STABILIZATION OF WATER-COAL COMPO­SITE FUELS USING CARBON MICRO-NANO­MATERIALS AND AMINO ALCOHOLS
№1 (English)

Як цитувати

Klishchenko, R. (2023). STABILIZATION OF WATER-COAL COMPO­SITE FUELS USING CARBON MICRO-NANO­MATERIALS AND AMINO ALCOHOLS. Український хімічний журнал, 89(9), 3-13. https://doi.org/10.33609/2708-129X.89.09.2023.3-13

Анотація

The study investigated the potential of stabilizing composite water-coal fuel (CWCF) by adding carbon micro-nanomaterials obtained through the plasma-chemical conversion of organics-containing wastewater and amino alcohols. The study focused on systems based on anthracite with a solid phase concentration of 62%. Two amino alcohols, 2-amino-­2-methyl-1-propanol (AMP) and 2-amino-­2-ethyl-1,3-propanediol (AEPD) were used at concentrations of 0.25%, 0.5%, 1%, and 2.5% by weight of CWCF.

The low stability and heterogeneity of coal particle distribution in organic liquids cause an increase in the viscosity of dispersed systems in combined systems. To regulate the rheological properties and stabilize the CWCF, chemicals such as dispersants, plasticizers, and stabili­zers are added. The CWCF 's properties can be improved by using additives such as sodium, calcium, and magnesium lignosulfonates, and naphthalene sulfonic acids. However, these reagents may not provide the desired properties of coal slurries in organomineral environments. Therefore, substitutes for these pro­ducts need to be found.

Amino alcohols are commonly used as dispersants and stabilizers, especially in the production of water-based paints. They are low in cost, low in toxicity, and serve as anti-corrosive agents and pH stabilizers without causing excessive foaming. To strengthen the spatial structure, reactive particles such as carbon micro- and nanomaterials (CNM) can be introduced into the CWCF. Unlike polyelectrolytes and surfactants, CNM particles can have a varying number of active centers depending on the method of formation. By varying the properties of CNMs, it is possible to increase the number of contact centers and form a spatial grid without increasing the concentration of surfactants and polyelectrolytes. This is because contact interactions are activated during grinding, forming a new surface with energy-saturated active centers. As a result, the concentration of the system can be increased, and the calorific value of the fuel can be increased as well. However, the presence of an organic component can render mechanochemical activation ineffective by shielding active sites with large organic molecules. Therefore, identifying the most effective stabilizer reagents and deve­loping technology for their introduction into the dispersed system is a crucial and intricate problem in obtaining CWCF

The study revealed that the ξ potential of anthracite particles is 40–45 mV in the pre­sence of amino alcohols. Sedimentation stabi­lity in the presence of highly dispersed carbon additives increases from 5–6 to 10–14 days, i.e., almost twice. The introduction of highly dispersed carbon leads to an increase in the effective viscosity of the systems and can be recommended for controlling the fluidity of the CWCF. The technical and operational requirements are best met by the CWCF containing 0.25% AMR and 1% highly dispersed carbon.

https://doi.org/10.33609/2708-129X.89.09.2023.3-13
№1 (English)

Посилання

Li Dedi, Liu Jianzhong, Wang Shuangni, Cheng Jun. Study on coal water slurries prepared from coal chemical wastewater and their industrial application. Applied Energy. 2020. 268: 114976. doi. /10.1016/j.apenergy.2020.114976

Makarov A.S., Boruk S.D., Egurnov A.I., Dimitryuk T.N., Klishchenko R.E. Utilization of industrial wastewater in production of coal-water fuel. J. Water Chem Technol. 2014. 36: 180–3.

doi./10.3103/S1063455X14040055.

Liu J.Z., Wang S.N., Li N., Wang Y., Li D.D., Cen K.F. Effects of metal ions inorganic wastewater on coal water slurry and dispersant properties. Energy Fuels. 2019. 33: 7110–7. doi./10.1021/acs.energyfuels.9b01146.

Kuznetsov G.V., Syrodoy S.V., Purin M.V., Zenkov A.V., Gvozdyakov D. V., Larionov K.B. Justifcation of the possibility of car tires recycling as part of coal-water composites. Journal of

Environmental Chemical Engi­nee­ring, 2021. 9: 1–20. doi: 10.1016/j.jece.2020.104741

Lin Song; Liu, Zhentang Zhao, Enlai Qian, Jifa Li, Xiaoliang Zhang, Qiming Ali, Muhammad. A study on the FTIR spectra of pre- and post-explosion coal dust to evaluate the effect of functional groups on dust explosion. Process Safety and Environmental Protection. 2019. 130:30712–30728. doi: 10.1016/j.psep.2019.07.018

Zhang W.B., Luo J., Huang Y., Zhang C., Du L., Guo J. Synthesis of a novel dispersant with topological structure by using humic acid as raw material and its application in coal water slurry preparation. Fuel. 2020. 262: 116576. doi. 10.1016/j.fuel.2019.116576.

Burnett C.L., Bergfeld W.F., Belsito D.V., Klaassen C.D., Marks J.G., Shank R.C., Slaga T. J., Snyder P.W., Andersen F. A. Final Amended Report on Safety Assessment on Aminomethyl Propanol and Aminomethyl Propanediol. International Journal of Toxi­cology. 2009. 28(6): 141–161. doi:10.1177/1091581809350932

Testa C., Zammataro A., Pappalardo A., Sfra­zzetto G. T. Catalysis with carbon nano­par­ticles. RSC Advances. 2019. 9. (47). 27659–27664. doi: 10.1039/c9ra05689k

Zammataro, Agatino; Sfrazzetto G.T. Carbon Dots as Catalysts: A New Class of Nanozymes. Current Organocatalysis. 2020. 7(1). 3–6 doi: 10.2174/2213337206666190702165008

Wang R.K., Ma Q.Q., Zhao Z., Ye X.M., Jin Q., Zhao Z.H. Adsorption of surfactants on coal surfaces in the coking wastewater environ­ment: kinetics and effects on the slurrying properties of coking wastewater-coal slurry. Ind. Eng. Chem. Res. 2019. 58: 12825–34. doi./10.1021/acs.iecr.9b01829.

Kim Hae Jung, Shi Yao, He Junwei, Lee Hy­eon-Hui, Lee Chang-Ha. Adsorption characteristics of CO 2 and CH 4 on dry and wet coal from subcritical to supercritical conditions. Chemical Engineering Journal. 2011. 171(1): 45–53. doi: 10.1016/j.cej.2011.03.035

Oickle A.M., Goertzen S.L., Hopper K.R., Abdalla Y.O., Andreas H.A. Standardization of the Boehm titration: Part II. Method of agitation, effect of filtering and dilute titrant. Carbon. 2010. 48(12): 3313–3322. doi: 10.1016/j.carbon.2009.11.050.

Goncharuk V., Klishchenko R., Kornienko I. Destruction of GT Azo Active Orange Dye in the Flow–Through Plasma–Chemical Reactor. Journal of Water Chemistry and Technology. 2018. 40(4): 185–189. doi: 10.3103/S1063455X1706008X

Maaß S., Rojahn J., Hänsch R., & Kraume M. Automated drop detection using image ana­lysis for online particle size monitoring in multiphase systems. Computers & Chemical Engineering. 2012. 45: 27–37. doi: 10.1016/j.compchemeng.2012.05.014.

Mishchuk N., Kornilovich B., Klishchenko R. pH regulation as a method of intensification soil electroremediation. Colloids and Surfaces A: Physicochem. Eng. Aspects. 2007. 306(1–3): 171–179. doi:10.1016/j.colsurfa.2007.03.014

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