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Biomass Conversion and Biorefinery

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01.04.2017 | Original Article

Identification of acoustic fields in aqueous biomass solutions of banana waste pretreated by power ultrasound

verfasst von: H. A. Villa-Vélez, M. L. Cornelio, J. L. G. Corrêa, J. Telis-Romero

Erschienen in: Biomass Conversion and Biorefinery | Ausgabe 1/2018

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Abstract

High-intensity ultrasound is a technology used to improve the performance of processes in the chemical, pharmaceutical, biomass pretreatment, and food industries. However, few studies were described in the literature to comprehend the acoustic wave propagation in the material and their efficiency in the process. Thus, this study aims to determine the acoustic fields of aqueous biomass solutions from flower stalk banana using the calorimetric method and a determined sonotrode position. These tests were conducted at temperatures from 0 to 60 °C and ultrasound power from 120, 160, to 320 W. Also, the specific heat capacity and density of the solution were determined experimentally as a function of the solution concentration (0.040 to 0.100 g biomass mL⁻¹), pH (3, 5, and 7), and temperature. The position of the thermocouple was maintained at 1 cm from the sonotrode, and the ultrasound frequency was 24 kHz. The methods and results presented in this study can be used to reproduce acoustic field calculations in aqueous biomass solutions, aiming the construction of acoustic processor systems.

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Langan P, Gnanakaran S, Rector KD, Pawley N, Fox DT, Cho DW et al (2011) Exploring new strategies for cellulosic biofuels production. Energy Environment Sci 4:3820–3833CrossRef

Velásquez-Arredondo HI, de Oliveira JS, Benjumea P (2012) Exergy efficiency analysis of chemical and biochemical stages involved in liquid biofuels production processes. Energy 41:138–145CrossRef

Hoogwijk M, Faaij A, van de Broek R, Berndes G, Gielen D, Turkenburg W (2003) Exploration of the ranges of the global potential of biomass for energy. Biomass Bioenergy 25:119–133CrossRef

Villa-Vélez HA, Váquiro HA, Telis-Romero J (2015) The effect of power-ultrasound on the pretreatment of acidified aqueous solutions of banana flower-stalk: structural, chemical and statistical analysis. Ind Crop Prod 66:52–61CrossRef

Hammond JB, Egg R, Diggins D, Coble CG (1996) Alcohol from bananas. Bioresour Technol 56:125–130CrossRef

Tock JY, Lai CL, Lee KT, Tan KT, Bhatia S (2010) Banana biomass as potential renewable energy resource: a Malaysian case study. Renew Sust Energ Rev 14:798–805CrossRef

Olsen C, Arantes V, Saddler J (2012) The use of predictive models to optimize sugar recovery obtained after the steam pre-treatment of softwoods. Biofuels Bioprod Biorefin 6:534–548CrossRef

Xiong Q, Kong S-C, Passalacqua A (2013) Development of a generalized numerical framework for simulating biomass fast pyrolysis in fluidized-bed reactors. Chem Eng Sci 99:305–313CrossRef

Xiong Q, Aramideh S, Kong S-C (2013) Modeling effects of operating conditions on biomass fast pyrolysis in bubbling fluidized bed reactors. Energy Fuel 27:5948–5956CrossRef

10.

Kumar P, Barret DM, Delwiche MJ, Stroeve P (2011) Pulsed electric field pretreatment of switchgrass and wood chip species for biofuel production. Ind Eng Chem Res 50:10996–11001CrossRef

11.

Luo J, Fang Z, Smith RL (2014) Ultrasound-enhanced conversion of biomass to biofuels. Prog Energ Combust Sci 41:56–93CrossRef

12.

Sawant SS, Anil AC, Krishnamurthy V, Gaonkar C, Kolwalkar J, Khandeparker L et al (2008) Effect of hydrodynamic cavitation on zooplankton: a tool for disinfection. Biochem Eng J 42:320–328CrossRef

13.

Pinjari DV, Pandit AB (2010) Cavitation milling of natural cellulose to nanofibrils. Ultrason Sonochem 17:845–852CrossRef

14.

Berlan J, Mason TJ (1992) Sonochemistry: from research laboratories to industrial plants. Ultrasonics 30:203–212CrossRef

15.

Cárcel JA, Benedito J, Mulet A (2012) Food process innovation through new technologies: use of ultrasound. J Food Eng 110:200–207CrossRef

16.

Merouani S, Hamdaoui O, Rezgui Y, Guemini M (2014) Energy analysis during bubble oscillations: relationship between bubble energy and sonochemical parameters. Ultrasonics 54:227–232CrossRef

17.

Sasmal S, Goud VV, Mohanty K (2012) Ultrasound assisted lime pretreatment of lignocellulosic biomass toward bioethanol production. Energy Fuel 26:3777–3784CrossRef

18.

Park ND, Helle SS, Thring RW (2012) Combined alkaline and ultrasound pre-treatment of thickened pulp mill waste activated sludge for improved anaerobic digestion. Biomass Bioenergy 46:750–756CrossRef

19.

Khanel SK, Montabo M, Leeuwen J, Srinivasan G, Grewell D (2007) Ultrasound enhanced glucose release from corn in ethanol plants. Biotechnol Bioeng 98:978–985CrossRef

20.

Jiang J, Zhao Q, Wei L, Wang K, Lee D-J (2011) Degradation and characteristic changes of organic matter in sewage sludge, using microbial fuel cell with ultrasound pretreatment. Bioresour Technol 102:272–277CrossRef

21.

