Creation of Structural Polymer Composite Materials for Functional Application Using Physicochemical Modification

Kolosov, A. E.; Сівецький, Володимир Іванович; Kolosova, Elena; Vanin, Volodymyr; Gondlyakh, Aleksandr; Sidorov, D. É.; Ivitskiy, Igor I.

doi:10.1155/2019/3501456

Cited by 15 publications

(6 citation statements)

References 51 publications

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“…Also, based on the developed approach, PCMs modeling is possible using both chemical modification and combined physicochemical modification of the components of PCMs including OFFs of rope and woven types [73,74]. At the same time, the modification should ultimately lead to improved PCMs operational characteristics [75] and also contribute to increasing the productivity of molding and energy saving when receiving reinforced composites due to the ordering of their structure, improvement of interfacial interaction at the "fiber-polymer matrix" interface, and reduction of voids in the formed composite [76].…”

Section: E Methods Of Modeling the Parameters Of The Process Of "Free"mentioning

confidence: 99%

Modeling the Structures of Oriented Macrofiber Polymer Composites as Capillary‐Porous Bodies

Kolosov

Gondlyakh

Сівецький

et al. 2020

Advances in Materials Science and Engineering

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The problems of modeling the structure and design of technical parameters for forming of oriented macrofiber polymer composites are analyzed. The considered approaches are based on the application of geometric modeling of the structure of oriented fibrous fillers and the design of the parameters of technical means for forming oriented macrofiber polymer composite materials. Peculiarities of the application of the phenomenological and structural approaches to the design of structural and technological parameters of technical means and to the calculation of the elements of composite structures based on oriented macrofibrous fillers are considered. The technique for determining the structural characteristics of oriented macrofibrillar fillers based on its adequate geometric model as capillary-porous bodies is given. As the structural characteristics, the porosity, the specific internal surface, and also the effective (hydraulic) capillary radius of oriented macrofibrous fillers are considered. It is noted that the obtained structural models are used, in particular, to the prognosis of the design and technological parameters of the technical means for molding macro-fiber polymer composite materials.

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Section: E Methods Of Modeling the Parameters Of The Process Of "Free"mentioning

confidence: 99%

Modeling the Structures of Oriented Macrofiber Polymer Composites as Capillary‐Porous Bodies

Kolosov

Gondlyakh

Сівецький

et al. 2020

Advances in Materials Science and Engineering

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“…В качестве преимущества можно отметить простоту технической реализации, независимо от формы обрабатываемой детали. Однако пропускание ультразвука в КМ может вызывать модификацию структуры и свойств [40]. В частности возможно уменьшение размеров полимерных молекул в результате их деления, образование новых структурных образований и химических связей.…”

Section: результаты исследования и их обсуждениеunclassified

Physical and Chemical Prerequisites for Efficient Mechanical Processing of Composite Materials

Shigin

2023

СНТ (MHT)

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В статье показаны исследования состава, структуры процессов изготовления полимерных композиционных материалов. Выполнен аналитический обзор исследований в области физических и химических свойств полимерных материалов. Раскрыто содержание известных исследований, направленных на изучение механических свойств полимерных и композиционных материалов. В статье представлен анализ структуры и физико-механических свойств полимерных и композиционных материалов. Раскрыты особенности формирования межатомных связей в металлах и полимерных материалов. Выполнено сравнение процессов механической обработки резанием металлов и полимерных материалов. Рассмотрены энергетические подходы в проблеме разрушения межатомных связей внутри металлов и полимерных материалов в процессе резания. Выполнен анализ существующих технических решений и научных направлений в исследовании механизмов резания металлов и композиционных материалов с точки зрения повышения эффективности и качества процесса. В частности представлены передовые исследования в области механической обработки полимерных материалов с применением высокоскоростной обработки, предварительной обработки поверхности полимера, пропускания ультразвуковых колебаний внутри материала, а также наложения ультразвуковых вибраций на режущий инструмент. В статье сделаны выводы о перспективных подходах механической обработки композиционных материалов с целью повышения качества обработки, ресурса инструмента, снижения энергоемкости процесса. Ключевые слова: композиционные материалы, механическая обработка, энергоемкость, качество обработки, трещинообразование, предварительная обработка, вибрационное точение, ультразвуковые колебания Работа выполнена в рамках государственного задания Минобрнауки России на выполнение коллективом научной лаборатории «Интеллектуальные материалы и структуры» проекта «Разработка многофункциональных интеллектуальных материалов и структур на основе модифицированных полимерных композиционных материалов способных функционировать в экстремальных условиях» (Номер темы FEFE-2020-0015).

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“…The use of composite materials based on polymers is an important factor in improving the efficiency and successful development of leading industries [ 1 ]. At the same time, the rapid development and improvement of composite materials, as well as the constant need for modern production in them, urgently require the creation of competitive materials with predictable properties [ 2 , 3 ] and the development of high-quality polymer composites with specified technical characteristics [ 4 , 5 , 6 ].…”

Section: Introductionmentioning

confidence: 99%

Modeling of Polymer Composite Materials Chaotically Reinforced with Spherical and Cylindrical Inclusions

et al. 2022

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The technical and economic efficiency of new PCMs depends on the ability to predict their performance. The problem of predicting the properties of PCMs can be solved by computer simulation by the finite element method. In this work, an experimental determination of the physical and mechanical properties of PTFE PCMs depending on the concentration of fibrous and dispersed filler was carried out. A finite element model in ANSYS APDL was built to simulate the strength and load-bearing capacity of the material with the analysis of damage accumulation. Verification of the developed computer model to predict the mechanical properties of composite materials was performed by comparing the results obtained during field and model experiments. It was found that the finite element model predicts the strength of chaotically reinforced spherical inclusions of composite materials. This is due to the smoothness of the filler surfaces and the lack of filler dissection in the model. Instead, the prediction of the strength of a finite element model of chaotically reinforced cylindrical inclusions of composite materials requires additional analysis. The matrix and the fibrous filler obviously have stress concentrators and are both subject to the difficulties of creating a reliable structural model.

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Creation of Structural Polymer Composite Materials for Functional Application Using Physicochemical Modification

Cited by 15 publications

References 51 publications

Modeling the Structures of Oriented Macrofiber Polymer Composites as Capillary‐Porous Bodies

Modeling the Structures of Oriented Macrofiber Polymer Composites as Capillary‐Porous Bodies

Physical and Chemical Prerequisites for Efficient Mechanical Processing of Composite Materials

Modeling of Polymer Composite Materials Chaotically Reinforced with Spherical and Cylindrical Inclusions

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