Journal of Sustainable Architecture and Civil Engineering 2016/1/14 12 *Corresponding author: danute.palubinskaite@ktu.lt The Utilization of Biomass Bottom Ashes in Cement System Received 2016/04/10 Accepted after revision 2016/05/30 Journal of Sustainable Architecture and Civil Engineering Vol. 1 / No. 14 / 2016 pp. 12-19 DOI 10.5755/j01.sace.14.1.14893 © Kaunas University of Technology The Utilization of Biomass Bottom Ashes in Cement System JSACE 1/14 http://dx.doi.org/10.5755/j01.sace.14.1.14893 Introduction Danutė Vaičiukynienė*, Vitoldas Vaitkevičius, Jūratė Krulikauskaitė Kaunas University of Technology, Faculty of Civil Engineering and Architecture Studentu st. 48, LT-51367 Kaunas, Lithuania Aras Kantautas Kaunas University of Technology, Faculty of Сhemical Technology Radvilenu st. 19, LT-50254 Kaunas, Lithuania Vilimantas Vaičiukynas Aleksandras Stulginskis University, Faculty of Water and Land Management Universiteto g.10, LT- 53361 Akademija, Kaunas District Municipality, Lithuania Valdas Rudelis Joint-stock company “LIFOSA”, Juodkiškio st. 50, LT-57502 Kėdainiai, Lithuania By producing 1 ton of Portland cement clinker in environment releasing about 0.85 tons of CO2: 70% of limestone decarbonation and 30% of electricity and thermal consumption. High specific CO2 emissions results take the responsibility of Portland cement industry for about 5% of global CO2 emissions. One of the ways to reduce CO2 emissions is the use of Portland cement substituting materials. Properly treated ashes could become not a waste of biofuel but a valuable raw material for new construction materials. This paper presents results about the characterization of the biomass bottom ash sourced from the combustion of plant biomass located in Lithuania, and the study of new cement formulations incorporated with the biomass bottom ash. The study includes a comparative analysis of the phase formation and the setting of cement with bottom ash composite. Techniques such as X-ray diffraction (XRD), X-ray fluorescence spectroscopy (XRF), measurement of hydration temperature were used to determine the structure and composition of the formulations. KEYWORDS: biomass bottom ash, hardened cement paste, zeolite. Biomass is a renewable energy source that is increasingly being used worldwide. However, be- cause of recent increases in production, waste products from biomass combustion are becoming a relevant environmental and economic problem. Currently biomass bottom ash from biomass combustion is waste with no practical applications and generally deposited in landfills. Because of the pozzolanic contribution of conventional concrete, biomass bottom ash can also be used as a partial substitute for cement. Biomass fly/bottom ashes have been used to produce mortars in addition to commercial cement. The presence of ash modifies the pastes rheological behavior. Materials display fair compression strength after 28 d of ageing in water. Materials aged 180 d in water suffer of high potassium elution (Maschio et. al., 2011). In the research (da Luz 13 Journal of Sustainable Architecture and Civil Engineering 2016/1/14 Garcia et al., 2013) suggest bottom-ash, a waste material to ground and to test for use as a partial cement replacement material. Mortar with ground bottom-ash showed marginal durability loss but improved strength at later ages. Ground bottom-ash, non-glassy, may be used as a filler, con- tributing to sustainable construction. There are some results have been published on the use of biomass bottom ash as filler in concretes or in road embankments. The results prove the feasible application of biomass bottom ashes as filler in road embankments. Furthermore, its use as cement-treated materials or non-structural concrete, depending on the replacement percentage (Hinojosa et. al., 2014). In the research (Beltrán et. al., 2014), concrete consisting of recycled aggregate substitutions was manufactured by applying different replacement rates of natural sand with biomass bottom ash. The results showed a worse behavior in mechanical properties and durability properties, however these reductions were inferior to it can be expected, due to the appropriate manufacture of the concrete applied. In another work (Cabrera et. al., 2014) it was determined that biomass bottom ash possesses acceptable properties to be used as a filler material in the core of road embankments over 5 m in height without additional precautionary measures, such as the construction