Quantitative data on the wettability of the surface of particles of thermochemically prepared ferromagntic powders have been obtained for the first time. It is established that their wettability can be enhanced by the introduction of surfactant substances. This makes it possible to create different nanostructured materials, for example, glues and sealants in which nanocomposite ferromagnetics serve as fillers. These materials are used to seal cracks, and eliminate defects in active main gas pipelines operating under extreme conditions.Information on the character of component interaction is required where ferromagnetic powders are used as fillers for the development of various nanostructured sealing compounds, for example, glues and sealants. Familiar composites do not fully satisfy material requirements for the sealing of cracks, blowholes, and other defects in active main gas lines operating under extreme conditions. In many cases, different liquids that may affect the surface properties of ferromagnetic powders are used as the disperse medium in the development of different composites.The purpose of the present study is to investigate the wettability of ferromagnetic powders that we have used as fillers in developing glues and sealants for service under extreme conditions. Nanocomposite Fe powders and powders containing 60 mass% of Fe, 30 mass% of Co, and 10 mass% of Ni were prepared by thermochemical means [1]. The powders have particle sizes ranging from 0.06 to 0.1 μm, and a specific surface of 20-28 m 2 /g. The surface of the powder particles is hydrophilic, and the particles are corrosion resistant, nonpyrophoric, and endure heating temperatures to 100 ± 10°C.The magnetic characteristics of the iron powders are: a coercive force H c = 24-32 kA/m, a specific saturation induction σ s = 100-120 A ⋅ m 2 /kg, a specific residual induction σ r = 22-28 A ⋅ m 2 /kg, and a coefficient of relative residual induction K = 0.2-0.25. The magnetic characteristics of the iron − cobalt − nickel powders are: H c = 49-60 kA/m, σ s = 180-200 A ⋅ m 2 /kg, σ r = 70-80 A ⋅ m 2 /kg, and K = 0.4-0.45. The phase composition of the iron powders, mass%, was established by methods of NGR-spectroscopy and x-ray phase analysis: 50-60 of Fe met , 25-30 of Fe 3 C, 14-19 of Fe 3 O 4 , and 0.7-1 of free C. Powders of the iron − cobalt − nickel system contained the following, mass%: 65-70 of the metals, 18-20 of Fe 3 C, 12-14 of Fe 3 O 4 , and 1-1.2 of free C. The surface of the powders is protected by the oxides of iron and its carbide.The heat of wetting Q of the iron and Fe − Co − Ni powders by different solvents was determined using an Setaram-made Calvier microcalorimeter in accordance with the familiar procedure outlined in [2]. Selection of solvents was dictated by their continued use for the development of nanostructured materials. The surface of the particles of the ferromagnetic powders is hydrophilic.
621.762The possibility of utilizing nanopowders of iron and Fe − Co − Ni produced bu a thermochemical method in the fabrication of sealing composition materials is investigated. It is established that such hermetic sealing composition materials function reliably under extremal conditions and guarantee elevated strength of adhesion to the surface of the metal and high corrosion and temperature stability.There is a need today for new methods of fabricating and investigating the properties of nanostructure sealing composition materials as well as improving existing methods. Of particular note in this connection is the regulation of the thermal and chemical stability of the structures that are obtained as well as questions related to the reliability and service life of these composite materials on objects that are to be protected against damage. The efficiency and reliability of a sealing composition material are determined largely by its ability to withstand extremal conditions caused by the external environment and repeated thermocycling in the interval of temperatures from −50 to +50°C. The composite material must possess high corrosion resistance and increased strength of their adhesion with metal.In the course of use (for example, in pipelines), maintenance operations, in particular, to eliminate leakage of gas out of discontinuities (air holes, cracks, microcracks, and other flaws), represent a special difficulty. Such operations are basically carried out through the use of welding, vibratory treatment of welded structures, and ultrasonic impact treatment. In practice, however, these techniques are not always implemented. In such cases the use of sealing compositions (sealants), which function for lengthy periods of time under rigid conditions without the need for additional bonding or preliminary treatment of the bonded surfaces [1], is an extremely promising approach.Therefore, the objective of the present study is to investigate the use of ferromagnetic powder as a nanostructural component in creating sealing compositions that function under extremal conditions (in the interval of temperatures from −50 to +50°C and at a pressure of 6.5 MPa). Analysis of known data and preliminary trials showed that other fillers do not always conform with the requirements imposed on the composite materials that are used to create hermetic sealing of cracks in gas pipelines [2]. Thus, the principal drawbacks with the use of, for example, powders of electrolytic or carbonyl iron as filler for composite material can be seen in their pyrophoricity and corrosion instability at temperatures from −50 to +50°C, the hydrophobicity of the surface (nonwettability of particles by the solvent), and the impossibility of assuring homogeneity of the composition (particle size 1-5 μm).The use of iron oxides with hydrophobic surface of particles as filler similarly does not enable us to produce a composite material capable of functioning under extremal conditions. In certain cases such filling is possible but to assure that the composite mate...
scite is a Brooklyn-based organization that helps researchers better discover and understand research articles through Smart Citations–citations that display the context of the citation and describe whether the article provides supporting or contrasting evidence. scite is used by students and researchers from around the world and is funded in part by the National Science Foundation and the National Institute on Drug Abuse of the National Institutes of Health.
Contact Info
customersupport@researchsolutions.com
10624 S. Eastern Ave., Ste. A-614
Henderson, NV 89052, USA
Product
Resources
This site is protected by reCAPTCHA and the Google Privacy Policy and Terms of Service apply.
Copyright © 2024 scite LLC. All rights reserved.
Made with 💙 for researchers
Part of the Research Solutions Family.
