Учебное пособие 800539
.pdfISSN 2219-1038
СТРОИТЕЛЬНАЯ МЕХАНИКА И КОНСТРУКЦИИ
Научный журнал
Выпуск № 3 (26), 2020
Строительная механика и сопротивление материалов
Прикладные задачи механики деформируемого твердого тела
Механика грунтов
Расчет и проектирование металлических конструкций
Расчет и проектирование железобетонных конструкций
Расчет и проектирование конструкций из полимерных материалов
Расчет и проектирование мостов и транспортных сооружений
Расчет и проектирование оснований и фундаментов зданий и сооружений
Прочность соединений элементов строительных конструкций
Динамическое воздействие подвижной нагрузки на упругие системы
Экспериментальные и натурные исследования конструкций и материалов
Воронеж
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СТРОИТЕЛЬНАЯ МЕХАНИКА И КОНСТРУКЦИИ
НАУЧНЫЙ ЖУРНАЛ
Издается с 2010 г. |
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Учредитель и издатель – федеральное государственное бюджетное образовательное учреждение высшего образования «Воронежский государственный технический университет».
Территория распространения — Российская Федерация.
РЕДАКЦИОННАЯ КОЛЛЕГИЯ ЖУРНАЛА:
Главный редактор: Сафронов В. С., д-р техн. наук, проф., Воронежский государственный технический университет
Зам. главного редактора: Козлов В. А., д-р физ.-мат. наук, проф., Воронежский государственный технический университет
Ответственный секретарь: Габриелян Г.Е., канд. техн. наук, доцент, Воронежский государственный технический университет
Буренин А. А., д-р техн. наук, проф., чл.-корр. РАН, Институт машиноведения и металлургии Дальневосточного отделения РАН, г. Комсомольск-на-Амуре Гриднев С. Ю., д-р техн. наук, проф., Воронежский государственный технический университет
Зверев В. В., д-р техн. наук, проф., Липецкий государственный технический университет Ефрюшин С. В., канд. техн. наук, доцент, Воронежский государственный технический университет Кирсанов М. Н., д-р физ.-мат. наук, проф., Национальный исследовательский университет «МЭИ»
Колчунов В. И., д-р техн. наук, проф., академик РААСН, Юго-Западный государственный университет Леденев В. В., д-р техн. наук, проф., Тамбовский государственный технический университет Нгуен Динь Хоа, канд. техн. наук, Национальный строительный университет, Вьетнам
Нугужинов Ж. С., д-р техн. наук, проф., Казахстанский многопрофильный институт реконструкции и развития Карагандинского государственного технического университета, Казахстан Овчинников И. Г., д-р техн. наук, проф., Саратовский государственный технический университет
Пшеничкина В. А., д-р техн. наук, проф., Волгоградский государственный технический университет Трещев А. А., д-р техн. наук, проф., чл.-корр. РААСН, Тульский государственный университет Турищев Л. С., канд. техн. наук, доцент, Полоцкий государственный университет, Беларусь
Шапиро Д. М. |
, д-р техн. наук, проф., Воронежский государственный технический университет |
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Шимановский А. О., д-р техн. наук, проф., Белорусский государственный университет транспорта, Беларусь Шитикова М. В., д-р физ.-мат. наук, проф., советник РААСН, Воронежский государственный технический университет
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© ФГБОУ ВО «ВГТУ», 2020
ISSN 2219-1038
STRUCTURAL MECHANICS
AND STRUCTURES
Scientific Journal
ISSUE № 3 (26), 2020
Structural mechanics and strength of materials
Applied problems of mechanics of solid body under deformation
Soil mechanics
Calculation and design of metal structures
Calculation and design of reinforced concrete structures
Calculation and design from polymeric structures
Calculation and design of bridges and transport structures
Calculation and design of bases and foundations of buildings and structures
Strength of joints of building structure units
Mobile load dynamic affect on elastic systems
Pilot and field observations of structures and materials
Voronezh
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STRUCTURAL MECHANICS AND STRUCTURES
SCIENTIFIC JOURNAL
Published since 2010 |
Issued 4 times a year |
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Founder and publisher – Voronezh State Technical University.
