ГОСТ Р ИСО 18437-6-2021. Национальный стандарт Российской Федерации. Вибрация и удар. Определение динамических механических свойств вязкоупругих материалов. Часть 6. Метод температурно-временной суперпозиции

[1]

ISO 472,

Plastics - Vocabulary

[2]

ISO 4664-1,

Rubber, vulcanized or thermoplastic - Determination of dynamic properties - Part 1: General guidance

[3]

ISO 6721-4,

Plastics - Determination of dynamic mechanical properties - Part 4: Tensile vibration - Non-resonance method

[4]

ISO 6721-5,

Plastics - Determination of dynamic mechanical properties - Part 5: Flexural vibration - Non-resonance method

[5]

ISO 6721-6,

Plastics - Determination of dynamic mechanical properties - Part 6: Shear vibration - Non-resonance method

[6]

ISO 6721-7,

Plastics - Determination of dynamic mechanical properties - Part 7: Torsional vibration - Non-resonance method

[7]

ISO 6721-12,

Plastics - Determination of dynamic mechanical properties - Part 12: Compressive vibration - Non-resonance method

[8]

ISO 10112,

Damping materials - Graphical presentation of the complex modulus

[9]

ISO 18437-2,

Mechanical vibration and shock - Characterization of the dynamic mechanical properties of visco-elastic materials - Part 2: Resonance method

[10]

ISO 18437-3,

Mechanical vibration and shock - Characterization of the dynamic mechanical properties of visco-elastic materials - Part 3: Cantilever shear beam method

[11]

ISO 18437-4,

Mechanical vibration and shock - Characterization of the dynamic mechanical properties of visco-elastic materials - Part 4: Dynamic stiffness method

[12]

ISO 18437-5,

Mechanical vibration and shock - Characterization of the dynamic mechanical properties of visco-elastic materials - Part 5: Poisson ratio based on comparison between measurements and finite element analysis

[13]

FERRY J.D. Visco-elastic properties of polymers. John Wiley & Sons, New York, Third Edition, 1980

[14]

DEALY J. and PLAZEK D. Time-Temperature Superposition - A User Guide. Rheology Bulletin. 2009, 78 (2) pp. 16 - 31

[15]

MADIGOSKY W. et al. A method for modelling polymer visco elastic data and the temperature shift function. J. Acoust. Soc. Am. 2006, 119 (6) pp. 3760 - 3765

[16]

GERGESOVA M. et al. The closed form t-T-P shifting (CFS) algorithm. J. Rheol. (N.Y.N.Y.). 2011, 55 (1) pp. 1 - 17

[17]

GERGESOVA M. et al. Closed Form Solution for Horizontal and Vertical Shifting of Viscoelastic Material Functions in Frequency Domain. Rheologica Acta, 2016, ISSN: 0035-4511 (Print) 1435 - 1528 (Online)

[18]

DAO K.C. and DICKEN D.J. Fatigue failure mechanisms in polymers. Polym. Eng. Sci. 1987, 27 (4) pp. 271-276

[19]

MENARD K.P. Dynamic mechanical analysis: A practical introduction. CRC Press, Florida, 1999

УДК 534.322.3.08:006.354

ОКС 17.160

Ключевые слова: вязкоупругие материалы, термореологически простые материалы, модуль упругости, модуль накопления, модуль потерь, температурно-временная суперпозиция, обобщенная кривая