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    • CIVIL AND INDUSTRIAL ENGINEERING

      • 01

        Development of design and estimate documentation for the construction of civil and industrial facilities, in frame and frameless design, monolithic and prefabricated structures and buildings, metal structures, reinforced concrete;

      • 02

        Design of outdoor power supply systems, outdoor and indoor electric lighting, power electrical equipment and substations;

      • 03

        Design of trunk and intra-block fiber-optic communication lines, video surveillance systems, security and access systems;

      • 04

        Design of external water supply, sewerage, water drainage and drainage, gas supply, and heat supply networks;

      • 05

        Engineering surveys (engineering-topographic; engineering-geodetic; engineering-hydrological, engineering-geological;

      • 06

        Technical inspection of buildings and structures;

      • 07

        ВIM design;

      • 08

        3D laser scanning;

      • 09

        Qualified legal support for projects.

    • MINING & METALLURGICAL ACTIVITIES

      • 01

        Development of design and estimate documentation for the construction of mining facilities;

      • 02

        Adaptation of projects and technological processes in the mining and metallurgical sector of foreign projects and design solutions to Kazakhstani norms and requirements;

      • 03

        Design of roads and railways;

      • 04

        Development of environmental projects;

      • 05

        Industrial safety;

      • 06

        Preparation of tender documentation;

      • 07

        Evaluation and analysis of objects to determine the cost of engineering and design;

      • 08

        ВIM design;

      • 09

        Comprehensive implementation of author's supervision;

      • 10

        Development of projects for related infrastructure facilities for mining, processing and metallurgical industries;

      • 11

        Carrying out engineering survey work.

    • MINING & METALLURGICAL ACTIVITIES

      • 01

        Development of design and estimate documentation for the construction of civil and industrial facilities, in frame and frameless design, monolithic and prefabricated structures and buildings, metal structures, reinforced concrete;

      • 02

        Design of outdoor power supply systems, outdoor and indoor electric lighting, power electrical equipment and substations;

      • 03

        Design of trunk and intra-block fiber-optic communication lines, video surveillance systems, security and access systems;

      • 04

        Design of external water supply, sewerage, water drainage and drainage, gas supply, and heat supply networks;

      • 05

        Engineering surveys (engineering-topographic; engineering-geodetic; engineering-hydrological, engineering-geological;

      • 06

        Technical inspection of buildings and structures;

      • 07

        ВIM design;

      • 08

        3D laser scanning;

      • 09

        Qualified legal support for projects.

    • CIVIL AND INDUSTRIAL ENGINEERING

      • 01

        Development of design and estimate documentation for the construction of mining facilities;

      • 02

        Adaptation of projects and technological processes in the mining and metallurgical sector of foreign projects and design solutions to Kazakhstani norms and requirements;

      • 03

        Design of roads and railways;

      • 04

        Development of environmental projects;

      • 05

        Industrial safety;

      • 06

        Preparation of tender documentation;

      • 07

        Evaluation and analysis of objects to determine the cost of engineering and design;

      • 08

        ВIM design;

      • 09

        Comprehensive implementation of author's supervision;

      • 10

        Development of projects for related infrastructure facilities for mining, processing and metallurgical industries;

      • 11

        Carrying out engineering survey work.

    • CIVIL AND INDUSTRIAL ENGINEERING

      • 01

        Development of design and estimate documentation for the construction of civil and industrial facilities, in frame and frameless design, monolithic and prefabricated structures and buildings, metal structures, reinforced concrete;

      • 02

        Design of outdoor power supply systems, outdoor and indoor electric lighting, power electrical equipment and substations;

      • 03

        Design of trunk and intra-block fiber-optic communication lines, video surveillance systems, security and access systems;

      • 04

        Design of external water supply, sewerage, water drainage and drainage, gas supply, and heat supply networks;

      • 05

        Engineering surveys (engineering-topographic; engineering-geodetic; engineering-hydrological, engineering-geological;

      • 06

        Technical inspection of buildings and structures;

      • 07

        ВIM design;

      • 08

        3D laser scanning;

      • 09

        Qualified legal support for projects.

