Contenido principal del artículo

La ceniza de bagazo de caña de azúcar, es un residuo agroindustrial sólido resultante de la quema del bagazo en calderas para cogeneración de energía. El objetivo de estudio del presente artículo de revisión es evaluar sistemáticamente el uso de la ceniza de bagazo de caña de azúcar como componente puzolánico de una nueva aplicación de residuos sostenible para la estabilización de suelos con el propósito de disminuir el impacto ambiental negativo de la construcción. El método utilizado de estudio se basó en un análisis específico en la recopilación de los artículos pertenece al estrato de tiempo de 2017 al 2021; donde están distribuidos de la siguiente manera: 05 artículo de EBSCO, 48 de Scopus, 2 de SciELO y 25de ScienceDirect. En conclusión, de acuerdo al estudio crítico de los resultados encontrados sustentamos que el uso del método de estabilización del suelo mejora con éxito el suelo arcilloso.

Dr. Sócrates Muñoz, Universidad Señor de Sipan

Ingeniero Civil egresado de la Universidad Nacional Pedro Ruiz Gallo Lambayeque en el año 2006, con 11 años de experiencia en ejecución de obras civiles y producción de pre fabricados y pretensados y 8 años de colegiado, con grado de Magister en Ciencias de la Tierra con Mención en Geotecnia egresado de la Universidad Nacional de San Agustín Arequipa, con un Diplomado en Especialización Geología Aplicada en Minería por en la Cámara Minera del Perú. Mis valores primordiales son la lealtad, responsabilidad, compañerismo, la puntualidad y el deseo de superación. Ex Docente de pre grado en los cursos de Mecánica de Suelos, Mecánica de Fluidos, Geología en las Universidad Catolica San Pablo, Universidad Nestor Caceres Velasquez, Universidad Alas Peruanas, Ex Docente de Post Grado de la Universidad Nestor Caceres Velasquez del curso de Mecanica de Suelos y Rocas, Profesor de la Universidad Señor de Sipán

Sr. Mario Millones, Universidad Señor de Sipan

Estudiante de Ingeniería Civil

Sr. Cristian Villanueva, Universidad Señor de Sipan

Estudiante de Ingeniería Civil

1.
Muñoz Perez SP, Millones-Chapoñan M, Villanueva-Meza CD. La Ceniza de Bagazo de Caña de Azúcar Como Aditivo Estabilizador en Suelos Arcillosos con Fines de Pavimen-tación: Una Revisión Literaria. inycomp [Internet]. 30 de diciembre de 2022 [citado 27 de enero de 2023];25(1). Disponible en: https://revistaingenieria.univalle.edu.co/index.php/ingenieria_y_competitividad/article/view/11801

L. C. Dang, H. Khabbaz y B.-J. Ni, «Improving engineering characteristics of expansive soils using industry waste as a sustainable application for reuse of bagasse ash,» Transportation Geotechnics, vol. 31, p. 100637, 2021.

P. G. Quedou, E. Wirquin y C. Bokhoree, «Sustainable concrete: Potency of sugarcane bagasse ash as a cementitious material in the construction industry,» Case Studies in Construction Materials, vol. 14, p. e00545, 2021.

R. G. D. Molin Filho, L. M. S. Colpini, M. Ferrer, M. F. Nagano, J. M. Rosso, E. A. Volnistem, P. R. Paraíso y L. M. de Jorge, «Characterization of different sugarcane bagasse ashes generated for preparation and application as green products in civil construction,» Clean Technologies and Environmental Policy, vol. 21, pp. 1687-1698, 2019.

R. L. Figueiredo y S. Pavía, «A study of the parameters that determine the reactivity of sugarcane bagasse ashes (SCBA) for use as a binder in construction,» SN Applied Sciences, vol. 2, p. 1515, 2020.

E. C. Mansaneira, N. Schwantes-Cezario, G. F. Barreto-Sandoval y B. Martins-Toralles, «[Sugar cane bagasse ash as a pozzolanic material],» DYNA (Colombia), vol. 84, pp. 163 - 171, 2017.

