Cutting-edge breakthrough
BCI Group adheres to technological innovation and vertical integration, proactively developing basic resources such as energy, water, land, and networks with a forward-looking approach. By increasing R&D investment, the Group drives the effective integration of fundamental elements in the computing infrastructure industry chain.
Green Power Integration Architecture
The BCI Green Power Integration Architecture is designed for the BCI Super Energy Complex Infrastructure Cluster. As the world’s first demonstration zone featuring physical grid connection, localized consumption, and fully integrated “source-grid-load-storage” coordination across the entire industrial chain, it aims to fully unlock and leverage the regulatory potential of both the power supply side and the demand side. To this end, BCI has constructed large-scale wind and solar power bases, high-performance transmission systems, and energy storage stations near the infrastructure campus. These facilities work in tandem with the local power grid and peak-shaving resources such as thermal power to ensure a continuously increasing proportion of green electricity used by the infrastructure and the entire upstream and downstream industrial chain.
Extended-Duration Shared Energy Storage Station Technology
BCI integrates the backup power systems of traditional infrastructure and relocates them in an integrated manner to comprehensive energy stations, establishing Extended-Duration Independent Energy Storage. This approach grants the systems public infrastructure status, enabling them to be dispatched by the grid to participate in peak shaving, frequency regulation, and other grid services, thereby generating corresponding revenue and enhancing asset utilization efficiency.
Water-Side Natural Cooling Technology
A surface water cascade recycling plant will be introduced around the infrastructure campus to provide an open-loop natural cooling source for campus heat dissipation. By combining and staging the use of two free cooling sources—"air" and "water"—year-round natural cooling will be achieved. This approach is expected to deliver 15%–20% energy savings and reduce water consumption by approximately 60%.
Fully Prefabricated Campus-Wide Construction
During the construction of its campus buildings, BCI adopted a fully prefabricated approach by utilizing a precast concrete frame structural system. Key building components such as beams, columns, and exterior walls were entirely prefabricated, significantly accelerating the construction timeline while enabling green and zero-carbon deployment across the campus.
