1. INTRODUCTION
⌅The
global production of crop residues has been increasing progressively in
recent decades. Production is estimated at 280 Mt/year for cereal crops
and 3758 Mt/year for 27 food crops (11. Lal, R. 2005. World crop residues production and implications of its use as a biofuel. Environ. Int. 31(4):575-584. https://doi.org/10.1016/j.envint.2004.09.005.
).
Waste that is produced after harvesting and processing of crops include
stalks (corn), straw (rice, wheat, sugar cane), leaves, husks (rice,
wheat) and seed shells (palm), among others. This puts great pressure on
agricultural ecosystems (22.
Velasco-Muñoz JF, Aznar-Sánchez JA, López-Felices B, Román-Sánchez IM.
2022. Circular economy in agriculture. An analysis of the state of
research based on the life cycle. Sustain. Prod. Consum. 34:257-270. https://doi.org/10.1016/j.spc.2022.09.017.
). Agricultural waste disposal is an increasing environmental problem and concern in most countries (33.
Rithuparna R, Jittin V, Bahurudeen A. 2021. Influence of different
processing methods on the recycling potential of agro-waste ashes for
sustainable cement production: A review. J. Clean. Prod. 316:128242. https://doi.org/10.1016/j.jclepro.2021.128242.
).
One factor that influences this is global rice production, which has increased by 2.9 million tons since 2017 (44. Sekhar CSC. Climate change and rice economy in Asia: Implications for trade policy. Rome: FAO. 2018. (Vol. 2018).
).
Currently, the world annual rice production is estimated at 700 million
tons. RH represents approximately 20% of the rice mass (33.
Rithuparna R, Jittin V, Bahurudeen A. 2021. Influence of different
processing methods on the recycling potential of agro-waste ashes for
sustainable cement production: A review. J. Clean. Prod. 316:128242. https://doi.org/10.1016/j.jclepro.2021.128242.
, 66.
Das S, Patel A. 2018. Potential of rice husk ash in concrete
production: A literature review. Research Gate (internet). Retrieved
from: https://www.researchgate.net/publication/324079453_Potential_of_rice_husk_ash_in_concrete_production_A_literature_review
). Therefore, the annual amount of waste generated in the form of RH is around 150 million tons (55. Singh B. 2018. Rice husk ash. In Waste and supplementary cementitious materials in concrete. Woodhead Publishing. https://doi.org/10.1016/B978-0-08-102156-9.00013.
).
In Colombia, there are a total of 293,179 planted hectares of rice (88.
DANE. 2013. Encuesta nacional de arroz mecanizado, ENAM, Colombia.
Retrieved from
https://www.dane.gov.co/files/investigaciones/boletines/arroz/boletin_ENAM_Isem22.pdf.
). Of these, 155,519 hectares are in the Eastern Plains, which produce 177,641 tons of rice annually (88.
DANE. 2013. Encuesta nacional de arroz mecanizado, ENAM, Colombia.
Retrieved from
https://www.dane.gov.co/files/investigaciones/boletines/arroz/boletin_ENAM_Isem22.pdf.
). This represents 20.84% of national production (99.
Aguirre Osorio L. 2019. Economic technical analysis for the use of rice
husk in the generation of electrical energy from the gasification
process. Case study: Pacande rice mill in the city of
Villavicencio–Meta. Master’s thesis. Colombia: Universidad Libre.
). A total of 55,298 hectares are in the Tolima department, with a production of 406,737 tons of rice annually (88.
DANE. 2013. Encuesta nacional de arroz mecanizado, ENAM, Colombia.
Retrieved from
https://www.dane.gov.co/files/investigaciones/boletines/arroz/boletin_ENAM_Isem22.pdf.
). This represents 18% of national production. According to DANE (88.
DANE. 2013. Encuesta nacional de arroz mecanizado, ENAM, Colombia.
Retrieved from
https://www.dane.gov.co/files/investigaciones/boletines/arroz/boletin_ENAM_Isem22.pdf.
), rice is the third most important product in Colombian agriculture.
One
of the difficulties in the cultivation of rice is the disposal and
final usage that is given to the biomass of RH this biomass. This
represents just over 58,635 tons per year in Colombia. However, it is
considered waste once the rice production process ends (99.
Aguirre Osorio L. 2019. Economic technical analysis for the use of rice
husk in the generation of electrical energy from the gasification
process. Case study: Pacande rice mill in the city of
Villavicencio–Meta. Master’s thesis. Colombia: Universidad Libre.
).
Currently, most of the RH that is obtained is eliminated through
open-air combustion. On other occasions it is disposed of in rivers. It
is also used as bedding for animals in trucks for livestock
transportation and a small part is used as fertilizer (1010. Boletín Técnico. 2020. Encuesta nacional de arroz mecanizado, ENAM (internet). Colombia. DANE, Fedearroz. Retrieved from: https://www.dane.gov.co/files/investigaciones/boletines/arroz/bol_arroz_IIsem20.pdf
). These uses have a negative environmental impact and do not comply with current environmental regulations.
In addition to the food industry, the construction industry has a great environmental impact due to the generation of waste and the consumption of raw materials. In cement production, environmental impacts and CO2 emissions are generated during the stages of extraction of raw materials, production, commercialization, use, end of useful life, recycling and final disposal.
The cement production stage is a
complex process that includes the use of a large amount of raw materials
and fuels (petroleum coke, coal, natural gas, fossil fuels, biomass or
some waste) and energy (electricity and heat) in addition to
auxiliaries, air and water (1212.
Valderrama C, Granados R, Cortina JL, Gasol CM, Guillem M, Josa A.
2013. Comparative LCA of sewage sludge valorisation as both fuel and raw
material substitute in clinker production. J. Clean. Prod. 51:205-213. https://doi.org/10.1016/j.jclepro.2013.01.026.
, 1313.
Galvez-Martos JL, Schoenberger, H. 2014. An analysis of the use of life
cycle assessment for waste co-incineration in cement kilns. Resources.
Conserv. Recycl. 86:118-131. https://doi.org/10.1016/j.resconrec.2014.02.009.
). As a result of the use and processing of this raw material, cement production has a significant environmental impact (1414.
Georgiopoulou M, Lyberatos G. 2018. Life cycle assessment of the use of
alternative fuels in cement kilns: A case study. J. Environ. Manage.
216:224-234. https://doi.org/10.1016/j.jenvman.2017.07.017.
).
Although cement production causes the formation of wastewater, solid
waste and noise, the main environmental problems are associated with
energy consumption and air emissions (1515.
Schorcht F, Kourti I, Scalet BM. 2013. Best available techniques (BAT)
reference document for the production of cement, lime and magnesium
oxide. Luxembourg: Prospective Technological Studies.
).
Approximately between 5% and 7% of total global anthropogenic CO2
emissions and 3% of total greenhouse gas emissions are derived from
cement production (1313.
Galvez-Martos JL, Schoenberger, H. 2014. An analysis of the use of life
cycle assessment for waste co-incineration in cement kilns. Resources.
Conserv. Recycl. 86:118-131. https://doi.org/10.1016/j.resconrec.2014.02.009.
). In addition, cement production represents approximately 12% to 15% of total industrial energy use worldwide (1717.
Aranda-Usón A, Ferreira G, Mainar-Toledo MD, Scarpellini S, Sastresa
EL. 2012. Energy consumption analysis of Spanish food and drink,
textile, chemical and non-metallic mineral products sectors. Energy.
42(1):477-485. https://doi.org/10.1016/j.energy.2012.03.021.
). In total, for one ton of cement clinker, 0.87 tons of CO2 are released into the atmosphere (1818.
Shwekat K, Wu HC. 2018. Benefit-cost analysis model of using class F
fly ash-based green cement in masonry units. J. Clean. Prod.
198:443-451. https://doi.org/10.1016/j.jclepro.2018.06.229.
).However,
this value can vary depending on location, technology, production
efficiency, the mix of energy sources used to generate electricity, and
the selection of furnace fuels. For this reason, international
organizations such as the Intergovernmental Panel on Climate Change
(IPCC) or the International Energy Agency (IEA) have considered it
crucial that cement manufacturers implement effective CO2 emission mitigation scenarios during the cement manufacturing stage (1616.
Rhaouti Y, Taha Y, Benzaazoua M. 2022. Assessment of the environmental
performance of blended cements from a life cycle perspective: a
systematic review. Sustain. Prod. Consum. 36:32-48. https://doi.org/10.1016/j.spc.2022.12.010.
).
To reduce the impacts of the agricultural industry and the construction industry, work has been done to mitigate impacts in the cement production stage by developing different mixtures with industrial waste. Industrial and agricultural by-products such as fly ash and RH are considered supplementary or replacement cementitious materials in the production of concrete, as a cement replacement fraction.
A large
number of studies have indicated that RH can be used in the construction
industry, due to its high silica content. RH is composed of 50%
cellulose, 25-30% lignin, 15-20% silica, and 10-15% moisture. Its bulk
density is small, in the range of 90-150 kg/m3 (55. Singh B. 2018. Rice husk ash. In Waste and supplementary cementitious materials in concrete. Woodhead Publishing. https://doi.org/10.1016/B978-0-08-102156-9.00013.
). With adequate processing before use, it can be used as a component for cement manufacturing (33.
Rithuparna R, Jittin V, Bahurudeen A. 2021. Influence of different
processing methods on the recycling potential of agro-waste ashes for
sustainable cement production: A review. J. Clean. Prod. 316:128242. https://doi.org/10.1016/j.jclepro.2021.128242.