S. Deepika, G. Anand, A. Bahurudeen y M. Santhanam, «Construction products with sugarcane bagasse ash binder,» Journal of Materials in Civil Engineering, vol. 29, p. 10, 2017.

A. Kumar Yadav, K. Gaurav, R. Kishor y S. K. Suman, «Stabilization of alluvial soil for subgrade using rice husk ash, sugarcane bagasse ash and cow dung ash for rural roads,» International Journal of Pavement Research and Technology, vol. 10, pp. 254 - 261, 2017.

j. Luo, Z. Lin, Y. Que, S. Li, K. Yao, Y. Jiang, H. Zhang y J. F. Chen, «[Effect of subsoiling depths on soil physical characters and sugarcane yield],» Chinese Journal of Applied Ecology, vol. 30, pp. 405 - 412, 2019.

P. Setayesh Gar, N. Suresh y V. S. Bindiganavile, «Sugar cane bagasse ash as a pozzolanic admixture in concrete for resistance to sustained elevated temperatures,» Construction and Building Materials, vol. 153, pp. 929 - 936, 2017.

M. Jafari y J. Jung, «Thermal properties of fly ashes and biomass ashes including wood bagasse ashes and sugarcane bagasse ashes,» Journal of Materials in Civil Engineering, vol. 29, p. 3, 2017.

J. He, S. Kawasaki y V. Achal, «The utilization of agricultural waste as agro-cement in concrete: A review,» Sustainability (Switzerland), vol. 12, p. 6971, 2020.

G. C. Cordeiro, T. R. Barroso y R. D. Toledo Filho, «Enhancement the Properties of Sugar Cane Bagasse Ash with High Carbon Content by a Controlled Re-calcination Process,» KSCE Journal of Civil Engineering, vol. 22, pp. 1250-1257, 2018.

C. K. Gupta, A. K. Sachan y R. Kumar, «Examination of Microstructure of Sugar Cane Bagasse Ash and Sugar Cane Bagasse Ash Blended Cement Mortar,» Sugar Tech, vol. 23, pp. 651 - 660, 2021.

A. L. Yadav, V. Sairam, L. Muruganandam y K. Srinivasan, «An overview of the influences of mechanical and chemical processing on sugarcane bagasse ash characterisation as a supplementary cementitious material,» Journal of Cleaner Production, vol. 245, p. 118854, 2020.

E. J. Ejelikwu, J. Manasseh y A. Abubakar, «Sugarcane bagasse ash stabilization of reclaimed asphalt pavement as highway material,» International Journal of Pavement Engineering, vol. 20, pp. 1385-1391, 2019.

R. Seyoum, B. B. Tesfamariam, D. M. Andoshe, A. Algahtani, G. M. S. Ahmed y V. Tirth, «Investigation on control burned of bagasse ash on the properties of bagasse ash-blended mortars,» Materials, vol. 14, p. 17, 2021.

S. S. Solanke y P. Y. Pawade, «An investigation of mechanical properties of concrete by addition of sugarcane baggase ash and steel fiber,» Journal of Physics: Conference Series, vol. 1913, p. 1, 2021.

G. P. Lyra, V. Dos Santos, B. C. de Santis, R. R. Rivaben, C. Fischer, E. M. D. J. A. Pallone y J. A. Rossignolo, «Reuse of sugarcane bagasse ash to produce a lightweight aggregate using microwave oven sintering,» Construction and Building Materials, vol. 222, pp. 222 - 228, 2019.

K. S. Sohal y R. P. Singh, «Sustainable Use of Sugarcane Bagasse Ash in Concrete Production,» Lecture Notes in Civil Engineering, vol. 113, pp. 397 - 407, 2021.

