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<article xmlns:xlink="http://www.w3.org/1999/xlink" xmlns:mml="http://www.w3.org/1998/Math/MathML" xmlns:xsi="http://www.w3.org/2001/XMLSchema-instance" xmlns="https://jats.nlm.nih.gov/publishing/1.1/" xml:lang="ru" article-type="research-article" dtd-version="1.1" specific-use="eps-0.1">
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				<journal-id journal-id-type="publisher-id">asa</journal-id><journal-title-group>
			<journal-title xml:lang="ru">Строительство и техногенная безопасность</journal-title></journal-title-group>			<issn pub-type="ppub">2413-1873</issn>			<publisher><publisher-name>КФУ им. В.И. Вернадского</publisher-name></publisher>
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			<article-id pub-id-type="doi">10.37279/2413-1873-2021-20-15-22</article-id><article-id pub-id-type="publisher-id">112</article-id>
			<article-categories><subj-group xml:lang="en"><subject>Construction</subject></subj-group><subj-group xml:lang="ru"><subject>Строительные науки</subject></subj-group></article-categories>
			<title-group><article-title xml:lang="ru">РАЗВИТИЕ КОНСТРУКЦИЙ И ТЕХНОЛОГИИ ВЫСОКОТОЧНОГО МОНТАЖА ТРУБОБЕТОННЫХ КОЛОНН КИНЕМАТИЧЕСКИХ СИСТЕМ СЕЙСМИЧЕСКОЙ ЗАЩИТЫ КАРКАСОВ ГРАЖДАНСКИХ ЗДАНИЙ</article-title><trans-title-group xml:lang="en"><trans-title>DEVELOPMENT OF CONSTRUCTIONS AND TECHNOLOGIES OF HIGH-PRECISION INSTALLATION OF PIPE CONCRETE COLUMNS OF KINEMATIC SYSTEMS OF SEISMIC PROTECTION OF CIVIL BUILDINGS FRAMES</trans-title></trans-title-group></title-group>
			<contrib-group content-type="author">
				<contrib contrib-type="author">
<name-alternatives>					<name>
						<surname>Андронов</surname>
						<given-names>А. В.</given-names>
					</name>
					<name xml:lang="en">
						<surname>Andronov</surname>
						<given-names>A. V.</given-names>
					</name>
</name-alternatives>					<xref ref-type="aff" rid="aff-1"/>
				</contrib>
				<contrib contrib-type="author">
<name-alternatives>					<name>
						<surname>Семенов</surname>
						<given-names>С. Ю.</given-names>
					</name>
					<name xml:lang="en">
						<surname>Semenov</surname>
						<given-names>S. Y.</given-names>
					</name>
</name-alternatives>					<xref ref-type="aff" rid="aff-2"/>
				</contrib>
				<contrib contrib-type="author">
<name-alternatives>					<name>
						<surname>Шаленный</surname>
						<given-names>В. Т.</given-names>
					</name>
					<name xml:lang="en">
						<surname>Shalenny</surname>
						<given-names>V. T.</given-names>
					</name>
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			<institution content-type="orgname">Крымский Федеральный университет им. В.И. Вернадского, Академия строительства и архитектуры 295943, г. Симферополь, ул. Киевская, 181, andronovav58@mail.ru</institution>
			<institution content-type="orgname" xml:lang="en">Academy of Construction and Architecture of theV.I. Vernadsky Crimean Federal University,Simferopol, Kiyevskaya St., 181, andronovav58@mail.ru</institution>
			</aff>
			<aff id="aff-2">
			<institution content-type="orgname">Сочинский государственный университет, Инженерно-экологический факультет 354000, Краснодарский край, г. Сочи, ул. Политехническая, д. 7, smu5sochi@mail.ru</institution>
			<institution content-type="orgname" xml:lang="en">Sochi State University, Faculty of Environmental Engineering 354000, Krasnodar region, Sochi, st. Polytechnic, 7, smu5sochi@mail.ru</institution>
			</aff>
			<aff id="aff-3">
			<institution content-type="orgname">Крымский Федеральный университет им. В.И. Вернадского, Академия строительства и архитектуры 295943, г. Симферополь, ул. Киевская, 181, v_shalennyj@mail.ru</institution>
			<institution content-type="orgname" xml:lang="en">Academy of Construction and Architecture of theV.I. Vernadsky Crimean Federal University,Simferopol, Kiyevskaya St., 181, v_shalennyj@mail.ru</institution>
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			<pub-date date-type="pub" publication-format="electronic">
				<day>22</day>
				<month>03</month>
				<year>2021</year>
			</pub-date>
				<issue seq="1">20(72)</issue><issue-id>68</issue-id><fpage>15</fpage>
				<lpage>22</lpage>
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				<copyright-statement>Copyright (c) 2021 Строительство и техногенная безопасность</copyright-statement>