of road shoulders. In the research (Beltrán et al., 2014) three series with different amount of biomass bottom ashes manufacture. Mechanical prop- erties were negatively with the addition of recycled aggregates. Durability properties declined with increasing recycled aggregates. In another work (Modolo et al., 2013) determined that bottom ash from biomass burning can be used as aggregate in mortars. Incorporation does not induce nega- tive impacts. Mortar producers due to the replacement of treated and calibrated sand may achieve economic savings. In the research (Beltrán et al., 2016) analyzed samples of biomass bottom ash- es from wood and olive trees. Low density, high absorption and high organic matter content were observed. Biomass bottom ashes were classified as subsidiary material feasible as construction material. The use of the ashes as a filler material in road embankments was proved. Some scientists suggest biomass bottom ashes to utilize as component in building materials. For ashes that cannot be recycled it is possible to utilize as building material or as component in building products. The key factors for success in all forms of utilization are consistency of ash quality and availability of large quantities (Pels et al., 2005). In the present work (Wang et al., 2007) the use of biomass bottom ash significantly increased the porosity of mortars and it led to the decline of mechanical properties. According to the Carrasco et al., (2014) the addition of bottom ash increases the material’s porosity, thereby decreases its thermal conductivity and compressive strength. The mixture with a 1:1 Si/Ca molar ratio shows the best mechanical characteristics (61.11 MPa) with acceptable thermal conductivity value (0.773 W/mK) and could potentially be used in products such as building blocks, since partially replacing the cement with ash produced samples based on criteria of the EN standards. The aim of this work is to investigate possibilities of hydrothermal treated biomass bottom ashes in Portland cement mixtures. XRD analysis data show that in the biomass bottom ashes (Fig. 1) silicon dioxide and calcium carbonate prevailed. There are small amount of calcium oxide, magnesium oxide, anorthoclase and gehlenite. In investigated biomass bottom ashes it is believed that calcium oxide should be left after firing of biomass. It is slowly hydrate and going carbonation. Amorphous SiO2 waste are industrial by-product, i. e., amorphous SiO2 · nH2O (Lifosa, Lithuania). This amorphous SiO2 is polluted with the impurities of fluoride compounds. Chemical composition of this waste is show in Tabale 1. The commercial Portland cement of type CEM I 52.5R was used for the tests. Chemical composi- tion of Portland cement and biomass bottom ashes was given in Table 1. After the XRF analysis it was determined that CaO (48.97 %), SiO2 (22.39 %), MgO (8.29 %), and K2O (8.69 %), contain the largest amount of oxides in the biomass bottom ashes (Table 1). Materials and methods Journal of Sustainable Architecture and Civil Engineering 2016/1/14 14 Reagents NaOH (Delta Chem, Czech Re- public), Al(OH)3 (Lachema, Czech Republic) was used in this work as well. The X-ray diffraction analysis of the ma- terials was performed using the X-ray diffractometer Bruker D8 Advance. CuKα radiation and Ni filter were used. The pow- er X-ray diffraction patterns were identified with references available in PDF-2 data base (PDF – 2 International Centre for Dif- fraction Data, 12 Campus Boulevard New- town Square, PA 19073-3273 USA). Chemical compositions of these materials were investigated by X-ray fluorescence spectrometer Bruker X-ray S8 Tiger WD, using rhodium (Rh) tube, anode voltage Ua up to 60 kV, electric current I up to 130 mA. The pressed samples were measured in helium atmosphere. Measurements were performed using SPECTRA Plus QUANT EXPRESS method. The cement paste hydration tempera- ture measurements were performed with 8-channel USB TC-08 Thermocouple Data Logger (temperature measurement range from -270 to +1820 °C). The suspension of biomass bottom ash was treated in hydrothermal way. Zeoliti- zation conducted in the kiln SNOL 200/200 for 1 hour at 100oC. NOTES: Q – silicon dioxide SiO2, CA – calcium oxide CaO, M – magnesium oxide CC – calcium carbonate CaCO3, A – anorthoclase (Na,K)(Si3Al)O8, G – gehlenite Ca2 Al(AlSiO7). Chemical composition, % Portland cement clinker Biomass bottom ashes Amorphous SiO2 waste SiO2 20.61 22.39 71.64 