R. G. D. Molin Filho, L. M. S. Colpini, M. M. Ferrer, M. F. Nagano, J. M. Rosso, E. A. Volnistem, P. R. Paraíso y L. M. de Jorge, «Characterization of different sugarcane bagasse ashes generated for preparation and application as green products in civil construction,» Clean Technologies and Environmental Policy, vol. 21, pp. 1687 - 1698, 2019.

J. E. Edeh, I. Samson y A. Terhemba, «RICE-HUSK ASH-CARBIDE-WASTE STABILIZATION OF RECLAIMED ASPHALT PAVEMENT,» Nigerian Journal of Technology, vol. 35, nº 3, pp. 465-472, 2016.

A. A. Franca, J. Schultz, . R. Borges, F. Wypych y A. S. Mangrich, «Rice Husk Ash as Raw Material for the Synthesis of Silicon and Potassium Slow Release Fertilizer,» Printed in Brazil, vol. 28, nº 11, pp. 2211-2217, 2017.

D. E. Intari, W. Fathonah y B. Saputro, «Performance of asphalt concrete mixture (AC-WC) using asphalt added with the waste of rice husk ash,» Civil Engineering Department, University of Sultan Ageng Tirtayasa, vol. 673, pp. 1-6, 2019.

H. Abdurrahman, G. Wibisono, M. Qoryati, I. R. Sitompul y O. M, «Mechanical properties of crumb rubber-rice husk ash concrete as a rigid pavement material,» IOP Conf. Series: Materials Science and Engineering, vol. 615, pp. 1-8, 2019.

M. Adamu, O. A. Kingsley, H. S. Ibarahim, I. M. Husseini y S. Haruna, «Durability performance of pervious concrete containing rice husk ash and calcium carbide: A response surface methodology approach,» Case Studies in Construction Materials, vol. 14, pp. 547-556, 2021.

A. Al-Hdabi, «Laboratory investigation on the properties of asphalt concrete mixture with Rice Husk Ash as filler,» Construction & Building Materials., vol. 126, pp. 544-551, 2016.

A. Alireza , R. B. Rezvan , N. Navid , J. Farhang y M. Farzin Poorheydari , «Laboratory evaluation of the effect of coal waste ash (CWA) and rice husk ash (RHA) on performance of asphalt mastics and Stone matrix asphalt (SMA) mixture,» Construction and Building Materials, vol. 236, pp. 1-16, 2020.

M. Ameri, F. Gozali Asl, M. Modiri Gharehveran y A. Behnood, «Effects of copper slag and recycled concrete aggregate on the properties of CIR mixes with bitumen emulsion, rice husk ash, Portland cement and fly ash,» Construction and Building Materials, vol. 96, pp. 172-180, 2015.

Arabani, Mahyar ; Tahami , Seyed Amid ; Taghipoor, Mohammad, «Laboratory investigation of hot mix asphalt containing waste materials,» containing waste materials, pp. 2164-7402, 2016.

Arabani, Mahyar; AmidTahami, Seyed, «Assessment of mechanical properties of rice husk ash modified asphalt mixture,» Construction and Building Materials, vol. 149, pp. 350-358, 2017.

A. J. M. Araújo, A. R. O. Sousa, D. . A. Macedo, R. P. S. Dutra y L. . F. A. Campos, «Effects of granite waste addition on the technological properties of industrial silicate based-ceramics ,» Materials Research Express, pp. 12-22, 2019.

O. S. Seick , . M. Adamah , P. Elodie , E. Gilles y T. François , «Synthesis and characterization of geopolymer binders based on local materials from Burkina Faso – Metakaolin and rice husk ash,» Construction and Building Materials, vol. 124, pp. 301-311, 2016.

P. C. Arroyo Martimez, N. Sanchez Flores, M. Villafuerte Castrejón y R. Vivar Ocampo, «Synergistic Effect of 4A Zeolite from Rice Husk Ash without Aging Time and Silane on the Adhesion Properties of a Warm Mix Asphalt,» Sociedade Brasileira de Química, vol. 29, nº 1, pp. 58-66, 2018.