Territory of distribution — Russian Federation.
EDITORIAL BOARD OF THE JOURNAL:
Chief editor: Safronov V. S., Dr. of Tech. Sc., Prof.,
Voronezh State Technical University
The deputy chief editor: Kozlov V.A., Dr. of Physical and Mathematical Sc., Prof.,
Voronezh State Technical University
Executive secretary: Gabrielyan G.E., PhD of Tech. Sc., Associate Prof.,
Voronezh State Technical University
EDITORIAL BOARD MEMBERS:
Burenin А.А., Dr. of Physical and Mathematical Sc., Prof., Corresponding Member of RAS , Institute of Mechanical Engineering and Metallurgy of the Far Eastern Branch of RAS, Komsomolsk on Amur
Gridnev S.Yu., Dr. of Tech. Sc., Prof., Voronezh State Technical University Zverev V.V., Dr. of Tech. Sc., Prof., Lipetsk State Technical University
Efryushin S.V., PhD of Tech. Sc., Associate Prof., Voronezh State Technical University
Kirsanov M.N., Dr. of Physical and Mathematical Sc., Prof., National Research University «Moscow Power Engineering Institute»
Kolchunov V.I., Dr. of Tech. Sc., Prof., academician of RAACS, South-West State University Ledenyov V.V., Dr. of Tech. Sc., Prof., Tambov State Technical University
Nguen Dinh Hoa, PhD of Tech. Sc., National University of Civil Engineering, Socialist Republic of Vietnam Nuguxhinov Zh.S., Dr. of Tech. Sc., Prof., Kazakh Multidisciplinary Reconstruction and Development Institute of Karaganda State Technical University, Republic of Kazakhstan
Ovchinnikov I.G., Dr. of Tech. Sc., Prof., Saratov State Technical University Pshenichkina V.A., Dr. of Tech. Sc., Prof., Volgograd State Technical University
Trechshev A.A., Dr. of Tech. Sc., Prof., Corresponding Member of RAACS, Tula State University Turichshev L.S., PhD of Tech. Sc., Associate Prof., Polotsk State University, Republic of Belarus
Shapiro D.M. |
, Dr. of Tech. Sc., Prof., Voronezh State Technical University |
Shimanovsky A.O., Dr. of Tech. Sc., Prof., Belarusian State University of Transport, Republic of Belarus
Shitikova M.V., Dr. of Physical and Mathematical Sc., Prof., adviser of RAACS, Voronezh State Technical University
Editor: Agranovskaja N. N.
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© Voronezh State Technical University, 2020
4
СОДЕРЖАНИЕ
СТРОИТЕЛЬНАЯ МЕХАНИКА И СОПРОТИВЛЕНИЕ МАТЕРИАЛОВ
Кирсанов М. Н.
Математическая модель четырехсегментной статически определимой пространственной фермы …………………………………………………………….
Овсянникова В. М.
Зависимость деформаций балочной фермы трапециевидной формы от числа панелей ………………………………………………………………………
Петриченко Е. А.
Нижняя граница частоты собственных колебаний фермы Финка …………………
Журавлев Г. М., Шалынков К. А.
Исследование влияния сейсмичности площадки строительства на устойчивость здания ………………………………………………………………………………….
РАСЧЕТ И ПРОЕКТИРОВАНИЕ МОСТОВ И ТРАНСПОРТНЫХ СООРУЖЕНИЙ
Сафронов В. С., Абрамов И. В., Антипов А. В.
Вероятностная оценка опасности функционирования водопропускной железобетонной трубы из дефектных сборных элементов под высокой насыпью
РАСЧЕТ И ПРОЕКТИРОВАНИЕ МЕТАЛЛИЧЕСКИХ КОНСТРУКЦИЙ
Кузнецов Д. Н.
