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Academic literature on the topic 'Тонкостінні елементи конструкцій'
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Journal articles on the topic "Тонкостінні елементи конструкцій"
ПЕРЕЛЬМУТЕР, А. В., and В. В. ЮРЧЕНКО. "ДОСЛІДЖЕННЯ ОБЛАСТІ НЕСУЧОЇ ЗДАТНОСТІ ТОНКОСТІННИХ СТЕРЖНЕВИХ ЕЛЕМЕНТІВ ІЗ ХОЛОДНОГНУТИХ ПРОФІЛІВ." Наука та будівництво 21, no. 3 (September 26, 2019): 42–48. http://dx.doi.org/10.33644/scienceandconstruction.v21i3.110.
Full textЛітот, О. В., and T. A. Манько. "МОДЕЛЮВАННЯ ОПРАВКИ ДЛЯ СТВОРЕННЯ ТОНКОСТІННИХ БЕЗЛЕЙНЕРНИХ ПАЛИВНИХ БАКІВ РАКЕТ-НОСІЇВ ІЗ КОМПОЗИЦІЙНИХ МАТЕРІАЛІВ." Математичне моделювання, no. 2(45) (December 13, 2021): 58–63. http://dx.doi.org/10.31319/2519-8106.2(45)2021.246947.
Full textКовальчук, С. Б., and О. В. Горик. "АНАЛІТИЧНИЙ РОЗВ’ЯЗОК ЗАДАЧІ ЗГИНУ БАГАТОШАРОВОЇ СИМЕТРИЧНОЇ КРУГОВОЇ АРКИ ПІД ДІЄЮ НОРМАЛЬНОЇ СИЛИ У СЕРЕДНЬОМУ ПЕРЕРІЗІ. ПОВІДОМЛЕННЯ 1. АРКИ ВЕЛИКОЇ КРИВИЗНИ." Вісник Полтавської державної аграрної академії, no. 2 (June 28, 2019): 270–83. http://dx.doi.org/10.31210/visnyk2019.02.36.
Full textЛіганенко, В. В., Н. С. Урум, and О. І. Рященко. "АНАЛІЗ КОНСТРУКЦІЙ САМОРЕГЕНЕРУЮЧИХ ФІЛЬТРІВ ПРИ ОЧИЩЕННІ МОТОРНОГО МАСТИЛА В ДВИГУНАХ ВНУТРІШНЬОГО ЗГОРЯННЯ." Vodnij transport, no. 2(33) (February 23, 2022): 13–22. http://dx.doi.org/10.33298/2226-8553/2022.2.33.02.
Full textПерельмутер, А. В., and В. В. Юрченко. "ПРО ДОЦІЛЬНІСТЬ ТА ФОРМУЛЮВАННЯ ЗАДАЧ ПОШУКУ ОПТИМАЛЬНИХ ПРОЄКТНИХ РІШЕНЬ СТЕРЖНЕВИХ КОНСТРУКЦІЙ ІЗ ХОЛОДНОГНУТИХ ПРОФІЛІВ." Таврійський науковий вісник. Серія: Технічні науки, no. 6 (February 15, 2022): 140–52. http://dx.doi.org/10.32851/tnv-tech.2021.6.18.
Full textКОРЕНЄВ, Р. В., and П. А. РЕЗНІК. "РОЗРАХУНОК ТА АНАЛІЗ БЕЗКАРКАСНИХ АРКОВИХ СИСТЕМ, ВИКОНАНИХ ІЗ ТОНКОСТІННИХ ХОЛОДНОДЕФОРМОВАНИХ ПРОФІЛІВ." Наука та будівництво, no. 1(15) (April 7, 2019): 100–109. http://dx.doi.org/10.33644/scienceandconstruction.v0i1(15).16.
Full textКовальчук, С. Б., and О. В. Горик. "АНАЛІТИЧНИЙ РОЗВ’ЯЗОК ЗАДАЧІ ЗГИНУ БАГАТОШАРОВОЇ СИМЕТРИЧНОЇ КРУГОВОЇ АРКИ ПІД ДІЄЮ НОРМАЛЬНОЇ СИЛИ В СЕРЕДНЬОМУ ПЕРЕРІЗІ. ПОВІДОМЛЕННЯ 2. АРКИ МАЛОЇ КРИВИЗНИ." Вісник Полтавської державної аграрної академії, no. 3 (September 27, 2019): 256–66. http://dx.doi.org/10.31210/visnyk2019.03.35.
