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DTU B112 Research Center/Christensen & Co Architects
Text description provided by the architect. The open and visionary building B112 creates a framework for knowledge sharing and innovation. Here, researchers and students conduct resource recovery experiments in state-of-the-art functional laboratories with state-of-the-art working environments. Glass walls between laboratories encourage interdisciplinary collaboration, just as warm breakout spaces encourage organic contact between people.
The new laboratory building is a beacon of resource efficiency research innovation at DTU Sustain. The unique exterior reflects golden tones in the sunlight, giving the building a contemporary appearance that echoes the groundbreaking research conducted within. Large windows give the building an open and inviting appearance, drawing passersby into the building. Openness is also a key feature of the building’s interior, as the many windows allow the house’s users to feel its activity. This creates the framework for a strong community with knowledge sharing at its core, while nurturing a creative and scientific environment.
Recycle. B112’s state-of-the-art facilities provide an ideal environment for innovative research in resource recovery and recovery. The overall layout idea is that gross functions occur on the ground floor, while more refined and analytical functions occur on the upper floors. The first floor also houses a sample reception area where trucks can unload. From here, the materials are sorted and distributed throughout the building for further processing in the laboratories on floors 1 and 2. Glass walls between laboratories allow students and scientists to be inspired by experiments taking place throughout the building. Windows on the façade allow daylight to stream into the building, while scientists can enjoy views of the surrounding green space, a quality that contributes to health and well-being in a working and learning environment.
Cooperation is key. From the laboratories and offices, the house’s users have easy access to the adjacent lounge area. Here they can share knowledge with their peers and experience a sense of community. On all three floors of the house we created spaces that support interdisciplinary collaboration and organic social contact. From the flexible conference center at the entrance, which can accommodate group work, exhibitions and large institutional meetings, to the three-story lobby, which visually connects all floors and allows overhead light to flow throughout the house. The house’s open architecture creates a calm atmosphere, allowing users to see the surrounding buildings, green spaces and the building’s own green courtyard.
Ambitious. Building B112 demonstrates DTU’s high level of sustainability ambitions. In order to make informed decisions related to sustainability, we conducted multiple life cycle assessments (LCA) starting from the initial stages of the design process. In particular the analysis of massing, construction principles, facade materials, insulation and flooring materials influenced further projects. We let the results of the LCA assessment guide the design process through to the final design, delivering innovative solutions that met DTU’s ambitions. The project was completed prior to LCA’s request.
In order to meet the high demands for flexibility and sustainability, especially with regard to material consumption, the column/beam principle was chosen as the structural system. Traditionally, laboratory construction would involve load-bearing facades to accommodate the need for long spans and efficient installation routes. The same degree of flexibility can be achieved over time by integrating the facade columns into the facade structure. This allows the creation of laboratories within spaces originally designated as office areas. Likewise, open-plan offices can be arranged on one side of the wider laboratory.
The building has received DGNB Diamond certification. In order to ensure the high architectural quality of the solution, we actively cooperate with DGNB Diamond in project development. For example, we orient the building according to light conditions and install glass walls between laboratories to ensure low energy consumption and a good indoor climate. In addition, we carefully select materials according to circular principles, ensuring that we not only minimize the variety of materials, but also according to life cycle quality. We also prioritized architectural flexibility so that the building can adapt to the growth of the research community, maintaining functionality throughout its life cycle.
Vision for the future. The building provides an optimal framework for research in the field of environmental and resource studies. Facilities include modern facilities for receiving, handling and processing surplus products. The building also houses microbiology laboratories, metal and organic laboratories. The plan proactively plans for future needs, making the laboratory layout flexible and able to adapt to changing needs. This is achieved by arranging vertical shafts and horizontal ducts to allow ample room for future upgrades/expansion.
For the main layout of the technical installation, the requirement was that parts could be changed without affecting the surrounding areas/floors, and that rooms and sub-areas could be isolated/disconnected individually. Equipment is connected with as few obstacles as possible to allow for free layout and use of the laboratory. Installation is ready for maximum flexibility. Vertical main lines should be dimensioned to ensure maximum consumption on any floor. Therefore, it is a unique laboratory building that can accommodate approximately 18 researchers and students every day.
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