Pressure-driven microfluidics [[electronic resource] /] / Václav Tesar̆ |
Autore | Tesař Václav <1939-> |
Pubbl/distr/stampa | Boston, [Mass.] ; ; London, : Artech House, 2007 |
Descrizione fisica | 1 online resource (422 p.) |
Disciplina |
620.106
629.8042 |
Collana | Artech House integrated microsystems series |
Soggetto topico |
Microfluidics
Fluidic devices |
Soggetto genere / forma | Electronic books. |
ISBN | 1-59693-135-3 |
Formato | Materiale a stampa |
Livello bibliografico | Monografia |
Lingua di pubblicazione | eng |
Nota di contenuto |
Contents; Preface; Chapter 1 Introduction and Basic Concepts; 1.1 MEANING AND USE OF MICROFLUIDICS; 1.1.1 Why fluids?; 1.1.2 Why devices without moving parts?; 1.1.3 Why the small size?; 1.2 BASIC PROPERTIES OF DEVICES; 1.2.1 Terminals; 1.2.2 Providing the driving pressure difference; 1.3 FLOW CHARACTERIZATION PARAMETERS; 1.3.1 Character of the flow and the Reynolds number Re; 1.3.2 Scaling down and Re; 1.3.3 Compressibility and the Mach number Ma; 1.3.4 Relation to molecular scale: Knudsen number Kn; 1.3.5 Periodic unsteady flows: Stokes and Strouhal numbers
1.4 REGIONS OF OPERATING PARAMETERS IN MICROFLUIDICSReferences; Chapter 2 Basics of Driving Fluid by Pressure; 2.1 PRESSURE AND VELOCITY; 2.2 FLOW RATE AND CHANNEL CROSS-SECTIONS; 2.2.1 Integral state parameter; 2.2.2 Implications of manufacturing technology; 2.3 STATE PARAMETERS; 2.4 DISSIPATION OF FLUID ENERGY; 2.4.1 Conversion ek->eT; 2.4.2 Steady-state characteristic and the characterization parameter Q; 2.4.3 Total dissipation of jet energy; 2.4.3 Dissipation in separated regions; 2.4.5 Friction loss mechanism; 2.4.6 Asymptotic subdynamic regime 2.5 STATE PARAMETERS FOR COMPRESSIBLE FLOWS2.6 LAWS OF FLOW BRANCHING; 2.6.1 Branching factors; 2.6.2 Comparison with data for biological branchings; 2.6.3 Optimality criteria dictated by manufacturing technology; 2.7 UNSTEADY FLOW EFFECTS: INERTANCE; 2.8 FLUID ACCUMULATION: CAPACITANCE; 2.8.1 Accumulation mechanisms; 2.8.2 Gravitational capacitance; 2.8.3 Fluid compression capacitance; 2.8.4 Capacitance due to wall elasticity; 2.8.5 Capillary capacitance; References; Chapter 3 Simple Components and Devices; 3.1 CONNECTING CHANNELS; 3.2 AREA CONTRACTIONS AND NOZZLES 3.2.1 Characterization: search for a nozzle invariant3.2.2 Generation of free jets and droplets; 3.2.3 Generating submerged jets; 3.3 DIFFUSERS AND COLLECTORS; 3.4 RESTRICTORS: OBSTACLES TO THE FLOW; 3.5 DIODES; 3.5.1 Labyrinth diodes; 3.5.2 Vortex diodes; 3.5.3 Reverse flow diverters; 3.6 REACTORS AND HEAT EXCHANGERS; 3.7 MIXERS; 3.8 THREE-TERMINAL JET PUMP TRANSFORMERS; 3.8.1 Venturi transformers: a nozzle and a diffuser; 3.8.2 Essential facts about jet pump transformers: two nozzles and a diffuser; 3.8.3 Common terminal and different connections into the circuit 3.9 TOWARD THE SUBDYNAMIC LIMITReferences; Chapter 4 Valves and Sophisticated Devices; 4.1 LOADING CHARACTERISTICS; 4.1.1 Loading a simple jet-type device; 4.1.2 Passive flow control valves; 4.1.3 Load-switching in a passive Coanda-effect valve; 4.1.4 Passive jet-type pressure regulators; 4.2 FLUIDIC CONTROL ACTION: ACTIVE VALVES; 4.2.1 Jet deflection; 4.2.2 Colliding jets; 4.2.4 Separation and supercirculation; 4.2.5 Displacement; 4.2.6 Fluid "plug"; 4.3 JET DEFLECTION; 4.3.1 The deflection mechanism; 4.3.2 Simplest example of the jet-deflection valve 4.3.3 Symmetric proportional control valves |
Record Nr. | UNINA-9910455729903321 |
Tesař Václav <1939-> | ||
Boston, [Mass.] ; ; London, : Artech House, 2007 | ||
Materiale a stampa | ||