Full textMednikova, M. A. "КОНТРОЛЬ ТОЧНОСТІ РОЗВ’ЯЗКУ ПРИ ВИЗНАЧЕННІ НАПРУЖЕНОГО СТАНУ В ОСЛАБЛЕНИХ ОТВОРОМ ОБОЛОНКАХ." Проблеми обчислювальної механіки і міцності конструкцій, no. 29 (May 25, 2019): 175–87. http://dx.doi.org/10.15421/42190014.
Full textRyabenkiy, V. M., I. I. Chudaykin, and J. D. Targunakova. "INVESTIGATION OF THE THIN STRUCTURES INDUCED MAGNETOSTATIC FIELDS IN A THREE-DIMENSIONAL SPACE BY MEANS OF THE OF THE MODIFIED BOUNDARY ELEMENTS METHOD DEVELOPMENT." Tekhnichna Elektrodynamika 2018, no. 5 (August 9, 2018): 15–21. http://dx.doi.org/10.15407/techned2018.05.015.
Full textDissertations / Theses on the topic "Тонкостінні елементи конструкцій"
Мартиненко, Володимир Геннадійович, and Геннадій Іванович Львов. "Скінченно-елементний підхід до знаходження анізотропних в’язкопружних характеристик композиційного матеріалу." Thesis, Національний технічний університет "Харківський політехнічний інститут", 2017. http://repository.kpi.kharkov.ua/handle/KhPI-Press/47547.
Full textАтрошенко, Олександр Олександрович. "Аналіз конструкційної міцності складених тонкостінних конструкцій з болтовим з'єднанням елементів." Thesis, НТУ "ХПІ", 2016. http://repository.kpi.kharkov.ua/handle/KhPI-Press/21789.
Full textThesis for the degree of Candidate of technical Sciences in specialty 05.02.09 – dynamics and strength of machines. National technical University "Kharkiv Polytechnic Institute", Ministry of Education and Science of Ukraine, Kharkiv, 2016. The thesis is devoted to the development of approaches, methods and models to study structural strength of composite thin-walled engineering structures with bolted elements. This work is solves the problem of analysis of the stress-strain state of composite thin-walled engineering structures with bolted elements, as well as its implementation and determination of the distribution of deflections, displacements and longitudinal efforts. Also in this formulation the following important factors were taken into account: the gap in bolted joints, friction force between the contacting surfaces, the pre-tightening of bolted connections, the presence of polymeric materials, as well as consideration of the corrugated shape of panels used. On the basis of mathematical models of the stress-strain state of the shell, the rod and plate structures, a mathematical model that takes into consideration the influence of axial forces and geometric nonlinearity in general on stress-strain state of composed thin-walled structures was elaborated in this thesis. The results of solving some applied problems were obtained. The regularities of changes of stress-strain state of thin-walled engineering structures at variation of design and process parameters were defined.
Шейченко, Роман Ігорович. "Забезпечення міцності тонкостінних конструкцій із підвищеними технічними характеристиками." Thesis, Національний технічний університет "Харківський політехнічний інститут", 2019. http://repository.kpi.kharkov.ua/handle/KhPI-Press/41327.
