“The O'Sea project includes a series of lower buildings, but the real eye-catcher is the 16-story high residential tower,” Koen Coelus starts. “The floor plan of this tower is simple enough: a rectangle of 17 by 25 meters. What makes the building stand out is that over four successive floor levels the floor plan is revolved over more than 2.5° with respect to one of the corners, giving the tower building its characteristic distorted look. Unsurprisingly, managing torsional loads is the most important structural challenge for this building."
"To understand what is happening here," Maarten Vervaet explains, "it is interesting to zoom in on the four floors which this story is all about. Although a rotation of more than 2.5° per floor level does not seem to be so much, it does imply that the most distant corner point on any floor shifts horizontally by about 137cm. If you look at that over the four floors combined, it is evident that a shift of 5.5m cannot remain without any consequences for the layout of the living spaces in this building. Interior walls must be moved to guarantee spacious and comfortable living spaces for the residents on each floor. And columns should also move along while rotating the four floors, to transfer permanent and service loads to the lower floors.
Over four successive floor levels, the rectangular floor plan of the O'Sea tower is revolved over more than 2.5° with respect to one of the corners. To account for the related horizontal shifts, interior walls must be moved, and columns should move along as well.
The rotation of the four floors with respect to a corner point gives rise to an eccentricity between the resultants of the permanent loads for the successive floor levels. The outcome is a torsional load on the load-bearing structure. This torsional load induces horizontal deformations even when the building structure is subjected to vertical loads only. The analysis and the management of these deformations is one of the challenges that we resolved through a 3D structural analysis using Diamonds.
The O'Sea tower’s rigid central core is of crucial importance in this respect. Starting at the central core, load-bearing concrete walls radiate towards the facade of the building. These walls are rigidly connected to the floor slabs, which provides the torsional rigidity that is needed to resist the torsional load on the building structure. The rigid floor slabs accommodate the horizontal component of the torsional load and transfer the related horizontal loads to the concrete walls and the central core. That makes it possible to design the slanted columns as hinged at both ends. Additional vertical columns are provided where it is necessary to support load-bearing interior walls.
As mentioned before, the analysis of the horizontal deformations was one of the most important objectives for the 3D structural design analysis using Diamonds. In fact, these analyses confirmed that the permanent loads, self-weight in particular, had by far the most significant impact on the horizontal deformations. Horizontal deformations under the effect of wind loads were found to be even smaller than the horizontal deformations due to the building's self-weight."
Opening up new skylines
"Although our project portfolio includes a wide range of building structures, this high-rise building is typical of how we think and work," Koen Coelus concludes. "Since 1985 I have seen the construction industry change dramatically. It is only by staying alert to these changes that Stedec NV has become what it is today. Opening up new horizons, that's what matters to us. Or maybe it is more appropriate to say: opening up new skylines?"
Stedec is a firm for structural engineering, specialized in developing and calculating building structures in concrete and steel. Stedec is one of the most important firms for structural engineering in West Flanders and each year Stedec is responsible for the structure of buildings with a total value of over 300 million Euros in the inland as well as in foreign countries.
Nowadays, a structural engineering is an important participant in the building process and in the building team. In cooperation with the project manager, the architect and general contractor, we always look for the most economic and optimal structural solution for each building. Because of the tight schedules and completion periods becoming shorter and since there is a lack of qualified construction workers, an integrated precast structure is the only solution. From the start, Stedec develops the most efficient precast structure for residential buildings as well as for office buildings.
From this point of view, Stedec provides not only the common structural engineering, but also studies where the formwork plans already take into account an execution in precast concrete. Furthermore, Stedec has the know-how to make production drawings of precast concrete elements, which can directly be implemented into the production process of the precast manufacturer. We can also adapt and optimize existing studies of structures in situ into a fully precast structure.
A BIM-model becomes the more and more important in construction. Stedec has the necessary know-how and software to be a full partner in de BIM-process of each project.
Structural engineering office Stedec was founded in 1985 by Koenraad Coelus, and has been acquired since 1 january 2018 by VK Engineering, part of the group VK Architects & Engineers.
BuildSoft customer since 1989