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Geotechnical investigation of borrow pit as a subgrade material for road construction at Victor Attah International Airport, Uyo, Nigeria

Treść / Zawartość
Identyfikatory
Warianty tytułu
PL
Badanie geotechniczne materiału z wykopu jako podłoża do budowy dróg na międzynarodowym lotnisku Victor Attah, Uyo, Nigeria
Języki publikacji
EN
Abstrakty
EN
One of the mass prompt practices of soils is for engineering projects such as the construction of roads, buildings, dams, and so on. Therefore, suitability of index and mechanical properties needs to be investigated. This study aims to determine the essential quality material required for road construction, thereby poses détente prospect for the disposal of ineffectual atrophy generated on sites. Such materials are classified into index and mechanical properties. Six subgrade samples were taken at the depth to bottom ranging from (1.0-5.0) m and tested. The sample was subdued to the laboratory tests, such as Sieve Analysis, Atterberg limits, compaction, California Bearing Ratio (CBR), and Specific Gravity (SG) respectively. The mechanical analysis which involved particle size distribution revealed that the subgrade was finely grated with a limit of ≤35% for subgrade passing sieve No. 200 (0.075 mm) with 29.1%, with an average Natural Moist Content (NMC) of 13.9%. The Maximum Dry Density (MDD) and Optimum Moisture Content (OMC) were 1.83 mg/m3 and 11.5%. The index analysis involved the liquid and plastic limits determination of Liquid Limit (LL) of 35.8%, Plastic Limit (PL) of 24.0%, and a Plasticity Index (PI) of 12%. California Bearing Ratio (CBR) results were 20.3% (soaked). The SG test results ranged from (2.68-2.94) kg/m3, employing the American Association of State Highway and Transport Officials (AASHTO) system of soil classification. The AASHTO grouped the materials into A-1, subgroups A-1-b and A-2-4 constituting 50% and 29.1%, with significant materials composed of stone fragments and sand rating the subgrade samples as excellent to good materials suitable for road construction.
PL
Jedną z masowych praktyk związanych z gruntami są projekty inżynieryjne, takie jak budowa dróg, budynków, zapór itp. Dlatego należy zbadać przydatność gruntu i jego właściwości mechaniczne. Niniejsze badanie ma na celu określenie niezbędnych właściwości materiału wysokiej jakości wymaganego do budowy dróg, co stwarza perspektywę usunięcia nieefektywnych wykopów generowanych na terenie. Materiały są klasyfikowane według wskaźników i właściwości mechanicznych. Sześć próbek gruntu pobrano z głębokości w zakresie 1,0-5,0 m i poddano badaniom. Próbki zostały poddane testom laboratoryjnym, takim jak analiza sitowa, granice Atterberga, zagęszczenie, kalifornijski wskaźnik nośności (CBR) i ciężar właściwy szkieletu gruntowego (GS). Analiza rozkładu wielkości cząstek wykazała, że grunt był drobnoziarnisty o uziarnieniu ≤35% dla sita nr 200 (0,075 mm) oraz 29,1%, przy średniej naturalnej wilgotności gruntu (W) wynoszącej 13,9%. Maksymalna gęstość szkieletu gruntowego (ρds) i optymalna zawartość wilgoci (Wopt) wyniosły odpowiednio 1,83 mg/m3 i 11,5%. Wyznaczono granice płynności i plastyczności: granica płynności (wL) wynosiła 35,8%, a granica plastyczności (wp) 24,0% oraz wskaźnik plastyczności (Ip) na poziomie 12%. Kalifornijski wskaźnik nośności (CBR) wyniósł 20,3% (po nasiąkliwości). Wyniki badań GS wahały się od 2,68 do 2,94 kg/m3, przy zastosowaniu systemu klasyfikacji gruntów AASHTO. Według AASHTO pogrupowano grunty na A-1, podgrupy A-1-b i A-2-4 stanowiące 50% i 29,1%, przy czym materiały składające się z odłamków kamieni i piasku oceniono jako doskonałe lub dobre materiały nadające się na budowy dróg.
Rocznik
Strony
44--54
Opis fizyczny
Bibliogr. 41 poz., rys., tab., wykr., wzory
Twórcy
  • Department of Geoscience, University of Uyo, Uyo, Nigeria
  • Department of Geoscience, University of Uyo, Uyo, Nigeria
  • Department of Physics, Michael Okpara University of Agriculture, Umudike, Nigeria
  • University of Uyo, Uyo, Nigeria
  • Department of Physics, University of Uyo, Uyo, Nigeria
Bibliografia
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  • [6] Aka M.U., Ibuot J.C. and Agbasi O.E., (2020b), Integration of Seismic Refraction Tomography (SRT) and Electrical Resistivity Tomography (ERT) to investigate the effects of landslide in Itu L. G. A., Akwa Ibom State, Southern Nigeria. Trends in Applied Science Research. 15: 266-274. Doi. 10.3923/tasr.2020.266.274.
  • [7] Akaolisa C.C.Z., Oparah J.C. and Agbasi O.E. (2021), Geotechnical Characteristics of Benin Formation, Owerri Imo State, Nigeria (2021), Brilliant Engineering 3(2):1-5. https://doi.org/10.36937/ben.2022.4569.
  • [8] Aroka K.R. (2009), Soil Mechanics and foundation Engineering. Nai Sarak, Delhi: Standard Publisher Distributor.
  • [9] ASTM D422 (2007), Standard Test Method for Particle-Size Analysis of Soils, ASTM International, Philadelphia, USA.
  • [10] ASTM D4318 (2010), Test Methods for Liquid Limit, Plastic Limit, and Plasticity Index of Soils, ASTM International, Philadelphia, USA.