, 1919.
Chindaprasirt P, Rukzon S. 2008. Strength, porosity and corrosion
resistance of ternary blend Portland cement, rice husk ash and fly ash
mortar. Constr. Build. Mater. ISSN 0950-0618, 22(8):1601-1606. https://doi.org/10.1016/j.conbuildmat.2007.06.010.
).
In some studies, rice husk ash (RHA) has been used as a pozzolanic
material in the manufacture of cement in different percentages. Mineral
additions to cement in the form of pozzolanic material have been used to
improve the mechanical resistance and durability of mortars, associated
with cost savings and the reduction of environmental impacts (2020.
Silva FG, Liborio JB, Helene, P. 2008. Improvement of physical and
chemical properties of concrete with brazilian silica rice husk (SRH).
Rev. Ing. Contrucc. 23(1):18-25. http://doi.org/10.4067/S0718-50732008000100002.
).
Some researchers observed that the highest compressive strength
occurred between the levels of 10 and 15% RHA replacement in concrete
for all cure durations (20-2720.
Silva FG, Liborio JB, Helene, P. 2008. Improvement of physical and
chemical properties of concrete with brazilian silica rice husk (SRH).
Rev. Ing. Contrucc. 23(1):18-25. http://doi.org/10.4067/S0718-50732008000100002.
21.
Anwar M, Miyagawa T, Gaweesh M. 2000. Using rice husk ash as a cement
replacement material in concrete. Waste Manage. 1:671-684. https://doi.org/10.1016/S0713-2743(00)80077-X.
22.
Bui DD, Hu J, Stroeven P. 2005. Particle size effect on the strength of
rice husk ash blended gap-graded Portland cement concrete. Cem. Concr.
Compos. 27(3):357-366. https://doi.org/10.1016/j.cemconcomp.2004.05.002.
23.
Ferraro RM, Nanni A. 2012. Effect of off-white rice husk ash on
strength, porosity, conductivity and corrosion resistance of white
concrete. Constr. Build. Mater. 31:220-225. https://doi.org/10.1016/j.conbuildmat.2011.12.010.
24.
Muthadhi A, Kothandaraman S. 2013. Experimental Investigations of
Performance Characteristics of Rice Husk Ash–Blended Concrete. J. Mater.
Civ. Eng. 25(8):1115-1118. https://doi.org/10.1061/(ASCE)MT.1943-5533.0000656.
25.
Givi AN, Rashid SA, Aziz FN, Salleh MA. 2010. Assessment of the effects
of rice husk ash particle size on strength, water permeability and
workability of binary blended concrete. Constr. Build. Mater. 4:100147. https://doi.org/10.1016/j.clet.2021.100147.
26.
Saraswathy V, Ha-WonSong. 2007. Corrosion performance of rice husk ash
blended concrete. Constr. Build. Mater. 21(8):1779-1784. https://doi.org/10.1016/j.conbuildmat.2006.05.037.
37.
Phonphuak N, Chindaprasirt P. 2015. Types of waste, properties, and
durability of pore-forming waste-based fired masonry bricks. Eco-Effic.
Mason. Bricks Blocks. Design. Proper. Durab. 2015:103-127. https://doi.org/10.1016/B978-1-78242-305-8.00006-1.
). Chao-Lung (2828.
Chao-Lung H, Anh-Tuan BL, Chun-Tsun C. 2011. Effect of rice husk ash on
the strength and durability characteristics of concrete. Constr. Build.
Mater. 25(9):3768-3772. https://doi.org/10.1016/j.conbuildmat.2011.04.009.
)
found that the best cement replacement was up to 20% RHA. In their
study, they obtained 28-day compressive strength in the range of 47-66
MPa.
The RHA percentage replacement level for the highest tensile
strength (28 days) was observed between 10% and 20%. Compressive and
tensile strength were found to decrease beyond the addition of the
optimal replacement level of RHA due to caking of excess RHA and the
dilution effect. Tambichik (2929.
Tambichik MA, Mohamad N, Samad AA, Bosro MZ, Iman MA. 2018. Utilization
of construction and agricultural waste in Malaysia for development of
Green Concrete: A Review. IOP Conference Series: Earth and Environmental
Science. 140:012134. https://doi.org/10.1088/1755-1315/140/1/012134.
) also compared some articles on RHA. Ukpata (3030.
Ukpata JO, Ephraim ME, Akeke GA. 2012. Compressive strength of concrete
using lateritic sand and quarry dust as fine aggregate. ARPN J. Eng.
Appl. Sci. 7(1):81-92. https://www.semanticscholar.org/paper/COMPRESSIVE-STRENGTH-OF-CONCRETE-USING-LATERITIC-AS-UkpataEphraim/34ed801acaff65f812c9ea037a265569e8e6c0b5#citing-papers.
)
found that an addition of 5 to 10% RHA increased strength. A further
addition of up to 15% to 25% RHA led to a slight 15% reduction in
strength. A decrease in strength values was observed when the levels of
RHA increased. It was observed that the water resistance of concrete
with RHA as a supplementary cementing material (partial replacement of
cement) was outstanding (3131.
Hesami S, Ahmadi S, Nematzadeh M. 2014. Effects of rice husk ash and
fiber on mechanical properties of pervious concrete pavement. Constr.
Build. Mater. 53:680-691. https://doi.org/10.1016/j.conbuildmat.2013.11.070.
).
The penetration of chloride ions, which is the most important
characteristic for durability and the prevention of corrosion, was also
excellent (3232.
Aprianti E, Shafigh P, Bahri S, Farahani JN. 2014. Supplementary
cementitious materials origin from agricultural wastes – A review.
Constr. Build. Mater. 74:176-187. https://doi.org/10.1016/j.conbuildmat.2014.10.010.
).
Alternate
uses of RHA have been identified. For example, it can be used as fine
aggregate in mortar-type adhesives for ceramic tile placement (3333.
Novoa Galeano MA, Becerra León LD, Vásquez Piñeros MP. 2016. Rice husk
ash and its effect on adhesive mortars. Avances Investigación en
Ingeniería (internet). Dec 1. 11(2). Retrieved from: https://revistas.unilibre.edu.co/index.php/avances/article/view/233.
), with and without pretreatments, as an addition in the manufacture of light mortars (3434.
Serrano T, Borrachero M, Monzó JM. 2012. Con cascarilla de arroz:
diseño de mezclas y evaluación de propiedades. Dyna (internet).
Retrieved from: http://www.scielo.org.co/scielo.php?script=sci_arttext&pid=S0012-73532012000500015.
), and to improve the mechanical properties of durability and cement compression from the mixture with RH (3535.
Aguilar Sierra J. 2009. Alternatives for the use of rice husks in
Colombia (degree’s thesis). Colombia: Engineering faculty, Universidad
de Sucre.
). Other research shows that RH can be used
as an additive in the production of refractory bricks, fire retardants
and wood particles, among others (36-3836. Jeetah P, Golaup N, Buddynauth K. 2015. Production of cardboard from waste rice husk. J. Environ. Chem. Eng. 3(1):52-59. https://doi.org/10.1016/j.jece.2014.11.013.
37.
Phonphuak N, Chindaprasirt P. 2015. Types of waste, properties, and
durability of pore-forming waste-based fired masonry bricks. Eco-Effic.
Mason. Bricks Blocks. Design. Proper. Durab. 2015:103-127. https://doi.org/10.1016/B978-1-78242-305-8.00006-1.
38.
Kazmi SM, Abbas S, Munir MJ, Khitab A. 2016. Exploratory study on the
effect of waste rice husk and sugarcane bagasse ashes in burnt clay
bricks. J. Build. Eng. 7:372-378. https://doi.org/10.1016/j.jobe.2016.08.001.
). Previous studies have been carried out that demonstrate the viability of using RHA and fly ash. Gursel (3939.
Gursel AP, Masanet E, Horvath A, Stadel A. 2014. Life-cycle inventory
analysis of concrete production: A critical review. Cem. Concr. Compos.
7:372-378. https://doi.org/10.1016/j.cemconcomp.2014.03.005.
) developed a critical review on concrete production life cycle inventory analysis. Gursel (4040.
Gursel AP, Maryman H, Ostertag C. 2016. A life-cycle approach to
environmental, mechanical, and durability properties of “green” concrete
mixes with rice husk ash. J. Clean. Prod. 11(1):823-836. https://doi.org/10.1016/j.jclepro.2015.06.029.
)
analyzed the performance of the RHA ternary and quaternary concrete mix
in terms of its durability, mechanical properties and its GW potential.
Tong (4141.
Tong KT, Vinai R, Soutsos MN. 2018. Use of Vietnamese rice husk ash for
the production of sodium silicate as the activator for alkali-activated
binders. J. Clean. Prod. 201:272-286. https://doi.org/10.1016/j.jclepro.2018.08.025.
)
analyzed the use of RHA in Vietnam by developing a low cost, low
environmental impact sodium silicate solution from RHA. Sarah (4242.
Fernando S, Gunasekara C, Law DW, Nasvi MCM, Setunge S, Dissanayake R.
2021. Life cycle assessment and cost analysis of fly ash–rice husk ash
blended alkali-activated concrete. J. Environ. Manage. 295:113140. https://doi.org/10.1016/j.jenvman.2021.113140.
