Development of dimensionally stable structures of multilayer pipelines and cylindrical pressure vessels from carbon fiber reinforced plastic

Authors

DOI:

https://doi.org/10.15587/1729-4061.2018.150027

Keywords:

composites, carbon fiber reinforced plastic, carbon fibers, reinforcement schemes, pipeline designs, dimensional stability, elastic deformations

Abstract

In the framework of the momentless theory of cylindrical thin shells, the elastic deformation of multilayer pipes and pressure vessels is investigated. It is assumed that the pipes and pressure vessels are made by two-way spiral winding of carbon fiber reinforced plastic tape on a metal mandrel.

The analysis of the dependences of elastic deformations on the reinforcement angles is performed. The relations for axial and circumferential deformations of the wall, depending on the structure of the layer package, reinforcement angles under static loading are obtained. The separate and combined effect of internal pressure and temperature is considered. For the separate effect of loads, the graphs of deformations against the winding angle are plotted.

Composite pipes made of KMU-4L carbon fiber reinforced plastic, as well as composite metal-composite pipes, are investigated. The results obtained for thermal loads are in good agreement with the data of the known experiment and solution. Depending on the load parameters, composite and metal-composite structures with dimensionally stable properties are determined.

It is shown that dimensionally stable structures can be used to solve the problem of compensation of elastic deformations of pipelines. For this purpose, using the ASCP software package, the variant analysis of model structures is performed. By the comparative analysis of the three versions of the structure, layer package structures and reinforcement schemes, ensuring a significant reduction of loads on the supporting elements are obtained. On the example of a pipeline with a flowing fluid, it is shown that the use of dimensionally stable multilayer pipes makes it possible to eliminate bending deformations and significantly reduce the level of working forces and stresses.

Dimensionally stable composite multilayer pipes open up new approaches to the design of pipelines and pressure vessels. It is possible to create structures with predetermined (not necessarily zero) displacement fields, consistent with the fields of the initial technological displacements, as well as with the displacements of conjugate elastic elements and equipment when the operating mode changes. The scope of such structures is not limited to "hot" pipes. The results can be used in cryogenic engineering

Author Biographies

Yurii Loskutov, Volga State University of Technology Lenina ave., 3, Yoshkar-Ola, Russia, 424000

PhD, Associate Professor

Departament of Strength of Materials and Applied Mechanics

Alex Baev, Volga State University of Technology Lenina ave., 3, Yoshkar-Ola, Russia, 424000

PhD, Associate Professor

Department of radio engineering and biomedical systems

Leonid Slavutskii, Chuvash State University named after I. N. Ulyanov Moscowskiy ave., 15, Cheboksary, Russia, 428015

Doctor of Physical and Mathematical Sciences, Professor

Department of Automation and Control in Technical Systems

Gubeydulla Yunusov, Mari State University Lenina sq., 1, Yoshkar-Ola, Russia, 424000

Doctor of Technical Sciences, Professor

Department of mechanization of production and processing of agricultural products

Michael Volchonov, Kostroma State Agricultural Academy Training Town, 34, Karavaevo village, Kostroma region, Russia, 156530

Doctor of Technical Sciences, Professor

Department of technical systems in agro-industrial complex

Vladimir Medvedev, Chuvash State Agricultural Academy K. Marksa str., 29, Cheboksary, Russia, 428000

Doctor of Technical Sciences, Professor

Department of transport-technological machines and complexes

Petr Mishin, Chuvash State Agricultural Academy K. Marksa str., 29, Cheboksary, Russia, 428000

Doctor of Technical Sciences, Professor

Department of transport-technological machines and complexes

Sergey Alatyrev, Chuvash State Agricultural Academy K. Marksa str., 29, Cheboksary, Russia, 428000

Doctor of Technical Sciences, Associate Professor

Department of operation of transport-technological machines and complexes

Petr Zaitsev, Chuvash State Agricultural Academy K. Marksa str., 29, Cheboksary, Russia, 428000

Doctor of Technical Sciences, Professor

Department of mechanization, electrification of automation of agricultural production

Mikhail Loskutov, Volga State University of Technology Lenina ave., 3, Yoshkar-Ola, Russia, 424000

Engineer

Center for Fundamental Education

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Published

2018-12-10

How to Cite

Loskutov, Y., Baev, A., Slavutskii, L., Yunusov, G., Volchonov, M., Medvedev, V., Mishin, P., Alatyrev, S., Zaitsev, P., & Loskutov, M. (2018). Development of dimensionally stable structures of multilayer pipelines and cylindrical pressure vessels from carbon fiber reinforced plastic. Eastern-European Journal of Enterprise Technologies, 6(7 (96), 32–38. https://doi.org/10.15587/1729-4061.2018.150027

Issue

Vol. 6 No. 7 (96) (2018): Applied mechanics

Section

Applied mechanics

License

Copyright (c) 2018 Yurii Loskutov, Alex Baev, Leonid Slavutskii, Gubeydulla Yunusov, Michael Volchonov, Vladimir Medvedev, Petr Mishin, Sergey Alatyrev, Petr Zaitsev, Mikhail Loskutov

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