Bread dough aeration dynamics during pressure step-change mixing: Studies by X-ray tomography, dough density and population balance modelling

L. Trinh; T. Lowe; G. M. Campbell; P. J. Withers; P. J. Martin

doi:10.1016/j.ces.2013.06.053

Bread dough aeration dynamics during pressure step-change mixing: Studies by X-ray tomography, dough density and population balance modelling

L. Trinh, T. Lowe, G. M. Campbell, P. J. Withers, P. J. Martin

Research output: Contribution to journal › Article › peer-review

Abstract

Industrial bread dough mixing often involves a period of mixing under high headspace pressure to enhance oxygen availability, followed by a period of partial vacuum to favourably manipulate the final bubble size distribution. This paper presents the results of a study using X-ray tomography to measure the gas bubble size distribution in dough samples over the course of a pressure step-change mix. The first objective of the current work was to measure bubble size distributions at points throughout a pressure-step dough mixing process using a non-synchrotron X-ray source. The second objective was to fit a simplified population balance model to the measured size distributions. The third objective was to use the data set and fitted model to explore the validity of the assumptions within the simplified model and to consolidate understanding of underlying aeration and mixing phenomena and the resultant process dynamics. It was found that the dynamic changes in the bubble size distribution of a bread dough during pressure-step mixing could be accurately measured using a laboratory X-ray source. The response of the cumulative dough voidage to a pressure-step change during mixing could be reproduced very well using the simplified population balance model (which assumes: all entrained bubbles are the same size, no bubble break-up or coalescence, and likelihood of bubble disentrainment is proportional to bubble volume). The measured response of the bubble number density and mean volume agreed reasonably well with that predicted by the simplified model (with parameters fitted to only cumulative voidage data). It is demonstrated that the decrease in number density following a pressure step-decrease is much more short-lived than the decrease in size which is permanent. © 2013 Elsevier Ltd.

Original language	English
Pages (from-to)	470-477
Number of pages	7
Journal	Chemical Engineering Science
Volume	101
DOIs	https://doi.org/10.1016/j.ces.2013.06.053
Publication status	Published - 20 Sept 2013

Keywords

Aeration
Bread dough
Bubble
Food processing
Mixing
Population balance

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10.1016/j.ces.2013.06.053

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Structural Evolution across multiple time and length scales
Withers, P. (PI), Cartmell, S. (CoI), Cernik, R. (CoI), Derby, B. (CoI), Eichhorn, S. (CoI), Freemont, A. (CoI), Hollis, C. (CoI), Mummery, P. (CoI), Sherratt, M. (CoI), Thompson, G. (CoI) & Watts, D. (CoI)
1/06/11 → 31/05/16
Project: Research

Cite this

@article{83e68d6c9f0a46268b08c644f4217fae,

title = "Bread dough aeration dynamics during pressure step-change mixing: Studies by X-ray tomography, dough density and population balance modelling",

abstract = "Industrial bread dough mixing often involves a period of mixing under high headspace pressure to enhance oxygen availability, followed by a period of partial vacuum to favourably manipulate the final bubble size distribution. This paper presents the results of a study using X-ray tomography to measure the gas bubble size distribution in dough samples over the course of a pressure step-change mix. The first objective of the current work was to measure bubble size distributions at points throughout a pressure-step dough mixing process using a non-synchrotron X-ray source. The second objective was to fit a simplified population balance model to the measured size distributions. The third objective was to use the data set and fitted model to explore the validity of the assumptions within the simplified model and to consolidate understanding of underlying aeration and mixing phenomena and the resultant process dynamics. It was found that the dynamic changes in the bubble size distribution of a bread dough during pressure-step mixing could be accurately measured using a laboratory X-ray source. The response of the cumulative dough voidage to a pressure-step change during mixing could be reproduced very well using the simplified population balance model (which assumes: all entrained bubbles are the same size, no bubble break-up or coalescence, and likelihood of bubble disentrainment is proportional to bubble volume). The measured response of the bubble number density and mean volume agreed reasonably well with that predicted by the simplified model (with parameters fitted to only cumulative voidage data). It is demonstrated that the decrease in number density following a pressure step-decrease is much more short-lived than the decrease in size which is permanent. {\textcopyright} 2013 Elsevier Ltd.",

