Multiplet relaxation transitions in fluorurethane coating after climate aging

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The relaxation transition from a glassy to a highly elastic state (α-transition) of a fluoropolyurethane coating deposited on the surface of VPS-48/778 glass fiber reinforced plastic was studied using the method of dynamic mechanical analysis. It is shown that the relaxation maximum of the dynamic loss modulus in the initial state is a superposition of α1-, α2-, α3-transitions, corresponding, respectively, to transitions from the glassy to highly elastic state of VE-69 enamel and EP-0215 epoxy primer. The transition temperature α1, which is the glass transition temperature of fluoropolyurethane VE-69, after 3 years of exposure decreases in proportion to the average annual air temperature of the region. The transition temperatures α2 and α3 after full-scale exposure due to post-curing increased by 13−15°C and acquired stable values α2 = 99 ± 1°C, α3 = 122.5 ± 0.5°C, regardless of the climatic conditions of the tests.

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M. Lebedev

Federal Research Centre «The Yakut Scientific Centre of the Siberian Branch of the Russian Academy of Sciences», V. P. Larionov Institute of Physical-Technical Problems of the North of Siberian Branch of the Russian Academy of Sciences

Email: startsev@iptpn.ysn.ru

Corresponding Member of the RAS

俄罗斯联邦, 677980 Yakutsk

O. Startsev

Federal Research Centre «The Yakut Scientific Centre of the Siberian Branch of the Russian Academy of Sciences», V. P. Larionov Institute of Physical-Technical Problems of the North of Siberian Branch of the Russian Academy of Sciences

编辑信件的主要联系方式.
Email: startsev@iptpn.ysn.ru
俄罗斯联邦, 677980 Yakutsk

T. Koval

Gelendzhik Center for Climate Testing VIAM named after Georgy Vladimirovich Akimov - NRC "Kurchatov Institute"

Email: startsev@iptpn.ysn.ru
俄罗斯联邦, 353466 Gelendzhik

I. Veligodsky

Gelendzhik Center for Climate Testing VIAM named after Georgy Vladimirovich Akimov - NRC "Kurchatov Institute"

Email: startsev@iptpn.ysn.ru
俄罗斯联邦, 353466 Gelendzhik

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2. Fig. 1. Temperature dependences of E ¢ (1) and E ¢¢ (2) of fiberglass samples VPS-48/7781 in the initial state, from the surface of which the VE-69 coating and EP-0215 ​​primer have been removed.

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3. Fig. 2. Temperature dependences of E ¢ (1) and E ¢¢ (2) of samples of fiberglass VPS-48/7781 with VE-69 coating and EP-0215 ​​primer before exposure.

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4. Fig. 3. Temperature dependences of E ʹ (1) and E ʺ (2) of dried samples of fiberglass VPS-48/7781 before exposure, from the surface of which the VE-69 coating was removed, but the EP-0215 ​​primer layer was retained.

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5. Fig. 4. Dependence of the amount of desorbed moisture on the drying time at a temperature of 60°C from a sample of fiberglass VPS-48/7781 with primer EP-0215 ​​and coating VE-69, exposed for 3 years in Vladivostok.

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6. Fig. 5. Temperature dependences of E ʺ of fiberglass VPS-48/7781 coated with EP-0215 ​​primer and VE-69 enamel after 3 years of exposure in Vladivostok without preliminary conditioning (1) and after drying at 60°C until the mass of the samples is completely stabilized (2).

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