Geodesic
Implementation of the calculation of the stress-deformed state of layered pipes from composites and determination of wave velocity in hydrolic impact
Problemy fiziki, matematiki i tehniki, no. 3 (2021), pp. 19-23.

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The problem of computer implementation of calculating of the stress-strain state of laminated pipes made of composites and determining the wave velocity during water hammer is solved. Two variants of the problem are considered: a pipe with an inner coating consisting of a functionally gradient material, and a pipe with an inner coating of a composite, a fibrous composite consisting of a matrix and fibers, the elastic modulus of which is determined by the rule of mixtures.
Keywords: laminated pipe, functional-gradient material, lined pipe, stress-strain state, wave velocity.
Mots-clés : composite 
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V. V. Mozharovsky; S. V. Kirhintsava. Implementation of the calculation of the stress-deformed state of layered pipes from composites and determination of wave velocity in hydrolic impact. Problemy fiziki, matematiki i tehniki, no. 3 (2021), pp. 19-23. http://geodesic.mathdoc.fr/item/PFMT_2021_3_a2/

[1] F. Evangelista et al., “Wave celerity in hydraulic transients computation for cipp-rehabilitated pipes”, Int. J. Comp. Meth. and Exp. Meas., 8:4 (2020), 326–340

[2] F. Hongyuan et al., “Parameter analysis of wall thickness of cured-in-place pipe linings for semistructured rehabilitation of concrete drainage pipe”, Mathematical Problems in Engineering, 2020, 5271027, 1–16

[3] V.V. Mozharovskii, D.S. Kuzmenkov, E.A. Golubova, “Metodika rozrakhunku napruzheno-deformovanogo stanu sharuvatikh trub z urakhuvannyam yavisch povzuchosti i relaksatsii”, Visnik Kiivskogo natsionalnogo universitetu imeni Tarasa Shevchenko, 2017, no. 3, 151–156

[4] N. Tutuncu, M. Ozturk, “Exact solutions for stresses in functionally graded pressure vessels”, Composites: Part B: Engineering, 32 (2001), 683–686 | DOI

[5] S.I. Rubinov, J.B. Keller, “Wave propagation in a fluid-filled tube”, Journal of the Acoustical Society of America, 50 (1971), 198–223 | DOI

[6] S.I. Rubinov, J.B. Keller, “Wave propagation in viscoelastic tube containing a viscous fluid”, Journal of Fluid Mechanics, 88 (1978), 181–203 | DOI

[7] C.S.W. Lavooij, A.S. Tijsseling, “Fluid-structure interaction in liquid-filled piping systems”, Journal of Fluids and Structures, 1991, no. 5, 573–595 | DOI

[8] A.S. Tijsseling, “Fluid-structure interaction in liquid-filled pipe systems: a review”, Journal of Fluids and Structures, 1996, no. 10, 109–146 | DOI

[9] F.E. Hachem, A.J. Schleiss, “A review of wave celerity in frictionless and axisymmetrical steel-lined pressure tunnels”, Journal of Fluids and Structures, 27 (2011), 311–328 | DOI