S. Caro, N. Vega, J. Husserl y A. E. Alvarez, «Studying the impact of biomodifiers produced from agroindustrial wastes on asphalt binders,» Construction and Building Materials, vol. 126, pp. 369-380, 2016.

F. W. Cavalcate y J. C. Moizinho, «The Influence of Unusual Materials as Prospective Fillers in the Hot Mix Asphalt,» Materials Science and Engineering, vol. 245, pp. 1-9, 2017.

Chaira y E. Mawardi, «Utilization of palm shells fly ash as filler on the mixture of Asphalt Concrete Wearing Course (AC–WC),» IOP Conference Series Earth and Environmental Science, vol. 325, pp. 1-8, 2019.

S. A. Tahami, M. Arabani y A. Foroutan Mirhosseini, «Usage of two biomass ashes as filler in hot mix asphalt,» Construction and Building Materials, vol. 170, pp. 547-556, 2018.

J. Choudhary, B. Kumar y A. Gupta, «Utilization of solid waste materials as alternative fillers in asphalt mixes: A review,» Construction and Building Materials, vol. 234, p. 117271, 2020.

H. Khabbaz y B.-J. Ni, «Improving engineering characteristics of expansive soils using industry waste as a sustainable application for reuse of bagasse ash,» Transportation Geotechnics, vol. 31, p. 100637, 2021.

A. Farred, Z. B. A. Ahmand S, I. Hafeez y A. A, «Use of agricultural waste ashes in asphalt binder and mixture: A sustainable solution to waste management,» Construction and Building Materials, p. 259, 2020.

W. C. Ferrão y J. C. Moizinho, «The Influence of Unusual Materials as Prospective Fillers in the Hot Mix Asphalt,» IOP Conference Series: Materials Science and Engineering, vol. 245, 2017.

S. A. Foroutan Mirhosseini, M. M. Khabiri y A. Kavussi, «Applying surface free energy method for evaluation of moisture damage in asphalt mixtures containing date seed ash,» Construction and Building Materials, vol. 125, pp. 408-416, 2016.

. L. Zhen, . A. Sha, W. Wang y J. Gao, «Studying the Properties of SBS/Rice Husk Ash-Modified Asphalt Binder and Mixture,» Advances in Materials Science and Engineering, pp. 1-11, 2020.

P. O. Awoyera, I. A. A. Mansouri y A. Viloria, «new formulation for strength characteristics of steel slag aggregate concrete using an artificial intelligence-based approach,» Computers and Concrete, vol. 24, pp. 333 - 341, 2021.

J. Cabrera, G. Escalante y P. Castro-Borges, «Compressive strength of concretes with blast furnace slag. Re-visited state-of-the-art,» ALCONPAT, vol. 6, pp. 64-83, 2021.

T. Cai, A. Issakhov, Á. G. Roco-Videla y A. S. Agdas, «The compressive strength of concrete retrofitted with wind ash and steel slag pozzolans with a water-cement based polymers,» Advances in Concrete Construction, vol. 11, pp. 507 - 519, 2021.

S. Chakravarthi y S. Shankar, «Utilization of recycled aggregates in cement-treated bases: a state-of-the-art review,» Soluciones de infraestructura innovadoras, vol. 6, p. 191, 2021.

K. Dilli Bai, A. Krishna Rao y V. M. Sounthararajan, «Strength characteristics of slag based steel fiber reinforced concrete with partial replacement of steel slag in coarse aggregate,» International Journal of Recent Technology and Engineering, vol. 8, pp. 3449 - 3452, 2019.

R. Y. Z. S. K. L. Y. F. S. W. K. L. J. T. Y. H. Dingqiang Fan, «A new development of eco-friendly Ultra-High performance concrete (UHPC): Towards efficient steel slag application and multi-objective optimization,» Construction and Building Materials, vol. 306, p. 124913, 2021.