Al2O3 5.45 2.51 11.26 Fe2O3 3.36 2.18 1.31 CaO 63.42 48.97 0.42 SO3 0.80 0.58 - MgO 3.84 8.29 - K2O 1.31 8.69 - Na2O 0.94 0.28 - P2O5 - 5.05 - MnO - 0.35 - TiO2 - 0.33 - BaO - 0.16 - SrO - 0.06 - Rb2O - 0.02 - ZrO2 - 0.04 - ZnO - 0.04 - CuO - 0.02 - Cl - 0.04 - F - - 20.84 Fig. 1 X-Ray diffraction pattern of biomass bottom ashes Table 1 Chemical composition of Portland cement clinker and biomass bottom ashes and amorphous SiO2 waste 15 Journal of Sustainable Architecture and Civil Engineering 2016/1/14 By replacing 10 % of Portland cement to biomass bottom ashes 4×4×16 cm samples from this cement paste were made. It was found that micro and macro cracks opened while these samples were hard- en (Fig 1.). The reason of these defects should be calcium and magnesium oxides hydration reaction (1 and 2). It causes volume expansion, internal stresses and cracks appearance in the solid sample. Therefore, in cement systems biomass bottom ashes cannot be used without additional processing. There are many researches (Liu, 2016; Nagrockiene et al., 2016; Gerengi et al., 2015; Małolepszy et al., 2015), where zeolite as Portland cement substituting materials are widely used. Therefore, in this study the biomass bottom ashes were an attempt to zeolitize. The zeolitization of biomass bottom ashes may be obtained by heating some aluminosilicate ma- terials in the presence of alkaline solutions. The process of zeolitization took place according this scheme: Biomass bottom ashes (CaO, MgO) + Amorphous SiO2 waste Al(OH)3 + H2O + NaOH h Hydrothermal treatment t ≈ 100 °C, 1 h h Biomass bottom ashes + Zeolite + Calcium silicate hydrate It was prepared five samples series (Table 2). In the mixtures No 1 and No 2 only biomass bottom ashes without amorphous SiO2 waste addition was used. In the last three (No 3, No 4 and No 5) mixtures two-aluminosilicate materials was used. (1)CaO +H2O → Ca(OH)2 (2)MgO +H2O → Mg(OH)2 No SiO2, mol Al2O3, mol Na2O, mol H2O, mol The source of SiO2 and Al2O3 Biomass bottom ashes, % Amorphous SiO2 waste, % 1 2 1 2 15 100 - 2 2 1 1 15 100 - 3 2 1 2 15 50 50 4 2 1 2 15 70 30 5 2 1 2 15 80 20 After zeolization of investigated mixture the mineral composition of it was found (Fig. 2). Based on the XRD investigation in mixtures products silicon dioxide, aluminum hydroxide, calcium alumi- num iron silicate hydroxide, calcium carbonate predominates and harmful, not hydrated calcium and magnesium oxides there are. Thus, by using hydrothermal treatment of investigated mixture No1 and No2 the harmful calcium and magnesium oxides was not bonded to compounds. Results and discussion Fig.1 Hardened cement paste sample with biomass bottom ashes (One half of sample 4×4×16cm) Table 2 The quantities of primary materials for zeolitization Journal of Sustainable Architecture and Civil Engineering 2016/1/14 16 Therefore, part of ash was mixed with amorphous SiO2 waste in order to intensify the reaction of harmful calcium and magnesium oxides (Table 2, mixture 3-5). After the examination of zeolitized mixtures, it was found that in all three mixtures zeolite and calcium silicate hydrates were formed. It is important to emphasize that in this case, harmful calcium and magnesium oxides were fully bind into compounds that are harmless to cement hydration. It is likely that using zeolitized prod- ucts of No 3 - No 5 mixtures as a Portland cement replacement material, it should not be caused problems for cement systems during hydration. NOTES: Q – silicon dioxide SiO2, Al – aluminum hydroxide Al(OH)3, CC – calcium carbonate CaCO3, CA – calcium oxide CaO, CF – calcium aluminum iron silicate hydroxide Ca3AlFe(SiO4)(OH)8, A – anorthoclase (Na,K)(Si3Al)O8 NOTES: Q – silicon dioxide SiO2, CC – calcium carbonate CaCO3, Na – zeolite Na2OAl2O31.68SiO2·1.8H2O, CF – calcium aluminum iron silicate hydroxide Ca3AlFe(SiO4)(OH)8, G – gehlenite Ca2Al(AlSiO7), K – calcium silicate hydrate Ca1.5SiO3.5·xH2O Fig. 2 X-Ray diffraction pattern of zeolitized biomass bottom ashes Fig. 3 X-Ray diffraction pattern of zeolitized biomass bottom ashes 17 Journal of Sustainable Architecture and Civil Engineering 2016/1/14 After the X-ray diffraction the hydration temperature of cement paste tests was measured (Fig. 4). It was determined that the main peaks of all investigated Portland cement pastes are higher in the specimens with 5% of zeolitized materials (mixtures 3 – 5). In all investigated cases, Portland cement paste hydration temperature increased compared