				<copyright-year>2021</copyright-year>
				<copyright-holder>Строительство и техногенная безопасность</copyright-holder>
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			<self-uri>https://www.stroyjurnal-asa.ru/index.php/asa/article/view/112</self-uri>
			<abstract><p>Аннотация. Рассматриваются, выбранные в качестве перспективных, системы сейсмической изоляции кинематического типа, впервые предложенные в бывшем Советском Союзе профессором Черепинским Ю.Д. Дальнейшее развитие данная технология получила в работах профессора Курзанова А.М., внедрившего свои разработки на объектах Краснодарского края РФ.  Однако и проанализированная инновационная отечественная технология не лишена недостатков в части точности монтажа и конструкции шарнирных узлов  опирания трубобетонных колонн цокольного этажа.</p>
<p>Предмет исследования: конструкция и технология устройства сейсмозоляции надземных этажей гражданских зданий при помощи кинематических систем из трубобетонных колонн.</p>
<p>Материалы и методы: анализ состояния вопроса с характеристикой позитивных и негативных сторон существующей технологии,  обоснование путей возможного прогрессивного развития конструкций и технологии устройства сейсмоизолирующих систем кинематического типа,  повышающих надежность их работы под сейсмической нагрузкой. Создание графических моделей узлов опирания трубобетонных колонн, реализующих намеченные направления в конкретные конструктивные решения и технологию их реализации.</p>
<p>Результаты: Запатентованные конструкции узлов шарнирного опирания трубобетонных колонн кинематических систем сейсмической изоляции каркасов гражданских объектов и технологическая схема их выверки и высокоточного монтажа.</p>
<p>Выводы: Обосновано предложены новые конструктивные решения узлов шарнирного опирания трубобетонных колонн кинематических систем сейсмической изоляции, а также усовершенствованная технология  их монтажа, предполагающие повышение надежности их долговременной эксплуатации в районах повышенной сейсмической активности.</p></abstract><trans-abstract xml:lang="en"><p>Summary. Seismic isolation systems of kinematic type, selected as promising ones, first proposed in the former Soviet Union by Professor Yu.D. Cherepinsky, are considered. This technology was further developed in the works of Professor A.M. Kurzanov, who introduced his developments at the facilities of the Krasnodar Territory of the Russian Federation. However, the analyzed innovative domestic technology is not without its drawbacks.</p>
<p>Subject of research: the design and technology of seismic isolation of overground floors of civil buildings using kinematic systems made of pipe-concrete columns.</p>
<p>Materials and methods: analysis of the state of the art with a description of the positive and negative aspects of the existing technology, substantiation of the ways of possible progressive development of structures and technology of seismic isolation systems of the kinematic type, increasing the reliability of their operation under seismic load. Creation of graphic models of the nodes of support of concrete columns, implementing the intended directions in specific design solutions and technology for their implementation.</p>
<p>Results. Patented designs of joints for pivotal support of pipe-concrete columns of kinematic systems for seismic isolation of frames of civil objects and a technological scheme for their alignment and high-precision installation.</p>
<p>Conclusions: New design solutions have been proposed for the joints of the hinged support of pipe-concrete columns of kinematic systems of seismic isolation, as well as an improved technology for their installation, implying an increase in the reliability of their long-term operation in areas of high seismic activity.</p></trans-abstract><kwd-group xml:lang="en"><title>Keywords</title><kwd>kinematic seismic isolation systems</kwd><kwd>high-precision assembly technology</kwd></kwd-group><kwd-group xml:lang="ru"><title>Ключевые слова</title><kwd>кинематические системы сейсмоизоляции</kwd><kwd>технология высокоточного монтажа</kwd></kwd-group><counts><page-count count="8"/></counts>
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