Effect of microsilica supplement on workability and density of equally  moveable flow concrete and concrete strength

Akhmadov Sunnatillo Abdulloyevich; Khaidarova Dilfuza Vasitovna; Suleymanova Gavkhar Asatullayevna

The article examines the possibility of improving the concrete composition, by introducing the component of microsilica, in order to reduce the consumption of cement in concrete and, consequently, its cost. The result of using a mixture based on Portland slag cement (M 400) of Magnitogorsk Cement and Refractory Plant is described. The composition of concrete also included the following: porphyritic gravel GOP MMK fraction 10 - 20 mm; sand river fraction 0,16 - 5 mm; mixing water from the municipal water supply system and microsilica of the Chelyabinsk electrometallurgical plant with SiO2 content of 65- 83.38%. The authors reviewed the effect of microsilica on the strength of equally moveable concrete and the effect of microsilica on the properties of equally moveable mixtures and concrete. It was found that the addition of microsilica in an amount of 5 ... 15% of the weight of cement density of equally mobile, including concrete decreases by 80 ... 85 kg/m3; mix workability decreases from 5 to 0 cm; the strength of the concrete increases by 45 ... 90% – for steamed concrete; and by 19 ... 40% – for concrete hardening in normal conditions. According to the work results, saving of cement in concrete of B15...B25 class due to the introduction of microsilica may amount to 41 to 183 kg/m3, depending on curing conditions and the properties of concrete mixtures. The authors conclude that there are real prerequisites for the systematic organization of industrial production of new thermal insulation materials on an industrial scale using regional resources.

Jurnal nomi“Muhandis” xalqaro ilmiy jurnali
Nashr sonivol. 2 issue 1 2024
Ko'rishlar soni 11

Internet havola

DOI

UzSCI tizimida yaratilgan sana 14-06-2024

O'qishlar soni 11

Nashr sanasi 01-04-2024

Asosiy tilIngliz

Sahifalar13-16

Kalit so'z

mobility

cement

strength

microsilica

concrete mixes

English

The article examines the possibility of improving the concrete composition, by introducing the component of microsilica, in order to reduce the consumption of cement in concrete and, consequently, its cost. The result of using a mixture based on Portland slag cement (M 400) of Magnitogorsk Cement and Refractory Plant is described. The composition of concrete also included the following: porphyritic gravel GOP MMK fraction 10 - 20 mm; sand river fraction 0,16 - 5 mm; mixing water from the municipal water supply system and microsilica of the Chelyabinsk electrometallurgical plant with SiO2 content of 65- 83.38%. The authors reviewed the effect of microsilica on the strength of equally moveable concrete and the effect of microsilica on the properties of equally moveable mixtures and concrete. It was found that the addition of microsilica in an amount of 5 ... 15% of the weight of cement density of equally mobile, including concrete decreases by 80 ... 85 kg/m3; mix workability decreases from 5 to 0 cm; the strength of the concrete increases by 45 ... 90% – for steamed concrete; and by 19 ... 40% – for concrete hardening in normal conditions. According to the work results, saving of cement in concrete of B15...B25 class due to the introduction of microsilica may amount to 41 to 183 kg/m3, depending on curing conditions and the properties of concrete mixtures. The authors conclude that there are real prerequisites for the systematic organization of industrial production of new thermal insulation materials on an industrial scale using regional resources.

Kalit so'z

mobility

cement

strength

microsilica

concrete mixes

№ Muallifning F.I.Sh. Lavozimi Tashkilot nomi

1 Akhmadov S.A. Assistant Тashkent State Transport University

2 Khaidarova D.V. Student Tashkent Institute of Architecture and Civil Engineering

3 Suleymanova G.A. Student Tashkent Institute of Architecture and Civil Engineering

№ Havola nomi

1 Kim D.J. Characteristics of Limited Shrinkage During Drying of Arched Steel Fiber Concrete / D.J. Kim, S.X. Kim, V.K. Choi // Applied Sciences. — 2021. — 11(16). — p. 7537. — DOI: 10.3390/app11167537.

