Tensile Test Method for Basalt Roving

Leonid U. Stupishin; S.G. Emelyeanov; E.V. Savelyeva; Fedor Altuhov

doi:10.4028/www.scientific.net/KEM.821.506

Paper Titles

Strengthening of Reinforced Concrete Beams Using Bamboo Fiber/Epoxy Composite Plates in Flexure
p.465

A Review Study on the Characterization of Geopolymer Concrete
p.472

Acoustic Emission Signals of Pull-Off Test for Concrete Slab Strengthened with CFRP Using Various Surface Preparations
p.479

Effect of Dipotassium Hydrogen Phosphate and Calcium Nitrate on Strength and Microstructural Properties of Geopolymer Mortar
p.486

Compressive Strength Variations in Lightweight Aggregate Concrete Samples Affected by Segregation Caused by Excessive Vibration
p.493

Prediction of Bending Beam Rheometer Test Outputs Using Artificial Neural Networks
p.500

Tensile Test Method for Basalt Roving
p.506

Mechanical Performances of Green Engineered Cementitious Composites Incorporating Various Types of Sand
p.512

Energy Savings of PCM-Incorporated Building in Hot Dry Climate
p.518

HomeKey Engineering MaterialsKey Engineering Materials Vol. 821Tensile Test Method for Basalt Roving

Tensile Test Method for Basalt Roving

Abstract:

In the construction industry there is no method for tensile testing of materials of basalt complex filaments of small diameters and roving. The existing methods of testing fibers and roving presented in regulatory documents are intended for textile materials and materials based on fiberglass. The studies cited in the article were aimed at studying the strength properties of roving materials and a multifilament yarn based on basalt fibers, as well as working out methods for testing them. The article presents studies of the strength characteristics of roving and complex yarn based on basalt fiber, on which testing of basalt material samples was tested. The strength characteristics of various forms of basalt materials for various adhesive processing were obtained. The applied experimental test procedure was appreciated positively.

You might also be interested in these eBooks

View Preview

Info:

Periodical:

Key Engineering Materials (Volume 821)

Pages:

506-511

DOI:

https://doi.org/10.4028/www.scientific.net/KEM.821.506

Citation:

Cite this paper

Online since:

September 2019

Authors:

Leonid U. Stupishin*, S.G. Emelyeanov, E.V. Savelyeva, Fedor Altuhov

Keywords:

Basalt Fiber, Basalt Multifilament Thread, Basalt Roving, Composite Material, Epoxy Binder, Reinforcement, Tensile Strength, Universal Adhesive Binder

Export:

RIS, BibTeX

Price:

Permissions CCC:

Request Permissions

Permissions PLS:

Request Permissions

Сopyright:

Citation:

* - Corresponding Author

References

[1] I.V. Borovskikh, N.M. Morozov, Increased durability of basalt fiber in cement concretes. Izvestiya KGSAU, 2(20) (2012) 160-165.

Google Scholar

[2] I.A. Starovoytova, E.S. Zykova, A.M. Suleymanov, A.N. Semenov, M.V. Mishurova, Study of the physicomechanical characteristics of nano-modified basalt roving and composite material based on it. Izvestiya KGSAU, 3(37) (2016).

Google Scholar

[3] E.M. Babich, V.E. Babich, E.E. Polyanovskaya, The study of the adhesion of reinforcement to concrete by the method of mathematical planning of the experiment, Vestnic Belorussko-rossiskogo universiteta (Bulletin of the Belarusian-Russian University). 4(45) (2014) 136-146.

DOI: 10.53078/20778481_2014_4_136

Google Scholar

[4] A.K. Kychkin, A.A. Vasilyeva, Study of physico-mechanical characteristics of composite reinforcing bars made on the basis of basalt roving. Bulletin of the North-Eastern Federal University. 3 (9), (2012) 80-85.

Google Scholar

[5] V.G. Khozin, A.N. Kuklin Features of the test and the nature of the destruction of polymer composite reinforcement. Engineering and Construction Journal, 3 (2014) 40-50.

Google Scholar

[6] A.A. Dalinkevich, K.Z. Gumargaliyeva, S.S. Marakhovsky, A.V. Aseev, Basalt fiber polymer composites as promising corrosion-resistant materials. Corrosion: materials, protection, 4 (2015), 37-42.

Google Scholar

[7] Glass textile materials. Method for determination of breaking load and elongation at break: GOST 6943.10-2015. - Instead of GOST 6943.10–79; enter 01.06.2016. -M .: Standardinform 2015. –11 p.

Google Scholar

[8] Fiberglass. Roving Production of test samples and determination of tensile strength of impregnated rovings: GOST 34261-2017 (ISO 9163: 2005); Enter 07/01/2017 –M .: Standardinform 2017. –22 p.

Google Scholar

[9] Staple fiber and chemical harness. Methods for determining the breaking load and elongation at break: GOST 10213-2002 (ISO). - instead of GOST 10213.2-73; Enter 01/01/2003. . - Minsk: Interstate Council for Standardization, Metrology and Certification, 2002. - 11.

Google Scholar

[10] Polymer composites, production of plates for the manufacture of samples for testing: GOST 33345-2015 (ISO); enter 06/01/2016. . - M .: Standardinform, 2016. - 28 p.

Google Scholar

[11] Polymer composites. Test method for tensile flat samples: GOST 56785-2015; enter 10/27/2015. –M .: Standardinform, 2016. - 20 p.

Google Scholar

[12] Polymer composites. Test method. Tensile tests; GOST 32656 - 2017 (ISO 527-4,1997, ISO 527-5, 2009), enter July 1, 2017 –M .: Standartinform, 2017. - 28 p.

Google Scholar

[13] Yu.M. Tarnopolsky, V.L. Kulakov, Test methods for composites. Mechanics of composites, 5/6 (39) (2001) 6690693.

Google Scholar

[14] L.Yu. Stupishin, E.V. Savelieva, A.V. Masalov, D.A. Pochernyaev, Modern technology of composite materials, Ufa, (2016).

Google Scholar

[15] L.U. Stupishin, Variational criteria for critical levels of internal energy of a deformable solids, Applied Mechanics and Materials, 578-579 (2014) 1584-1587.

DOI: 10.4028/www.scientific.net/amm.578-579.1584

Google Scholar