Lo trovi qui: Univ. Federico II | ||
|
Pressure-driven microfluidics [[electronic resource] /] / Václav Tesar̆ |
Autore | Tesař Václav <1939-> |
Pubbl/distr/stampa | Boston, [Mass.] ; ; London, : Artech House, 2007 |
Descrizione fisica | 1 online resource (422 p.) |
Disciplina |
620.106
629.8042 |
Collana | Artech House integrated microsystems series |
Soggetto topico |
Microfluidics
Fluidic devices |
ISBN | 1-59693-135-3 |
Formato | Materiale a stampa |
Livello bibliografico | Monografia |
Lingua di pubblicazione | eng |
Nota di contenuto |
Contents; Preface; Chapter 1 Introduction and Basic Concepts; 1.1 MEANING AND USE OF MICROFLUIDICS; 1.1.1 Why fluids?; 1.1.2 Why devices without moving parts?; 1.1.3 Why the small size?; 1.2 BASIC PROPERTIES OF DEVICES; 1.2.1 Terminals; 1.2.2 Providing the driving pressure difference; 1.3 FLOW CHARACTERIZATION PARAMETERS; 1.3.1 Character of the flow and the Reynolds number Re; 1.3.2 Scaling down and Re; 1.3.3 Compressibility and the Mach number Ma; 1.3.4 Relation to molecular scale: Knudsen number Kn; 1.3.5 Periodic unsteady flows: Stokes and Strouhal numbers
1.4 REGIONS OF OPERATING PARAMETERS IN MICROFLUIDICSReferences; Chapter 2 Basics of Driving Fluid by Pressure; 2.1 PRESSURE AND VELOCITY; 2.2 FLOW RATE AND CHANNEL CROSS-SECTIONS; 2.2.1 Integral state parameter; 2.2.2 Implications of manufacturing technology; 2.3 STATE PARAMETERS; 2.4 DISSIPATION OF FLUID ENERGY; 2.4.1 Conversion ek->eT; 2.4.2 Steady-state characteristic and the characterization parameter Q; 2.4.3 Total dissipation of jet energy; 2.4.3 Dissipation in separated regions; 2.4.5 Friction loss mechanism; 2.4.6 Asymptotic subdynamic regime 2.5 STATE PARAMETERS FOR COMPRESSIBLE FLOWS2.6 LAWS OF FLOW BRANCHING; 2.6.1 Branching factors; 2.6.2 Comparison with data for biological branchings; 2.6.3 Optimality criteria dictated by manufacturing technology; 2.7 UNSTEADY FLOW EFFECTS: INERTANCE; 2.8 FLUID ACCUMULATION: CAPACITANCE; 2.8.1 Accumulation mechanisms; 2.8.2 Gravitational capacitance; 2.8.3 Fluid compression capacitance; 2.8.4 Capacitance due to wall elasticity; 2.8.5 Capillary capacitance; References; Chapter 3 Simple Components and Devices; 3.1 CONNECTING CHANNELS; 3.2 AREA CONTRACTIONS AND NOZZLES 3.2.1 Characterization: search for a nozzle invariant3.2.2 Generation of free jets and droplets; 3.2.3 Generating submerged jets; 3.3 DIFFUSERS AND COLLECTORS; 3.4 RESTRICTORS: OBSTACLES TO THE FLOW; 3.5 DIODES; 3.5.1 Labyrinth diodes; 3.5.2 Vortex diodes; 3.5.3 Reverse flow diverters; 3.6 REACTORS AND HEAT EXCHANGERS; 3.7 MIXERS; 3.8 THREE-TERMINAL JET PUMP TRANSFORMERS; 3.8.1 Venturi transformers: a nozzle and a diffuser; 3.8.2 Essential facts about jet pump transformers: two nozzles and a diffuser; 3.8.3 Common terminal and different connections into the circuit 3.9 TOWARD THE SUBDYNAMIC LIMITReferences; Chapter 4 Valves and Sophisticated Devices; 4.1 LOADING CHARACTERISTICS; 4.1.1 Loading a simple jet-type device; 4.1.2 Passive flow control valves; 4.1.3 Load-switching in a passive Coanda-effect valve; 4.1.4 Passive jet-type pressure regulators; 4.2 FLUIDIC CONTROL ACTION: ACTIVE VALVES; 4.2.1 Jet deflection; 4.2.2 Colliding jets; 4.2.4 Separation and supercirculation; 4.2.5 Displacement; 4.2.6 Fluid "plug"; 4.3 JET DEFLECTION; 4.3.1 The deflection mechanism; 4.3.2 Simplest example of the jet-deflection valve 4.3.3 Symmetric proportional control valves |
Record Nr. | UNINA-9910780748403321 |
Tesař Václav <1939-> | ||
Boston, [Mass.] ; ; London, : Artech House, 2007 | ||
Materiale a stampa | ||
Lo trovi qui: Univ. Federico II | ||
|