with the reference specimen tempera- ture. These temperature increases can be explained by filler effect. The physical presence of par- ticles enhanced the hydration of the clinker phases. This effect is called the filler effect. This effect has been attributed to the increase of the number of nucleation sites provided by the extra surface from the particles (Berodier et al., 2012). Investigating specimens with No 4 and No 5 zeolitzed material, hydration temperatures were very similar to the control specimen. By using zeolitzed material No 3, the main reaction of hydration, it was with longer duration than control specimen (from 630 min until 702 min). This indicates that zeolitzed material No 3 slightly delays the hydration of hardened cement paste. _ It was found that the biomass bottom ashes cannot be used directly as Portland cement substi- tuting material due to calcium and magnesium oxides hydration reactions in already hardened samples. In these samples volume increases and cracks occur during hardening process. _ It has been found that in the zeolitization products of biomass bottom ashes with amorphous SiO2 waste mixtures calcium and magnesium oxides are bind in complex compounds of zeolite and calcium silicates hydrates. For this reason, do not cause problems during Portland cement hydration. _ In all investigated cases, Portland cement paste hydration temperature increased compared with the reference specimen temperature. These temperature increases can be explained by filler effect. NOTES: 3, 4, 5 according Table 2. Fig. 4 The dependence of hydration temperature of Portland cement paste on the amount of biomass bottom ash Conclusions Journal of Sustainable Architecture and Civil Engineering 2016/1/14 18 Beltrán, M.G., Agrela, F., Barbudo, A., Ayuso, J., Ramírez, A. Mechanical and durability properties of concretes manufactured with biomass bottom ash and recycled coarse aggregates, Construction and Building Materials, 2014; 72: 231-238. Beltrán, M.G., Barbudo, A., Agrela, F., Jiménez, J.R., de Brito, J. Mechanical performance of bedding mor- tars made with olive biomass bottom ash, Construc- tion and Building Materials, 2016; 112: 699-707. Berodier E., Scrivener K. Impact of filler on hydra- tion kinetics. in 32nd Cement and Concrete Science Conference, Queen’s University Belfast, 2012; 1–4. Cabrera, M., Galvin, A.P., Agrela, F., Carvajal, M.D., Ayuso, J. Characterisation and technical feasibility of using biomass bottom ash for civil infrastruc- tures. Construction and Building Materials, 2014; 58: 234-244. Carrasco, B., Cruz, N., Terrados, J., Corpas, F.A., Pérez, L. An evaluation of bottom ash from plant biomass as a replacement for cement in building blocks. Fuel, 2014; 118: 272-280. da Luz Garcia, M., Sousa-Coutinho, J. Strength and du- rability of cement with forest waste bottom ash. Con- struction and Building Materials, 2013; 41: 897-910. Gerengi, H., Kurtay, M., Durgun, H. (). The effect of zeolite and diatomite on the corrosion of reinforce- ment steel in 1M HCl solution. Results in Physics. 2015; 5: 148-153. Hinojosa, M.J.R., Galvín, A.P., Agrela, F., Perianes, M., Barbudo, A. (. Potential use of biomass bottom ash as alternative construction material: conflictive chemical parameters according to technical regula- tions. Fuel, 2014; 128: 248-259. Liu, Q.W. Influences of concrete mechanical prop- erties when using zeolite powder as admixture. 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Professor Kaunas University of Technology, Faculty of Chemical technology Main research area Building materials Address Radvilenu st. 19, LT-50254 Kaunas, Lithuania Tel. +370-37-300163 E-mail: aras.kantautas@ktu.lt VILIMANTAS VAIČIUKYNAS Lector Aleksandras Stulginskis University, Faculty of Water and Land Management Main research area Drainage construction materials Address Universiteto g.10, LT- 53361 Akademija, Kaunas District Municipality, Lithuania Tel. +370 61434230 E-mail: vilimantas.vaiciukynas@ outlook.com JŪRATĖ KRULIKAUSKAITĖ Master student Kaunas University of Technology, Faculty of Civil Engineering and Architecture Main research area Building materials Address Studentu st. 48, LT-51367 Kaunas, Lithuania Tel. +370 37 300465 E-mail: j.krulikauskaite@gmail. com VALDAS RUDELIS Engineer - technologist Joint-stock company “LIFOSA” Main research area Building materials Address Juodkiškio st. 50, LT-57502 Kėdainiai, Lithuania Tel. +370 61282463 E-mail: v.rudelis@lifosa.com About the authors