Asiedu NY, Hildebrandt D, Glasser D (2014). Batch distillation targets for minimum energy consumption. Industrial and Engineering Chemistry Research 53(7):2751-2757.
Crossref

Barolo M, Guarise GB (1996). Batch distillation of multicomponent systems with constant relative volatilities. Chemical Engineering Research and Design 74(8):863-871.
Crossref

Bernot C, Doherty MF, Malone MF (1993). Design and operating targets for non-ideal multicomponent batch distillation. Industrial and Engineering Chemistry Research 32(2):293-301.
Crossref

Bhusnure O, Mali S (2015). Recent Trends In Ion- Exchange Chromato-Graphy. The International Journal of Drug Policy 403-416.

Diwekar UM, Madhavan KP (1991). Multicomponent batch distillation column design. Industrial and Engineering Chemistry Research 30(4):713-721.
Crossref

Gustinelli G, Eliasson L, Svelander C, Andlid T, Lundin L, Ahrné L, Alminger M (2018). Supercritical Fluid Extraction of Berry Seeds: Chemical Composition and Antioxidant Activity. Journal of Food Quality 2018, 
Crossref

Jana AK, Khan NM, Maiti D (2013). Improving energy efficiency and cost-effectiveness of batch distillation for separating wide boiling constituents. II: Internal versus external heat integration. Chemical Engineering and Processing: Process Intensification 72:122-129.
Crossref

Jansens PJ, Fahkri F, Graauw J, Olujic Z (2001). Energy saving potential of a heat integrated distillation column. Proceedings of the Topical Distillation Symposium, AIChE 2001 Spring Meeting, Houston pp. 19-25.

Jawad SK, Husien NSM (2018). Solvent Extraction Method for Separation and Determination of Zn (||) by Using of Imidazole Derivative. International Journal of Engineering and Technology 7(4.36):553-556.
Crossref

Khan MN, Babu GUB, Jane A (2012). Improving Energy Efficiency and Cost - Effectiveness of Batch Distillation for Separating Wide Boiling Constituents. 1.Vapor Recompression Column. Industrial and Engineering Chemistry Research 51(47):15413-15422.
Crossref

Kulkarni SJ (2017). Various aspects of distillation with emphasis on modeling, optimization and simulations - a review. International Journal of Scientific Research in Chemistry (IJSRCH) 2(1):1-4.

Li QS, Song CY, Wu HL, Liu H, Qian YQ (2008). Performance and applications of flow-guided sieve trays for distillation of highly viscous mixtures. Korean Journal of Chemical Engineering 25(6):1509-1513.
Crossref

Lone SR, Rather MA (2015). Modeling and Similation of a Distillation Column using ASPEN PLUS for seperating methanol/water mixture. International Journal of Scientific and Engineering Research 6(3):619-627
Crossref

Luyben WL (2005). Effect of feed composition on the selection of control structures for high-purity binary distillation. Industrial and Engineering Chemistry Research 44:7800-7813.
Crossref

Manzo F Tzouanas V, Barbieri E (2012). Modeling, simulation, and control of heat integrated distillation columns: a case study. American Society for Engineering Education (ASEE) 1:1-6.

Nakaiwa M, Huang K, Naito K, Endo A, Owa M, Akiya T, Nakane T, Takamatsu T (2000). A new configuration of ideal heat integrated distillation columns. Computers and Chemical Engineering 24:239-245.
Crossref

Narvaes-Garcia A, Loria JCZ, Marin AR, Quiroz AVC (2014). Simple multicomponent batch distillation procedure with a variable reflux policy. Brazilian Journal of Chemical Engineering 31(2):531-542.
Crossref

Olujic Z, Fakhri F, de Rijke A, de Graauw J, Jansens PJ (2003). Internal heat integration-the key to an energy conserving distillation column. Journal of Chemical Technology and Biotechnology 78:241-248.
Crossref

Patil NP, Patil VS (2016). Operational and economic assessment of distillation column from the performance of tray, International Conference on Global Trends in Engineering, Technology and Management (ICGTETM-2016) 500-505.

Popoola LT, Adeniran JA, Akinola SO (2012). Investigations into optimization models of crude oil distillation column in the context of feed stock and market value. Advances in Chemical Engineering and Science 2(4):474-480.
Crossref

Pribic P, Roza M, Zuber L (2006). How to improve the energy savings in distillation and hybrid distillation-pervaporation systems. Separation Science and Technology 41(11):2581-2602.
Crossref

Roffel B, Betlem BHL, de Blouw RM (2003). A comparison of the performance of profile position and composition estimators for quality control in binary distillation. Computers and Chemical Engineering 27:199-210.
Crossref

Salomone HE, Chiotti OJ, Iribarren OA (1997). Short-cut design procedure for batch distillations. Industrial and Engineering Chemistry Research 36:130-136.
Crossref

Sharmila M, Mangaiyarkarasi MV (2014). Modeling and Control of Binary Distillation Column. International Journal Of Advanced Research In Electrical, Electronics and Instrumentation Engineering 3(4):105-111.

Soave G, Feliu JA (2002). Saving energy in distillation towers by feed splitting. Applied Thermal Engineering 22(8):889-896.
Crossref

Soave GS, Gamba S, Pellegrini LA, Bonomi S (2006). Feed-splitting technique in cryogenic distillation. Industrial and Engineering Chemistry Research 45:5761-5865.
Crossref

Sundaram S, Evans LB (1993). Shortcut procedure for simulating batch distillation operations. Industrial and Engineering Chemistry Research 32:511-518.
Crossref

Thurton R, Bailie RC, Whiting WB, Shaeiwitz JA (2003). Analysis, Synthesis, and Design of Chemical Processes. Prentice Hall.

Wankat PC (2007). Balancing diameters of distillation column with vapor feeds. Industrial and Engineering Chemistry Research 46:8813-8826.
Crossref

Wankat PC (2014). Improved rectifying columns. Industrial and Engineering Chemistry Research 53(22):9158-9168.
Crossref

Wankat PC (2015). Economic Analysis for Improved Rectifying Columns. Separation Science and Technology 50(16):2525-2531.
Crossref

Zhu G, Henson MA, Megan L (2001) Low-order dynamic modeling of Cryogenic distillation columns based on nonlinear wave phenomenon, Separation and Purification Technology 24(3):467-487.