  • [11] ASTM D698 (2012), Standard Test Methods for Laboratory Compaction of Soil Standard Effort, ASTM International, Philadelphia, USA.
  • [12] ASTM D5084-10 (2010), Standard Test Method for Measurement of Hydraulic Conductivity of Saturated Porous Material Using a Flexible Wall Permeameter, STM International, Philadelphia, USA.
  • [13] Avbovbo A.A. (1978), Tertiary Iithostratigraphy of Niger Delta, Ame. Ass. Pet. Geol. 62: 297-306.
  • [14] Brady N.C. and Weil R.R. (2010), Elements of the Nature and Properties of Soils, 3rd edition, page 95, Upper Saddle River, New Jersey, Prentice Hall.
  • [15] Charkley F.N., Zhang K., and Mei G. (2019), Shear strength of compacted clays as affected by mineral content and wet-dry cycles, Advances in Civil Engineering. (8): 1-8. https://doi.org/10.1155/2019/8217029.
  • [16] Coduto D.P. (2007), Geotechnical Engineering: Principles and Practices, New Delhi: Prentice Hall of India Private Limited.
  • [17] Didei I.S. and Oborie E. (2018), Classification and evaluation of soil compaction at shallow depth in Ogobiri and its environs, Bayelsa State, South-South Nigeria. International Journal of Agriculture and Earth Science. 4(1): 22-33.
  • [18] Environment Protection Agency (EPA) (2014), LFE4 - Earthworks in landfill engineering: Design, construction and quality assurance of earthworks in landfill engineering. United Kingdom Environment Agency, Bristol.
  • [19] Fidelis O.A., Samuel I.A., Opeyemi E.O., Temitope F.A., Kayode H.L., James R.A., Josiah O.B. and Abiose M.O., (2019), Bacteria removal efficiency data and properties of Nigerian clay used as a household ceramic water filter, Results in Engineering. https://doi.org/10.1016/j.rineng.2019.100011
  • [20] Godwin M.K., Gina O.I., Josiah N.S., Kingsley I.O., Iheoma C.N., Azikiwe P.O., (2020), Characterization of certain Nigerian clay minerals for water purification and other industrial applications, Heliyon 2020; 6: e03783. https://doi.org/10.1016/j.heliyon.2020.e03783.
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  • [22] Head K.H., (1994a), Manual for soil laboratory testing, soil classification and compaction tests, Halsted Press, New York.
  • [23] Head K.H., (1994b), Manual of soil laboratory testing, Permeability, shear strength and compressibility tests, 2nd edition. Pentech Press, London.
  • [24] Hunt R.E., (2007), Characteristics of geologic materials and formations: a Field Guild for Geotechnical Engineers, Boca Raton: CSC Press.
  • [25] Ihekweme G.O., Obianyo I.I., Orisekeh K.I., Kalu-Uka G.M., Nwuzor I.C. and Onwualu A.P., (2021), Plasticity characterization of certain Nigeria clay minerals for their application in ceramic water filters, Science Progress. doi:10.1177/00368504211012148.
  • [26] Lancellotta R., (2009), Geotechnical Engineering, New york: Taylor and Francis.
  • [27] Malomo S. (1977), The Nature and Engineering properties of some Red Soils, N.E. Brazil, Ph.D. Thesis Univ. of Leeds, Leeds.
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  • [29] Ogbuagu F.U. and Okeke C.A.U., (2019), Geotechnical properties of lateritic soil from Nimo and Nteje areas of Anambra State, Southeastern Nigeria. IOP Conference Series Materials Science and Engineering. 640(1): 012078. https://doi.org/10.1088/1757-899X/640/1/012078.
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  • [32] Ola S.A., (1978), Geotechnical properties and Behavior of some stabilized Nigerian Laterite Soil,T.J. Engr. Geo. London, 3; 144-160.
  • [33] Onakunle O., Omole D.O. and Ogbiye A.S., (2019), Stabilization of lateritic soil from Agbara Nigeria with ceramic waste dust. Cogent Engineering, 6(1): 1710087. https://doi.org/10.1080/23311916.2019.1710087.
  • [34] Opeyemi E.O., Bamidele O.A., Elijah A.A., Emeka S.N., Abayomi E.M., Olugbenga O.E., Temidayo O. and Grace A. (2018), Ameliorating effect of milled eggshell on cement stabilized lateritic soil for highway construction, Case Studies in Construction Materials, 9; e00191, https://doi.org/10.1016/j.cscm.2018.e00191.
  • [35] Osinubi K.J., Eberemu A.O., Gadzama E.W. and Ijimdiya T.S. (2019), Plasticity characteristics of lateritic soil treated with Sporosarcina pasteurii in microbial-induced calcite precipitation application, SN Appl Sci 2019; 1(8): 1-12. https://doi.org/10.1007/s42452-019-0868-7.
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  • [37] Robert U.W., Etuk S.E., Agbasi O.E. and Umoren G.P. (2020), Comparison of clay soils of different colors existing under the same conditions in a location, Imam Journal of Applied Science, 5: 68-73. https://www.e-ijas.org/text.asp?2020/5/2/68/291584.
  • [38] Rowe R.K., Quigley R.M., and Booker J.R. (1995), Clayey barrier systems for waste disposal facilities, E and FN Spon, London.
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Uwagi
Opracowanie rekordu ze środków MNiSW, umowa nr SONP/SP/546092/2022 w ramach programu "Społeczna odpowiedzialność nauki" - moduł: Popularyzacja nauki i promocja sportu (2024).
Typ dokumentu
Bibliografia
Identyfikator YADDA
bwmeta1.element.baztech-e19c6645-5c36-400c-9883-1bef8db05d59
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