Revitalization and Extension of Supporting Structure of Stage Roof in State Playhouse Dresden, Germany
|Structural Analysis||KREBS+KIEFER Ingenieure GmbH
|Project Planning||Architekturbüro Wagner
|Investor||Saxonian Real Estate and Construction Management
Length ~ 33 m | Width: ~ 16 m | Height: ~ 9 m | Weight: ~ 16 t
Number of Nodes: 2,516 | Members: 4,077 | Materials: 4 | Cross-Sections: 91
The theatre built from 1911 to 1913 has a varied history. The building was destroyed by the Allied air attacks in February 1945, reconstructed in the post‑war years, and damaged by floods in August 2002. Within an 18‑week break, the Dresden theatre has been was extensively renovated and modernized.
Due to the short time limit, there were up to 230 workers on site, working in three shifts. Among other things, the construction included the renovation of the stage equipment and strengthening the roof structure of the stage tower. KREBS+KIEFER engineers scrutinised the stability of the stage roof using RSTAB. The stability analysis detected deficiencies in load‑bearing capacity, which required reinforcement measures.
Roof Structure of Stage Tower
The total height of the stage tower is about 38 m, measured from the stage floor to the top of the roof. The primary structure of the roof consists of five steel trusses arranged parallel to each other. The trusses have a height of 4.1 m and a span of about 32.2 m, and are placed on reinforced concrete columns. The top chord nodes of the outer truss girder are partially braced on the existing walls by inclined members. Together with the members perpendicular to the trusses, an additional load transfer occurs in the transverse direction, which can be taken into account by 3D modelling in RSTAB.
In the bottom chord plane of the truss girder, there is a new fly loft including twelve point hoists with a self‑weight of 4.0 kN, among other things. Rope lines are used for moving loads of up to 5.0 kN, such as stage sets, decorations, lighting equipment, etc. Furthermore, the old machines were replaced by new, heavier ones, and various imposed loads were increased.
For the design of structural components and connections, the acting internal forces in the current state were determined in the analytical model. In another model, all new structural components were added and the newly entered permanent and variable loads were applied. Using super combinations, it was possible to superimpose the internal forces and perform the ultimate limit state design.
The structural recalculation for the final state after installing the new stage equipment resulted in overloading various structural members. This required the implementation of various reinforcement measures. For example, the load of the most loaded outer truss girders was reduced by implementing diagonal bracing to the adjacent trusses in the transversal direction. Also, numerous site joints and node areas had to be reinforced by arranging supplementary metal plates and replacing rivets by fitted bolts with a higher load‑bearing capacity.
On 29. October 2016, the successful renovation project with the total cost of € 11 million was celebrated by performing Shakespeare's Othello.Source
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Programs Used for Structural Analysis
The structural engineering software for design of frame, beam and truss structures, performing linear and nonlinear calculations of internal forces, deformations, and support reactions
Stress analysis of steel members
Superpositioning results of different construction stages with varying structural and loading conditions