keywords = "Aeration, Bread dough, Bubble, Food processing, Mixing, Population balance",

author = "L. Trinh and T. Lowe and Campbell, {G. M.} and Withers, {P. J.} and Martin, {P. J.}",

note = "Export Date: 1 September 2013 Source: Scopus CODEN: CESCA Language of Original Document: English Correspondence Address: Martin, P.J.; University of Manchester, School of Chemical Engineering and Analytical Science, Manchester M13 9PL, United Kingdom; email: [email protected] References: APV Corporation Ltd, 1992. Dough mixing (UK Patent GB 2 264 623A, HMSO, London, UK)Babin, P., Della Valle, G., Dendievel, R., Lassoued, N., Salvo, L., Mechanical properties of bread crumbs from tomography based Finite Element simulations (2005) J. Mater. Sci., 40, pp. 5867-5873; Babin, P., Della Valle, G., Chiron, H., Cloetens, P., Hoszowska, J., Pernot, P., R{\'e}guerre, A.L., Dendievel, R., Fast X-ray tomography analysis of bubble growth and foam setting during breadmaking (2006) J. Cereal Sci., 43, pp. 393-397; Bajd, F., Ser{\v s}a, I., Continuous monitoring of dough fermentation and bread baking by magnetic resonance microscopy (2011) Magn. Reson. Imaging, 29, pp. 434-442; Baker, J.C., Mize, M.D., Mixing doughs in vacuum and in the presence of various gases (1937) Cereal Chem., 14, pp. 721-734; Baker, J.C., Mize, M.D., The origin of the gas cells in bread dough (1941) Cereal Chem., 19, pp. 84-94; Bellido, G.G., Scanlon, M.G., Page, J.H., Hallgrimsson, B., The bubble size distribution in wheat flour dough (2006) Food Res. Int., 39, pp. 1058-1066; Bonny, J.M., Rouille, J., Della Valle, G., Devaux, M.-F., Douliez, J.-P., Renou, J.-P., Dynamic magnetic resonance microscopy of flour dough fermentation (2004) Magn. Reson. Imaging, 22, pp. 395-401; Campbell, G.M., Rielly, C.D., Fryer, P.J., Sadd, P.A., The measurement of bubble size distributions in an opaque food fluid (1991) Food Bioprod. Process., 69, pp. 67-76; Campbell, G.M., Herrero Sanchez, R., Payo Rodriguez, R., Merchan, M.L., Measurement of dynamic dough density, and the effect of surfactants and flour type on aeration during mixing and gas retention during proving (2001) Cereal Chem., 78, pp. 272-277; Campbell, G.M., Rielly, C.D., Fryer, P.J., Sadd, P.A., Aeration of bread dough during mixing: the effect of mixing dough at reduced pressure (1998) Cereal Foods World, 43 (3), pp. 163-167; Campbell, G.M., Shah, P., Entrainment and disentrainment of air during bread dough mixing and their scale-up of dough mixers (1999) Bubbles in Food, pp. 11-20. , Eagan Press, Minnesota, USA, G.M. Campbell, C. Webb, S.S. Pandiella, K. Niranjan (Eds.); Cauvain, S.P., Young, L.S., (2006) Baked Products, pp. 120-147. , Blackwell, Oxford, UK; Cents, A.H.G., Brilman, D.W.F., Versteeg, G.F., Wijnstra, P.J., Regtien, P.P.L., Measuring bubble, drop and particle sizes in multiphase systems with ultrasound (2004) AIChE J., 50, pp. 2750-2762; Chamberlain, N., Collins, T.H., The Chorleywood Bread Process: the importance of air as a dough ingredient (1977) FMBRA Bull., 4, pp. 122-132; Chin, N.L., Martin, P.J., Campbell, G.M., Aeration during bread dough mixing. I. Effect of direction and size of a pressure step-change during mixing on the turnover of gas (2004) Food Bioprod. Process., 82, pp. 261-267; Elmehdi, H.M., Page, J.H., Scanlon, M.G., Monitoring dough fermentation using acoustic waves (2003) Food Bioprod. Process., 81, pp. 217-223; Martin, P., Controlling the breadmaking process: the role of bubbles in bread (2004) Cereal Foods World, 49, pp. 72-75; Martin, P.J., Chin, N.L., Campbell, G.M., Aeration during bread dough mixing II. A population balance model of aeration (2004) Food Bioprod. Process., 82, pp. 268-281; Martin, P.J., Chin, N.L., Campbell, G.M., Morrant, C.J., Aeration during bread dough mixing. III. Effect of scale-up (2004) Food Bioprod. Process., 82, pp. 282-290; Press, W.H., Flannery, B.P., Teukolsky, S.A., Vetterling, W.T., (1986) Numerical Recipes: The Art of Scientific Computing, pp. 529-538. , Cambridge University Press, UK, Cambridge; Rautenbach, C., Mudde, R.F., Yang, X., Melaaen, M.C., Halvorsen, B.M., A comparative study between electrical capacitance tomography and time-resolved X-ray tomography (2013) Flow Meas. Instrum., 30, pp. 34-44; Romano, A., Cavella, S., Toraldo, G., Masi, P., 2D structural imaging study of bubble evolution during leavening (2013) Food Res. Int., 50, pp. 324-329; Shah, P., Campbell, G.M., McKee, S.L., Rielly, C.D., Proving of bread dough: modelling the growth of individual bubbles (1998) Food Bioprod. Process., 76, pp. 73-79; Spooner, T.F., (1999), Controlled atmosphere. Baking and Snack, February, pp. 96-102Stevenson, R., Harrison, S.T.L., Mantle, M.D., Sederman, A.J., Moraczewski, T.L., Johns, M.L., Analysis of partial suspension in stirred mixing cells using both MRI and ERT (2010) Chem. Eng. Sci., 65, pp. 1385-1393; Turbin-Orger, A., Boller, E., Chaunier, L., Chiron, H., Della Valle, G., R{\'e}guerre, A.-L., Kinetics of bubble growth in wheat flour dough during proofing studied by computed X-ray micro-tomography (2012) J. Cereal Sci., 56, pp. 676-683",

