FMagnesium hydroxide-based flame-retardant fillers for polymer materials and the effect of particle size on the dehydration process at high temperatures-Reference-Cited by-同舟云学术

FMagnesium hydroxide-based flame-retardant fillers for polymer materials and the effect of particle size on the dehydration process at high temperatures

Published:2022-10-27 Issue:7-8 Volume: Page:44-47
ISSN:0554-2901
Container-title:Plasticheskie massy
language:
Short-container-title:Plastičeskie massy

Author:

BREKHOVA K. A.¹,SIMONOV-EMELYANOV I. D.¹

Affiliation:

1. MIREA - Russian Technological University (Lomonosov Institute of Fine Chemical Technologies)

Abstract

Exemplifed by various grades of magnesium hydroxide used as halogen-free flame-retardant fillers, the regularities of the destruction and dehydration process depending on the size of the disperse phase particles – from large (45 microns) to nanoparticles (50–100 nm) – were considered for the first time.By DTA and TGA methods, the effect of the size of magnesium hydroxide particles on the temperature of the beginning of decomposition, the temperature range of the dehydration reaction, the kinetics and volumes of water release, the thermal effects of the reaction and the formation of coke residue when exposed to high temperatures was established.The analysis of the data obtained allows us to draw the main conclusion - the particle size of halogen-free fire-retardant fillers has a significant effect on the parameters and kinetics of the process of decomposition of magnesium hydroxide (the brucite mineral) at high temperatures, which must be taken into account when creating and processing dispersed-filled polymer composite materials (DFPCM).It has been established that from the point of view of the decomposition process and the release of water by flame retardants at high temperatures, grades based on magnesium hydroxide with a particle diameter of more than ~10 μm are the most effective for the production of DFPCMs.

Publisher

Publishing House Plastic Ltd

Subject

Polymers and Plastics,Chemical Engineering (miscellaneous)

Reference13 articles.

1. Kats G.S. Napolniteli dlya polimernykh kompozitsionnykh materialov / G.S. Kats, D.V. Milevski // M.: Khimiya, 1981. – S. 12–48.

2. Kablov V.F. Osnovnye sposoby i mekhanizmy povysheniya ogne-teplozashchitnoi stoikosti materialov / V.F. Kablov, O.M. Novopol'tseva, V.G. Kochetkov, A.G. Lapina // Izvestiya VGTU. – 2016. – №4. – S. 46–60.

3. Nikitina A.V. Bezgalogennye antipireny-napolniteli na osnove smesi gidromagnezit+khantit dlya polimernykh materialov / A.V. Nikitina, I.D. Simonov-Emel'yanov //Plasticheskie massy. – 2018. – №7–8. – S. 37–42. DOI: 10.35164/0554-2901-2018-7-8-37-42.

4. Svatikov A. Yu. Termicheskaya stabil'nost' polimernykh kabel'nykh kompozitsii s napolnitelem-antipirenom / A.Yu. Svatikov, I.D. Simonov-Emel'yanov // Tonkie khimicheskie tekhnologii. – 2018. – T. 13. – №6. – S. 35–41. DOI: 10.32362/2410-6593-2018-13-6-35-41.

5. Aseeva R.M. Gorenie polimernykh materialov / R.M. Aseeva, G.E. Zaikov // M.: Nauka, 1981. 280 s.

Cited by 2 articles. 订阅此论文施引文献订阅此论文施引文献，注册后可以免费订阅5篇论文的施引文献，订阅后可以查看论文全部施引文献

1. Generalized nomogram for determining the type of structure and composition of fire-resistant polymer composite materials with fire-retardant fillers;Plasticheskie massy;2024-03-15

2. Projection of structure and compositions of resistance to burning polymer composite materials with flame retardants based on magnesium hydroxide;Fine Chemical Technologies;2023-05-27