Abstract:
Zero-liquid discharge systems have proven to be quite effective as a long-term brine management strategy. The availability of powerful modeling and optimization tools for the design of cost-effective zero-liquid discharge systems is vital, so as to ensure that only the best -performing systems are designed, constructed and operated. To date, the design of zero liquid discharge systems have been modeled in terms of flow rate only, without accounting for the effect of other parameters such as the feed salinity, temperature and pressure. The focus of this work is to integrate additional operating parameters (mainly temperature, salinity and electricity pricing), into a modified optimization model and to determine, more accurately, the best zero liquid discharge system configuration based on specific brine feed characteristics. The proposed model has been implemented using a case study and sensitivity analysis is performed to determine the most optimal structure under different inlet conditions. The results indicate that the optimal configuration is highly sensitive to brine temperature, and salinity. Moreover, this work also demonstrates how non-brine related conditions, such as electricity pricing, affects the design of such systems.
Description:
Thesis. M.E. American University of Beirut. Department of Chemical and Petroleum Engineering, 2019. ET:7069.
Advisor : Dr. Sabla Alnouri, Assistant Professor, Baha and Walid Bassatne Department of Chemical Engineering and Advanced Energy ; Members of Committee : Dr. Joseph Zeaiter, Associate Professor, Baha and Walid Bassatne Department of Chemical Engineering and Advanced Energy ; Dr. Mahmoud Al-Hindi, Associate Professor, Baha and Walid Bassatne Department of Chemical Engineering and Advanced Energy
Includes bibliographical references (leaves 38-44)
