Structural Mechanics of Engineering Constructions and Buildings

Строительная механика инженерных конструкций и сооружений

1815-52352587-8700

Peoples’ Friendship University of Russia named after Patrice Lumumba (RUDN University)

33411

10.22363/1815-5235-2022-18-5-444-457

Analytical and numerical methods of analysis of structures

Аналитические и численные методы расчета конструкций

Research Article

Influence of the soil base on the stress-strain state of a large-span building with a cylinder-and-slab roof

Влияние грунтового основания на напряженно-деформированное состояние большепролетного здания с цилиндро-плитным покрытием

https://orcid.org/0000-0002-0907-786X

Kuzhakhmetova

Elvira R.

Кужахметова

Эльвира Рафаэльевна

engineer, senior lecturer, Department of Reinforced Concrete and Stone Structures

инженер, старший преподаватель, кафедра железобетонных и каменных конструкции, Институт промышленного и гражданского строительства

elja_09@bk.ru

https://orcid.org/0000-0002-4911-8515

Sutyrin

Valerii I.

Сутырин

Валерий Игоревич

Doctor of Technical Sciences, Professor, Head of the Institute of Engineering and Technology

доктор технических наук, профессор образовательно-научного кластера «Институт высоких технологий»

vsutyrin@mail.ru

Moscow State University of Civil Engineering (National Research University)Национальный исследовательский Московский государственный строительный университет

Immanuel Kant Baltic Federal UniversityБалтийский федеральный университет имени Иммануила Канта

15122022

185

VOL 18, NO5 (2022)

ТОМ 18, №5 (2022)

44445729012023

2022

Kuzhakhmetova E.R., Sutyrin V.I.

Кужахметова Э.Р., Сутырин В.И.

https://creativecommons.org/licenses/by-nc/4.0

https://journals.rudn.ru/structural-mechanics/article/view/33411

The authors consider finite element models of a large-span building with a cylinder-and-slab roof as a large spatial mechanical system with different boundary conditions. The first model represents the superstructure of the building with a fixed-end at the soil base level. In the second model, the superstructure is based on the substructure, which includes a pile foundation and a soil base with different physical and mechanical properties. The purpose of the study is a comparative numerical analysis of the stress-strain state of a large-span building with different boundary conditions. The numerical study revealed the influence of the structural features of the substructure of the building, as well as the physical and mechanical properties of the soil base on the stress-strain state of the long-span roof and the building as a whole. Numerical static analysis of spatial finite element models of a large-span building was carried out in the СAE class Femap NX Nastran software package. The results of the static analysis demonstrated a significant structural influence of the substructure of a large-span building on the characteristics of its stress-strain state. In the next article, it is proposed to conduct a modal analysis for these building models.

Рассмотрены конечно-элементные модели большепролетного здания с цилиндро-плитным покрытием как большой пространственной механической системы с разными граничными условиями. Первая модель представляет конструкцию надземной части здания с жесткой заделкой на уровне основания. У второй модели конструкция надземной части опирается на подземную часть, включающую свайный фундамент и грунтовое основание с разными физико-механическими свойствами. Цель исследования - сравнительно-численный анализ НДС большепролетного здания с разными граничными условиями. В ходе численного исследования выявлено влияние конструктивных особенностей подземной части здания, а также физико-механических свойств грунта на напряженно-деформированное состояние большепролетного покрытия и здания в целом. Численный статический анализ пространственных конечно-элементных моделей большепролетного здания проводился в программном комплексе САЕ класса Femap NX Nastran. Результаты статического анализа продемонстрировали существенное структурное влияние подземной части большепролетного здания на характеристики его НДС. В следующей статье предполагается провести модальный анализ для указанных моделей здания.

finite element methodsystembuildingstructurelarge-span buildingcylindrical roofcylindrical-and-slab roofpilerammed pilebored pilecone-shaped pileconical pilecone-shaped pile

метод конечных элементоврасчетная модельсистемазданиесооружениебольшепролетное зданиепространственное покрытиецилиндрическое покрытиецилиндро-плитное покрытиесваянабивная сваябуронабивная сваясвая в форме конусасвая конической формысвая конусообразной формы

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