Total Site Heat Integration of Mechanical Vapour Recompression Multi-Effect Evaporators for Older Kraft Mills

conference paper

English

This paper aims to apply Total Site Heat Integration (TSHI) to appropriately integrate Mechanical and Thermal Vapour Recompression with multi-effect evaporators at older Kraft Mills, to cause a step reduction in fossil fuel use and its associated emissions. Heat and power demands for older Kraft Mills are chiefly satisfied from Recovery Boilers (RB), heavily supplemented by biomass/fossil fuel boilers, and integrated with steam turbines. Prior to firing, black liquor - the RB fuel - is concentrated from about 18 % to 67 % in a multi-effect evaporator, which demands 20 % of site-wide thermal energy. With access to renewable electricity, this study finds that vapour recompression can be economically integrated into a multi-effect evaporator at older Kraft Mills. The vapour recompression configuration with the greatest economic potential used 2-stages of mechanical vapour recompression and 1-stage of thermal vapour recompression. This system achieved a levelised profit of NZD 8.56 M/y, a payback period of 1.0 y and an internal rate of return of 103 %. An optimum integrated set-up needs to account for site-specific heat demand and utility supply profiles through TSHI.

Earnings; Evaporators; Fossil fuels; Fuels; Investments; Specific heat; Steam turbines; Economic potentials; Heat integration; Internal rate of return; Multi-effect evaporators; Payback periods; Recovery boilers; Renewable electricity; Vapour recompression; Kraft Mills;

Walmsley, T.G.; Ong, B.H.Y.; Atkins, M.J.; Klemeš, J.J.; Walmsley, M.R.W., Varbanov, P.S.

1. 10. 2017

Italian Association of Chemical Engineering - AIDIC

978-88-95608-51-8

Chemical Engineering Transactions

2283-9216

Chemical Engineering Transactions

61

Republic of Italy

265

270

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