TY  - BOOK
AU  - Drioli,Enrico
AU  - Cassano,Alfredo
AU  - Charcosset,Catherine
AU  - Conidi,Carmela
AU  - Crespo,Joao G.
AU  - Cuperus,F.Petrus
AU  - De,Sirshendu
AU  - Drioli,Enrico
AU  - Franken,A.C.M.(Ton)
AU  - Gani,Rafigul
AU  - Gésan-Guiziou,Genevieve
AU  - Giorno,Lidietta
AU  - Jiao,Bining
AU  - Lipnizki,Frank
AU  - Lutze,Philip
AU  - Mietton Peuchot,Martine
AU  - Mondor,Martin
AU  - Mucchetti,Germano
AU  - Roux-de Balmann,Hélène
AU  - Ruby Figueroa,René
AU  - Tsibranska,Irene
AU  - Tylkowski,Bartosz
AU  - Mondal,Sourav
AU  - Brazinha,Carla
AU  - El Rayess,Youssef
AU  - Mazzei,Rosalinda
AU  - Piacentini,Emma
TI  - Integrated Membrane Operations: In the Food Production
SN  - 9783110285666
AV  - TP159 .M4 I564 2013 
U1  - 660.28424 
PY  - 2013///
CY  - Berlin
PB  - De Gruyter
KW  - Membranes (Technology)
KW  - Membrane separation
KW  - Industrial applications
KW  - Membrane reactors
KW  - Food industry and trade
KW  - SCIENCE
KW  - Chemistry
KW  - Industrial & Technical
KW  - bisacsh
KW  - TECHNOLOGY & ENGINEERING
KW  - Chemical & Biochemical
KW  - Electronic books
N1  - 3.3 Concentration of fruit juices; Includes bibliographical references and index; Preface; Author index; 1 Membrane applications in agro-industry; 1.1 Introduction; 1.2 Membranes in biorefinery; 1.2.1 What is biorefinery?; 1.2.2 Mild extraction techniques; 1.2.3 Use of membranes in biorefinery; 1.2.3.1 Crossflow; 1.2.3.2 Cross-rotation (CR) filtration; 1.2.3.3 Rotating membranes; 1.2.3.4 Vibrational membranes; 1.2.4 Removing minerals from road-side grass; 1.2.5 Biofuel including microalgae; 1.3 Membranes in vegetable oils and fats; 1.3.1 Membrane technology applied to vegetable oils; 1.3.2 Solvent recovery and reuse; 1.3.3 Wax removal and/or recovery; 1.3.4 Goodies in oil; 1.4 Application scale and outlook1.4.1 Application scale; 1.4.2 Outlook; 1.5 References; 2 Process intensification in integrated membrane processes; 2.1 Introduction; 2.1.1 Background: process intensification; 2.1.2 Membranes and process intensification; 2.2 Synthesis/design of membrane-assisted PI -- overview and concepts; 2.2.1 Mathematical formulation of the PI synthesis problem; 2.2.2 PI synthesis based on the decomposition approach; 2.2.3 Phenomena as building blocks for process synthesis; 2.2.4 Connection of phenomena; 2.3 Synthesis/design of membrane-assisted PI -- workflow; 2.3.1 Steps of the general workflow2.3.1.1 Step 1: Define problem; 2.3.1.2 Step A2: Analyze the process; 2.3.1.3 B2: Identify and analyze necessary tasks to achieve the process target; 2.3.1.4 Step 6: Solve the reduced optimization problem and validate most promising; 2.3.2 KBS workflow; 2.3.3 UBS workflow; 2.3.3.1 Step U2: Collect PI equipment; 2.3.3.2 Step U3: Select and develop models; 2.3.3.3 Step U4: Generate feasible flowsheet options; 2.3.3.4 Step U5: Fast screening for process constraints; 2.3.4 PBS workflow; 2.3.4.1 Step P3: Identification of desirable phenomena; 2.3.4.2 Step P4: Generate feasible operation/flowsheet options2.3.4.3 Step P5: Fast screening for process constraints; 2.4 Synthesis/design of membrane-assisted PI -- sub-algorithms, supporting methods and tools; 2.4.1 Sub-algorithms; 2.4.2 Supporting methods and tools; 2.4.2.1 Knowledge base tool; 2.4.2.2 Model library; 2.4.2.3 Method based on thermodynamic insights; 2.4.2.4 Driving force method; 2.4.2.5 Extended Kremser method; 2.4.2.6 Additional tools; 2.5 Conceptual example; 2.5.1 Step 1: Define problem; 2.5.2 Step A2: Analyze the process; 2.5.3 Result of the PBS workflow; 2.5.3.1 Step P3: Identification of desirable phenomena2.5.3.2 Step P4: Generate feasible operation/flowsheet options; 2.5.3.3 Step P5: Fast screening for process constraints; 2.5.3.4 Step 6: Solve the reduced optimization problem and validate most promising; 2.5.4 Comparison of solutions obtained from PBS, KBS and UBS; 2.5.4.1 Result of the KBS workflow; 2.5.4.2 Result of the UBS workflow; 2.5.4.3 Comparison of the results; 2.6 Conclusions; 2.7 References; 3 Integrated membrane operations in fruit juice processing; 3.1 Introduction; 3.2 Clarification of fruit juices
N2  - Membranes are the most effective separation processes with practically unlimited selectivity of separation and seem to be very promising and profitable in designing of the innovative Clean Technologies, which will become inevitably necessary on the long run. An introduction to integrated membrane operations is followd by applications in the several industries of the food sector
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