)
developed a Life cycle analysis and a Life Cycle Cost of the activated
concrete with alkali mixed with fly ash and RHA, in which environmental
and economic factors were quantified by evaluating the emission of
greenhouse gases (GHG), the impacts and environmental benefits and cost
analysis of using fly ash and RHA in alkali-activated concrete compared
to Portland cement concrete.Other studies have focused on the analysis
and reduction of environmental impacts of Portland cement using
industrial waste such as fly ash and kiln residues (43-4543.
O’Brien KR, Ménaché J, O’Moore LM. 2009. Impact of fly ash content and
fly ash transportation distance on embodied greenhouse gas emissions and
WC in concrete. Int. J. Life Cycle Assess. 14:621–629. https://doi.org/10.1007/s11367-009-0105-5.
44.
Passuello A, Rodríguez ED, Hirt E, Longhi M, Bernal SA, Provis JL,
Kirchheim AP. 2017. Evaluation of the potential improvement in the
environmental footprint of geopolymers using waste-derived activators.
J. Clean. Prod. 166:680-689. https://doi.org/10.1016/j.jclepro.2017.08.007.
45.
Sandanayake M, Gunasekara C, Law D, Zhang G, Setunge S. 2018.
Greenhouse gas emissions of different fly ash based geopolymer concretes
in building construction. J. Clean. Prod. 204:399-408. https://doi.org/10.1016/j.jclepro.2018.08.311.
). Some studies have focused on the environmental effect of fly ash in concrete (4646.
Celik K, Meral C, Gursel AP, Mehta PK, Horvath A, Monteiro PJ. 2015.
Mechanical properties, durability, and life-cycle assessment of
self-consolidating concrete mixtures made with blended portland cements
containing fly ash and limestone powder. Cem. Concr. Compos. 56:59-72. https://doi.org/10.1016/j.cemconcomp.2014.11.003.
) and on the granulated residues of the kilns in the concrete (4747.
Jamshidi A, Kurumisawa K, Nawa T, Hamzah MO. 2015. Analysis of
structural performance and sustainability of airport concrete pavements
incorporating blast furnace slag. J. Clean. Prod. 90:195-210. https://doi.org/10.1016/j.jclepro.2014.11.046.
).
Research has also been conducted that focuses on the use of RH as fuel, through the gasification process (4848.
Higman C, Tam S. 2014. Advances in coal gasification, hydrogenation,
and gas treating for the production of chemicals and fuels. Chem. Rev.
114(3).1673–1708. https://doi.org/10.1021/cr400202m.
).
Experiments have been undertaken on the combustion of rice husk and
obtaining the energetic properties of this biomass and its capacity for
energy generation (4949.
Martínez Ángel JD, Pineda Vásquez TG, López Zapata JP. 2010. Combustion
experiments with rice husks in a fluidized bed for the production of
silica-rich ash. Faculty of Engineering Magazine University of Antioquia
(Internet). Retrieved from. https://www.redalyc.org/articulo.oa?id=43016341011.
).
The gasification of biomass to obtain biogas and subsequently
electricity is a thermochemical process in which a carbonaceous
substrate (organic waste) is transformed into a combustible gas. This is
carried out through a series of reactions that occur at a certain
temperature, always in the presence of a gasifying agent (air, oxygen
and/or water vapor). In this process, gases such as carbon monoxide,
carbon dioxide, hydrogen, methane and small chain hydrocarbons are
produced. The potential use of the gas obtained from the process as fuel
in power generation equipment makes it interesting for the formulation
of sustainable alternatives since it allows diversification of the
energy matrix (99.
Aguirre Osorio L. 2019. Economic technical analysis for the use of rice
husk in the generation of electrical energy from the gasification
process. Case study: Pacande rice mill in the city of
Villavicencio–Meta. Master’s thesis. Colombia: Universidad Libre.
).
Although
the physical, chemical and mechanical properties of rice husk ash in
cement and concrete have been evaluated, studies on the environmental
and economic impact of their use in the manufacture of these new
materials for the production of concrete ecology should be studied in
greater depth. Consequently, the goal of this study was to evaluate the
environmental impacts of the use of rice husk ash as a replacement for
cement in the production of concrete. This evaluation was carried out
using the life cycle analysis methodology. Life cycle assessment (LCA)
is a robust tool that allows the quantification of potential
environmental effects in terms of impact categories (4848.
Higman C, Tam S. 2014. Advances in coal gasification, hydrogenation,
and gas treating for the production of chemicals and fuels. Chem. Rev.
114(3).1673–1708. https://doi.org/10.1021/cr400202m.
).
The analysis and quantification of the environmental impacts of cement
production require an analytical and holistic approach. Life cycle
analysis (LCA) methodology (5151.
European Standard EN ISO 14044. 2006. Environmental management—life
cycle assessment—requirements and guidelines. International Organization
for Standardization.
) allows the measurement and
evaluation of impacts associated with the processes in each stage of the
life cycle. For this study, the city of Ibagué-Tolima is chosen as the
study area, since it stands out for the high production of rice in
Colombia. These results are expected to generate considerable knowledge
transfer between academia, industry, government and companies, and at
the same time contribute to generating significant changes in the
cities.
2. LIFE CYCLE ASSESSMENT (LCA) METHODOLOGY
⌅2.1. Goal and scope definition
⌅In this study, the extraction of RHA was evaluated as a partial replacement for Portland cement in cementitious mixes. Then, the use of cement with RHA was assessed in concrete production.
The department of Tolima-Ibagué (Colombia) was selected as the study area (Figure 1) to evaluate the environmental impacts of RHA extraction and the subsequent partial replacement of Portland cement in cementitious mixes and in concrete.
2.2. Functional unit
⌅1 m3 of concrete was chosen as the functional unit. For cement and RHA, 1 kg of material was chosen.
2.3. System boundary and life cycle inventory
⌅Primary data were obtained from interviews with companies and organizations in Colombia (rice mill, concrete, cement and aggregate plants in the department of Tolima). These data were supplemented with the Ecoinvent V3 database and adapted to the Colombian context. The location data and transport distances, which could not be obtained during the visits that were carried out, were supplemented using Google Earth Pro.
2.3.1. Transport scenarios
⌅In the study area, there is only one cement production plant. As the existing concrete plants are located at a close distance in the city of Ibague, for this study an equidistant point was taken as the location of the concrete plant. The means of transport for the raw materials to the cement plant and the aggregates to the concrete plant was a truck of type 10-20 t EURO 5. The various transport distances are listed in Table 1.
| Transport details for | Distance (km) |
|---|---|
| Raw materials for the cement plant | 5 km |
| RHA to the cement plant | 14 km |
| Aggregates to the concrete plant | 36.2 km |
| Cement to the concrete plant | 21.8 km |
2.3.2. Cement Portland
⌅The clinker process modeled for Colombia from the Ecoinvent 3 database was used as a basis. In this process, clinker is produced by sintering a mixture that consists mainly of limestone and clay at temperatures between 1400°C and 1500ºC. This clinker process was considered for the production of Portland cement, according to the Colombian technical standard NTC 121.
2.3.3. Rice husk ash
⌅This procedure considers the production of 1 kg of RHA in the cogeneration of electricity and heat from RH as biomass. That is, rice husk ash (RHA) is obtained from gasification for electricity generation. Ash recovery starts from the gasification process when the rice husk enters the gasifier for the cogeneration process in which electricity and heat are generated, as shown in Figure 2 and Table 2. Disposal of rice husks is avoided and electricity is generated.
| Input/output | Unit | Value | Source |
|---|---|---|---|
| Avoided products | |||
| Electricity | kWh | 1.76 | Company consulted, 2021 |
| Final disposal of the husk | kg | 3.33 | Company consulted, 2021 |
| Heat | MJ | 9.06 | Company consulted, 2021- Ecoinvent 3.3 |
| Input | |||
| Rice Husk | kg | 3.33 | Company consulted, 2021 |
| Synthesis Gas-Gasification | m3 | 0.73 | (4040.
Gursel AP, Maryman H, Ostertag C. 2016. A life-cycle approach to
environmental, mechanical, and durability properties of “green” concrete
mixes with rice husk ash. J. Clean. Prod. 11(1):823-836. https://doi.org/10.1016/j.jclepro.2015.06.029. ); Ecoinvent 3.3 |
| Cogeneration | kWh | 1.76 | Company consulted, 2021- Ecoinvent 3.3 |
| Ash crushing (electricity) | kWh | 0.0067 | (4040.
Gursel AP, Maryman H, Ostertag C. 2016. A life-cycle approach to
environmental, mechanical, and durability properties of “green” concrete
mixes with rice husk ash. J. Clean. Prod. 11(1):823-836. https://doi.org/10.1016/j.jclepro.2015.06.029. ) |
| Ash crushing (machines) | kg | 8.21 E-8 | Company consulted, 2021- Ecoinvent 3.3 |
| Output | |||
| Ash | kg | 1 | Company consulted, 2021 |
| Tar | kg | 0.3 | Company consulted, 2021 |
| Main emissions | |||
| Carbon dioxide | kg | 0.27 | Ecoinvent 3.3 |
| Water | m3 | 1.61E-5 | Ecoinvent 3.3 |
| Nitrogen oxids | kg | 4.64 E-6 | Ecoinvent 3.3 |
2.3.4. Pozzolanic cement
⌅To
evaluate the environmental impact of pozzolanic cement, cement
alternatives were first created based on the percentage replacement of
RHA with Portland cement. The results of previous studies (Table 3)
were used to define the cement alternatives, indicating the maximum
percentage of replacement of the ash by cement without compromising the
properties of the cement or concrete by the addition of pozzolan. In
general, the best results were obtained with a maximum replacement of
25% of the RHA by Portland cement. In addition, NSR 6.4.4.2 states that
the maximum percentage for replacement of pozzolans is 25% (5252.