    • MINING & METALLURGICAL ACTIVITIES

      • 01

        Development of design and estimate documentation for the construction of mining facilities;

      • 02

        Adaptation of projects and technological processes in the mining and metallurgical sector of foreign projects and design solutions to Kazakhstani norms and requirements;

      • 03

        Design of roads and railways;

      • 04

        Development of environmental projects;

      • 05

        Industrial safety;

      • 06

        Preparation of tender documentation;

      • 07

        Evaluation and analysis of objects to determine the cost of engineering and design;

      • 08

        ВIM design;

      • 09

        Comprehensive implementation of author's supervision;

      • 10

        Development of projects for related infrastructure facilities for mining, processing and metallurgical industries;

      • 11

        Carrying out engineering survey work.

    • 1. Regulatory framework

      • The architect must work with the standards that will be provided by the client:
      • Sn rk 1.04–… (standards for the composition and design of design documentation)
      • Sn rk 2.02–05–2013 (general plan and layout)
      • Sn rk 3.02–… (public buildings – applicable to administrative buildings and administrative units)
      • Sn rk 2.03-30-2017 (loads and impacts — joint work with rc/cm)
      • Sp rk on fire safety
      • Sanpin rk for industrial production
      • Standards for energy efficiency and thermal engineering of enclosing structures
      • Requirements of the state expertise (too gostroyexpertiza, rse gosexpertiza)
      • International standards (preferred for non-residents)
      • Ibc, nfpa - in terms of industrial safety
      • Ashrae (for collaboration with mep)
      • Iso on ergonomics and warehouses

    • 2. Requirements for qualifications and skills

      Education and experience

      • Specialized education: architecture / industrial and civil construction
      • 3-5 years of work experience, experience in industrial facilities is required
      • Knowledge of production technology:
      • Grain processing
      • Compound feed
      • Mining activities
      • Industrial facilities
      • Work skills

      Confident possession of:

      • Archicad
      • Autocad
      • Navisworks (coordination with kz/km/mep) (desirable)
      • Skill in developing architectural units, including connections with steel structures
      • Understanding the enterprise's technological processes (list of rooms, flows, hygienic breaks)

    • 3. Requirements for architectural solutions at industrial facilities

      3.1. Functional-technological logic

      • Архитектор обязан:
      • Обеспечить правильные входные группы, логистику потоков (сырьё → производство → склад → отгрузка)
      • Учитывать транспорт внутри цеха (электрокары, штабелёры, боковые погрузчики)
      • Закладывать технологические разрывы, санразрывы
      • Учитывать санитарные зоны (внешние)

      3.2. Spatial planning solutions

      • Minimum room heights according to technology
      • Placement of overhead cranes, monorails, hoists
      • Layout of the administrative and amenity buildings
      • Correct location of emergency exits

      3.3. Design solutions (boundary of responsibility)

      • The architect must:
      • Coordinate the design scheme with the kz/km
      • Take into account the placement of columns, steps 6x6, 9x6, 12x24, 24x30
      • Provide openings for technological equipment
      • Be responsible for fire safety decisions:
      • Degree of fire resistance
      • Fireproof walls
      • Evacuation routes
      • Pdv

      3.4. Enclosing structures

      • The architect is obliged to ensure:
      • Heating engineering according to the standards of the republic of kazakhstan
      • Absence of cold bridges
      • Choice of wall material:
      • Sandwich panels
      • Reinforced concrete panels
      • Brick
      • Selection of fire barriers, insulation units, roofing systems
      • A proper system of drainage, storm drains, and internal drainage

    • 4. Interaction with other sections

      4.1. With KZ/KM engineers

      • combination of coordinates, marks, and column sections
      • issuing requirements for openings and apertures
      • wall/truss/column junctions
      • joint bim coordination and clash checks

      4.2. WITH MEP (OV, VK, EO, APS)

      • The architect is obliged to take into account:
      • Shafts, niches, trays, technological channels
      • Ventilation chambers and engine rooms
      • Places for transformer substations, ups, server rooms
      • Sanitary and welfare facilities for staff

      4.3. With the enterprise's technologists

      • The architect is obliged to:
      • Tie in technological lines
      • Take into account sanitary zones inside buildings
      • Provide areas for equipment maintenance
      • Provide dimensions of openings for equipment delivery

    • 5. Results and deliverables (what the architect should deliver)

      5.1. Model (BIM)

      • Full revit ar model
      • Configured levels, axes, connections
      • Sheets with a3 frame "Strong-holding"
      • Dwg export for subcontractors