H. El-Hassan, A. Hussein, J. Medljy y T. El-Maaddawy, «Performance of steel fiber-reinforced alkali-activated slag-fly ash blended concrete incorporating recycled concrete aggregates and dune sand,» Buildings, vol. 11, p. 327, 2021.

V. J. Ferreira, A. Sáez-De-Guinoa Vilaplana, T. García-Armingol, A. Aranda-Usón, C. Lausín-Gónzalez, A. M. López-Sabirón y G. Ferreira, «Evaluation of the steel slag incorporation as coarse aggregate for road construction: Technical requirements and environmental impact assessment,» Journal of Cleaner Production, vol. 130, pp. 175 - 186, 2016.

J. Guo, Y. Bao y M. Wang, «Steel slag in China: Treatment, recycling, and management,» Waste Management, vol. 78, pp. 318-330, 2018.

Hanif, «Use of Steel Slag with Variations of Fas Compressive Strength of Concrete,» Materials Science and Engineering, vol. 536, p. 012029, 2018.

L. He, C. Zhan, S. Lyu, J. R. Grenfell, J. Gao, K. J. Kowalski, J. Valentin, J. Xie, L. Ržek y T. Ling, «Application status of steel slag asphalt mixture,» Jiaotong Yunshu Gongcheng Xuebao/Journal of Traffic and Transportation Engineering, vol. 20, pp. 15 - 33, 2020.

F. Jinmiao, Z.-y. Han, Q. Ge, Z. Bian y W. Li, «Comparative study on properties of recycled concrete mixed with slag and polypropylene fiber/steel fiber,» Journal of Physics: Conference Series, vol. 1904, p. 012018, 2021.

X. P. S. C. S. W. L. Z. G. J. Keke Sun, «Utilization of BOF steel slag aggregate in metakaolin-based geopolymer,» Construction and Building Materials, vol. 300, p. 124024, 2021.

Z. J. B. J. X. Q. Lai M.H., «Improving mechanical behavior and microstructure of concrete by using BOF steel slag aggregate,» Construction and Building Materials, vol. 277, p. 122269, 2021.

Y. C. Lim, Y. J. Shih, W. Yang, C. Chen y C. Dong, «Recycling dredged harbor sediment to construction materials by sintering with steel slag and waste glass: Characteristics, alkali-silica reactivity and metals stability,» Journal of Environmental Management, vol. 270, p. 110869, 2020.

J. Liu, Z. Wang, H. Guo y F. Yan, «Thermal transfer characteristics of asphalt mixtures containing hot poured steel slag through microwave heating,» Journal of Cleaner Production, vol. 308, p. 127225, 2021.

D. Luo, Y. Wang, S. Zhang, D. Niu y Z. Song, «Frost resistance of coal gangue aggregate concrete modified by steel fiber and slag powder,» Applied Sciences (Switzerland), vol. 9, p. 3229, 2020.

P. Martauz, V. Václavík y B. Cvopa, «The properties of concrete based on steel slag as a by-product of metallurgical production,» Key Engineering Materials, vol. 838, pp. 10-20, 2020.

G. Zhao, «Structural and morphological characterization of steel slag powder and its effect on crack resistance of asphalt concrete,» Journal of Wuhan University of Technology, vol. 42, pp. 1055-1058, 2018.

T. Zhang, B. Ma, Q. J. D. Jiang y Z. Jin, «Comparative research on the effect of various mineral admixtures on the early hydration process of cement,» Construction and Building Materials, vol. 301, p. 124372, 2021.

B. Zhang, S. Cui, Z. L. Liu y Z. L. Liu, «Field tests of cement fly-ash steel-slag pile composite foundation,» Journal of Testing and Evaluation, vol. 45, pp. 860 - 872, 2016.

paquito, patata, Calahorra: Sembraos, 2010.

A. Franca, J. Schultz, R. Borges, F. Wypych y A. Manhrich, «Ceniza de cáscara de arroz como materia prima para sintesis de fertilizantes de liberacionn lenta de silicio y potasio,» Revista de la sociedad quimica Brasileña, vol. 28, pp. 2211-2217, 2017.