Full textТhesis for candidate of technical science degree (Philosophy Doctor) in speciality 05.02.09 – Dynamics and Strength of Machines (13 – mechanical engineering). – National Тechnical University «Kharkov Polytechnic Institute», Kharkiv, 2019. The needs of modern industry, transport and services in innovative products with increased technical and economic characteristics have recently been increasing dramatically. Large proportion of such products are thin-walled engineering structures, which rationally combine mass and strength characteristics. At the same time, strict rules and regulations are applied to many products (aircraft, ships, rolling stock, cranes, reloaders, high-pressure vessels, chemical industry equipment, agricultural equipment) for ensure the operation safety. Accordingly, design studies use established computational methods, as well as traditional technical solutions. In spite of pressure of established practice, which tends to create products as "clones" of long-created analogues, opposite trend also applies. It is generated by general aspiration for progress, even in conservative areas of activity, as well as economic considerations. Moreover, many consumers of innovative products set their additional requirements for products aimed at extending service life of structures, increasing their productivity, intensity of operating modes or load capacity. In these circumstances, in addition to regulatory restrictions, there are additional ones, which complicates the requirements fulfillment for projected designs. Thus, the scientific and practical task of developing methods for strength ensuring of innovative thin-walled engineering structures under action of operating loads complex has appeared and is intensified in its urgency and importance. Its formulation, solution and implementation to design studies practice is goal, content and directions of dissertation research. In the dissertation work the scientific and technical problem is solved, which consists in methods and models improvement for strength ensurance of thin-walled engineering structures under action of operational loads complex. In the work for stress-strain state analysis of thin-walled engineering structures the theory of elasticity ratios and the finite element method are used. Geometric shape formation of investigated structures was carried out by methods of solid state and surface modeling. For structure and size variation of studied objects, the method of generalized parametric modeling for innovative thin-walled engineering structures is adapted and developed. Experimental studies were carried out using strain gauge and accelerometer methods. In course of dissertation research the following scientific results were obtained: 1) an analysis of operating conditions, regulatory requirements, as well as analysis methods of thin-walled engineering structures taking into account the constrains on durability, and on this basis, the dissertation research directions were determined; 2) methods and models for design parameters justification of innovative thin-walled engineering structures according to strength criteria under action of operational loads complex, taking into account regulatory constraints are improved; 3) solution of a number of applied tasks of technical solutions substantiation for the thin-walled engineering structures according to strength and durability criteria; 4) computational and experimental studies of stress-strain state of innovative thin-walled engineering structures that are designed on the basis of recommendations with application of dissertation research results; 5) research results are introduced into production.
Шейченко, Роман Ігорович. "Забезпечення міцності тонкостінних конструкцій із підвищеними технічними характеристиками." Thesis, Національний технічний університет "Харківський політехнічний інститут", 2019. http://repository.kpi.kharkov.ua/handle/KhPI-Press/41324.
Full textThesis for the degree of Candidate of Technical Sciences in specialty 05.02.09 – Dynamics and strength of machines. National Technical University «Kharkiv Polytechnic Institute», Ministry of Education and Science of Ukraine, Kharkiv, 2019. The thesis is devoted to the improvement of methods and models for the design ensuring of the strength of thin-walled engineering structures under the action of operational loadings complex. The justification for rational parameters and design solutions for thin-walled engineering structures is carried out according to the criteria of mass minimizing, stresses reducing, and service life increasing. Various additional criteria such as cost, manufacturability, economy, energy efficiency, can be taken into account in the formation of the quality function. The dependences approximations of criterion values, which are gradually localized, from variable parameters are taken into account. The structure, design and technological solutions of thin-walled engineering structures, structural parameters and operating modes are the generalized parameters. This provides a solution to the problems of a single analysis, multivariate studies, as well as the justification for rational design and technological solutions. The following generalizations are considered: unification, expediency, efficiency, loading identification, verification, forecasting, tune-up in development of known approach. The algorithmization of proposed methods for calculating of the stress strain state of thin-walled engineering structures has also been carried out based on a combination of the advantages of universal and special systems. A number of applied problems are solved. Parametric finite element models of researched objects have been developed based on a set of studies of the stress-strain state of the power elements. The rational design parameters of innovative thin-walled engineering structures are determined. The results of experimental studies of innovative tank cars, platform cars and loading cranes, which are designed and manufactured based on the implementation of recommendations from dissertation research, are presented. Comparative experimental and computational studies of the structures stress-strain state were carried out. They are combined with certification tests, during which the stresses in the power elements were recorded. The operational loadings are determined which are acting on thin-walled structures. During the tests, regularities were established that determine the dependence of the loadings components on the structure from various factors. Verification of the numerical models parameters of thin-walled engineering constructions elements was carried out. Designed on the basis of researches innovative structures have improved technical and economic characteristics compared with similar ones.
Бондаренко, Марина Олександрівна. "Забезпечення міцності тонкостінних конструкцій шляхом обґрунтування параметрів із використанням апроксимацій поверхонь відгуку." Thesis, НТУ "ХПІ", 2018. http://repository.kpi.kharkov.ua/handle/KhPI-Press/37533.
