Process and Economic Optimisation of a Milk Processing Plant with Solar Thermal Energy

Computer Aided Chemical Engineering

Volumn 38, Issue , 2016, Pages 1347-1352

  Bühler, Fabian ^a   Nguyen, Tuong Van ^a   Elmegaard, Brian ^a   Modi, Anish ^a  

^a TECHNICAL UNIVERSITY OF DENMARK   (Denmark)

Author keywords

Economic Optimisation; Milk Powder; Process Integration; Solar Thermal

Indexed keywords

EID: 84994323888     PISSN: 15707946     EISSN: None     Source Type: Book Series    
DOI: 10.1016/B978-0-444-63428-3.50229-0     Document Type: Chapter

References (21)

1. Atkins, M.J., Walmsley, M.R.W., Morrison, A.S., Integration of solar thermal for improved energy efficiency in low-temperature-pinch industrial processes. Energy 35:5 (2010), 1867–1873.
2. Bejan, A., Tsatsaronis, G., Moran, M., Thermal design and optimization, 1996, Wiley-Interscience.
3. Danish Energy Agency, Energy Statistics 2012. Tech. rep, 2014.
4. Dansk Energi Analyse A/S, IDAs Klimaplan 2050: Energibesparelser i erhvervslivet. Tech. rep, 2009, Danish Society of Engineers (IDA), Copenhagen.
5. Duffie, J.A., Beckman, W.A., Solar Engineering of Thermal Processes, fourth edi Edition, 2013, Wiley.
6. Incropera, F., Fundamentals of heat and mass transfer, 2007, John Wiley and Sons.
7. Linnhoff, B., Hindmarsh, E., The pinch design method for heat exchanger networks. Chemical Engineering Science 38:5 (jan 1983), 745–763.
8. Nemet, A., Klemeš, J.J., Varbanov, P.S., Kravanja, Z., Methodology for maximising the use of renewables with variable availability. Energy 44:1 (2012), 29–37.
9. Nemet, A., Kravanja, Z., Klemeš, J.J., Integration of solar thermal energy into processes with heat demand. Clean Technologies and Environmental Policy 14:3 (2012), 453–463.
10. Perez, R., A new simplified version of the Perez diffuse irradiance model for titled surfaces. Solar Energy 39:3 (1987), 221–231.
11. Perez, R., Ineichen, P., Seals, R., Michalsky, J., Stewart, R., Modeling daylight availability and irradiance components from direct and global irradiance. Solar Energy 44:5 (1990), 271–289.
12. Perez, R., Stewart, R., Solar irradiance conversion models. Solar Cells 18:3-4 (sep 1986), 213–222.
13. Quaschning, V., Simulation der Abschattungsverluste bei solarelektrischen Systemen, 1996, Verlag Dr. Köster, Berlin.
14. Quijera, J.A., Alriols, M.G., Labidi, J., Integration of a solar thermal system in a dairy process. Renewable Energy 36:6 (jun 2011), 1843–1853.
15. Quijera, J.A., Alriols, M.G., Labidi, J., Usage of solar energy in an industrial process. Chemical Engineering Transactions 25:August (2011), 875–880.
16. Reda, I., Andreas, A., Solar position algorithm for solar radiation applications. Solar Energy 76:5 (2004), 577–589.
17. Schnitzer, H., Brunner, C., Gwehenberger, G., Minimizing greenhouse gas emissions through the application of solar thermal energy in industrial processes. Journal of Cleaner Production 15:13-14 (2007), 1271–1286.
18. Turton, R., Bailie, R.C., Whiting, W.B., Shaeiwitz, J.a., Bhattacharyya, D., Analysis, Synthesis, and Design of Chemical Processes, 40, 2001.
19. Walmsley, T.G., Walmsley, M.R., Tarighaleslami, A.H., Atkins, M.J., Neale, J.R., Integration options for solar thermal with low temperature industrial heat recovery loops. Energy, 2015, 1–9.
20. Walmsley, T.G., Walmsley, M.R.W., Atkins, M.J., Neale, J.R., Integration of industrial solar and gaseous waste heat into heat recovery loops using constant and variable temperature storage. Energy 75 (2014), 53–67.
21. Yee, T., Grossmann, I., Simultaneous optimization models for heat integrationII. Heat exchanger network synthesis. Computers & Chemical Engineering 14:10 (1990), 1165–1184.