Esfahani MR, Azin M (2012) Pretreatment of sugar cane bagasse by ultrasound energy and dilute acid. Asia Pac J Chem Eng 7:274–278CrossRef

22.

Rokhina EV, Repo E, Virkutyte J (2010) Comparative kinetic analysis of silent and ultrasound-assisted catalytic wet peroxide oxidation of phenol. Ultrason Sonochem 17:541–546CrossRef

23.

Yunus R, Salleh SF, Abdullah N, Biak DRA (2010) Effect of ultrasonic pre-treatment on low temperature acid hydrolysis of oil palm empty fruit bunch. Bioresour Technol 101:9792–9796CrossRef

24.

Raso J, Mañas P, Pagán R, Sala FJ (1999) Influence of different factors on the output power transferred medium by ultrasound. Ultrason Sonochem 5:157–162CrossRef

25.

Xiong Q, Xu F, Ramirez E, Pannala S, Daw CS (2016) Modeling the impact of bubbling bed hydrodynamics on tar yield and its fluctuations during biomass fast pyrolysis. Fuel 164:11–17CrossRef

26.

Toma M, Fukutomi S, Asakura Y, Koda S (2011) A calorimetric study of energy conversion efficiency of a sonochemical reactor at 500 kHz for organic solvents. Ultrason Sonochem 18:197–208CrossRef

27.

Hu Y, Zhang Z, Yang C (2008) Measurement of hydroxyl radical production in ultrasonics aqueous solutions by a novel chemiluminescence method. Ultrason Sonochem 15:665–672CrossRef

28.

Lin S, Xu L (2012) Study on the radial vibration and acoustic field of an isotropic circular ring radiator. Ultrasonics 52:103–110CrossRef

29.

Moholkar VS, Sable SP, Pandit AB (2000) Mapping the cavitation intensity in an ultrasonic bath using the acoustic emission. AICHE J 46:684–695CrossRef

30.

Kumar A, Gogate PR, Pandit AB (2007) Mapping the efficacy of new designs for large scale sonochemical reactors. Ultrason Sonochem 14:538–544CrossRef

31.

Margulis MA, Maximenko NA (1991) The influence of ultrasound on oscilating reactions. Appendix: measurement of ultrasound absorbed power (calorimetric method). In: Mason TJ (ed) Advances in sonochemistry, 2nd edn. JAI Press Inc, London, pp 1–328

32.

Koda S, Kimura T, Kondo T, Mitone H (2003) A standard method to calibrate sonochemical efficiency of an individual reaction system. Ultrason Sonochem 10:149–156CrossRef

33.

AOAC (1997) Official methods of analysis international. Association of Offical Analytical Chemists International, Gaithersburg

34.

Mason TJ, Lorimer JP, Bates DM (1992) Quantifying sonochemistry: casting some light on a “black art”. Ultrasonics 30:40–42CrossRef

35.

Cevik A (2007) Unified formulation for web crippling strength of cold-formed steel sheeting using stepwise regression. J Constr Steel Res 63:1305–1316CrossRef

36.

Goodenough AE, Hart AG, Stafford R (2012) Regression with empirical variable selection: description of a new method and application to ecological datasets. PLoS One 7:1–10CrossRef

37.

Chen Y, Shi R, Shu S, Gao W (2013) Ensemble and enhanced PM₁₀ concentration forecast model based on stepwise regression and wavelet analysis. Atmos Environ 74:346–359CrossRef

38.

Castell-Palou A, Váquiro HA, Cárcel JA, Rosselló C, Femenia A, Simal S (2012) Mathematical modeling of moisture distribution and kinetics in cheese drying. Dry Technol 30:1247–1255CrossRef

39.

Korosi G, Kovats ES (1981) Density and surface tension of 83 organic liquids. J Chem Eng Data 26:323–332CrossRef

40.

Petošic A, Svilar D, Ivancevic B (2011) Comparison of measured acoustic power results gained by using three different methods on an ultrasonic low-frequency device. Ultrason Sonochemistry 18:567–576CrossRef

41.

Villa-Vélez HA, Váquiro HA, Lopes-Filho JF, Telis VRN, Telis-Romero J (2015) Study of the specific heat capacity of biomass from banana waste for application in the second-generation ethanol industry. Environ Prog Sustain Energy 34:1221–1228CrossRef

42.

Brotchie F, Grieser F, Ashokkumar M (2009) Effect of power and frequency on bubble-size distributions in acoustic cavitation. Phys Rev Let 102:084302-084301–084302-084304CrossRef

43.

Hauptmann M, Struyf H, Mertens P, Heyns M, De Gendt S, Glorieux C et al (2013) Towards an understanding and control of cavitation activity in 1 MHz ultrasound fileds. Ultrason Sonochemistry 20:77–88CrossRef

44.

Pantea C, Osterhoudt CF, Sinha DN (2013) Determination of acoustical nonlinear parameter β of water using the finite amplitude method. Ultrasonics 53:1012–1019CrossRef

Titel: Identification of acoustic fields in aqueous biomass solutions of banana waste pretreated by power ultrasound
verfasst von: H. A. Villa-Vélez
M. L. Cornelio
J. L. G. Corrêa
J. Telis-Romero
Publikationsdatum: 01.04.2017
Verlag: Springer Berlin Heidelberg
Erschienen in: Biomass Conversion and Biorefinery / Ausgabe 1/2018
Print ISSN: 2190-6815
Elektronische ISSN: 2190-6823
DOI: https://doi.org/10.1007/s13399-017-0256-8

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