Малый стальной сферический купол с решеткой из шестигранников ……………
Зверев В. В., Тезиков Н. Ю., Жидков К. Е.
Оценка влияния повреждения компенсаторов на напряженно-деформированное состояние колонки охлаждения при действии высоких температур .……………..
РАСЧЕТ И ПРОЕКТИРОВАНИЕ ЖЕЛЕЗОБЕТОННЫХ КОНСТРУКЦИЙЙ
Али Ясир Аль-Бухейти, Леденев В. В., Савинов Я. В., Умнова О. В.
Концентраторы напряжений в зданиях с кирпичными стенами…………………..
К юбилею В. С. Сафронова ………………………………………………………….
Памяти Д. М. Шапиро ………………………………………………………………
Правила оформления статей ………………………………………………………..
5
7
13
21
30
41
53
65
73
85
92
98
CONTENT
STRUCTURAL MECHANICS
AND STRENGTH OF MATERIALS
M. N. Kirsanov
Mathematical model of a four-segment statically determinate spatial truss………………………………………………………………………………………
V. M. Ovsyannikova
Dependence of deformations of a trapezous truss beam on the number
of panels…………………………………………………………………………........
E. A. Petrichenko
Lower bound of the natural oscillation frequency of the Fink truss …………………….
G. M. Zhuravlev, K. A. Shalynkov
Investigation of the influence of various factors on the seismic stability
of a building…………………………………………………………………………..
7
13
21
30
CALCULATION AND DESIGN OF BRIDGES |
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AND TRANSPORT STRUCTURES |
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V. S. Safronov, I. V. Abramov, A. V. Antipov |
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Probable hazard functioning assessment of reinforced concrete culvert from defective |
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assemble elements under high embankment …………………………………………… |
41 |
CALCULATION AND DESIGN |
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OF METAL STRUCTURES |
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D. N. Kuznetsov |
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Small steel spherical dome with hexagon grid ………………………………………… |
53 |
V. V. Zverev, N. Yu. Tezikov, K. E. Zhidkov |
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Assessment of the influence of compensators damage on cooling column deflected |
65 |
mode under high temperatures .………………………………………………………… |
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CALCULATION AND DESIGN |
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OF REINFORCED CONCRETE STRUCTURES |
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Ali Yasir Al-Buheiti, V. V. Ledenev, Ya. V. Savinov, O. V. Umnova |
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Concentrators in buildings with brick walls …………………………………………… |
736 |
For the jubilee of V. S. Safronov ……………………………………………………. |
85 |
In memory of D. M. Shapiro ………………………………………………………… |
92 |
Requirements for articles to be published …………………………………………… |
98 |
6
СТРОИТЕЛЬНАЯ МЕХАНИКА И СОПРОТИВЛЕНИЕ МАТЕРИАЛОВ
УДК 624.074.27
MATHEMATICAL MODEL OF A FOUR-SEGMENT STATICALLY
DETERMINATE SPATIAL TRUSS
M. N. Kirsanov
National Research University “MPEI”,
Russia. Moscow
Dr.Sci., Professor tel: +7(495)362-73-14; e-mail:c216@ya.ru
The truss consists of four identical segments – rays connected in the center. The supports are located at the ends of the segments, each of which is a gable space truss. The design deflection is calculated in an analytical form for three types of loads. The result in the form of a polynomial in the number of panels is generalized to an arbitrary number of panels in the segment. The distribution of forces in the rods of the structure is shown. Linear asymptotics of the
solution are found.
Keywords: spatial truss, deflection, exact solution, Maple, induction, number of panels, asymptotics
Problem statement
Spatial trusses are most often calculated numerically [1-5]. In cases where the calculation of a spatial truss can be reduced to the calculation of a certain number of planar trusses, for example, by decomposing the load on the planes of the corresponding trusses, analytical methods are also used. Formulas are known for calculating deflection and forces in rods of planar regular trusses that are critical with respect to loss of stability and strength [6]. By induction, analytical solutions can be obtained for the deflection of spatial regular trusses with an arbitrary number of panels [7]. In this paper, we propose a new coating scheme consisting of four identical co-working segments (Fig. 1). the Truss has six support rods. Three rods model a spherical joint, two — a cylindrical one, and one
— a vertical support. These supports are located at three of the eight corner points of the truss segments. The remaining five free hinges are applied vertical forces from the equilibrium condition in the projection on the vertical of a symmetrically loaded truss.
