrest anchorage points are not equivalent to structurally load-bearing anchors in the construction stage. For planning and execution, the applicable technical rules and project specifications apply; decisions must be aligned with the specific structure.