year = "2013",

month = sep,

day = "20",

doi = "10.1016/j.ces.2013.06.053",

language = "English",

volume = "101",

pages = "470--477",

journal = "Chemical Engineering Science",

issn = "0009-2509",

publisher = "Elsevier BV",

}

TY - JOUR

T1 - Bread dough aeration dynamics during pressure step-change mixing: Studies by X-ray tomography, dough density and population balance modelling

AU - Trinh, L.

AU - Lowe, T.

AU - Campbell, G. M.

AU - Withers, P. J.

AU - Martin, P. J.

N1 - Export Date: 1 September 2013 Source: Scopus CODEN: CESCA Language of Original Document: English Correspondence Address: Martin, P.J.; University of Manchester, School of Chemical Engineering and Analytical Science, Manchester M13 9PL, United Kingdom; email: [email protected] References: APV Corporation Ltd, 1992. Dough mixing (UK Patent GB 2 264 623A, HMSO, London, UK)Babin, P., Della Valle, G., Dendievel, R., Lassoued, N., Salvo, L., Mechanical properties of bread crumbs from tomography based Finite Element simulations (2005) J. Mater. Sci., 40, pp. 5867-5873; Babin, P., Della Valle, G., Chiron, H., Cloetens, P., Hoszowska, J., Pernot, P., Réguerre, A.L., Dendievel, R., Fast X-ray tomography analysis of bubble growth and foam setting during breadmaking (2006) J. Cereal Sci., 43, pp. 393-397; Bajd, F., Serša, I., Continuous monitoring of dough fermentation and bread baking by magnetic resonance microscopy (2011) Magn. Reson. Imaging, 29, pp. 434-442; Baker, J.C., Mize, M.D., Mixing doughs in vacuum and in the presence of various gases (1937) Cereal Chem., 14, pp. 721-734; Baker, J.C., Mize, M.D., The origin of the gas cells in bread dough (1941) Cereal Chem., 19, pp. 84-94; Bellido, G.G., Scanlon, M.G., Page, J.H., Hallgrimsson, B., The bubble size distribution in wheat flour dough (2006) Food Res. Int., 39, pp. 1058-1066; Bonny, J.M., Rouille, J., Della Valle, G., Devaux, M.-F., Douliez, J.-P., Renou, J.-P., Dynamic magnetic resonance microscopy of flour dough fermentation (2004) Magn. Reson. Imaging, 22, pp. 395-401; Campbell, G.M., Rielly, C.D., Fryer, P.J., Sadd, P.A., The measurement of bubble size distributions in an opaque food fluid (1991) Food Bioprod. Process., 69, pp. 67-76; Campbell, G.M., Herrero Sanchez, R., Payo Rodriguez, R., Merchan, M.L., Measurement of dynamic dough density, and the effect of surfactants and flour type on aeration during mixing and gas retention during proving (2001) Cereal Chem., 78, pp. 272-277; Campbell, G.M., Rielly, C.D., Fryer, P.J., Sadd, P.A., Aeration of bread dough during mixing: the effect of mixing dough at reduced pressure (1998) Cereal Foods World, 43 (3), pp. 163-167; Campbell, G.M., Shah, P., Entrainment and