METHODS FOR STABILIZING AND STRENGTHENING YOLDIAN CLAYS AND WEAK CLAY SOILS WHEN CREATING A SUBGRADE IN THE FAR NORTH REGIONS
Abstract and keywords
Abstract (English):
Purpose: Definition of the most effective methods and components for strengthening weak Yoldian clays used in the creation of transport routes in the North regions. Methods: The definition of the main physical-mechanical characteristics of clay soil was carried out in accordance with the requirements: of GOST (Russia State Standard) 12536—2014 “Soils. Methods for laboratory determination of granulometric (grain) and microaggregate composition”; GOST 25584—2016 “Methods for laboratory determination of the filtration coefficient”; GOST 22733—2016 “Soils. Method for laboratory determination of maximum density”; GOST 5180—2015 “Soils. Methods of laboratory determination of physical characteristics”; GOST 25100—2020 “Soils. Classification”. It is shown that the effective strengthening of weak clay soil is achieved as a result of its preliminary stabilization with the help of granulated blast-furnace slag or natural limestone of ≈2.5 mm fraction. The rational amount of granulated blast-furnace slag or limestone is 15 wt.% of the soil mass and at the same time, clay soil has the highest strength value — (2.25–2.45) MPa. The difference in strength indicators in favor of limestone constitutes 9.0%. It has been experimentally established that in order to increase reinforced clay soil strength it is effective to use granulated blast-furnace slag in combination with finely ground blast-furnace slag which rational amount of is 10 wt.% of soil mass which achieved strength of corresponds to M20–M25 grade. It has been defined that for comprehensive improvement of the indicators as strength, density, and frost resistance it is necessary to introduce additionally to clay soil, reinforced with blast-furnace metallurgical slag as reactive components which it’s effective to use Portland cement in amount of not more than 5 wt.% of soil mass in combination with dry complex chemical additive “PRA” which rational amount of constitutes 2.0 wt.% by weight of (Portland cement + finely ground blast-furnace slag). Practical significance: Stabilized and comprehensively strengthened weak clayey soil is characterized by the following actual indicators: M50 F35 K10 — 0.026 m/day which can be used as a base at construction of transport routes of local importance in the regions of the North.

Keywords:
Clay soil, stabilization, strengthening, strength, filtration coefficient, granulated blast-furnace slag, finely ground slag, chemical additive
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References

1. Abu-Hasan M. S. Vliyanie razlichnyh vidov armirovaniya na deformacionnye harakteristiki glinistogo grunta v usloviyah sezonnogo zamerzaniya i ottaivaniya / M. S. Abu-Hasan, V. V. Egorov // Seriya konferenciy IOP: Materialovedenie i inzheneriya. - 2020. - T. 753. - Vyp. 4, 5. - DOI:https://doi.org/10.1088/1757-899X/753/4/042083.

2. Avvad T. Chislennyy analiz s ispol'zovaniem modeli uprugoplasticheskogo grunta dlya odinochnoy svai v glinyanom sloe dlya izucheniya vliyaniya dopolnitel'noy nagruzki na raspredelenie poverhnostnogo treniya / T. Avvad, S. Al' Kodsi, V. Ulic-kiy, A. Shashkin, L. Avvad // Konspekt lekciy po grazhdanskomu stroitel'stvu. - 2020. - № 49. - S. 499-506. - DOI:https://doi.org/10.1007/978-981-15-0450-1_52.

3. Solov'eva V. Vysokoeffektivnaya remontnaya smes' dlya vosstanovleniya i za-schity povrezhdennyh betonnyh konstrukciy / V. Solov'eva, I. Stepanova, D. Solov'ev, A. Kasatkina // Konspekt lekciy po grazhdanskomu stroitel'stvu ssylka otklyuchena. - 2020. - № 50. - S. 369-375. - DOI:https://doi.org/10.1007/978-981-15-0454-9_38.

4. Shershneva M. Geoekozaschitnye ekrany pri stroitel'stve i ekspluatacii do-rog v holodnyh regionah / M. Shershneva, A. Saharova, I. Kozlov // Konspekt lekciy po stroitel'stvu ssylka otklyuchena. - 2020. - № 50. - S. 347-356. - DOI:https://doi.org/10.1007/978-981-15-0454-9_36 27.