Asociación Colombiana de Ingeniería Sísmica. 2010. Reglamento
Colombiano de Construcción Sismo Resistente NSR-10 (Internet). Bogotá,
Colombia. Retrieved from. https://www.unisdr.org/campaign/resilientcities/uploads/city/attachments/3871-10684.pdf.
).
| Author | Rice husk ash replacement percentages (%) | w/b |
|---|---|---|
| Saraswathy (2626.
Saraswathy V, Ha-WonSong. 2007. Corrosion performance of rice husk ash
blended concrete. Constr. Build. Mater. 21(8):1779-1784. https://doi.org/10.1016/j.conbuildmat.2006.05.037. ) |
5%-10%-15%-20%-25%-30% | 0.53 |
| Ganesan (5353.
Ganesan K, Rajagopal K, Thangavel K. 2008. Rice husk ash blended
cement: Assessment of optimal level of replacement for strength and
permeability properties of concrete. Constr. Build. Mater.
22(8):1675-1683. ) |
5%-10%-15%-20%-25%-30%-35% | 0.53 |
| Chao -lung (2828.
Chao-Lung H, Anh-Tuan BL, Chun-Tsun C. 2011. Effect of rice husk ash on
the strength and durability characteristics of concrete. Constr. Build.
Mater. 25(9):3768-3772. https://doi.org/10.1016/j.conbuildmat.2011.04.009. ) |
10%-20%-30% | 0.39-0.44-0.50 |
| Ferraro (2323.
Ferraro RM, Nanni A. 2012. Effect of off-white rice husk ash on
strength, porosity, conductivity and corrosion resistance of white
concrete. Constr. Build. Mater. 31:220-225. https://doi.org/10.1016/j.conbuildmat.2011.12.010. ) |
7,5%-15% | 0.44 |
| Rawaid (5454.
Khan R, Jabbar A, Ahmad I, Khan W, Naeem Khan A, Mirza J. 2012.
Reduction in environmental problems using rice-husk ash in concrete.
Constr. Build. Mater. 30:360-365. https://doi.org/10.1016/j.conbuildmat.2011.11.028. ) |
25% | |
| Mattey (5555.
Mattey PE, Robayo RA, Díaz JE, Delvasto S, Monzó J. 2015. Application
of rice husk ash obtained from agro-industrial process for the
manufacture of nonstructural concrete blocks. Rev. Latinoam. de Metal. y
Mater. 35(2):285-294. https://ve.scielo.org/scielo.php?pid=S0255-69522015000200015&script=sci_abstract&tlng=en. ) |
20% | 0.40-0.43 |
| Salazar (5656.
Salazar-Carreño D, García-Cáceres RG, Ortiz-Rodríguez OO. 2015.
Laboratory processing of Colombian rice husk for obtaining amorphous
silica as concrete supplementary cementing material. Constr. Build.
Mater. 96:65-75. https://doi.org/10.1016/j.conbuildmat.2015.07.178. ) |
20%-40% | 0.48 |
| Gursel (2020.
Silva FG, Liborio JB, Helene, P. 2008. Improvement of physical and
chemical properties of concrete with brazilian silica rice husk (SRH).
Rev. Ing. Contrucc. 23(1):18-25. http://doi.org/10.4067/S0718-50732008000100002. ) |
10%-15%-20% | 0.33 |
| Hu (5757.
Hu L, He Z, Zhang S. 2020. Sustainable use of rice husk ash in
cement-based materials: Environmental evaluation and performance
improvement. J. Clean. Prod. 264:121744. https://doi.org/10.1016/j.jclepro.2020.121744. ) |
0% -5%-10%-15% | 0.50 |
| Chetan (5858.
Chetan D, Aravindan A. 2020. An experimental investigation on strength
characteristics by partial replacement of rice husk ash and Robo sand in
concrete. Mater. Today: Proceedings. 33(1):502-507. https://doi.org/10.1016/j.matpr.2020.05.075. ) |
5%-10%-15%-20%,10% | 0.43 |
| Rumman (5959.
Rumman R, Bari MS, Manzur T, Kamal MR, Noor MA. 2020. A durable
concrete mix design approach using combined aggregate gradation bands
and rice husk ash based blended cement. J. Build. Eng. 30. 30:101303. https://doi.org/10.1016/j.jobe.2020.101303. ) |
0%-8%-10% | 0.43-0.45-0.47 |
| Jittin (55. Singh B. 2018. Rice husk ash. In Waste and supplementary cementitious materials in concrete. Woodhead Publishing. https://doi.org/10.1016/B978-0-08-102156-9.00013. ) |
20% | |
| Depaa (6060.
Depaa RAB, Priyadarshini V, Hemamalinie A, Francis Xavier J,
Surendrababu K. 2021. Assessment of strength properties of concrete made
with rice husk ash. Mater. Today: Proceedings. 45(7):6724-6727. https://doi.org/10.1016/j.matpr.2020.12.605. ) |
15% | 0.45 |
| Sathurshan (6161.
Sathurshan M, Yapa I, Thamboo J, Jeyakaran T, Navaratnam S, Siddique R,
Zhang J. 2021. Untreated rice husk ash incorporated high strength
self-compacting concrete: Properties and environmental impact
assessments. Environ. Challenges. 2:100015. https://doi.org/10.1016/j.envc.2020.100015. ) |
5%-10%-15%-20%-25% | 0.34 |
W/b=water/binder
For the present work, the alternatives (A1 to A6) of partial substitution by RHA in cement production were defined as shown in Table 4.
| Material | Alternatives | Cement Portland (%) | Rice Husk Ash (%) | |
|---|---|---|---|---|
| Cement | A1 | PC100-RHA0 | 100 | 0 |
| A2 | PC95-RHA5 | 95 | 5 | |
| A3 | PC90-RHA10 | 90 | 10 | |
| A4 | PC85-RHA15 | 85 | 15 | |
| A5 | PC80-RHA20 | 80 | 20 | |
| A6 | PC75-RHA25 | 75 | 25 | |
For the impact evaluation, the pozzolanic cement processes were created from Portland cement and RHA in SimaPro 9.3.3.
2.3.5. Concrete with pozzolanic cement (RHA)
⌅To evaluate the environmental impact of concrete production, the Ecoinvent 9.3.3 base concrete process modeled for Colombia was taken as a reference. This was adapted to the data from the study area using the references provided by the companies that were visited. In this study, the design process of a 21 MPa concrete was applied according to NSR 10, which is used for building construction and general use. Its dosage contains 350 kg of cement, 170 kg of water and a water-binder ratio (w/b) of 0.48.
The cement used for conventional concrete is Portland cement. Pozzolanic concrete is made with different percentages of RHA replacing some of the Portland cement (Table 5). What was interesting in this study was to keep all the variables constant and only substitute the traditional Portland cement for the different pozzolanic cements (with different percentages of rice husk ash) to find out the environmental and economic advantages of this substitution. In this way, the amount of binder (binder= PC+RHA) remained constant, what changed was the percentage of Portland cement within the total binder, as can be seen in Table 5.The system limits for concrete are shown in Figure 3.
| Material | Alternatives | w/b | W (kg) | PC (kg) | RHA (kg) | FA (kg) | CA (kg) | Additives (kg) | |
|---|---|---|---|---|---|---|---|---|---|
| Concrete | A7 | C-PC100-RHA0 | 0.48 | 170 | 350 | 0 | 700 | 1050 | 2.2 |
| A8 | C-PC95-RHA5 | 0.48 | 170 | 332.5 | 17.5 | 700 | 1050 | 2.2 | |
| A9 | C-PC90-RHA10 | 0.48 | 170 | 315 | 35 | 700 | 1050 | 2.2 | |
| A10 | C-PC85-RHA15 | 0.48 | 170 | 297.5 | 52.5 | 700 | 1050 | 2.2 | |
| A11 | C-PC80-RHA20 | 0.48 | 170 | 280 | 70 | 700 | 1050 | 2.2 | |
| A12 | C-PC75-RHA25 | 0.48 | 170 | 262.5 | 87.5 | 700 | 1050 | 2.2 | |
W= Water; W/b=water/binder; PC=Cement Portland; RHA= Rice Husk Ash; CA= Coarse Aggregate; FA= Fine Aggregate; Binder= PC+RHA.
2.4. Life cycle impact assessment
⌅To define which impact categories to evaluate, other LCA studies that address the use of RHA in concrete were considered (Table 6). SimaPro 9.3.3 software was used to organize the inventory data and perform the impact assessment. SimaPro is a popular life cycle analysis tool that can be used to quantitatively measure the environmental impact of a product or service.
| Impact categories | A | E | GW | SOD | HCT | HNCT | MRS | FPMF | LU | FRS | WC |
|---|---|---|---|---|---|---|---|---|---|---|---|
| Silalertruksa (6262.
Silalertruksa T, Gheewala SH. 2013. A comparative LCA of rice straw
utilization for fuels and fertilizer in Thailand. Bioresour. Technol.
150:412-419. https://doi.org/10.1016/j.biortech.2013.09.015. ) |
X | X | X | X | X | X | |||||
| Rodriguez (6363.
Rodriguez Vieira D, Calmon JL, Zanellato Coelho F. 2016. Life cycle
assessment, LCA) applied to the manufacturing of common and ecological
concrete: A review. Constr. Build. Mater. 124:565-666. https://doi.org/10.1016/j.conbuildmat.2016.07.125. ) |
X | X | X | ||||||||
| Kwofie (6464.