      5.2. Drawings (set of design estimates)

      • Floor plans
      • Sections and knots
      • Specifications of openings, gates, doors
      • Facades with materials
      • Roof plan
      • General plan (if by an architect)

      5.3. Technical and economic indicators

      • Construction volume
      • Building area
      • Class of consequences
      • Fire resistance rating
      • Category of premises according to vz
      • Functional fire hazard class

    • 6. Quality and responsibility requirements

      • The architect is obliged to:
      • Ensure coordination of all sections
      • Carry out red lines of buildings, tie them into the general plan
      • Take into account fire regulations in each room
      • Issue solutions that avoid reworking of the kz/km
      • Produce nodes and specifications that eliminate ambiguity
      • Ensure the production of drawings in a corporate frame and format

    • 7. Communication requirements

      • The architect must:
      • Participate in all coordination meetings
      • Agree on the technical specifications with the customer
      • Keep a record of questions (rfi)
      • Record all changes in the change-log
      • Respond promptly to comments from the chief inspectorate, expert examinations, and related parties

    • 8. Requirements for discipline and deadlines

      • Strict adherence to the gantt chart
      • Daily task status update
      • Compliance with internal standards of stron-holding
      • Transfer all files via bim360 or a corporate server
      • Maintaining archiving of versions
      • Provide a portfolio

    • 1. THE ENGINEER MUST KNOW AND APPLY

      • SN RK 1.04-05-2011 — composition and execution of design estimates
      • SN RK 2.03-30-2017 — loads and impacts (in collaboration with the designer)
      • SP RK on steel structures
      • SP RK on reinforced concrete structures
      • SN RK 5.03-101-2013 — foundations and foundations
      • SN/SP on fire safety
      • SN on seismic resistance
      • State Expertise Requirements for Volume Design
      • Additionally (preferred)
      • Eurocode
      • AISC / ACI
      • Tekla BIM standards

    • 2. REQUIREMENTS QUALIFICATIONS

      • A KM/RC Design Engineer must have:
      • Education
      • Industrial/Civil Engineering / Construction / Design Engineer

      Experience

      • 3-5 years of KM/RC design development
      • Experience in industrial facilities is required
      • Experience working with:
      • Overhead cranes
      • Process platforms
      • Galleries, conveyors
      • Underground and above-ground foundations
      • Large-span buildings (24-36 m)

      Software proficiency

      • Required:
      • Tekla Structures (proficiency in modeling, labeling, specifications)
      • AutoCAD
      • Desirable:
      • IDEA StatiCa (assemblies)
      • Navisworks (coordination)
      • BIM360 / ACC

    • 3. MAIN KM/RC Design Responsibilities

      3.1. Modeling and Development of KM

      • The engineer is responsible for:
      • modeling the complete 3D building frame
      • designing:
      • columns
      • beams
      • trusses
      • connections
      • stairs
      • landings
      • fences
      • purlins
      • labeling elements in accordance with the Stron-Holding standard
      • designing structural assemblies taking into account the manufacturing technology
      • preparing assembly and detail drawings
      • generating:
      • rolled metal specifications
      • bolt lists
      • weld lists
      • element lists
      • producing drawings in KM and KMD formats

      3.2. Development of reinforced concrete structures

      • The engineer is responsible for:
      • modeling foundations for equipment, columns, and walls
      • generating:
      • reinforcement diagrams
      • reinforcement specifications
      • specifications of embedded parts
      • assembly diagrams for reinforced concrete elements
      • developing:
      • foundation slabs
      • grillage beams
      • basement walls
      • columns
      • floor slabs/beams
      • service platforms
      • providing assemblies:
      • reinforcement joints
      • anchoring
      • reinforcement of openings
      • reinforcements

    • 4. DEVELOPMENT QUALITY REQUIREMENTS

      4.1 The engineer must ensure:

      • Full coordination
      • coordination of reinforced concrete structures with:
      • Architectural design
      • Metalwork (OVP, VK, EO, APS)
      • Technologists
      • Main plan
      • absence of clashes
      • conformity of geometry with architecture
      • verification of all openings, holes, and embedded parts
      • Model accuracy
      • absence of intersections
      • correct orientation of elements
      • correct numbering of callouts and Brands
      • Absence of duplicates and unused elements
      • Compliance with production
      • The structural engineer must consider:
      • GOST rolled metal product sizes
      • Bolt standards: 8.8 / 10.9
      • Welded seams: types, lengths, legs
      • Tolerances of the manufacturing shop and installers
      • The structural engineer must consider:
      • Ease of reinforcement tying
      • Actual joints, releases, and overlaps
      • Formwork installation/dismantling
      • Concreting requirements (temperature, zones)

