ВИЗНАЧЕННЯ ГЕОМЕТРИЧНИХ ХАРАКТЕРИСТИК ШПУНТУ ДЛЯ РОЗРАХУНКІВ ДЕФОРМУВАННЯ ТОНКИХ СТІНОК У 2D ПОСТАНОВЦІ
DOI:
https://doi.org/10.31650/2707-3068-2020-24-11-18Abstract
One of the most common structural schemes used in the construction and reconstruction
of berths - is a thin wall (bolverk). This system consists of a front wall and an anchor system, which
includes a string and an anchor wall (or other type of anchoring device). There are some variations
of the design scheme, but each of them includes a front wall of sheet piling. The paper presents
options for determining the geometric characteristics of sheet piles for use in the calculations of flat
deformation (flat design model). In the standard assortments of sheet piling, only the general
geometrical characteristics of the section such as area, moment of inertia, moment of resistance,
radius of inertia are given, but this is not enough for use in finite element calculations. The complex
shape of the cross-section of the sheet pile (zeta, trough, straight, combined and other types of
cross-section) leads to differences in the definition of geometric characteristics and their
interpretation in the flat and spatial formulation of the stress-strain state. The paper presents a
method for determining the geometric characteristics of the cross section for a bending rod for a flat
design model. For finite element calculations, the lost complex for geotechnical calculations Midas
GTS NX is used. The use of the finite element method in determining the geometric characteristics
of the cross section of the sheet pile gives a relative error of up to 5% relative to the data given in
the range. What is acceptable for use in further calculations of berth structures. The paper considers
two options for one meter of the running wall: 1 m includes 1 tongue completely 600 mm and the
second partially 400 mm; in 1 m both sheet piles on 500 mm enter. The lowest value of the moment
of inertia was obtained for the first variant 72511 cm4, which coincides with the value from the
range by -0.26%. And for the second option, the moment of inertia is more than 12%. Therefore, the
calculations should take the most unfavorable option.