Kwofie EM, Ngadi M. 2017. A comparative lifecycle assessment of rural
parboiling system and an integrated steaming and drying system fired
with rice husk. J. Clean. Prod. 140(2):622-630. https://doi.org/10.1016/j.jclepro.2016.06.008. ) |
X | X | X | X | X | ||||||
| Unrean (6565.
Unrean P, Chin Lai Fui B, Rianawati E, Acda M. 2018. Comparative
techno-economic assessment and environmental impacts of rice
husk-to-fuel conversion technologies. Energy. 151:581-593. https://doi.org/10.1016/j.energy.2018.03.112. ) |
X | X | X | X | X | X | X | ||||
| Quispe (6666.
Quispe I, Rodrigo N, Ramzy K. 2019. Life cycle assessment of rice husk
as an energy source. A Peruvian case study. J. Clean. Prod.
209:1235-1244. doi: 10.1016/j.jclepro.2018.10.312. ) |
X | X | X | X | |||||||
| Mikhail (6767.
Mikhail Aberilla J, Gallego-Schmid A, Azapagic A. 2019. Environmental
sustainability of small-scale biomass power technologies for
agricultural communities in developing countries. Renew. Energ.
141:493-506. doi: 10.1016/j.renene.2019.04.036. ) |
X | X | X | X | X | X | X | X | X | X | |
| Lat (6868.
Lat Reaño Resmond. 2020. Assessment of environmental impact and energy
performance of rice husk utilization in various biohydrogen production
pathways. Bioresour. Technol. 299:122590. doi: 10.1016/j.biortech.2019.122590. ) |
X | X | X | ||||||||
| Varadharajan (6969.
Varadharajan S, Animesh J, Shwetambara V. 2020. Assessment of
mechanical properties and environmental benefits of using rice husk ash
and marble dust in concrete. Struct. 28:389-406. doi: 10.1016/j.istruc.2020.09.005. ) |
X | X | X | X | X | X | X | X | |||
| Thengane (7070.
Thengane SK, Burek J, Kung KS, Ghoniem AF, Sanchez DL. 2020. Life cycle
assessment of rice husk torrefaction and prospects for decentralized
facilities at rice mills. J. Clean. Prod. 275:123177. doi: 10.1016/j.jclepro.2020.123177. ) |
X | X | X | X | X | X | X | ||||
| Garces (7171.
Garces JIT, Dollente IJ, Beltran AB, Tan RR, Promentilla MAB. 2021.
Life cycle assessment of self-healing geopolymer concrete. Cleaner Eng.
Technol. 4:100147. https://doi.org/10.1016/j.clet.2021.100147. ) |
X | X | X | X | X | ||||||
| Caldas (7272.
Caldas Rosse L, M’hamed Yassin RDG, Pittau F, Andreola VM, Habert G,
Toledo Filho RD. 2021. Environmental impact assessment of wood
bio-concretes: Evaluation of the influence of different supplementary
cementitious materials. Constr. Build. Mater. 268:121146. https://doi.org/10.1016/j.conbuildmat.2020.121146. ) |
X | X | X | X | X | X | |||||
| Sarah (4242.
Fernando S, Gunasekara C, Law DW, Nasvi MCM, Setunge S, Dissanayake R.
2021. Life cycle assessment and cost analysis of fly ash–rice husk ash
blended alkali-activated concrete. J. Environ. Manage. 295:113140. https://doi.org/10.1016/j.jenvman.2021.113140. ) |
X | X | X | X | X | X | X | ||||
| Briones (7373.
Briones-Hidrovo A, Copa J, Tarelho LAC, Gonçalves C, Pacheco da Costa
T, Dias AC. 2021. Environmental and energy performance of residual
forest biomass for electricity generation: Gasification vs. combustion.
J. Clean. Prod. 289:125680. https://doi.org/10.1016/j.jclepro.2020.125680. ) |
X | X | X | X | X | X | |||||
| Sarah (7474.
Fernando S, Gunasekara C, Law DW, Nasvi MCM, Setunge S. 2022.
Environmental evaluation and economic analysis of fly ash-rice husk ash
blended alkali-activated bricks Ranjith Dissanayake, Dilan Robert.
Environ. Impact Assess. Rev. 95:106784. https://doi.org/10.1016/j.eiar.2022.106784. ) |
X | X | X | X | X | X | X | X | X | ||
| Alcazar (7575.
Alcazar-Ruiz A, Ortiz ML, Dorado F, Sanchez-Silva L. 2022. Gasification
versus fast pyrolysis bio-oil production: A life cycle assessment. J.
Clean. Prod. 336:130373. https://doi.org/10.1016/j.jclepro.2022.130373. ) |
X | X | X | X | X | X | X | X | |||
| Sampaio (7676.
Sampaio DOA, Tashima MM, Costa D, Quinteiro P, Dias AC, Akasaki JL.
2022. Evaluation of the environmental performance of rice husk ash and
tire rubber residues incorporated in concrete slabs. Constr. Build.
Mater. 357:129332. https://doi.org/10.1016/j.conbuildmat.2022.129332. ) |
X | X | X | X | X | X | X |
A= Acidification; E= Eutrophication; GW= Global Warming; SOD= Stratospheric Ozone Depletion; HCT= Human Carcinogenic Toxicity; HNCT= Human Non-Carcinogenic Toxicity; MRS= Mineral Resource Scarcity; FPMF= Fine Particulate Matter Formation; LU= Land Use; FRS= Fossil Resource Scarcity; WC= water consumption.
The result of the inventory
data obtained with SimaPro 9.3.3 is a long list of emissions and
resource consumption. The software includes several methods for
interpreting this list. The method that is best suited for the impact
categories chosen in this study is Recipe2016 Midpoint (H). This method
has been used by several well-known authors on this topic, such as: (6464.
Kwofie EM, Ngadi M. 2017. A comparative lifecycle assessment of rural
parboiling system and an integrated steaming and drying system fired
with rice husk. J. Clean. Prod. 140(2):622-630. https://doi.org/10.1016/j.jclepro.2016.06.008.
, 6666.
Quispe I, Rodrigo N, Ramzy K. 2019. Life cycle assessment of rice husk
as an energy source. A Peruvian case study. J. Clean. Prod.
209:1235-1244. doi: 10.1016/j.jclepro.2018.10.312.
, 6767.
Mikhail Aberilla J, Gallego-Schmid A, Azapagic A. 2019. Environmental
sustainability of small-scale biomass power technologies for
agricultural communities in developing countries. Renew. Energ.
141:493-506. doi: 10.1016/j.renene.2019.04.036.
, 6969.
Varadharajan S, Animesh J, Shwetambara V. 2020. Assessment of
mechanical properties and environmental benefits of using rice husk ash
and marble dust in concrete. Struct. 28:389-406. doi: 10.1016/j.istruc.2020.09.005.
, 7373.
Briones-Hidrovo A, Copa J, Tarelho LAC, Gonçalves C, Pacheco da Costa
T, Dias AC. 2021. Environmental and energy performance of residual
forest biomass for electricity generation: Gasification vs. combustion.
J. Clean. Prod. 289:125680. https://doi.org/10.1016/j.jclepro.2020.125680.
, 7676.
Sampaio DOA, Tashima MM, Costa D, Quinteiro P, Dias AC, Akasaki JL.
2022. Evaluation of the environmental performance of rice husk ash and
tire rubber residues incorporated in concrete slabs. Constr. Build.
Mater. 357:129332. https://doi.org/10.1016/j.conbuildmat.2022.129332.
, 7777.
Manjunatha M, Preethi S, Malingaraya, Mounika HG, Niveditha KN, Ravi.
2021. Life cycle assessment (LCA) of concrete prepared with sustainable
cement-based materials. Mater. Today: Proceedings. 47(13):3637-3644. https://doi.org/10.1016/j.matpr.2021.01.248.
).
This approach was chosen because it provides unambiguous values that
can be used to compare concrete with different alternatives, as used in
the study by (7777.
Manjunatha M, Preethi S, Malingaraya, Mounika HG, Niveditha KN, Ravi.
2021. Life cycle assessment (LCA) of concrete prepared with sustainable
cement-based materials. Mater. Today: Proceedings. 47(13):3637-3644. https://doi.org/10.1016/j.matpr.2021.01.248.
). Midpoint effects are considered more precise because they correspond to a higher level of empirical evidence. As in (7777.
Manjunatha M, Preethi S, Malingaraya, Mounika HG, Niveditha KN, Ravi.
2021. Life cycle assessment (LCA) of concrete prepared with sustainable
cement-based materials. Mater. Today: Proceedings. 47(13):3637-3644. https://doi.org/10.1016/j.matpr.2021.01.248.
),
the midpoint effect results were considered to evaluate the different
forms of effects produced by each constituent of the concrete and its
process.
3. RESULTS AND DISCUSSION
⌅3.1. Rice husk ash (RHA)
⌅Electricity and heat are generated through the process of obtaining ash through the gasification of RH. The processes that have impacts in all categories when RHA is obtained are electricity (high voltage-cogeneration) and synthetic gas, see Figure 4.
The
greatest impact from the use of electricity required during the
electricity and heat cogeneration process occurs in the ozone layer
depletion category at 43%, followed by 35% in the mineral resource
scarcity category and 6 % in the water consumption category. Syngas
production has impacts on water consumption (4%), mineral resource
scarcity (3%) and eutrophication (3%). These impacts are due to the use
of electricity and water during the process. There is a minimum impact
of 0.2% on land use due to waste disposal in landfills. These results
coincide with the study by (6767.