    • 5. INTERACTION WITH THE CALCULATION DESIGNER

      • The design engineer must:
      • Receive the calculation model and forces
      • Coordinate design schemes
      • Refine:
      • Support nodes
      • Sections
      • Reinforcement types
      • Truss/beam parameters
      • Check the model's compliance with the calculation data
      • Make changes to the design based on the calculation designer's comments

    • 6. DOCUMENTS TO BE ISSUED KM/KZh ENGINEER

      6.1. KM Drawing Set

      • General Information
      • General Frame Views
      • KM Plans
      • Sections
      • KM Assemblies
      • Rolled Metal Product Specification
      • List of Elements
      • List of Welds
      • List of Bolts
      • Details (KMD if necessary)

      6.2. Set of Reinforced Concrete Drawings

      • General Information
      • Foundation Plan
      • Slab/Grillage Reinforcement Diagrams
      • Columns, Walls, Beams, Beams
      • Reinforcement Outlets and Anchors
      • Reinforcement Specification
      • Embedded Parts Specification
      • Reinforcement Joints
      • Coordination Drawings with Measuring Instruments (MEPs), if necessary

    • 7. DESIGN REQUIREMENTS

      • The engineer is responsible for:
      • designing sheets in the Stron-Holding frame
      • adhering to the corporate style and design standards
      • complying with GOST/SN RK requirements for fonts, inscriptions, and numbering
      • naming files according to accepted standards
      • maintaining a Change Log of all changes
      • generating a complete PDF set + DWG/Tekla source files

    • 8. RESPONSIBILITIES OF THE RC/REINFORCED CONCRETE ENGINEER

      • The engineer is responsible for:
      • the accuracy of the drawings
      • the conformity of the model with the design data
      • errors resulting in rework KM/KZ
      • errors identified during construction
      • Quality of documentation
      • Task completion deadlines
      • Compliance with SN RK standards

    • Work Organization Procedure

      • • Access is provided to synchronize with the Stron-Holding LLP server and to the YouGile system for managing project tasks;
      • • Project work is performed in a file available on the Stron-Holding LLP server;
      • • The project file is stored and accessed for work from the synchronization folder linked to the Stron-Holding LLP server;
      • • Daily recording of actual working hours per task is carried out in the YouGile system, indicating the type of work performed;
      • • Payment is official and contract-based.

      General Requirements

      Higher professional education in one of the following fields:

      • “Water Supply and Sewerage”;

      • “Building and Structural Engineering Systems”;

      • Or an equivalent field.

      Design experience in Water Supply and Sewerage systems — at least 5 years, including:

      • At least 2–3 years on industrial and production facilities;

      Willingness to work according to the standards of the Republic of Kazakhstan, regardless of country of residence.

      Regulatory Framework (Mandatory)

      The engineer must know and apply:

      Key standards of the Republic of Kazakhstan, including (but not limited to):

      • Kazakhstani Construction Norms (SN RK) for internal and external water supply;

      • SN RK for sewage systems (domestic, industrial, stormwater);

      • Sanitary regulations and hygiene standards of Kazakhstan;

      • Environmental requirements of Kazakhstan (regarding wastewater discharge and treatment);

      • Fire safety requirements of Kazakhstan (regarding fire-fighting water supply).

      Software

      Mandatory proficiency in:

      • AutoCAD and/or Revit (Water Supply and Sewerage section);

      • Excel — for hydraulic calculations, water and wastewater balances;

      • Skills in reading and verifying engineering networks of related sections.

      Functional Responsibilities

      Development of the WSS section at the Design Documentation (RD) stage, including:

      • Domestic and potable water supply systems;

      • Fire-fighting water supply;

      • Domestic sewage;

      • Industrial sewage;

      • Stormwater drainage;

      • Where necessary — local treatment facilities (LTF), oil traps, grease traps, and other related sections.

      Execution of calculations for:

      • Water consumption;

      • Network hydraulics;

      • Pipe diameters;

      • Selection of pumping equipment;

      • Calculation of reservoirs, pumping stations (KNS), and LTF.

