Technord Verkor

• Objective & Scope: Designed the complete cable tray routing and supporting structures required for the facility's electrical systems.
• Coordination Process: Executed rigorous 3D clash detection to identify and resolve spatial conflicts between different engineering disciplines prior to construction.
• Final Deliverables: Generated precise, ready-to-use execution documents and extracted comprehensive Bills of Quantities (BOQs) to guide the on-site installation teams.

Sweco Takeda

• Objective & Scope: Integrated complex electrical systems and data utilizing Building Information Modeling (BIM) to create a comprehensive digital twin of the building's infrastructure.
• Modeling Process: Developed detailed 3D models encompassing distribution panels, containment raceways, lighting, and integrated security and communication networks (including CCTV and intercom systems).
• Coordination Process: Actively managed the model to identify and resolve interdisciplinary clashes between the electrical routing, structural components, and HVAC systems.
• Final Deliverables: Extracted updated Bills of Quantities (BOQs) and generated fully coordinated 2D plans for seamless site execution.

Technord Krug

• Objective & Scope: Engineered the electrical infrastructure layout, focusing on cable tray routing and the design of custom hanging structures for complex electrical cabinets.
• Modeling Process: Created highly accurate 3D families for liquid pumps and their related accessories (flow meters, valves, pressure and level sensors) based strictly on real-world dimensions and technical data sheets.
• Coordination Process: Continuously resolved multidisciplinary clashes, ensuring the electrical components integrated flawlessly with existing structural and HVAC elements within the main model.

LAU Solar Panels

• Objective & Scope: Collaborated closely with engineering and project management teams to define requirements and design the complete infrastructure for a solar installation.
• Engineering Process: Calculated precise voltage drops for each string while designing detailed 2D and 3D electrical layouts for stringing, cable trays, and earthing.
• Structural Integration: Created comprehensive structural drawings and Bills of Quantities for the steel framework required to support the solar array.
• Execution Support: Ensured all deliverables strictly met consultant standards, continuously updating designs to accommodate site modifications and directly supporting the installation team with on-demand technical details.

NLWE

• Objective & Scope: Designed the essential structural foundations and electrical room layout necessary to support a large-scale PV panel installation.
• Structural Process: Prepared detailed structural drawings for the concrete foundations supporting the steel framework, including the extraction of precise bar bending schedules for steel reinforcement.
• Modeling Process: Developed a comprehensive 3D model of the project's electrical room to ensure accurate spatial planning and equipment integration.

Elo Energy - Pylones SAS

• Objective & Scope: Digitized an existing pylon structure to create a highly accurate 3D representation for subsequent engineering evaluation and planning.
• Data Processing: Extracted and processed complex spatial data directly from raw point cloud files to translate real-world scans into precise digital models.

Ekium

• Objective & Scope: Executed the comprehensive 3D modeling of a building's entire interior electrical, lighting, and security infrastructure.
• Modeling Process: Detailed all hardware components within the BIM environment, including primary distribution panels, containment raceways, lighting layouts, and integrated security devices like CCTV and card readers.
• Final Deliverables: Extracted highly detailed 2D plans and cross-sections from the completed 3D model to serve as precise execution documents for the construction teams.

Endexia UCB Laboratory Revamping

• Objective & Scope: Electrical revamping project of Room 0.2.16 in Building R9 for UCB in Braine-l'Alleud, Belgium, aimed at partially converting an existing storage area into a histopathology laboratory.
• Execution Process: The scope includes decommissioning of existing installations, modification of electrical panels, implementation of new power and lighting distribution systems (normal/emergency/UPS), cable tray routing, sockets, grounding, commissioning, regulatory compliance, and handover of the as-built documentation, in accordance with the technical and HSE standards of the pharmaceutical site.

Endexia Saudi Bio Quality Control Laboratory Extension

• Objective & Scope: Electrical infrastructure project for the new QC Area of Saudi Bio in Riyadh, involving the design and implementation of complete power distribution, UPS backup systems, cable routing, sockets, LED lighting, grounding, fire detection, and gas extinguishing systems.
• Standards Compliance: The project was developed to meet pharmaceutical GMP standards, international electrical codes, and operational reliability requirements for laboratory and quality control facilities.

Endexia PolyPeptide Production Area Revamping

• Objective & Scope: The project consists of the electrical and instrumentation revamping of the H2 production area for Project NO 038 at PolyPeptide. It includes the dismantling of existing installations and the implementation of new low-voltage power distribution (normal, emergency, and UPS), lighting systems, power outlets, HVAC electrical supplies, interlocking airlock systems, fire and gas detection, data communication networks, purified water user points, and environmental monitoring integrated with DeltaV and BMS systems.
• Execution Process: The works are executed in two phases, including a shutdown intervention and a new installation phase, while ensuring compliance with GMP, safety, and applicable electrical standards.

