Plasma-chemical modification of concrete processed by colorific metal salts

Bondarenko, Diana; Bondarenko, Nadezda Ivanovna; Bessmertnyi, Vasiliy Stepanovich; Burlakov, N. M.

doi:10.2991/aime-17.2017.22

Cited by 7 publications

(4 citation statements)

References 7 publications

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“…Одной из наиболее эффективных высокопроизводительных, энергосберегающих и экологически чистых технологий является плазмохимическое воздействие электродуговой плазмы на поверхность композиционных многослойных изделий [13][14][15].…”

Section: Introductionunclassified

A Block of Thermal Insulation Materials With Protective and Decorative Coatings

Bessmertnyy

Kochurin

Bondarenko

et al. 2020

Construction Materials and Products

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scientific and technological principles of alternative plasma technology for the production of two-layer heat-resistant glass-like decorative coating were developed. The compositions of the intermediate heat-resistant layer and the technology of its application to the surface of the enclosing block of foam glass are proposed. The optimal parameters of plasma melting of heat-resistant and decorative coating layers were determined. The influence of high-speed characteristics of plasma jet thermal melting on the formation of texture and performance of two-layer heat-resistant coating is established. The features of the formation of amorphous vitreous and glass-crystalline phases of a two-layer heat-resistant coating are presented. Using x-ray phase analysis, the features of the phase composition of different layers of heat-resistant coating, as well as the laws of formation of its structural elements are studied. Based on the analysis of significant experimental material, it was concluded that the formation of the upper amorphous layer with liquating regions and minor gas inclusions. The conducted researches allowed to reveal and justify the features of the structure of the layers lying under the amorphous liquating. It was found that the two-layer protective and decorative coating had high physico-chemical and physico-mechanical properties: adhesion strength to the matrix of the foam glass block-1.25 ± 0.05 MPa, microhardness-785 HV, heat resistance-122°C, acid resistance – 98.5%, alkali resistance – 95.4%.

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Section: Introductionunclassified

A Block of Thermal Insulation Materials With Protective and Decorative Coatings

Bessmertnyy

Kochurin

Bondarenko

et al. 2020

Construction Materials and Products

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“…Высокотемпературное воздействие плазменного факе-ла даже при кратковременном воздействии на бетон вызывает в нем дегидратацию гидросиликатов, разупрочнение бетона и образование микротрещин. Это приводит к снижению прочностных характеристик декоративного слоя [11][12][13].…”

Section: Introductionunclassified

Plasmochemical Modification of Wall Building Materials

Bessmertnyy

Puchka

Bondarenko

et al. 2020

Construction Materials and Products

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the aim of the work is to study the effect of a high-temperature plasma torch on the processes of phase transformations and layer-by-layer modification of the protective and decorative coating on concrete using as a filler a mixture of quartz sand and hollow glass microspheres. The main tasks included: investigation of the processes of evaporation and thermal diffusion of oxides of plasma-coated coatings; study of phase transformations in the melt and its subsequent crystallization in the process of rapid spontaneous cooling of the fused protective and decorative coating; study of the effect of sodium liquid glass on the processes of polymorphic transformations of alumina and the formation of micro-wicks due to the intense diffusion of sodium oxide; study of operational characteristics of protective and decorative coatings. It was established that the initial phases in the protective-decorative coating are α-Al2O3 and CaO∙6Al2O3 (β-Al2O3), and the liquid sodium glass in the coating leads additionally to the formation of Na2O∙11Al2O3. The top layer of the protective and decorative coating is Na–Ca–Al–Si glass with regions of heterogeneities containing an increased content of sodium oxide. The content of aluminum oxide in the protective and decorative coating based on the battle of high-alumina refractory was 95.1 %. The introduction into the coating composition of sodium liquid glass minimizes the processes of dehydration of the binding component and changes the chemical composition of the protective and decorative coating. Reduction of the aluminum oxide content to 83.0 % affects the microhardness indicators. Microhardness of the concrete surface due to the introduction of liquid glass is reduced from 2510 HV to 887 HV.

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“…To expand the color characteristics and minimize dehydration, various fillers made of ceramics, glass, expanded clay, chamotte, waste from the mining or metallurgical industry, etc. are used before the plasma-chemical modification in the molding of concrete "face down" or "face up" [1][2][3][4][5][6][7][8][9]. Protectivedecorative coatings on concrete have relatively low quality indicators [10,11].…”

Section: Introductionmentioning

confidence: 99%

Plasma-chemical modification of concrete

Bondarenko¹,

Bondarenko²,

Bessmertnyi³

et al. 2018

Proceedings of the International Conference "Actual Issues of Mechanical Engineering" (AIME 2018)

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Plasma chemical modification (PCM) improves chemical resistance of a glazed decorative coating and expands opportunities for designing various types of the decoration of concrete. However, PCM exposes the material to a significant thermal shock that leads to dehydration of hydrosilicates in the cement matrix followed by loss of strength of the concrete coating. This results in a reduction in the service characteristics of the concrete protective and decorative layer such as adhesion strength and freeze-thaw resistance and shortens the coating durability. Therefore, the improvement of the PCM method is a hot topic of the study and it is one of the most effective and modern technologies, which will result in enhancement of serviceability of concrete with the glazed decorative coating. This study investigated the effect of incorporation of calcium aluminate cement as a silicon-based intermediate layer between the glazed decorative layer and the concrete surface. The study demonstrated that the calcium aluminate cement intermediate layer after plasma chemical modification was dehydrated. Based on mineral composition and structural analysis, the dehydrated layer was visually divided into three zones: the upper dense layer; an intermediate layer with micro cracks; and the bottom dense layer. The microstructure of the dehydrated zone is represented by small non-developed microcracks less than 50 μm. Magnesium spinel was the main crystal phase in a calcium aluminate cement matrix. The dense dehydrated zone had a shell-like fracture, which is typical for spinel with imperfect cleavage. This study developed a glazed decorative coating and a protective calcium aluminate cement-based intermediate layer with the adhesion strength of 4.1 MPa and freeze-thaw resistance of more than 50 cycles that exceed service characteristics of concrete with the coatings using other materials.

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Plasma-chemical modification of concrete processed by colorific metal salts

Cited by 7 publications

References 7 publications

A Block of Thermal Insulation Materials With Protective and Decorative Coatings

A Block of Thermal Insulation Materials With Protective and Decorative Coatings

Plasmochemical Modification of Wall Building Materials

Plasma-chemical modification of concrete

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