      Development of:

      • Network plans;

      • Profiles of external networks;

      • Axonometric diagrams;

      • Schematic diagrams;

      • Specifications of materials and equipment.

      Coordination with Related Sections

      The WSS Engineer must ensure coordination of solutions with:

      • AR (Architectural Section) — placement of sanitary fixtures, technical rooms, elevation marks;

      • KZh/KM (Structural/Metal Sections) — openings, embedded parts, foundations of pumping stations (KNS) and reservoirs;

      • OV (Heating, Ventilation, and Air Conditioning) — drainage, condensate, water treatment;

      • EOM (Electrical Section) — power supply for pumps, KNS, and local treatment facilities (LTF);

      • TX (Process/Technological Section) — composition and characteristics of industrial wastewater.

      Requirements for Deliverables (Output)

      The project documentation must:

      • Comply with the Construction Norms of the Republic of Kazakhstan (SN RK);

      • Be ready for state expertise/approval in Kazakhstan;

      • Include a complete set of calculations and justifications.

      Documentation formatting:

      • Format — according to the requirements of the Lead Designer;

      • Language — Russian;

      • Correct designations, elevation marks, and slopes.

      Communication and Work Organization

      Working language — Russian.

      Regular communication:

      • Participation in online meetings;

      • Prompt responses to comments from the Chief Project Engineer (GIP).

      Adherence to the approved work schedule and phased project delivery.

      Responsibility

      The WSS Engineer is responsible for:

      • The accuracy of hydraulic and process calculations;

      • Ensuring compliance of solutions with Kazakhstan’s sanitary and environmental requirements;

      • Addressing comments from state expertise/approval related to their section;

      • Revising documentation in case of errors made by the contractor.

      Restrictions and Prohibitions

      The engineer is prohibited from:

      • Independently changing the initial data without approval;

      • Directly contacting the Client or state expertise authorities;

      • Using standard solutions from other countries without adaptation;

      • Sharing materials with third parties.

      Legal and Contractual Conditions

      • The work is performed on the basis of a service/contract agreement.
      • Exclusive rights to the project are transferred to the Client/Lead Designer.
      • Confidentiality is mandatory.
      • Governing law — the legislation of the Republic of Kazakhstan.

      Requirements for Using the YouGile System and Hourly Payment

      The provisions of this section take precedence over other parts of the document regarding time tracking and work acceptance.

      At Stron-Holding LLP, working hours are recorded exclusively in the YouGile task management system, and an hourly payment system is applied based on actual time worked.

      YouGile is used as:

      • A single source of up-to-date tasks;

      • A tool for recording agreements;

      • The basis for milestone acceptance and assessment of completed work.

      The WSS Engineer is required to:

      • The WSS Engineer is required to:
      • • Work exclusively on tasks assigned in YouGile;
      • • Track time for each task in YouGile;
      • • Start work on tasks only after they have been assigned and recorded in the system;
      • • Document in comments any accepted assumptions, changes in calculation schemes, and reasons for deviations from the original solutions;
      • • Attach calculation model fragments, calculation notes, and explanations to tasks;
      • • Keep tasks up-to-date on a daily basis;
      • • Start and stop time tracking precisely when performing the work;
      • • Record in comments the details of completed actions and, if applicable, reasons for increased labor intensity.

      Only the working time that meets the following conditions is eligible for payment:

      • recorded in YouGile;
      • linked to a specific task;
      • accepted by the Client through changing the task status to “Accepted” in the YouGile system.

      Working time that is not recorded in the YouGile system is not subject to payment.

    16.01.2026

    Implementation of BIM Technologies at Stron Engineering (Holding): Advantages, Disadvantages, and Practical Value

    • Implementation of BIM Technologies at Stron Engineering (Holding): Advantages, Disadvantages, and Practical Value

    • In recent years, BIM technologies in design and construction have become an integral part of the operations of modern engineering companies. For holdings that implement complex architectural and engineering projects, the adoption of BIM (Building Information Modeling) is not merely digitalization, but a fundamental shift in the approach to project management.

      Stron Engineering (Holding) uses BIM technologies as a tool to improve design quality, reduce risks, and optimize collaboration among all project participants. This article examines the main advantages and disadvantages of BIM implementation, as well as the practical value of the BIM approach for an engineering holding.

