Partial strip-out

Partial strip-out is a central building block in selective deconstruction of buildings and facilities. It prepares conversion measures, refurbishments or subsequent demolition works by removing only the required components and fixtures while preserving load-bearing structures. In practice, this includes dismantling interior walls, ceiling build-ups, technical installations, floor and wall coverings, up to selected concrete components. To minimize emissions and avoid jeopardizing structural stability, concrete pulverizers and hydraulic rock and concrete splitters are frequently used; they are hydraulically operated and enable precise, low-vibration work. Solutions from Darda GmbH are used in this context especially when controlled removal, cutting or splitting is required.

Definition: What is meant by partial strip-out

Partial strip-out refers to the targeted, sectional removal of non- or only temporarily load-bearing components and fixtures within an existing structure. The objective is to create space for new uses, to prepare structural reinforcement, or to facilitate subsequent demolition without impairing the building’s structural stability. In contrast to complete gutting, only defined areas are processed during partial strip-out; load-bearing elements such as columns, beams, load-bearing walls or cores remain in place and are secured during the works. Typical activities include removing interior fit-out, MEP components, masonry sections, screeds, concrete haunches or cantilevers, as well as the selective exposure of reinforcement. Methods such as hydraulic splitting, cutting and shear processing are among the preferred approaches, as they work with low vibration and noise and can therefore be deployed in existing buildings, occupied buildings or sensitive industrial environments.

Methods and tools for partial strip-out

In partial strip-out, methods are selected based on the construction task, material type and static boundary conditions. Concrete pulverizers enable targeted biting and removal of concrete and masonry, including in slab and wall areas with reinforcement. Hydraulic splitter – often with stone splitting cylinders – generate controlled splitting forces in core drillings or joints and separate components with low vibration. Hydraulically operated combination shears, multi cutters, steel shears as well as specialized tank cutters are used to process different materials such as steel, composite members, lines, vessels or hybrid constructions. The power delivery is ensured by compact hydraulic power units; they provide pressure and flow for continuous, finely metered work.

Delimitation and classification in the deconstruction process

Partial strip-out lies between interior demolition and special demolition. It differs from complete gutting in that only the actually required scope is dismantled. This allows precise embedding in the following process chain: condition assessment, selection of deconstruction methods, dismantling/removal of defined components, intermediate haulage logistics, quality assurance and release for conversion or demolition. Tools such as concrete pulverizers and hydraulic splitter are often combined with core drilling and sawing measures to prepare cuts and split joints precisely.

Planning, survey and hazardous substance investigation

Sound work planning reduces risks and increases efficiency. Before starting, plans, structural documents and building inspection reports are evaluated, openings are probed and component thicknesses determined. Hazardous substance investigations identify possible hazards such as asbestos, PCB, PAH or mineral wool. The assessment of results influences the sequence of works, the choice of methods and the protective enclosure and extraction technology. For sensitive areas, coordinated emissions and dust management is to be provided to protect adjacent uses.

Step-by-step approach

1. Record the existing structure, understand load transfer, assess vibration sensitivity and low-vibration requirements.
2. Plan construction logistics: access routes, load pick-up points, intermediate material storage, waste routes.
3. Remove hazardous substances or enclose areas section by section.
4. Plan selective dismantling: sequence, temporary shoring, separation joints.
5. Define tool selection: concrete pulverizers, hydraulic splitter, shears, cutting tools, saws.
6. Size the hydraulic power pack and secure hose routing.
7. Organize quality assurance, documentation and approvals.

Static boundary conditions and protection of load-bearing components

Partial strip-out is performed in existing structures while maintaining structural stability. Before interventions, load transfer, reinforcement layout and restraint stresses must be checked. For openings, pre-cuts with sawing or drilling define the intended fracture line; the component can then be released with concrete pulverizers or by controlled splitting. With prestressed concrete or prestressed elements, particular caution and special procedures are required. Temporary shoring, support scaffolds and a collapse protection system prevent uncontrolled release of larger components.

Emissions control: noise, dust, vibration

Low emissions are essential in existing buildings, for example in hospitals, offices or inner-city locations. Hydraulic methods are advantageous here. Hydraulic splitter generate splitting forces inside the component and reduce vibrations; concrete pulverizers allow metered, pinpoint removal. In addition, low-dust cutting systems, local extraction and wetting of cut lines help. A low-noise, low-vibration working method minimizes service interruptions and protects sensitive equipment.

