Process and utility systems integration and optimisation for ultra-low energy milk powder production

Walmsley, Timothy Gordon; Atkins, Martin John; Walmsley, Michael R.W.; Philipp, Matthias; Peesel, Ron-Hendrik

doi:10.1016/j.energy.2017.04.142

Cited by 24 publications

(14 citation statements)

References 28 publications

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“…The specific energy use for scenario 3 was found to be 0.86 MWh per ton milk powder and 1.06 MWh per ton milk powder for scenario 4. These values are slightly higher than the thermal energy use of 0.59 MWh and electric energy use of 0.15 MWh per ton of milk found for the best configuration only considering the production in [15]. The best configuration was more advanced and also considered improvements to the spray dryer, reverse osmosis for pre-concentration and direct steam injection for pasteurization.…”

Section: Discussionmentioning

confidence: 78%

“…A factory to produce milk powder with an ultra-low energy input was studied by Walmsley et al [15]. Their approach applied a total site analysis, the implementation of evaporators with mechanical vapour recompression (MVR) and excess heat recovery of the drying air.…”

Section: Introductionmentioning

confidence: 99%

“…While many studies address strategies to lower fuel related CO2-emissions in industries, the accomplishment of this goal through electrification is not sufficiently studied. Research has focused on energy efficiency and fuel substitution at industrial sites [9,15,16] or on system studies [3,5,6] for the electrification of a country, but little work has been performed on implementing an optimised all-electric production site.…”

Section: Introductionmentioning

confidence: 99%

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A comparative assessment of electrification strategies for industrial sites: Case of milk powder production

et al. 2019

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Denmark has the ambitious plan of being independent from fossil fuels by 2050 and to run the entire energy system based on renewable energy sources. One of the most likely scenarios is a bigger deployment of wind farms and a massive electrification of the industry and transportation sectors. In 2016, the industry sector accounted for 20 % of the final energy use, which was by more than 50 % covered directly with fossil fuels. Electrification is a promising way for decarbonizing this sector but it will require significant economic investments and changes of the infrastructures. In this work, several strategies for electrifying industrial processes, based on the integration of heat pumps and electric heaters are presented. They were compared using energy, exergy, economic and environmental performance indicators. The production of milk powder was taken as a case study, as current factories are energy-intensive and require high-temperature heat generated by natural gas combustion. The highest energy efficiency and lowest exergy destruction was found for a system using a central heat pump system, with energy savings of 65 %. The implementation of decentralised heat pumps that exchange heat between process streams and electric heaters, results in smaller reductions of only 56 %. These two systems are likely profitable based on the energy price forecasts from 2020, but the decentral system allows for a gradual implementation of the most cost-effective measures. Highlights• Strategies for electrification of industrial sites to reduce fossil fuel use • Energy, exergy, environmental and economic analysis of electrification scenarios • Evaluation of an all-electric milk powder production with heat pump integration • Comparison of scenarios with future energy prices and emissions • Quantification of cost and emission reductions through heat pump integration

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Section: Discussionmentioning

confidence: 78%

Section: Introductionmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

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A comparative assessment of electrification strategies for industrial sites: Case of milk powder production

et al. 2019

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“…At the process level, previous works in the area of dairy processing include a comprehensive analysis of milk powder production [14] as well as key processes such as the evaporation system [15] and spray dryer [16]. More recent, Walmsley et al [17] integrated the utility and process systems to further raise the level of energy efficiency.…”

mentioning

confidence: 99%

“…Curing processes around 100 °C with longer holding-times are called sterilisation processes [27]. Compared to the presented examples on milk powder production [17] and pasteurisation [18], the described sterilisation batch process treats fluid product streams and uses jacketed heat exchangers in tanks. In discontinuous processes such as this batch sterilisation process, the heating and cooling requirements significantly change over time.…”

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confidence: 99%

Increasing energy efficiency of milk product batch sterilisation

Philipp

Schumm²,

Heck³

et al. 2018

Energy

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The food industry is a large energy consumer and most heat demands in food processing are low-temperature. The aim of this study is to develop and simulate innovative retrofits or redesigns that unlock the heat recovery potential of industrial batch sterilisation processes. The case study focuses on the whey cream process, although the method and results apply to similar batch sterilisation processes. The initial situation is compared to energy efficient designs based on Using a thermodynamic model, including the control system, the dynamic behaviour is simulated. The results show a high energy saving potential of up to 83%, faster processing with up to 60% timesaving, and favourable economics for the proposed novel designs.

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