Mikhail Aberilla J, Gallego-Schmid A, Azapagic A. 2019. Environmental
sustainability of small-scale biomass power technologies for
agricultural communities in developing countries. Renew. Energ.
141:493-506. doi: 10.1016/j.renene.2019.04.036.
) who found impacts from biomass gasification in the mineral resource scarcity category and impacts on land use.
The process of obtaining rice husk ash in the global warming category was improved at environmental level. This process saves energy due to the fact that heat and electricity are generated by cogeneration (renewable energy). Therefore, the energy savings also prevent the generation and release of carbon dioxide into the environment, which minimises the impact of global warming. The impacts in this category (global warming) were insignificant with respect to the savings or impacts avoided in it since the production of electricity from fossil fuels was avoided.
According to (6666.
Quispe I, Rodrigo N, Ramzy K. 2019. Life cycle assessment of rice husk
as an energy source. A Peruvian case study. J. Clean. Prod.
209:1235-1244. doi: 10.1016/j.jclepro.2018.10.312.
),
the production of 1 MJ from RH has lower impacts on global warming,
acidification and eutrophication categories than the production of 1 MJ
from coal. This corroborates the advantages of energy production from RH
(in a cogeneration process from husk) that has ash as a by-product.
According to (6666.
Quispe I, Rodrigo N, Ramzy K. 2019. Life cycle assessment of rice husk
as an energy source. A Peruvian case study. J. Clean. Prod.
209:1235-1244. doi: 10.1016/j.jclepro.2018.10.312.
),
if RH is used as a source of thermal energy instead of coal, the
environmental impact decreases by 97% in the global warming category for
each MJ generated. The results also suggest that gasification has up to
12 times lower impacts per kWh than combustion (6767.
Mikhail Aberilla J, Gallego-Schmid A, Azapagic A. 2019. Environmental
sustainability of small-scale biomass power technologies for
agricultural communities in developing countries. Renew. Energ.
141:493-506. doi: 10.1016/j.renene.2019.04.036.
).
In general, providing energy from residual biomass in small farming
communities would significantly reduce environmental impacts and improve
waste management practices (6767.
Mikhail Aberilla J, Gallego-Schmid A, Azapagic A. 2019. Environmental
sustainability of small-scale biomass power technologies for
agricultural communities in developing countries. Renew. Energ.
141:493-506. doi: 10.1016/j.renene.2019.04.036.
).
Likewise, the category of water consumption had a low environmental
impact since the process of cogeneration of heat and electricity
requires lower water consumption than that required to produce
electricity from fossil energy sources (Figure 4).
3.2. Comparison of the cements
⌅Figure 6 shows that the cement alternative that has the greatest environmental impact is PC100-RHA0. The greatest impacts were on global warming (100%), mineral resource scarcity (100%), fossil resource scarcity (100%), fine particulate matter formation (100%), human carcinogenic toxicity (100%), eutrophication (97%) and acidification (85%) categories. As the clinker percentage decreases and the RHA percentage increases, the environmental impacts decrease in all impact categories.
The
global warming category decreases as the RHA content increases. The
reason for these results is that when ash is obtained, impacts are
avoided due to the electrical energy and heat that are generated during
the process and due to the impacts avoided by the non-disposal of RH.
Although electricity consumption is necessary during the cogeneration
process, the amount is much less than the electrical energy generated
during the process. These positive results of lower CO2 emissions for RHA compared to cement coincide with the study carried out by Hu (5757.
Hu L, He Z, Zhang S. 2020. Sustainable use of rice husk ash in
cement-based materials: Environmental evaluation and performance
improvement. J. Clean. Prod. 264:121744. https://doi.org/10.1016/j.jclepro.2020.121744.
),
in which 157 kg CO2 eq/ton are required for the RHA compared to that
required for cement, which is 801.6 kg CO2 eq/ton. Likewise, in the
study by Hu (5757.
Hu L, He Z, Zhang S. 2020. Sustainable use of rice husk ash in
cement-based materials: Environmental evaluation and performance
improvement. J. Clean. Prod. 264:121744. https://doi.org/10.1016/j.jclepro.2020.121744.
), the energy required to obtain RHA was -353.5 MJ/ton, in terms of savings.
The process of obtaining Portland cement contributes to impacts in the global warming category due to the high energy consumption in the process of obtaining clinker. However, obtaining rice husk ash does not generate impacts in this category due to the energy savings from the cogeneration of electricity and heat during its production process.
The
cement alternative with the highest RHA replacement (PC75-RHA25) was
found to lead to savings in all impact categories compared to
PC100-RHA0. The greatest impact was on global warming. However, these
results were much lower than those obtained for PC100-RHA0. The total
greenhouse gases emission and energy consumption in the cement industry
can be reduced by using waste materials to replace virgin materials
(clinker/coal). This agrees with what was found by (7878.
Uzzal Hossaina Md, Sun Poona C, Lo IMC, Cheng JCP. 2017. Comparative
LCA on using waste materials in the cement industry: A Hong Kong case
study. Resources, Conserv. Recycl. 120:199-208. https://doi.org/10.1016/j.resconrec.2016.12.012.
).
In other impact categories evaluated for PC75-RHA25, the following savings were found: SOD (-100%), A (-100%), E (-100%), human non-carcinogenic toxicity (HNCT) (-100%), LU (-100%), WC (-100%), FPMF (-95%), MRS (-71%), HCT (-53%) and FRS (-37%). This is because when the Portland cement process was compared with the process for obtaining RHA, the pozzolanic material had lower impacts in these categories (Figure 5).
The
results show that Portland cement had higher environmental impacts
mainly due to the use of raw materials and fossil fuels. The use of ash
as an alternative material helps to reduce the environmental impacts.
This is in line with the results of (7878.
Uzzal Hossaina Md, Sun Poona C, Lo IMC, Cheng JCP. 2017. Comparative
LCA on using waste materials in the cement industry: A Hong Kong case
study. Resources, Conserv. Recycl. 120:199-208. https://doi.org/10.1016/j.resconrec.2016.12.012.
). Mendes (7979.
Mendes Moraesa CA, Goncalves Kielinga A, Oliveira Caetano M, Paulo
Gomes L. 2010. Life Cycle Analysis (LCA) for the incorporation of rice
husk ash in mortar coating. Resources, Conserv. Recycl.
54(12):1170-1176. https://doi.org/10.1016/j.resconrec.2010.03.012.
)
also quantified the number of environmental aspects and impacts of
mortar production with and without RHA and compared these impacts. They
found fewer impacts in the mortar with ash compared to the mortar
without RHA, in the processes of generation of rice husk ash,
beneficiation of rice husk ash and RHA transportation. Once again, this
shows the advantages of using RHA in binders. Impacts related to air
emissions (CO2, NOx, PM, CO and SO2) decreased with the increase in
supplementary cementitious materials according to (7676.
Sampaio DOA, Tashima MM, Costa D, Quinteiro P, Dias AC, Akasaki JL.
2022. Evaluation of the environmental performance of rice husk ash and
tire rubber residues incorporated in concrete slabs. Constr. Build.
Mater. 357:129332. https://doi.org/10.1016/j.conbuildmat.2022.129332.
).
The use of pozzolanic cement as a binder for concrete preparation
reduces the raw material consumption and reduces the environmental
impacts of cement production (7777.
Manjunatha M, Preethi S, Malingaraya, Mounika HG, Niveditha KN, Ravi.
2021. Life cycle assessment (LCA) of concrete prepared with sustainable
cement-based materials. Mater. Today: Proceedings. 47(13):3637-3644. https://doi.org/10.1016/j.matpr.2021.01.248.
).
Regarding water consumption, cementitious mixes with a higher percentage of Portland cement contribute to impacts in this category. By increasing the percentage of rice husk ash in the mixes, savings are found in this category. This is due to the fact that in the process of obtaining rice husk ash, savings result from the cogeneration of electricity and heat (and therefore these processes and the associated water consumption are avoided). This differs from obtaining Portland cement, which requires high energy consumption, and therefore water, in the clinker production process.
Likewise, the impacts on the mineral resource scarcity category were lower with the increase in RHA content, which resulted in 100%, 94%, 89%, 83%, 77% and 71% in PC100-RHA0, PC95-RHA5, PC90-RHA10, PC85-RHA15, PC80-RHA20 and PC75-RHA25, respectively. This is because, when the process of obtaining cement with obtaining rice husk ash was compared, it was found that obtaining Portland cement generates higher impacts in this category than obtaining rice husk ash. This is due to the consumption of raw materials extracted from nature to manufacture cement (limestone, clay, gypsum and iron ore), unlike the process of obtaining rice husk ash that uses a by-product of the rice industry.
Obtaining
rice husk ash uses a by-product of the rice industry. Therefore, when
it is compared to cement production, it presents savings in the scarcity
of natural resources category. In addition, (7474.
Fernando S, Gunasekara C, Law DW, Nasvi MCM, Setunge S. 2022.
Environmental evaluation and economic analysis of fly ash-rice husk ash
blended alkali-activated bricks Ranjith Dissanayake, Dilan Robert.
Environ. Impact Assess. Rev. 95:106784. https://doi.org/10.1016/j.eiar.2022.106784.
)
found that there are environmental benefits as the impacts due to the
disposal of RHA are reduced, since a residue becomes a valuable product
and therefore a natural resource.