Tool and power pack selection

The selection of equipment is based on material, component thickness, reinforcement ratio and accessibility. Hydraulics is standard, as it provides high forces in a compact design. Hydraulic power packs are sized according to the required pressure, flow rate and the number of tools operated in parallel. The following criteria support the decision:

• Concrete pulverizers: for removing concrete, masonry, creating openings, exposing reinforcement.
• Hydraulic splitter: for low-vibration separation of massive components, controlled releasing in core drilling.
• Combination shears and multi cutters: for mixed materials, sections, light steel beams, lines.
• Steel shear: for thick-walled steel components, reinforcing steel bundles, beams.
• Tank cutters: for safe dismantling of vessels, silos and pipelines in industrial plants (with explosion protection and suitable clearance measurements/ATEX zone compliance).

Hydraulic supply and deployment practice

Line runs should be routed short and protected to minimize pressure losses. Couplings must be secured against unintentional release. For indoor works, a quiet, low-emission power pack is advantageous. Operator guidance considers sight lines, safe standing areas and the step-by-step releasing of components.

Material separation, recycling and disposal

Selective partial strip-out enables high purity of fractions and contributes to the circular economy. Components are separated into fractions such as concrete, masonry, steel, non-ferrous metals, wood, plastics, bitumen and mineral wool. Concrete pulverizers support separating adherences, hydraulic splitter enable the controlled releasing of larger pieces for transport. Compliance with applicable rules for waste classification and documentation is required; information is always general and must be specified for the project.

Organization, logistics and site setup

Short routes and clear processes are decisive. Stripped-out areas are released section by section, containers and collection points are sensibly placed. Lifting devices and transport aids are matched to component weights. In existing buildings, pay attention to the load-bearing capacity of floors as well as to fire protection and escape route concepts. Coordination with subsequent trades prevents downtime; shutdown windows are agreed with users.

Application areas and typical use cases

• Concrete demolition and special demolition: openings in walls/slabs, selective removal of attachments; concrete pulverizers and splitting methods reduce vibrations.
• Strip-out and cutting: interior demolition in office and residential buildings, clinics, schools; combination of sawing, hydraulic splitter and shears.
• Rock excavation and tunnel construction: for modifications in underground structures, hydraulic splitting methods help where space is limited and strict emissions requirements apply.
• Natural stone extraction: controlled splitting of rock when exposing or removing inserts in stone operations.
• Special operations: dense, sensitive industrial plants, plant modifications and vessel dismantling under increased safety requirements, often with tank cutters and shears.

Safety and protective measures

Occupational safety takes priority. Hazard analysis, secured work areas and clear communication are mandatory. When working on closed vessels, clearance measurements, draining and cleaning as well as protection against ignition sources must be considered. Personal protective clothing, suitable extraction and the control of dust and noise emissions must be planned. Legal requirements may vary by project; notes are generally of a generic nature and do not replace a case-by-case assessment.

Quality assurance and documentation

Ongoing checks ensure dimensional accuracy, structural protection and purity of fractions. Photo documentation, inspection records, weigh tickets and approvals structure the process. For openings and breakthroughs, measuring the cuts, checking edge quality and confirming the residual load-bearing capacity of adjacent components is recommended. For hydraulic splitting, drill pattern, splitting direction and intended fracture lines are documented.

Typical risks and how to avoid them

Uncontrolled break-off, restrained components, hidden reinforcement or unrecognized utility lines are common risks. These can be minimized by surveys, pre-cut separation, temporary shoring and step-by-step removal with concrete pulverizers. Hydraulic splitter support predictable releasing in thick components, provided drill pattern and splitting sequence are aligned. In case of uncertainty about stress states, scale back measures and involve structural expertise.

Practical guide: from concept to execution

A practical concept links existing-conditions investigation, emissions management, tool selection and logistics. Start with a clear demolition plan, define separation joints and sequences, secure load-bearing components, choose hydraulic tools with sufficient drive power reserve and plan the waste management chain. This enables meeting time windows, avoiding rework and starting follow-up trades on schedule.