2 Yun H.D. The Effect of the Strength of the Reinforcing Fiber on the Mechanical Properties of High Strength Concrete. Fibers / H.D. Yun, S.H. Lim, V.K. Choi. — 2019. — 7(10). — p. 93. — DOI: 10.3390/fib7100093

3 Yun H.D. Microstructure and Mechanical Properties of Cement Mortar Containing Phase Transition Materials / H.D. Yun, J.V. Lee, Y.Y. Jang [et al.] // Applied Sciences. — 2019. — 9(5). — p. 943. — DOI: 10.3390/app9050943

4 Khan U. Evaluation of the Effectiveness of Khyber-Pakhtunkhwa Rice Husk Ash (RHA) in Improving the Mechanical Properties of Cement / U. Khan, K. Shehzada, T. Bibi [et al.] // Building and Construction Materials. — 2018. — Vol. 176. — p. 89-102

5 Barichevich A. The Effect of Polymer Fibers Recycled from Used Tires on the Properties of Wet-Coated Concrete / A. Barichevich, M. Pezer, M.J. Rukavina [et al.] // Building Materials. — 2018. — Vol. 176. — p. 135-144. — DOI: 10.1016/j.conbuildmat.2018.04.229

6 Permyakov M.B. Creating a Comfortable Environment in Small-Sized Housing / M.B. Permyakov, T.V. Krasnova // International Research Journal. — 2021. — 1(103). — Pt 1. — p. 165-169. — DOI: 10.23670/IRJ.2021.103.1.025

7 Udodov S. Mechanical and Physical Properties of Fine-Grained Concrete for Concrete Additive Manufacturing / S. Udodov, Y. Galkin, P. Belov // E3S Web of Conferences. — 2019. — 02041(2019). — DOI: 10.1051/e3sconf/20199102041

8 Permyakov M.B. Assessment of Reliability and Accident Risk for Industrial Buildings / M.B. Permyakov, A.N. Ilyin, V.M. Andreev [et al.] // MATEC Web of Conferences. — 2018. — p. 02007. — DOI: 10.1051/matecconf/201825102007

9 Perepelicyn V.A. Vysokokachestvennoe prirodnoe ogneupornoe syr'jo Urala [High Quality Natural Refractory Raw Materials of the Urals] / V.A. Perepelicyn, I.V. Jukseeva, L.V. Ostrjakov // Mineral'noe syr'jo Urala [Mineral Raw Materials of the Urals]. — 2008. — 3. — P. 14-30. — URL: https://www.elibrary.ru/item.asp?id=11699376 (accessed: 12.01.2023). [in Russian]

10 Perepelicyn V.A. Mineral'no-syr'evaja baza proizvodstva sovremennyh ogneuporov (prodolzhenie) [Mineral and Raw Material Base of Modern Refractories Production (continued)] / V.A. Perepelicyn, I.V. Jukseeva, L.V. Ostrjakov // Ogneupory i tehnicheskaja keramika [Refractories and Technical Ceramics]. — 2008. — 6. — c. 53-64. — URL: ttps://www.elibrary.ru/download/elibrary_15288 902_33279702.pdf (accessed: 14.01.2023). [in Russian]

11 Kononova O.V. Issledovanie vlijanija mikrokremnezema na svojstva samouplotnjajushhegosja keramzitobetona [Study of the Effect of Microsilica on the Properties of Self-Compacting Claydite Concrete] / O.V. Kononova, A.V. Loskutov // Trudy Povolzhskogo gosudarstvennogo tehnologicheskogo universiteta. Serija: Tehnologicheskaja [Proceedings of the Volga Region State Technological University. Series: Technological]. — 2015. — 3. — p. 193-198. [in Russian]

12 Andreevskaja T.S. Mikrokremnezem, mehanizm ego obrazovanija i oblasti primenenija [Microsilica, Its Mechanism of Formation and Applications] / T.S. Andreevskaja // Rol' innovacij v transformacii sovremennoj nauki: sbornik statej po itogam Mezhdunarodnoj nauchno prakticheskoj konferencii [The Role of Innovation in the Transformation of Modern Science: A Collection of Articles from the International Scientific and Practical Conference]. — 2018. — p. 9-11. [in Russian]

13 Pashkov E.I. Sovremennye tehnologii futerovki gazohodov teplovyh agregatov ogneupornymi materialami [Modern Refractory Technology for Lining Heat Trains with Refractory Materials] / E.I. Pashkov, M.B. Permjakov, T.V. Krasnova // Mezhdunarodnyj nauchno-issledovatel'skij zhurnal [International Research Journal]. — 2021. — 6 1(108). — p. 95-99. [in Russian]

14 Pashkov E.I. Zashhita teplotehnicheskih agregatov v agressivnoj vysokotemperaturnoj srede stroitel'nymi teploizoljacionnymi materialami [Protection of Heating Units in Aggressive High-Temperature Environments with Building Thermal Insulation Materials] / E.I. Pashkov, M.B. Permjakov, T.V. Krasnova // Vestnik evrazijskoj nauki [Journal of Eurasian Science]. — 2021. — Vol. 13. — 2. — p. 30. [in Russian]