3.3. Comparison of the concretes
⌅As can be seen in Figure 6,
concrete with Portland cement (C-PC100-RHA0) had the greatest
environmental impacts in all the categories evaluated. The greatest
impacts were in the global warming (100%), fine particulate matter
formation (100%), acidification (100%), eutrophication (100%), human
carcinogenic toxicity (100%), mineral resource scarcity (100%), fossil
resource scarcity (100%) and water consumption (100%) categories. The
process that contributed the most to these impacts in all the categories
evaluated was the production of Portland cement. However, concrete with
a higher percentage of pozzolanic cement had lower impacts in the
global warming and fossil resource scarcity category than concrete
without RHA. This coincides with Chen Lo (8080.
Lo FC, Lee MG, Lo SL. 2021. Effect of coal ash and rice husk ash
partial replacement in ordinary Portland cement on pervious concrete.
Constr. Build. Mater 286:122947. https://doi.org/10.1016/j.conbuildmat.2021.122947.
)
in their study in which the use of ash in concrete also reduced the
carbon footprint in relation to conventional concrete between 10% and
20% and in which the process that contributed the most to the impacts on
concrete was Portland cement. Manjunatha (7777.
Manjunatha M, Preethi S, Malingaraya, Mounika HG, Niveditha KN, Ravi.
2021. Life cycle assessment (LCA) of concrete prepared with sustainable
cement-based materials. Mater. Today: Proceedings. 47(13):3637-3644. https://doi.org/10.1016/j.matpr.2021.01.248.
)
also found that these impacts decreased considerably in comparison to
conventional concrete. Better results were obtained with a higher RHA
replacement percentage (25%). However, this replacement percentage in
the cement should not be increased, since previous studies show (Table 2)
that if this ash replacement percentage is increased in the cement, the
properties of the cement or concrete can be compromised by the addition
of pozzolan.
Likewise,
concrete with Portland cement (C-PC100-RHA0) had the lowest impact in
the land use category (56%). This is because in this category the impact
of cement production is minimal (11%) compared to the process of sand
extraction (82%). The concrete with the lowest environmental impacts was
the concrete with the highest RHA replacement percentage
(C-PC75-RHA25). This concrete had the greatest environmental impacts in
the mineral resource scarcity (73%), water consumption (57%) and global
warming (29%) categories, also due to the production of Portland cement
and the process for obtaining gravel. Environmental savings were also
present in the other categories. The greatest savings were in the human
non-carcinogenic toxicity (-100%), land use (-100%) and stratospheric
ozone depletion (-100%) categories. This was due to the savings caused
by the use of RH cement in the concrete, in agreement with what was
found by other authors (7777.
Manjunatha M, Preethi S, Malingaraya, Mounika HG, Niveditha KN, Ravi.
2021. Life cycle assessment (LCA) of concrete prepared with sustainable
cement-based materials. Mater. Today: Proceedings. 47(13):3637-3644. https://doi.org/10.1016/j.matpr.2021.01.248.
).
In general, all the types of concrete that were evaluated had impacts in the global warming and water consumption category. These impacts were greater when cementitious mixes with higher Portland cement content were used. When cementitious mixtures with a higher rice husk ash content were used, the impacts in this category were lower. This is because the process of obtaining rice husk ash is associated with the cogeneration of electricity and heat from rice husks. Therefore, the generation of electricity by means of fossil fuels is avoided, which implies lower CO2 emissions and less water consumption.
Another
category in which all the concretes that were evaluated had impacts is
the mineral resources extraction category. In this category, as the CP
content in the concretes increases, the impacts increase. This is due to
the consumption of raw material extracted from nature to obtain
Portland cement. By increasing the percentage of rice husk ash, the
impacts decrease because a by-product of the rice industry is used to
obtain this concrete, instead of the raw material extracted from nature
in the case of Portland cement. The use of rice husks as a replacement
for cement in the production of concrete is a research area with great
environmental benefits in Colombia, as has been shown by other studies (2020.
Silva FG, Liborio JB, Helene, P. 2008. Improvement of physical and
chemical properties of concrete with brazilian silica rice husk (SRH).
Rev. Ing. Contrucc. 23(1):18-25. http://doi.org/10.4067/S0718-50732008000100002.
, 2727. Sensale, Rodriguez G. 2006. Strength development of concrete with rice-husk ash. Cem. Concr. Compos. 28(2):158-160. https://doi.org/10.1016/j.cemconcomp.2005.09.005.
, 39-4239.
Gursel AP, Masanet E, Horvath A, Stadel A. 2014. Life-cycle inventory
analysis of concrete production: A critical review. Cem. Concr. Compos.
7:372-378. https://doi.org/10.1016/j.cemconcomp.2014.03.005.
40.
Gursel AP, Maryman H, Ostertag C. 2016. A life-cycle approach to
environmental, mechanical, and durability properties of “green” concrete
mixes with rice husk ash. J. Clean. Prod. 11(1):823-836. https://doi.org/10.1016/j.jclepro.2015.06.029.
41.
Tong KT, Vinai R, Soutsos MN. 2018. Use of Vietnamese rice husk ash for
the production of sodium silicate as the activator for alkali-activated
binders. J. Clean. Prod. 201:272-286. https://doi.org/10.1016/j.jclepro.2018.08.025.
42.
Fernando S, Gunasekara C, Law DW, Nasvi MCM, Setunge S, Dissanayake R.
2021. Life cycle assessment and cost analysis of fly ash–rice husk ash
blended alkali-activated concrete. J. Environ. Manage. 295:113140. https://doi.org/10.1016/j.jenvman.2021.113140.
).
RHA is an agricultural residue generated during the milling of rice.
Therefore, it can help reduce the environmental impact and promote
sustainable practices, under a life cycle approach. In the department of
Tolima, current annual production of rice is 406,737 tons, of which it
is estimated that 20% is RHA (33.
Rithuparna R, Jittin V, Bahurudeen A. 2021. Influence of different
processing methods on the recycling potential of agro-waste ashes for
sustainable cement production: A review. J. Clean. Prod. 316:128242. https://doi.org/10.1016/j.jclepro.2021.128242.
, 66.
Das S, Patel A. 2018. Potential of rice husk ash in concrete
production: A literature review. Research Gate (internet). Retrieved
from: https://www.researchgate.net/publication/324079453_Potential_of_rice_husk_ash_in_concrete_production_A_literature_review
). Therefore, it could be said that the department
of Tolima has replacement potential in the manufacture of 81,347 tons
of RHA concrete, as a pozzolanic material that favours the formation of
cementitious compounds.
3.4. Sensitivity analyses
⌅Sensitivity
analyzes were performed to assess the influence of greater distances
traveled by the RHA from the rice mill to the cement plant. This
sensitivity analysis for transportation distances has been evaluated by
other authors such as (7676.
Sampaio DOA, Tashima MM, Costa D, Quinteiro P, Dias AC, Akasaki JL.
2022. Evaluation of the environmental performance of rice husk ash and
tire rubber residues incorporated in concrete slabs. Constr. Build.
Mater. 357:129332. https://doi.org/10.1016/j.conbuildmat.2022.129332.
). The transport distance that was considered in Sections 3.2 and 3.3 is 14 km (Table 1).
In this section, only the processes are compared when this distance is
varied, to determine how viable the replacement of rice husk ash is by
increasing its transportation distance. The cement production with the
highest percentage of ash replacement (25%) at a distance of 14 km was
compared with this same production process, with the distance varied to
60 km and 100 km (Figure 7).
Transport turned out to be a variable that was negligible compared to
the positive environmental impacts of the use of RHA in cement, as shown
in Figure 7.
When RHA transported over a distance of 100 km from the mill to the
cement plant is used in the cement to make C-PC75-RHA25 concrete, it
still has environmental advantages, as shown in the Figure 8.
In this case, the environmental impacts were compared in the categories
of concrete C-PC75-RHA25 in which the ash was transported 14 km, or 60
km to 100 km. These results indicate that the variation in the transport
distance of rice husk ash to the cement plant (up to 100 km) does not
negatively affect the environmental impacts of cement and concrete
production with this pozzolanic material (Figure 7 and Figure 8).
3.5. Economic evaluation
⌅The
economic criteria were evaluated considering the production costs for
the products that were manufactured. The method used to calculate the
economic costs was based on an economic study of construction materials
conducted by (8181.
Tošić N, Marinković S, Dašić T, Stanić M. 2015. Multicriteria
optimization of natural and recycled aggregate concrete for structural
use. J. Clean. Prod. 87:766-776. https://doi.org/10.1016/j.jclepro.2014.10.070.
, 8282.
Suárez S, Calderón L, Gasso S, Roca X. 2018. Multi-criteria decision
analysis to assess the environmental and economic performance of using
recycled gypsum cement and recycled aggregate to produce concrete: the
case of Catalonia (Spain). Resources, Conserv. Recycl. 133:120-131. https://doi.org/10.1016/j.resconrec.2017.11.023.
) used this method to study a new concrete with recycled gypsum cement and recycled aggregates. Other authors such as (8383.
López Ruiz LA, Xavier Roca R, Lara Mercedes CM, Santiago Gasso D. 2022.
Multicriteria analysis of the environmental and economic performance of
circularity strategies for concrete waste recycling in Spain. Waste
Manage. 144:387-400. https://doi.org/10.1016/j.wasman.2022.04.008.
)
have used this method to analyze different concrete alternatives with
recycled aggregates from construction and demolition waste (CDW). The
objective of this study was to determine and then compare the
approximate costs of the alternatives for cement and concrete
production.