Fig. 1. Truss, n = 4, upper belt load
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© Кирсанов М. Н., 2020
7
Each segment with n panels contains
n1 3n 1
hinges and
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rods. Total number of rods
in the truss is K 36n 9 . The forces are calculated using the method of cutting nodes in the Maple symbolic mathematics system using the program [8], which was previously used both in the calculations of planar [9-13] and spatial trusses [7].
The simplest part of the solution is to get the forces in all the rods of the truss in an analytical form. The upper belt rods are compressed, the lower ones are stretched. Maple graphics tools allow you to get a visual picture of the distribution of forces (Fig. 2). Blue color indicates compressed rods, red stretched, black — unstrained. The thickness of the segments is conditionally proportional to the force modules.
Fig. 2. The distribution of stresses in the bars when the truss loaded at all the construction nods,
a 2m, b 5m, h 4m, |
n 3 |
The deflection is determined by the Maxwell – Mohr's formula:
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( P) |
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/ (EF ). |
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(1)
Here |
S |
(1) |
— force in the rod from the action of a unit vertical force on the central node C, |
S |
(1) |
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the stress in the rod from the action of external loads, |
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the rod. The cross sections of all rods are assumed to be the same. Summation is performed for all truss rods, except for the six reference ones. Regardless of the number of panels, the formula for deflection has the form
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P(C1a |
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C2b |
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C3c |
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C4d |
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C5ab |
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C6ba |
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) / (EFh |
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(2) |
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where c |
a2 b2 h2 , |
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h2 . Sequential calculation of trusses with a different number |
of panels from one to ten gives a sequence of coefficients. The common terms of these sequences are coefficients in (2). In the Maple computer mathematics system, recurrent equations are created to determine the common terms of sequences. For the coefficient C1 in the case of a distributed
load on all hinges, the fifth–order equation is obtained:
C1,n 5C1,n 1 10C1,n 2 10C1,n 3 5C1,n 4 C1,n 5 .
The solution of this equation has the form
C n(30n |
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4n |
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2n 1) / |
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Other coefficients are found in the same way:
4
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(3)
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C |
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3(2n 1) / 4, |
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C |
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n(6n 1) / 4, C |
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1/ 4, |
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n(3n 1) / 2, C |
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When the load acts only on the hinges of the upper belt, we have the solution
C n(10n |
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4n |
2 |
2n 1) / 4, |
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C |
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(2n 1) / 4, C |
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n(2n 1) / 4, |
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(4)
(5)
The simplest solution is obtained when a concentrated force acts on the middle hinge of the structure:
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n / 4, |
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n / 2, C |
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Deflection calculation and analysis
(6)
The features of the resulting solution are most easily traced on graphs. We construct the dependence of the relative deflection (2) with coefficients (3,4) on the height of the truss. We denote this value ' EF / (Psum L) , where the total load on the truss in the case of loading all the nodes of the structure has a value Psum P(12n 5) . Curves have minima. It is not possible to calculate these points analytically in a compact form; it is easier to get a numerical solution. It is noticeable, however, that an increase in the width of the truss leads to a shift of the extremum to the right, to larger values of height.
Fig. 3. Dependence of the relative deflection on the height of the truss at n =10,
a 2m
To solve (2) with coefficients (6) obtained in the case of a concentrated force, we trace the depend-
ence of the deflection on the number of panels for a fixed horizontal segment size |
L (2n 1)a |
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The deflection increases in this setting, but there is no expected horizontal asymptote. The limit operator of the Maple system gives the following tangent of the slope of the asymptote
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