15 Kramar L.Ja. Vlijanie dobavki mikro kremnezjoma na gidrataciju alita i sul'fatostojkost' cementnogo kamnja [Effect of Microsilica Additive on Alite Hydration and Sulphate Resistance of Cement Cake] / L.Ja. Kramar, B.Ja. Trofimov, L.S. Talisman [et al.] // Cement. — 1989. — 6. — p. 14-17. [in Russian]

16 Gamalij E.A. Struktura i svojstva cementnogo kamnja s dobavkami mikro kremnezjoma i polikarboksilatnogo plastifikatora [Structure and Properties of Cement Stone with Microsilica Additives and Polycarboxylate Plasticizer] / E.A. Gamalij, B.Ja. Trofimov, L.Ja. Kramar // Vestnik Juzhno-Ural'skogo gosudarstvennogo universiteta. Serija: Stroitel'stvo i arhitektura [Bulletin of South Ural State University. Series: Construction and Architecture]. — 2009. — 16(149). — p. 29-35. [in Russian]

17 Shuldjakov K.V. Vlijanie dobavki «mikrokremnezem-polikarboksilatnyj super plastifikator» na gidrataciju cementa, strukturu i svojstva cementnogo kamnja [Effect of the Additive "Microsilica-Polycarboxylate Super Plastifier" on Cement Hydration, Structure and Properties of Cement Stone] / K.V. Shuldjakov, L.Ja. Kramar, B.Ja. Trofimov [et al.] // Cement i ego primenenie [Cement and Its Applications]. — 2013. — 2. — p. 114-118. [in Russian].

Kutilmoqda

№	Muallifning F.I.Sh.	Lavozimi	Tashkilot nomi
1	Akhmadov S.A.	Assistant	Тashkent State Transport University
2	Khaidarova D.V.	Student	Tashkent Institute of Architecture and Civil Engineering
3	Suleymanova G.A.	Student	Tashkent Institute of Architecture and Civil Engineering

