Concrete gutting describes the targeted, selective deconstruction of concrete within existing structures. The goal is to partially remove components, create openings, reduce cross-sections, or remove damaged zones—always in a controlled, low-vibration manner and with an eye on the load-bearing capacity of the remaining structure. In practice, concrete gutting combines a planned approach with specialized methods such as hydraulic splitting, crushing, and cutting. In particular, concrete demolition shears as well as rock and concrete splitters are used; in combination with hydraulic power packs they enable precise, material-friendly removal and play a central role in concrete demolition and special deconstruction as well as in gutting and cutting.
Definition: What is meant by concrete gutting
Concrete gutting is the controlled removal of concrete areas within a structure without completely deconstructing the overall building. The focus is on selective removal: interior walls, slab or wall areas are opened, foundation heads are reduced, bearing zones are adjusted, or defective layers such as carbonated cover concrete are removed. Depending on the task, the intervention is carried out on unreinforced or reinforced concrete and planned so that structural action, component function, and adjacent uses are impacted as little as possible. The work is typically low-vibration, since methods such as hydraulic splitting and crushing are favored. Concrete gutting is thus a core element of selective deconstruction, asset preservation, and refurbishment—closely interlinked with sawing and drilling methods as well as construction logistics.
Planning, site process, and selection of suitable methods
Successful concrete gutting starts with a careful survey of existing conditions: drawings, probing, and, where appropriate, locating clarify reinforcement layout, member thicknesses, and utility lines. Based on this, the procedure is defined. Hydraulic methods are preferred when vibration and noise control, low equipment weight, and limited space are decisive. Concrete demolition shears enable controlled crushing of concrete and exposing the reinforcement. Rock and concrete splitters generate defined splitting forces in the borehole and break up massive concrete blocks or component areas without explosives and with minimal edge break-out. Hydraulic power units supply these tools with energy and must be matched to flow rate, pressure range, and mobility. In practice, methods are combined modularly—for openings, recesses, cross-section reductions, and staged deconstruction, e.g., floor by floor or bay by bay.
Tools and methods compared
Tool selection follows the objective: material properties, accessibility, work environment, and requirements for low dust, noise, and vibration determine the approach. Concrete demolition shears are ideal when components are to be deconstructed into manageable fragments and reinforcement must be selectively cut. Rock and concrete splitters come into their own where massive cross-sections, high compressive strengths, or restricted access are present and a low-vibration, controlled removal is required. Both methods are integral parts of concrete demolition and special deconstruction as well as gutting and cutting and can be combined with sawing and core drilling.
Concrete demolition shears: selective removal of components
Concrete demolition shears grip the concrete, break it locally, and allow reinforcement to be exposed and cut. The method is precise because the shear acts directly on the component and removal proceeds layer by layer. This results in low vibrations and protects adjacent components. In concrete gutting, concrete demolition shears are used to create wall openings, form penetrations, remove upstands, partially reduce beams, or precisely adjust concrete bearings. Indoors, the compact design of suitable shears in combination with hydraulic power packs is convincing when crane use is not possible and access is limited.
Rock and concrete splitters: controlled splitting instead of hammering
With hydraulic splitting, boreholes are drilled and splitting cylinders are inserted. High internal pressure generates splitting tension that releases the concrete along predefined lines. The method is low-vibration and dust-reduced, as no percussive mechanism is used. It is suitable for thick components, plinth zones, massive column heads, foundation blocks, and parapets. In tunnels and shafts, where vibrations are particularly critical, splitting enables controlled removal without explosives. In concrete gutting, the concrete can be selectively loosened in this way before concrete demolition shears or shear attachments pick up the fragments and further reduce them.
Hydraulic power packs as the energy source
Hydraulic power packs deliver the flow rate and pressure for concrete demolition shears and splitters. Performance parameters must be matched to the tool, member thickness, and continuous operation. Compact power packs are advantageous for interior demolition because they are easy to transport and allow quick changes between tools. Maintenance, filtration, and clean couplings ensure trouble-free operation and extend component service life.
