This project involved the reconstruction of an existing bitumen storage facility and the expansion of processing capacity through the installation of additional storage tanks.
The key challenge was ensuring reliable handling of highly viscous bitumen, requiring continuous heating across tanks and pipelines. Our team developed a fully coordinated pipe-in-pipe heating system using diathermic oil, supported by detailed thermal calculations and custom heat-exchange solutions.
All pipeline systems were designed for prefabrication and modular installation, reducing on-site complexity and ensuring constructability under tight operational constraints.
The project involved the construction of an underground diesel fuel storage facility designed to supply test stands with a reliable and controlled fuel system.
The facility includes a receiving area with loading and unloading operations, an emergency tank, and three receiving tanks, as well as a dispensing section consisting of eight dispensing tanks equipped with fuel filtration and metering systems.
The scope also covered underground pipeline installation in non-walkable utility channels, construction of a pipe rack connecting to an existing building, and the implementation of a lightning protection system for the entire facility.
The project focused on upgrading an existing gas distribution system through the installation of ultrasonic natural gas metering units at a CHP plant.
Laser scanning was used to accurately capture existing pipelines and steel structures, which were then reproduced in a coordinated BIM model. This allowed seamless integration of new equipment and contributed to reduced design risks, shorter implementation timelines, and optimized project costs.
During the project, we were responsible for the installation layout of process equipment and associated piping within a three-story industrial building.
The primary challenge was accommodating a large evaporation unit occupying two full floors while maintaining continuous access for operation and maintenance.
A detailed BIM model of the internal engineering systems was developed and used to generate coordinated layouts, 3D views, and visual representations. Based on this model, construction documents were prepared to support installation and construction activities.
In collaboration with international partners, we provided engineering and BIM support for a molasses processing facility within a large sugar production complex. The visualizations represent one of the main process buildings of the plant.
The project required close coordination with equipment procurement, construction, and installation activities. Design adjustments were implemented in parallel with ongoing site works, requiring a flexible and well-coordinated engineering approach.
A detailed BIM model was used to support design coordination and construction execution. This enabled efficient implementation of design changes, alignment between the model and construction documents, and optimization of project cost and schedule.
Our team designed an autonomous water cooling system comprising a block pumping station, modular cooling towers, and water storage tanks.
All engineering was developed within a coordinated BIM environment. Based on the BIM model, construction documents were prepared and used for installation and construction works.
The site was characterized by a compact layout, efficient engineering solutions, and a modular assembly approach, enabling effective use of space and streamlined installation.