№	Havola nomi
1	Kim D.J. Characteristics of Limited Shrinkage During Drying of Arched Steel Fiber Concrete / D.J. Kim, S.X. Kim, V.K. Choi // Applied Sciences. — 2021. — 11(16). — p. 7537. — DOI: 10.3390/app11167537.
2	Yun H.D. The Effect of the Strength of the Reinforcing Fiber on the Mechanical Properties of High Strength Concrete. Fibers / H.D. Yun, S.H. Lim, V.K. Choi. — 2019. — 7(10). — p. 93. — DOI: 10.3390/fib7100093
3	Yun H.D. Microstructure and Mechanical Properties of Cement Mortar Containing Phase Transition Materials / H.D. Yun, J.V. Lee, Y.Y. Jang [et al.] // Applied Sciences. — 2019. — 9(5). — p. 943. — DOI: 10.3390/app9050943
4	Khan U. Evaluation of the Effectiveness of Khyber-Pakhtunkhwa Rice Husk Ash (RHA) in Improving the Mechanical Properties of Cement / U. Khan, K. Shehzada, T. Bibi [et al.] // Building and Construction Materials. — 2018. — Vol. 176. — p. 89-102
5	Barichevich A. The Effect of Polymer Fibers Recycled from Used Tires on the Properties of Wet-Coated Concrete / A. Barichevich, M. Pezer, M.J. Rukavina [et al.] // Building Materials. — 2018. — Vol. 176. — p. 135-144. — DOI: 10.1016/j.conbuildmat.2018.04.229
6	Permyakov M.B. Creating a Comfortable Environment in Small-Sized Housing / M.B. Permyakov, T.V. Krasnova // International Research Journal. — 2021. — 1(103). — Pt 1. — p. 165-169. — DOI: 10.23670/IRJ.2021.103.1.025
7	Udodov S. Mechanical and Physical Properties of Fine-Grained Concrete for Concrete Additive Manufacturing / S. Udodov, Y. Galkin, P. Belov // E3S Web of Conferences. — 2019. — 02041(2019). — DOI: 10.1051/e3sconf/20199102041
8	Permyakov M.B. Assessment of Reliability and Accident Risk for Industrial Buildings / M.B. Permyakov, A.N. Ilyin, V.M. Andreev [et al.] // MATEC Web of Conferences. — 2018. — p. 02007. — DOI: 10.1051/matecconf/201825102007
9	Perepelicyn V.A. Vysokokachestvennoe prirodnoe ogneupornoe syr'jo Urala [High Quality Natural Refractory Raw Materials of the Urals] / V.A. Perepelicyn, I.V. Jukseeva, L.V. Ostrjakov // Mineral'noe syr'jo Urala [Mineral Raw Materials of the Urals]. — 2008. — 3. — P. 14-30. — URL: https://www.elibrary.ru/item.asp?id=11699376 (accessed: 12.01.2023). [in Russian]
10	Perepelicyn V.A. Mineral'no-syr'evaja baza proizvodstva sovremennyh ogneuporov (prodolzhenie) [Mineral and Raw Material Base of Modern Refractories Production (continued)] / V.A. Perepelicyn, I.V. Jukseeva, L.V. Ostrjakov // Ogneupory i tehnicheskaja keramika [Refractories and Technical Ceramics]. — 2008. — 6. — c. 53-64. — URL: ttps://www.elibrary.ru/download/elibrary_15288 902_33279702.pdf (accessed: 14.01.2023). [in Russian]
11	Kononova O.V. Issledovanie vlijanija mikrokremnezema na svojstva samouplotnjajushhegosja keramzitobetona [Study of the Effect of Microsilica on the Properties of Self-Compacting Claydite Concrete] / O.V. Kononova, A.V. Loskutov // Trudy Povolzhskogo gosudarstvennogo tehnologicheskogo universiteta. Serija: Tehnologicheskaja [Proceedings of the Volga Region State Technological University. Series: Technological]. — 2015. — 3. — p. 193-198. [in Russian]
12	Andreevskaja T.S. Mikrokremnezem, mehanizm ego obrazovanija i oblasti primenenija [Microsilica, Its Mechanism of Formation and Applications] / T.S. Andreevskaja // Rol' innovacij v transformacii sovremennoj nauki: sbornik statej po itogam Mezhdunarodnoj nauchno prakticheskoj konferencii [The Role of Innovation in the Transformation of Modern Science: A Collection of Articles from the International Scientific and Practical Conference]. — 2018. — p. 9-11. [in Russian]
13	Pashkov E.I. Sovremennye tehnologii futerovki gazohodov teplovyh agregatov ogneupornymi materialami [Modern Refractory Technology for Lining Heat Trains with Refractory Materials] / E.I. Pashkov, M.B. Permjakov, T.V. Krasnova // Mezhdunarodnyj nauchno-issledovatel'skij zhurnal [International Research Journal]. — 2021. — 6 1(108). — p. 95-99. [in Russian]
14	Pashkov E.I. Zashhita teplotehnicheskih agregatov v agressivnoj vysokotemperaturnoj srede stroitel'nymi teploizoljacionnymi materialami [Protection of Heating Units in Aggressive High-Temperature Environments with Building Thermal Insulation Materials] / E.I. Pashkov, M.B. Permjakov, T.V. Krasnova // Vestnik evrazijskoj nauki [Journal of Eurasian Science]. — 2021. — Vol. 13. — 2. — p. 30. [in Russian]
15	Kramar L.Ja. Vlijanie dobavki mikro kremnezjoma na gidrataciju alita i sul'fatostojkost' cementnogo kamnja [Effect of Microsilica Additive on Alite Hydration and Sulphate Resistance of Cement Cake] / L.Ja. Kramar, B.Ja. Trofimov, L.S. Talisman [et al.] // Cement. — 1989. — 6. — p. 14-17. [in Russian]
16	Gamalij E.A. Struktura i svojstva cementnogo kamnja s dobavkami mikro kremnezjoma i polikarboksilatnogo plastifikatora [Structure and Properties of Cement Stone with Microsilica Additives and Polycarboxylate Plasticizer] / E.A. Gamalij, B.Ja. Trofimov, L.Ja. Kramar // Vestnik Juzhno-Ural'skogo gosudarstvennogo universiteta. Serija: Stroitel'stvo i arhitektura [Bulletin of South Ural State University. Series: Construction and Architecture]. — 2009. — 16(149). — p. 29-35. [in Russian]
17	Shuldjakov K.V. Vlijanie dobavki «mikrokremnezem-polikarboksilatnyj super plastifikator» na gidrataciju cementa, strukturu i svojstva cementnogo kamnja [Effect of the Additive "Microsilica-Polycarboxylate Super Plastifier" on Cement Hydration, Structure and Properties of Cement Stone] / K.V. Shuldjakov, L.Ja. Kramar, B.Ja. Trofimov [et al.] // Cement i ego primenenie [Cement and Its Applications]. — 2013. — 2. — p. 114-118. [in Russian].