disentrainment of air during bread dough mixing and their scale-up of dough mixers (1999) Bubbles in Food, pp. 11-20. , Eagan Press, Minnesota, USA, G.M. Campbell, C. Webb, S.S. Pandiella, K. Niranjan (Eds.); Cauvain, S.P., Young, L.S., (2006) Baked Products, pp. 120-147. , Blackwell, Oxford, UK; Cents, A.H.G., Brilman, D.W.F., Versteeg, G.F., Wijnstra, P.J., Regtien, P.P.L., Measuring bubble, drop and particle sizes in multiphase systems with ultrasound (2004) AIChE J., 50, pp. 2750-2762; Chamberlain, N., Collins, T.H., The Chorleywood Bread Process: the importance of air as a dough ingredient (1977) FMBRA Bull., 4, pp. 122-132; Chin, N.L., Martin, P.J., Campbell, G.M., Aeration during bread dough mixing. I. Effect of direction and size of a pressure step-change during mixing on the turnover of gas (2004) Food Bioprod. Process., 82, pp. 261-267; Elmehdi, H.M., Page, J.H., Scanlon, M.G., Monitoring dough fermentation using acoustic waves (2003) Food Bioprod. Process., 81, pp. 217-223; Martin, P., Controlling the breadmaking process: the role of bubbles in bread (2004) Cereal Foods World, 49, pp. 72-75; Martin, P.J., Chin, N.L., Campbell, G.M., Aeration during bread dough mixing II. A population balance model of aeration (2004) Food Bioprod. Process., 82, pp. 268-281; Martin, P.J., Chin, N.L., Campbell, G.M., Morrant, C.J., Aeration during bread dough mixing. III. Effect of scale-up (2004) Food Bioprod. Process., 82, pp. 282-290; Press, W.H., Flannery, B.P., Teukolsky, S.A., Vetterling, W.T., (1986) Numerical Recipes: The Art of Scientific Computing, pp. 529-538. , Cambridge University Press, UK, Cambridge; Rautenbach, C., Mudde, R.F., Yang, X., Melaaen, M.C., Halvorsen, B.M., A comparative study between electrical capacitance tomography and time-resolved X-ray tomography (2013) Flow Meas. Instrum., 30, pp. 34-44; Romano, A., Cavella, S., Toraldo, G., Masi, P., 2D structural imaging study of bubble evolution during leavening (2013) Food Res. Int., 50, pp. 324-329; Shah, P., Campbell, G.M., McKee, S.L., Rielly, C.D., Proving of bread dough: modelling the growth of individual bubbles (1998) Food Bioprod. Process., 76, pp. 73-79; Spooner, T.F., (1999), Controlled atmosphere. Baking and Snack, February, pp. 96-102Stevenson, R., Harrison, S.T.L., Mantle, M.D., Sederman, A.J., Moraczewski, T.L., Johns, M.L., Analysis of partial suspension in stirred mixing cells using both MRI and ERT (2010) Chem. Eng. Sci., 65, pp. 1385-1393; Turbin-Orger, A., Boller, E., Chaunier, L., Chiron, H., Della Valle, G., Réguerre, A.-L., Kinetics of bubble growth in wheat flour dough during proofing studied by computed X-ray micro-tomography (2012) J. Cereal Sci., 56, pp. 676-683