    • What Are BIM Technologies and Why Engineering Companies Need Them

      BIM technologies are a method of information modeling for buildings and structures in which a digital model of an asset is created, containing not only geometry, but also data on structural elements, engineering systems, materials, costs, construction schedules, and operational parameters.

      For engineering and design companies, BIM:

      • integrates architectural, structural, and engineering design;
      • enables project management across all stages of the asset’s life cycle;
      • reduces the number of errors and inconsistencies in design documentation.
      Implementation of BIM Technologies at Stron Engineering (Holding): Advantages, Disadvantages, and Practical Value

      Advantages of Implementing BIM at Stron Engineering (Holding)

      Improved Design Quality and Reduced Errors

      One of the key advantages of BIM-based design is the ability to detect clashes between engineering systems, structural elements, and architectural solutions at the design stage.

      For Stron Engineering, this means:

      • a reduction in the number of design errors;
      • a decrease in the volume of rework;
      • improved quality of working documentation.

      The BIM model becomes a tool for quality control even before the project reaches the construction site.

      A Unified Information Environment for All Project Participants

      The implementation of BIM allows the creation of a single digital environment in which the following participants operate:

      • architects;
      • engineers from all disciplines;
      • BIM coordinators;
      • project managers;
      • clients.

      All changes in the BIM model are automatically reflected in all related elements, eliminating the use of outdated drawings and reducing the risk of uncoordinated decisions.

      Optimization of Construction Schedules and Costs

      The use of BIM technologies in engineering enables more accurate planning of:

      • material quantities;
      • design and construction phases;
      • project budget.

      For the holding, this provides:

      • more accurate cost estimates;
      • a reduction in unforeseen expenses;
      • increased project transparency for the client.

      Efficient Management of Technically Complex Projects

      Stron Engineering (Holding) undertakes projects with high engineering and technological complexity. The BIM approach allows for consideration of:

      • complex engineering systems;
      • non-standard structural solutions;
      • technological processes and client requirements.

      BIM modeling provides the ability to analyze various scenarios and optimize design solutions without compromising the integrity of the model.

      Competitive Advantages and Compliance with Market Requirements

      Today, BIM-based design is increasingly becoming a mandatory requirement for:

      • participating in tenders;
      • working with major investors;
      • executing international projects.

      The implementation of BIM strengthens Stron Engineering’s position as a modern engineering company focused on digital technologies and high quality standards.

      Implementation of BIM Technologies at Stron Engineering (Holding): Advantages, Disadvantages, and Practical Value

      Disadvantages and Challenges of Implementing BIM Technologies

      High Initial Investments

      The main drawback of implementing BIM is the significant upfront costs:

      • licenses for BIM software;
      • upgrading computer hardware;
      • implementation of BIM standards and protocols.

      For an engineering holding, these expenses require strategic planning and a phased implementation approach.

      Staff Training and Changes in Work Approaches

      BIM technologies require not only technical knowledge but also a shift in the mindset of specialists. The transition from traditional 2D design to BIM is accompanied by:

      • the need for staff training;
      • temporary reduction in productivity;
      • adaptation of business processes.

      However, in the long term, these investments pay off.

      Standardization and Coordination Issues

      For effective use of BIM within the holding, it is important to implement:

      • unified modeling standards;
      • coordinated classifiers and libraries;
      • a quality control system for BIM models.

      Without these measures, information modeling can lose its effectiveness.

      Managing Large Volumes of Data

      BIM models contain substantial amounts of information, requiring:

      • reliable storage;
      • data updates and maintenance;
      • information security.

      This increases the demands on the company’s IT infrastructure and internal processes.

      Short-Term and Long-Term Effects of BIM Implementation

      At the initial stage of BIM implementation:

      • costs increase;
      • staff workload rises;
      • process restructuring is required.

      In the long term:

      • design quality improves;
      • the number of errors and rework decreases;
      • schedules and budgets are optimized;
      • the company’s competitiveness is strengthened.

      Conclusion

      The implementation of BIM technologies at Stron Engineering (Holding) is a strategic decision aimed at enhancing the efficiency of design and construction project management. Despite the challenges and upfront investments during the implementation phase, BIM enables the holding to establish a robust digital workflow that meets modern market requirements.

      Proper BIM implementation, staff training, and the development of internal standards transform BIM technologies from an expense into a tool for long-term growth and increased value for clients.

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