| 1 - 1 |
Process Intensification Preface
Siirola J, Gani R |
| 2 - 38 |
Systematic process intensification using building blocks
Demirel SE, Li JP, Hasan MMF |
| 39 - 55 |
Process intensification of reactive separator networks through the IDEAS conceptual framework
da Cruz FE, Manousiouthakis VI |
| 56 - 73 |
A computer-aided approach for achieving sustainable process design by process intensification
Anantasarn N, Suriyapraphadilok U, Babi DK |
| 74 - 95 |
A computer-aided software-tool for sustainable process synthesis-intensification
Tula AK, Babi DK, Bottlaender J, Eden MR, Gani R |
| 96 - 104 |
Sustainable process design & analysis of hybrid separations
Tula AK, Befort B, Garg N, Camarda KV, Gani R |
| 105 - 122 |
A reactive distillation process for co-hydrotreating of non-edible vegetable oils and petro-diesel blends to produce green diesel fuel
Perez-Cisneros ES, Sales-Cruz M, Lobo-Oehmichen R, Viveros-Garcia T |
| 123 - 131 |
Techno-economic evaluation of an ultrasound-assisted Enzymatic Reactive Distillation process
Wierschem M, Skiborowski M, Gorak A, Schmuhl R, Kiss AA |
| 132 - 141 |
Optimal design of a multi-product reactive distillation system for silanes production
Medina-Herrera N, Tututi-Avila S, Jimenez-Gutierrez A, Segovia-Hernandez JG |
| 142 - 151 |
Optimal design of intensified processes for DME synthesis
Bildea CS, Gyorgy R, Brunchi CC, Kiss AA |
| 152 - 160 |
Optimal synthesis of rotating packed bed reactor
Qian Z, Chen Q, Grossmann IE |
| 161 - 172 |
Pseudo-transient models for multiscale, multiresolution simulation and optimization of intensified reaction/separation/recycle processes: Framework and a dimethyl ether production case study
Pattison RC, Tsay C, Baldea M |
| 173 - 184 |
Intelligent, model-based control towards the intensification of downstream processes
Papathanasiou MM, Steinebach F, Morbidelli M, Mantalaris A, Pistikopoulos EN |
| 185 - 196 |
Multi-objective optimization involving cost and control properties in reactive distillation processes to produce diphenyl carbonate
Contreras-Zarazua G, Vazquez-Castillo JA, Ramirez-Marquez C, Segovia-Hernandez JG, Alcantara-Avila JR |
| 197 - 211 |
Space-constrained purification of dimethyl ether through process intensification using semicontinuous dividing wall columns
Ballinger SE, Adams TA |
| 212 - 223 |
Integrated reaction-extraction process for the hydroformylation of long-chain alkenes with a homogeneous catalyst
McBride K, Kaiser NM, Sundmacher K |
| 224 - 236 |
A physics-based model for industrial steam-methane reformer optimization with non-uniform temperature field
Kumar A, Baldea M, Edgar TF |
| 237 - 245 |
Simulation of intensified process of sorption enhanced chemical-looping reforming of methane: Comparison with conventional processes
Phuluanglue A, Khaodee W, Assabumrungrat S |
| 246 - 258 |
An optimization-based operability framework for process design and intensification of modular natural gas utilization systems
Carrasco JC, Lima FV |
| 259 - 275 |
A systematic simulation-based process intensification method for shale gas processing and NGLs recovery process systems under uncertain feedstock compositions
Gong J, Yang MB, You FQ |
| 276 - 296 |
Multi-scale approaches for gas-to-liquids process intensification: CFD modeling, process synthesis, and global optimization
Onel O, Niziolek AM, Butcher H, Wilhite BA, Floudas CA |
| 297 - 307 |
Bioprocess intensification for the effective production of chemical products
Woodley JM |
| 308 - 316 |
Towards zero CO2 emissions in the production of methanol from switchgrass. CO2 to methanol
Martin M, Grossmann IE |
| 317 - 327 |
Optimal dynamic operation of microalgae cultivation coupled with recovery of flue gas CO2 and waste heat
Malek A, Alamoodi N, Almansoori AS, Daoutidis P |
| 328 - 347 |
Strategy to synthesize integrated solar energy coproduction processes with optimal process intensification. Case study: Efficient solar thermal hydrogen production
Gencer E, Agrawal R |
