SPATIAL TRANSFORMATION OF STRUCTURAL ELEMENTS OF MODERN COATINGS SHELLS
DOI:
https://doi.org/10.31650/2707-3068-2020-24-71-80Abstract
Currently, the principles of adaptive architecture are most often used in the practice
of building unique large-span spatial shell coverings. Constructed buildings and structures acquire
artificial intelligence for economical and comfortable operation and can use computer programs to
respond to changing environmental conditions. Such buildings and structures consist of structural
systems capable of transforming to meet the needs of operation. The particular complexity of the
design of transformable spatial structural systems is that their design scheme changes significantly
during operation, and all numerous extreme changes must be predicted in advance.
Structures that can change their geometric dimensions, that is, transform during operation, are
considered in the article to solve the problems of adaptive architecture to create the proper
microclimate inside buildings and structures.
Only spatial structures consisting of elements of complex displacement in space were
identified in the research, although there are many constructed transformable shells of coverings
with a simpler transformation in space (horizontal, around a vertical axis, along the guiding support
elements of the surface of the transfer shells).
The development of such structures has many directions. One of the most difficult is the
development of mobile structures in the space industry, when a large-sized structure packed in a
container of minimum dimensions is delivered into orbit, and in orbit it automatically opens to the
required dimensions.
Modern approaches to the transformation of structures are given, which were highly
appreciated during the new construction, reconstruction and operation of buildings and structures,
and are promising for further research and application. For examples, spatial shell structures were
used, as well as those operation and construction of which are carried out using computer programs.
The analysis of the constructed shells of various shapes using pneumatic formwork to obtain
mathematical models to determine the optimal overall dimensions and use in the design.




