Optimal sizing and operation of on-site combined heat and power systems for intermittent waste-heat recovery
- Resource Type
- Authors
- Pantaleo; Fordham, J; Oyewunmi, OA; Markides
- Source
- 9th International Conference on Applied Energy (ICAE2017)
- Subject
- Language
Coffee roasting is a highly energy intensive process with much of the energy being lost in intermittent cycles as discharged heat from the stack. In this work, combined heat and power (CHP) systems based on micro gas-turbines (MGT) are investigated for providing heat to the roasting process. Much of the heat released in a coffee roaster is from the afterburner that heats up the flue gases to high temperatures in order to remove volatile organic compounds (VOCs) and other pollutants. An interesting solution for utilizing waste heat is assessed through energy and material balances of a rotating drum coffee roasting with partial hot gas recycling. A cost assessment methodology is adopted to compare the profitability of three proposed system configurations integrated into the process. The case study of a major coffee torrefaction plant with 500 kg/h production capacity is assumed to carry out the thermo-economic assessment, under the Italian energy framework. The CHP options under investigation are: (i) regenerative topping MGT coupled to the existing modulating gas burner to generate hot air for the roasting process; (ii) intermittent waste-heat recovery from the hot flue-gases through an organic Rankine cycle (ORC) engine coupled to a thermal storage buffer; and (iii) non-regenerative topping MGT with direct recovery of turbine outlet air for the roasting process by means of an afterburner that modulates the heat demand of the roasting process. The results show that the profitability of these investments is highly influenced by the natural gas/electricity cost ratio, by the coffee torrefaction production capacity and by the intermittency level of discharged heat. The MGT appears as a more profitable option than waste-heat recovery via the ORC engine due to the intermittency of the heat source and the relatively high electricity/heat cost ratio.