5. Egorov V. Primenenie evolyucionnogo algoritma optimizacii shprengelevyh sistem transportnyh zdaniy i sooruzheniy dlya severnyh rayonov / V. Egorov, A. Kravchenko, M. Abu-Hasan // Seriya konferenciy IOP: Materialovedenie i inzheneriya. - 2020. - C. 753(2). - DOIhttps://doi.org/10.1088/1757-899X/753/2/022020.

6. Bogomolova N. Osobennosti inzhenernyh izyskaniy v rayonah rasprostraneniya vechnoy merzloty na primere proekta «Severnyy shirotnym sposobom» / N. Bogomolova, Yu. Milyushkan, S. Shkurnikov i dr. // Konspekt lekciy po grazhdanskomu stroitel'stvu. - 2020. - № 50. - S. 215-221. - DOI:https://doi.org/10.1007/978-981-15-0454-9_23 31.

7. Klemyacionok P. Ekstrapolyaciya krivyh szhatiya na vysokie davleniya dlya myagkih glinistyh gruntov / P. Klemyacionok, S. Kolmogorova, S. Kolmogorov // Konspekt lekciy po grazhdanskomu stroitel'stvu. - 2020. - № 50. - S. 233-238. - DOI:https://doi.org/10.1007/978-981-15-0454-9_25 32.

8. Babak N. Struktura atomov osnovnoy fazy promyshlennyh othodov prognoziruet svoystva stroitel'nyh materialov v transportnom stroitel'stve v holodnyh regionah / N. Babak // Konspekt lekciy po grazhdanskomu stroitel'stvu. - 2020. - T. 50 - S. 451-457. - DOI:https://doi.org/10.1007/978-981-15-0454-9_47. 33.

9. Belash T. A. Seysmostoykost' zdaniy na ottaivayuschih mnogoletnemerzlyh gruntah / T. A. Belash, T. V. Ivanova // Stroitel'nyy zhurnal. - 2020. - № 93(1). - S. 50-59. - DOI:https://doi.org/10.18720/MCE.93.5 34.

10. Bogdanova G. Metodika ocenki parametrov reakcii mnogoetazhnyh zdaniy s nelineynymi dinamicheskimi vibrogasitelyami pri seysmicheskih vozdeystviyah / G. Bogdanova, A. Benin // Konspekt lekciy po grazhdanskomu stroitel'stvu. - 2022. - № 180. - S. 553-564. - DOIhttps://doi.org/10.1007/978-3-030-83917-8_50.

11. Nikolaev S. V. Metodika vybora effektivnogo pogruzheniya i kontrolya glubiny zapolneniya stroitel'nyh materialov s otkrytoy teksturoy / S. V. Nikolaev, A. V. Benin, A. M. Popov // Journal of Physics: Conference Seriesthis link is disabled. - 2021. - № 2131(2). - DOI:https://doi.org/10.1088/1742-6596/2131/2/022055 36.

12. Huang W. Snizhenie gidratacii gliny putem dobavleniya organicheskogo stabilizatora / W. Huang, Y. Zhang, Z. Luo Et al. // Gliny i glinistye mineraly. - 2021. - T. 69. - S. 489-499 (2021). - DOI:https://doi.org/10.1007/s42860-021-00139-4 37.

13. Solov'eva V. Povyshenie urovnya svoystv kompozicionnyh materialov dlya stroitel'nyh geokonstrukciy s primeneniem dobavok novogo pokoleniya / V. Solov'eva, I. Stepanova, D. Solov'ev i dr. // Konspekt lekciy po stroitel'stvu neorganicheskih dobavok. - 2020. - № 50. - S. 387-393. - DOI:https://doi.org/10.1007/978-981-15-0454-9_40 38.

14. Solov'eva V. Mnogofunkcional'nye nanomodificirovannye betony novogo pokoleniya / V. Solov'eva, I. Stepanova, D. Solov'ev i dr. // Konspekt lekciy po stroitel'nomu stroitel'stvu ssylka otklyuchena. - 2020. - № 50. - S. 377-386. - DOI:https://doi.org/10.1007/978-981-15-0454-9_39. 39.

15. Solov'eva V. Vosstanovlenie povrezhdennyh geoosnovaniy na transporte s ispol'zovaniem vysokoeffektivnogo remontnogo rastvora / V. Solov'eva, D. Solov'ev, I. Stepanova, A. Kasatkina // MATEC Web of Conferences. - 2018. - № 239. - DOIhttps://doi.org/10.1051/matecconf /201823901015.

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