PY - 2013/9/20

Y1 - 2013/9/20

N2 - Industrial bread dough mixing often involves a period of mixing under high headspace pressure to enhance oxygen availability, followed by a period of partial vacuum to favourably manipulate the final bubble size distribution. This paper presents the results of a study using X-ray tomography to measure the gas bubble size distribution in dough samples over the course of a pressure step-change mix. The first objective of the current work was to measure bubble size distributions at points throughout a pressure-step dough mixing process using a non-synchrotron X-ray source. The second objective was to fit a simplified population balance model to the measured size distributions. The third objective was to use the data set and fitted model to explore the validity of the assumptions within the simplified model and to consolidate understanding of underlying aeration and mixing phenomena and the resultant process dynamics. It was found that the dynamic changes in the bubble size distribution of a bread dough during pressure-step mixing could be accurately measured using a laboratory X-ray source. The response of the cumulative dough voidage to a pressure-step change during mixing could be reproduced very well using the simplified population balance model (which assumes: all entrained bubbles are the same size, no bubble break-up or coalescence, and likelihood of bubble disentrainment is proportional to bubble volume). The measured response of the bubble number density and mean volume agreed reasonably well with that predicted by the simplified model (with parameters fitted to only cumulative voidage data). It is demonstrated that the decrease in number density following a pressure step-decrease is much more short-lived than the decrease in size which is permanent. © 2013 Elsevier Ltd.

AB - Industrial bread dough mixing often involves a period of mixing under high headspace pressure to enhance oxygen availability, followed by a period of partial vacuum to favourably manipulate the final bubble size distribution. This paper presents the results of a study using X-ray tomography to measure the gas bubble size distribution in dough samples over the course of a pressure step-change mix. The first objective of the current work was to measure bubble size distributions at points throughout a pressure-step dough mixing process using a non-synchrotron X-ray source. The second objective was to fit a simplified population balance model to the measured size distributions. The third objective was to use the data set and fitted model to explore the validity of the assumptions within the simplified model and to consolidate understanding of underlying aeration and mixing phenomena and the resultant process dynamics. It was found that the dynamic changes in the bubble size distribution of a bread dough during pressure-step mixing could be accurately measured using a laboratory X-ray source. The response of the cumulative dough voidage to a pressure-step change during mixing could be reproduced very well using the simplified population balance model (which assumes: all entrained bubbles are the same size, no bubble break-up or coalescence, and likelihood of bubble disentrainment is proportional to bubble volume). The measured response of the bubble number density and mean volume agreed reasonably well with that predicted by the simplified model (with parameters fitted to only cumulative voidage data). It is demonstrated that the decrease in number density following a pressure step-decrease is much more short-lived than the decrease in size which is permanent. © 2013 Elsevier Ltd.

KW - Aeration

KW - Bread dough

KW - Bubble

KW - Food processing

KW - Mixing

KW - Population balance

U2 - 10.1016/j.ces.2013.06.053

DO - 10.1016/j.ces.2013.06.053

M3 - Article

SN - 0009-2509

VL - 101

SP - 470

EP - 477

JO - Chemical Engineering Science

JF - Chemical Engineering Science

ER -

Bread dough aeration dynamics during pressure step-change mixing: Studies by X-ray tomography, dough density and population balance modelling

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Structural Evolution across multiple time and length scales

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