The reference costs for aggregates, cement and concrete were calculated by adding the cost of producing each material. The production costs for the materials were determined based on the costs reported by the companies and plants surveyed in Colombia. The data were collected in different years from different companies or plants with similar production capacities. These data were supplemented with secondary information on material production costs. The transportation distance was considered a constant since it was the same for all alternatives. For this reason, it was not included in the total price of the concrete. The production and sales costs of the materials that make up the concrete are shown in the Table 7, which indicates the source of the information.
| Material | Cost of production or sale ($/kg) | Source |
|---|---|---|
| Portland Cement | 0.288 | Requested company, 2022 |
| Rice husk ash | 0.156 | Visited company, 2022 |
| Fine aggregate | 0.003 | Visited company, 2022 |
| Coarse aggregate | 0.005 | Visited company, 2022 |
| Water | 0.001 | Ibal, 2022 |
| Retardant additive | 1.647 | Visited company, 2022 |
| Plasticizer additive | 2.459 | Visited company, 2022 |
Different
combinations of PC with RHA in different proportions were made and the
price of each alternative was determined using the cost of the material
PC and RHA given in Table 7.
We managed to substitute 25% of PC with RHA because the resistant
property of cement was maintained. A larger substitution would mean
losses in its resistance, as presented in Table 4. Only Chao (8484.
Liu C, Zhang W, Liu H, Lin X, Zhang R. 2022. A compressive strength
prediction model based on the hydration reaction of cement paste by rice
husk ash. Constr. Build. Mater. 340:127841. https://doi.org/10.1016/j.conbuildmat.2022.127841.
) presented an economic study of alternatives.
The six proposed cement alternatives are listed in Table 8.
| Material | Alternatives | Total price ($/kg) | |
|---|---|---|---|
| Cement | A1 | PC100-RHA0 | 0.29 |
| A2 | PC95-RHA5 | 0.28 | |
| A3 | PC90-RHA10 | 0.27 | |
| A4 | PC85-RHA15 | 0.27 | |
| A5 | PC80-RHA20 | 0.26 | |
| A6 | PC75-RHA25 | 0.26 | |
The methodology for calculating the economic criteria was based on data for the production of 1 kg of Portland cement (PC) for the alternatives of mixing with rice husk ash (RHA). From the results obtained, it appears that the alternative with 100% PC (A1) is cheaper than the other alternatives. In the second alternative (PC95-RHA5), the final price of cement/kg is reduced by 2.3%. In the last alternative (PC75-RHA25), the final cost was reduced by 11.5% (Table 8). On the other hand, the production costs of the six proposed concrete alternatives are listed in Table 9.
| Material | Alternatives | W ($/170 kg) | Pozzolanic cement ($/350 kg) | FA ($/700 kg) | CA ($/1050 kg) | RAd ($/1,1 kg) | PAd ($/1,1 kg) | Total cost/m3 | |
|---|---|---|---|---|---|---|---|---|---|
| Concrete | A7 | C-PC100-RHA0 | 0.1 | 100.8 | 2.0 | 4.9 | 1.8 | 2.7 | 112.3 |
| A8 | C-PC95-RHA5 | 0.1 | 98.5 | 2.0 | 4.9 | 1.8 | 2.7 | 110.0 | |
| A9 | C-PC90-RHA10 | 0.1 | 96.2 | 2.0 | 4.9 | 1.8 | 2.7 | 107.6 | |
| A10 | C-PC85-RHA15 | 0.1 | 93.9 | 2.0 | 4.9 | 1.8 | 2.7 | 105.3 | |
| A11 | C-PC80-RHA20 | 0.1 | 91.6 | 2.0 | 4.9 | 1.8 | 2.7 | 103.0 | |
| A12 | C-PC75-RHA25 | 0.1 | 89.3 | 2.0 | 4.9 | 1.8 | 2.7 | 100.7 | |
W= Water; C= Concrete; PC= Cement Portland; CA= Coarse Aggregate; FA= Fine Aggregate; Rad= Retardant additive; Pad= Plasticizer additive.
In this case, the economic criteria are based on the required data for the final price of 1 m3 of concrete for the cement alternatives proposed above (A1-A6) together with the price of pozzolanic cement ($/350 kg). For this reason, there are six alternatives (A7 to A12). The first alternative A7 with 100% PC (A1) was cheaper than the other alternatives.
In concrete there
are economic advantages between 2.1% and 10.3% of the final price when
PC and RHA are used compared to A7 (100% PC), estimated at $112.3 m3.
That is, a difference between $2.3 and $11.6. Alternative A12 is the
most economical because less cement is used in the mix with RHA. When
Chao (8484.
Liu C, Zhang W, Liu H, Lin X, Zhang R. 2022. A compressive strength
prediction model based on the hydration reaction of cement paste by rice
husk ash. Constr. Build. Mater. 340:127841. https://doi.org/10.1016/j.conbuildmat.2022.127841.
)
replaced 30% RHA, the concrete had mechanical properties closer to
those of conventional concrete, and the total cost of concrete was
reduced by 7.16%. Partial replacement of cement with rice husk ash can
thus lead to significant cost savings and reduce the negative
environmental impact of cement production. In addition to the economic
advantages mentioned above, a great possibility opens up in Colombia and
in the department of Tolima. Utilising RHA in concrete production may
provide an opportunity to reduce reliance on traditional cementitious
materials that are energy intensive and have a high carbon footprint (1616.
Rhaouti Y, Taha Y, Benzaazoua M. 2022. Assessment of the environmental
performance of blended cements from a life cycle perspective: a
systematic review. Sustain. Prod. Consum. 36:32-48. https://doi.org/10.1016/j.spc.2022.12.010.
).
This is in line with Colombia’s commitment to sustainable development
and climate change mitigation. Furthermore, the use of RHA can
contribute to the development of a circular economy by turning
agricultural waste into a valuable resource.
4. CONCLUSIONS
⌅This study evaluates the environmental impacts of cement and concrete mixes with rice husk ash, applied to the Colombian context. The following conclusions can be drawn:
-
Obtaining the RHA implies a saving of environmental impacts in all the categories evaluated. These results were observed by comparing the production of Portland cement with obtaining RHA. This is because impacts are avoided in obtaining the ash due to the electrical energy and heat that are generated during the process and due to the impacts avoided due to the non-disposal of RH. Although consumption of electricity is necessary during the cogeneration process, it is less than the electrical energy generated during the process. The process of obtaining rice husk ash in the global warming category turned out to be beneficial at an environmental level since it presents energy savings as heat and electricity are generated in this process by cogeneration (renewable energy).
-
It was concluded that the cement alternative that has the greatest environmental impact is PC100-RHA0. As the percentage of clinker decreases and the percentage of RHA increases, the environmental impacts decrease in all impact categories. The lowest impacts are found when 25% of RHA is used.
-
Concrete with Portland cement (C-PC100-RHA0) has the highest environmental impacts in all the evaluated categories and the concrete with the lowest environmental impacts turns out to be the concrete with the highest percentage of RHA replacement (C-PC75-RHA25). By using cementitious mixtures with a higher content of rice husk ash, the impacts on the global warming, water and mineral resource scarcity categories were lower, since the process of obtaining husk ash is associated with the cogeneration of electricity and heat from the rice husk. This means that the generation of electricity by means of fossil fuels is avoided, which implies lower CO2 emissions and less water consumption. In addition, by increasing the percentage of rice husk ash, the impacts decrease because a by-product of the rice industry is used to obtain this concrete, instead of raw material extracted from nature as in the case of Portland cement.
-
Within the sensitivity analysis, cement production is compared with the highest ash replacement percentage (25%), at a distance of 14 km and the same cement, but with an ash transport distance of 60 km and 100 km. Transportation turns out to be a variable that is negligible compared to the positive environmental impacts of the use of RHA in cement.
-
The use of the RHA generated during the RH gasification process for the production of electricity and heat turns out to be beneficial from the environmental perspective since it generates savings in environmental impacts in all the categories evaluated when it is used in cement and in concrete.
-
The use of RHA as a partial replacement for cement in concrete production results in significant economic advantages compared with conventional concrete. In addition, the negative environmental impact in cement production is cut considerably. In the case of concrete, all alternatives offer economic benefits.
The results open up great possibilities in Colombia and in the department of Tolima. The use of RHA in the production of concrete can provide an opportunity to reduce reliance on traditional cementitious materials that are energy intensive and have a high carbon footprint. To take advantage of these opportunities, more research and development efforts are required. Collaboration between academic institutions, government agencies and the private sector can play a crucial role in advancing the use of rice hulls in cement production. Future research can focus on deepening and optimising production processes, determining the appropriate mixing proportions of RHA in concrete, and evaluating the performance and long-term durability of RHA-based concrete under Colombian environmental conditions.
In addition, the use of rice hulls in the manufacture of concrete can boost the circular economy by turning agricultural waste into a valuable resource. This can encourage sustainability and the development of more environmentally friendly practices in the construction industry.
It is important to highlight that the successful implementation of the use of rice husks in the manufacture of concrete in Colombia will require awareness and the adoption of favourable policies by the relevant stakeholders. It is also necessary to establish quality standards and proper regulations to ensure the performance and safety of concrete made from rice husks. The use of rice husks as a replacement for cement in the production of concrete shows promising results and offers opportunities in the Colombian context. This approach can contribute to sustainable development, reduce carbon emissions and promote the efficient use of agricultural waste. Ongoing research and collaborations are key to facilitating the full use of this alternative material in the construction industry.