Combination shears, multi cutters, and steel shears
In complex gutting scenarios, concrete meets steel sections, utility lines, reinforcement bundles, and embedded items. Combination shears and multi cutters cut reinforcement, sheet, and sections once concrete demolition shears have released the concrete matrix. Steel shears are helpful when extensive reinforcement or steel structural parts must be selectively severed. This creates a coordinated process that separates concrete and metal by material type and facilitates downstream disposal or recycling.
Structural analysis, vibrations, and fabric protection
Every concrete gutting operation requires special attention to structural behavior. Load redistribution, edge distances, and preserving load-bearing zones must be clarified before starting. Hydraulic splitting and shear-based methods minimize vibrations and transverse oscillations, reducing the risk of cracking in adjacent components. In existing buildings with sensitive finishes or in densely built-up areas, this is a key advantage. Fabric protection also includes controlling dust, water, and vibration to protect installations, surfaces, and areas of use outside the work zone.
Fields of application in refurbishment and deconstruction
Concrete gutting addresses a wide range of tasks. Typical cases include penetrations for routing utilities, shafts and new services, creating openings for doors and windows, removing carbonated or chloride-contaminated cover concrete, reducing corbels and supports, and adjusting the cross-section of walls, columns, and slabs. In bridge works, this includes removing edge caps or exposing bearing zones. In industrial environments, concrete foundations and machine substructures are selectively deconstructed. In tunnels and shafts, splitters enable low-vibration partial removal to adjust profiles or integrate installations. In special operations, such as dismantling complex plants, concrete demolition shears can release the concrete while steel shears cut metallic installations. In this way the areas of use—concrete demolition and special deconstruction, gutting and cutting, and special operations—are covered.
Work organization, emissions, and construction logistics
An orderly sequence determines efficiency and quality. Core drillings for splitters are placed in a grid and aligned with load paths, shears engage prepared edges, and material is reduced step by step. Emissions must be minimized: dust is limited by extraction and targeted wetting, noise is reduced through tool choice and operating mode. Water should be used sparingly to avoid additional disposal loads. Construction logistics include short transport routes, dust-tight intermediate storage, and segregated separation of concrete, reinforcement, and embedded parts. Reducing to manageable sizes facilitates removal, especially in existing buildings with limited load-bearing capacity of access routes.
Material separation and circular economy
Concrete gutting contributes to resource conservation when material streams are cleanly separated. The clear separation of reinforcement, the separate handling of contaminated zones, and the unambiguous assignment of fractions improve recyclability. Depending on quality and local conditions, crushed concrete can be used as recycled aggregate. Precise, controlled removal with concrete demolition shears and splitters promotes this quality by reducing foreign content and limiting overbreak.
Quality assurance and documentation
Quality is the result of planning, qualification, and verification. Before starting, target geometries, tolerances, edge distances, and protection zones are defined. During the work, intermediate checks secure progress: member thicknesses, remaining cross-sections, and surface condition are inspected and documented. Touch-ups are carried out in a targeted manner, for example when reprofiling edges for connecting new components. Complete documentation supports further building work, such as concrete repair or the installation of new components.
Safety and regulatory framework
Concrete gutting is subject to general rules of occupational safety and building codes. Proper instruction, personal protective equipment, and adherence to manufacturer specifications for tools and power packs are fundamental measures. For indoor work, adequate ventilation, low-dust methods, and safe electrical and hydraulic routing must be considered. Structural interventions affecting load-bearing performance require appropriate structural assessment. Legal requirements may vary by region; early coordination with project stakeholders and authorities is therefore advisable.
Effective combinations in practice
Coordinated process chains have proven themselves in practice: splitters loosen massive component areas, concrete demolition shears handle crushing and the selective exposure of reinforcement, and shears additionally cut metallic installations. Hydraulic power packs supply all components efficiently. This combination is particularly beneficial in confined conditions, on slabs with limited load capacity, or in sensitive areas with strict limits on vibration and noise. In this way, the requirements of precise, material-friendly concrete gutting are met, and the interfaces to subsequent trades—such as concrete repair, installation of new components, or building services—are optimally prepared.