Full textThe thesis in qualification for a scientific degree of Candidate of Technical Science in speciality 05.02.09 ‒ dynamics and strength of machines, National Technical University "Kharkiv Polytechnical Institute", Kharkiv, 2018. The dissertation deals with the development of approach and models for providing of structural strength of complicated thin-walled machine-building structures, which operate in the conditions of geometric and physical nonlinearities using design solution validation. The developed approach is based on the use of mathematical model for stress-strain state taking into account geometric and physical nonlinearities and methods of approximation for constructing functions describing the evaluated characteristics of the object under study. The various factors behind the search for design solutions (including characteristics of strength, rigidity, technological and economic factors), are being added into this function. During searching for design solutions it is proposed to successively use approximation models of various accuracy degrees. The developed algorithm for rational parameters search, which takes into account the peculiarities of the response surface shape observed in solving applied problems, is applied to them. In this case, the solution is sought over the whole range of parameter changes. Thus, in the search process, global trends of changes in design decisions are taken into account, and not local ones, as in other approaches. This allows obtain a rational solution that is stable to changes in parameters, which are possible in course of design work and production conditions. The developed algorithms and models are used for solving test and applied problems. In particular, recommendations for the body framing of the bus, freight car, the frame of the tractor cabin, the BTR-80 and MT-L hulls are developed. Computational and experimental verification of developed finite-element models was carried out. The research was carried out at three objects: on the upper part of BTR-80 armored personnel carrier mock-up, and on the prototypes of BTR-3E hull and covered railcar. During frequency characteristics studies, the oscillations excitation of the hull mock-up was effected by rubberized drummer influence at certain points of structure. With use of verified finite element models, the BTR-3E hull prototype was investigated. The experimental research technique provided impulsive action on the hull at a number of points, and fixation of time distributions of accelerations at these points by accelerometers. The results difference is in range of 8-12% for frequencies of free oscillations and for damping logarithmic decrement. Computational studies, and then full-scale tests are also subject to the covered railcar prototype made with recommended settings. Average difference for displacement and stress is 15%.
Бондаренко, Марина Олександрівна. "Забезпечення міцності тонкостінних конструкцій шляхом обґрунтування параметрів із використанням апроксимацій поверхонь відгуку." Thesis, НТУ "ХПІ", 2018. http://repository.kpi.kharkov.ua/handle/KhPI-Press/37536.
Full textThe thesis in qualification for a scientific degree of Candidate of Technical Science in speciality 05.02.09 ‒ dynamics and strength of machines, National Technical University "Kharkiv Polytechnical Institute", Kharkiv, 2018. The dissertation deals with the development of approach and models for providing of structural strength of complicated thin-walled machine-building structures, which operate in the conditions of geometric and physical nonlinearities using design solution validation. The developed approach is based on the use of mathematical model for stress-strain state taking into account geometric and physical nonlinearities and methods of approximation for constructing functions describing the evaluated characteristics of the object under study. The various factors behind the search for design solutions (including characteristics of strength, rigidity, technological and economic factors), are being added into this function. During searching for design solutions it is proposed to successively use approximation models of various accuracy degrees. The developed algorithm for rational parameters search, which takes into account the peculiarities of the response surface shape observed in solving applied problems, is applied to them. In this case, the solution is sought over the whole range of parameter changes. Thus, in the search process, global trends of changes in design decisions are taken into account, and not local ones, as in other approaches. This allows obtain a rational solution that is stable to changes in parameters, which are possible in course of design work and production conditions. The developed algorithms and models are used for solving test and applied problems. In particular, recommendations for the body framing of the bus, freight car, the frame of the tractor cabin, the BTR-80 and MT-L hulls are developed. Computational and experimental verification of developed finite-element models was carried out. The research was carried out at three objects: on the upper part of BTR-80 armored personnel carrier mock-up, and on the prototypes of BTR-3E hull and covered railcar. During frequency characteristics studies, the oscillations excitation of the hull mock-up was effected by rubberized drummer influence at certain points of structure. With use of verified finite element models, the BTR-3E hull prototype was investigated. The experimental research technique provided impulsive action on the hull at a number of points, and fixation of time distributions of accelerations at these points by accelerometers. The results difference is in range of 8-12% for frequencies of free oscillations and for damping logarithmic decrement. Computational studies, and then full-scale tests are also subject to the covered railcar prototype made with recommended settings. Average difference for displacement and stress is 15%.