Endexia UCB T1 Building Extension

• Objective & Scope: The project consists of the extension and partial renovation of the T1 building for UCB, mainly to support microbiology and chemistry activities. It involves the design, supply, installation, and commissioning of a complete electrical and instrumentation (E&I) infrastructure, including low-voltage power distribution, lighting (normal and emergency), cabling systems, and earthing.
• System Integration: In addition, the project integrates multiple safety and building systems such as fire detection, access control, CCTV, gas detection, and automation interfaces, all connected to existing installations.
• Execution Focus: The works are executed in phases within an operational site and must comply with strict regulatory and technical standards to ensure safety, reliability, and performance.

Endexia GSK Decontamination Station Revamping

• Objective & Scope: The project consists of the replacement and upgrade of existing decontamination stations (A, B, C, and D) within a GSK facility due to equipment obsolescence, while ensuring continuous operation of the system. It includes the installation of new decontamination units, a new acid station with automated PLC control, and the integration of building automation, process control, and data systems.
• Execution Process: The scope also covers electrical works (power distribution, cabling, panels), dismantling of existing installations, and installation of new equipment, along with control systems such as access control and alarm management.
• Operational Continuity: The project is executed in multiple phases to maintain operational continuity, with full testing, commissioning, and compliance with strict GSK standards and safety requirements.

Endexia UCB B7 & B8 Electrical Resilience

• Objective & Scope: The project consists of a resilience study of the high-voltage and low-voltage electrical distribution network supplying buildings B7 and B8 at UCB, where reliable power is critical for sensitive research activities. It involves analyzing the existing installations through on-site data collection and detailed network modeling, followed by simulations to assess performance under fault conditions.
• Analysis & Findings: The study evaluates key aspects such as load flow, short-circuit currents, protection selectivity, and arc flash risks in order to identify weaknesses in the system. Based on these findings, it defines risks, assesses the robustness of the network, and proposes a prioritized action plan to improve reliability, safety, and continuity of electrical supply.

Sweco GSK Electrical Compliance Dossier

• Objective & Scope: The project consists of the development of an electrical compliance dossier for GSK’s facilities WN18, WN21 and WN22 in Wavre, involving detailed on-site surveys, verification, and updating of existing electrical data. It includes checking and validating electrical installations (panels, circuits, cabling, and protection systems), updating calculation notes and drawings (via ELEC-CALC and EPLAN), and identifying safety-critical elements such as arc flash risks and security circuits.
• Execution Process: The mission is carried out by coordinated teams and executed in phases, combining field data collection with engineering analysis, with the objective of ensuring that all installations meet current standards, are properly documented, and operate safely and reliably.

Sweco GSK UPS Feasibility Study

• Objective & Scope: The project consists of a feasibility study for the installation of new uninterruptible power supply (UPS) systems in buildings RX60, RX62, and RX64 at the GSK site in Rixensart, where continuous power is critical for research and development activities. It involves replacing obsolete UPS units with a redundant architecture of two high-capacity UPS systems capable of supplying all three buildings and ensuring uninterrupted power in case of failure.
• Design & Planning: The study covers multidisciplinary aspects including electrical design, civil works, HVAC, fire protection, access control, and alarms, while defining technical solutions, constraints, budget estimation, and execution planning to guarantee reliability, safety, and compliance with GSK standards.

Sweco GSK Solar Carport Feasibility Study

• Objective & Scope: The project consists of a feasibility study for the installation of solar carports in the parking areas WN32 and WN35 at the GSK Wavre site, aiming to produce renewable energy while maintaining existing parking capacity. It evaluates technical solutions for integrating photovoltaic panels mounted on carport structures, with options capable of generating up to approximately 1100–1260 MWh per year and supplying nearby buildings.
• Engineering & Integration: The scope includes the design, supply, installation, and connection of electrical systems such as panels, inverters, cabling, and distribution boards, as well as integration with the existing low- and high-voltage infrastructure. The project also defines execution planning, cost estimation, and system monitoring, ensuring a reliable, sustainable, and compliant energy solution.

Sweco UCB Electrical Cabinet Remediation

• Objective & Scope: The project consists of the remediation and updating of electrical cabinets for buildings R4 and R5 at UCB using EPLAN, aimed at ensuring accurate, compliant, and reliable electrical documentation. It involves verifying on-site installations, identifying discrepancies with existing drawings, and updating schematics in EPLAN, including circuits, components, and labeling.
• Standardization: The objective is to standardize documentation, improve traceability, and ensure that all electrical cabinets meet UCB standards, thereby facilitating maintenance, troubleshooting, and future system modifications.

Technord Transformer Cabinet Revamping

• Objective & Scope: The project consists of the revamping of transformer cabinets and the development of detailed electrical documentation, including the creation of multi-line electrical diagrams and a 3D model of the electrical cabinet via Eplan. It involves upgrading or reorganizing existing transformer panels to meet current technical and safety standards, while accurately representing all components, connections, and power circuits in the multi-line drawings.
• 3D Integration: In parallel, a 3D execution of the cabinet is developed to visualize the physical layout, optimize component placement, and facilitate installation and maintenance, ensuring a reliable, compliant, and well-documented electrical system.