M. A. Getahun, S. M. Shitote y C. A. Gariy Z, «Experimental investigation on engineering properties of concrete incorporating reclaimed asphalt pavement and rice husk ash,» Buildings, vol. 8, pp. 1-24, 2018.

Z. Han, A. Sha, Z. Tong, . Z. Liu, J. Gao , X. Zou y D. Yuan, «Study on the optimum rice husk ash content added in asphalt binder and its modification with bio-oil,» Construction and Building Materials, vol. 147, pp. 776-789, 2017.

H. J. Hassan y H. Z. Hussein, «Properties of modified asphalt mixtures with additives of fillers materials.,» IOP Conference Series: Materials Science and Engineering, vol. 737, p. 1.13, 2020.

V. Jittin, A. Bahurudeen y S. D. Ajimkya, «Utilisation of rice husk ash for cleaner production of different construction products,» Journal of Cleaner Production, vol. 263, pp. 1-27, 2020.

A. Meng, C. Xing, . Y. Tan, S. Xiao a, J. Li y G. Li, «Investigation on clogging characteristics of permeable asphalt mixtures,» Construction and Building Materials, vol. 264, pp. 1-13, 2020.

G. Ming, L. Shang y C. L. Fang, «Effect of coal ash and rice husk ash partial replacement in ordinary Portland cement on pervious concrete,» Materiales de construcción y edificación, vol. 286, 2021.

R. Mistry, S. Karmakar y R. T. Kumar, «Experimental evaluation of rice husk ash and fly ash as alternative fillers in hot-mix asphalt,» Buildings, pp. 1-12, 2019.

A. Modarres y Z. Hosseini, «Mechanical properties of roller compacted concrete containing rice husk ash with original and recycled asphalt pavement material,» Materials & Design, vol. 64, pp. 227-236, 2014.

T. M. Rengarasu, . J. Mohamed, J. Nishanthini y W. M. Bandara, «Suitability of coal bottom ash and carbonized rice husk in hot mix asphalt,» Asian Transport Studies, pp. 1-6, 2020.

Pires, Specht, Pinheiro, Pereira y Renz, «Comportamento mecânico de material fresado após processo de estabilização granulométrica e química por meio da incorporação de cimento e cinza de casca de arroz moíd,» Materia, vol. 21, nº 2, pp. 365-384, 2016.

R. Pradoto, E. Puri, T. Hadinata y Q. D. Rahman, «Improving strength of porous asphalt: a nano material experimental approach,» IOP Conf. Series: Materials Science and Engineering, vol. 849, pp. 1-9, 2020.

R. Putra Jaya, M. K. Mohd Satar, N. A. Abdullah, M. R. Hainin, N. Abdul Hassan, H. Yaacob, M. N. Mohd Warid, A. Mohamed y N. I. Ramli, «Effect of Black Rice Husk Ash on Asphaltic Concrete Properties under Aging Condition,» International Conference on Concrete Engineering and Technology, vol. 431, pp. 1-6, 2018.

R. Putra Jaya, M. . K. Mohd Satar y N. A. Mohamed Abdullah, «Effect of Black Rice Husk Ash on Asphaltic Concrete Properties under Aging Condition,» IOP Conference Series Materials Science and Engineering, vol. 431, nº 3, pp. 1-13, 2018.

. M. Raja y R. Tapas Kumar , «Performance evaluation of bituminous mix and mastic containing rice husk ash and fly ash as filler,» Construction and Building Materials, pp. 1-14, 2020.

P. J. Ramadhansyah, Y. Haryati, A. H. Norhidayah, H. Mohd Rosli, M. V. Muhammad Naqiuddin, M. Azman, A. H. Abdul Rahim y S. Ekarizan, «Creep and resilient modulus properties of asphaltic concrete containing black rice husk ash,» Earth and Environmental Science, vol. 220, pp. 1-7, 2019.