- 5 Ergebnisse
Kleinster Preis: € 176,85, größter Preis: € 227,00, Mittelwert: € 212,77
1
The Rheology Handbook (EUROPEAN COATING) - Mezger
Bestellen
bei amazon.de
€ 176,85
Versand: € 3,001
Bestellengesponserter Link
Mezger:

The Rheology Handbook (EUROPEAN COATING) - gebunden oder broschiert

2014, ISBN: 9783866308428

Vincentz Network, Gebundene Ausgabe, Auflage: 4, 432 Seiten, Publiziert: 2014-06-17T00:00:01Z, Produktgruppe: Buch, Hersteller-Nr.: black & white illustrations, 2.13 kg, Chemie, Naturwiss… Mehr…

Versandkosten:Gewöhnlich versandfertig in 3 bis 4 Tagen. Die angegebenen Versandkosten können von den tatsächlichen Kosten abweichen. (EUR 3.00) London Lane Company
2
The Rheology Handbook. (EUROPEAN COATING). - Mezger, Thomas G.
Bestellen
bei booklooker.de
€ 220,00
Versand: € 7,201
Bestellengesponserter Link

Mezger, Thomas G.:

The Rheology Handbook. (EUROPEAN COATING). - gebrauchtes Buch

2014, ISBN: 9783866308428

[PU: Vincentz Network], 8°, 432 Seiten, farbig illustr. OPbd. - sehr guter Zustand! Wie neu - 2014. MA7789 ISBN: 9783866308428, DE, [SC: 7.20], gebraucht; wie neu, gewerbliches Angebot, [… Mehr…

Versandkosten:Versand nach Deutschland. (EUR 7.20) Antiquariat Ehbrecht - Preis inkl. MwSt.
3
The Rheology Handbook. (EUROPEAN COATING). - Mezger, Thomas G.
Bestellen
bei AbeBooks.de
€ 220,00
Versand: € 4,901
Bestellengesponserter Link
Mezger, Thomas G.:
The Rheology Handbook. (EUROPEAN COATING). - gebunden oder broschiert

2014

ISBN: 3866308426

[EAN: 9783866308428], [PU: Vincentz Network], TECHNIK, NATURWISSENSCHAFTEN NOISBN, 8°, 432 Seiten, farbig illustr. OPbd. - sehr guter Zustand! Wie neu - 2014. MA7789 ISBN: 9783866308428 S… Mehr…

Versandkosten: EUR 4.90 Antiquariat Ehbrecht - Preis inkl. MwSt., Ilsede, Germany [6118770] [Rating: 5 (von 5)]
4
The Rheology Handbook. (EUROPEAN COATING).   4. Auflage. - Thomas G Mezger
Bestellen
bei buchfreund.de
€ 220,00
Versand: € 7,201
Bestellengesponserter Link
Thomas G Mezger:
The Rheology Handbook. (EUROPEAN COATING). 4. Auflage. - gebrauchtes Buch

2014, ISBN: 9783866308428

4. Auflage. 8°, 432 Seiten, farbig illustr. OPbd. - sehr guter Zustand! Wie neu - 2014. MA7789 ISBN: 9783866308428 Versand D: 7,20 EUR Technik, Naturwissenschaften, [PU:Vincentz Network,]

Versandkosten:Versandkosten innerhalb der BRD. (EUR 7.20) Antiquariat Ehbrecht, 31246 Ilsede
5
The Rheology Handbook. (EUROPEAN COATING). - Mezger, Thomas G.
Bestellen
bei Achtung-Buecher.de
€ 227,00
Versand: € 0,001
Bestellengesponserter Link
Mezger, Thomas G.:
The Rheology Handbook. (EUROPEAN COATING). - gebrauchtes Buch

2014, ISBN: 3866308426

4. Auflage. Unbekannter Einband 8°, 432 Seiten, farbig illustr. OPbd. - sehr guter Zustand! Wie neu - 2014. MA7789 ISBN: 9783866308428 Technik, Naturwissenschaften 1, [PU:Vincentz Network,]

Versandkosten:Versandkostenfrei innerhalb der BRD. (EUR 0.00) Antiquariat Ehbrecht Andreas Ehbrecht, 31246 Ilsede

1Da einige Plattformen keine Versandkonditionen übermitteln und diese vom Lieferland, dem Einkaufspreis, dem Gewicht und der Größe des Artikels, einer möglichen Mitgliedschaft der Plattform, einer direkten Lieferung durch die Plattform oder über einen Drittanbieter (Marketplace), etc. abhängig sein können, ist es möglich, dass die von eurobuch angegebenen Versandkosten nicht mit denen der anbietenden Plattform übereinstimmen.

Bibliographische Daten des bestpassenden Buches

Details zum Buch
The Rheology Handbook (EUROPEAN COATING)

Already in its 4th edition, this standard work describes the principles of rheology clearly, vividly and in practical terms. The book includes the rheology of additives in waterborne dispersions and surfactant systems. Not only it is a great reference book, it can also serve as a textbook for studying the theory behind the methods. The practical use of rheology is presented in the areas quality control, production and application, chemical and mechanical engineering, materials science and industrial research and development. After reading this book, the reader should be able to perform tests with rotational and oscillatory rheometers and interpret the results correctly.

Detailangaben zum Buch - The Rheology Handbook (EUROPEAN COATING)


EAN (ISBN-13): 9783866308428
ISBN (ISBN-10): 3866308426
Gebundene Ausgabe
Erscheinungsjahr: 2014
Herausgeber: Vincentz Network

Buch in der Datenbank seit 2014-07-09T08:18:09+02:00 (Berlin)
Detailseite zuletzt geändert am 2024-03-24T18:15:15+01:00 (Berlin)
ISBN/EAN: 9783866308428

ISBN - alternative Schreibweisen:
3-86630-842-6, 978-3-86630-842-8
Alternative Schreibweisen und verwandte Suchbegriffe:
Autor des Buches: thomas mezger
Titel des Buches: the rheology handbook, files, european handbook


Daten vom Verlag:

Titel: EUROPEAN COATING; The Rheology Handbook
Verlag: Vincentz Network
432 Seiten
Erscheinungsjahr: 2014-06-17
Gedruckt / Hergestellt in Deutschland.
Gewicht: 1,218 kg
Sprache: Englisch
199,00 € (DE)
204,60 € (AT)
Not available, publisher indicates OP
mit zahlr. Abbildungen und Tabellen

BA; GB; Hardcover, Softcover / Chemie/Sonstiges; Chemie; Elastic behavior, shear modulus, viscoelastic behavior; Creep tests, relaxation tests, oscillatory tests; Guideline for rheological tests; Measuring systems and instruments; Flow behavior, viscosity, rotational tests; Studierende in beschichtungstechnologischen Fach- und Hochschulstudiengängen
Fachliche Ein- und Umsteiger in der Lackforschung und -Entwicklung
Fachleute (Ingenieure und Chemiker) der betrieblichen Beschichtungspraxis
Laboranten und Techniker in der Lackindustrie
; EA

1 Introduction 1.1 Rheology, rheometry and viscoelasticity 1.2 Deformation and flow behavior 2 Flow behavior and viscosity 2.1 Introduction 2.2 Definition of terms 2.2.1 Shear stress 2.2.2 Shear rate 2.2.3 Viscosity 2.3 Shear load-dependent flow behavior 2.3.1 Ideally viscous flow behavior according to Newton 2.4 Types of flow illustrated by the Two-Plates Model 3 Rotational tests 3.1 Introduction 3.2 Basic principles 3.2.1 Test modes controlled shear rate (CSR) and controlled shear stress (CSS), raw data and rheological parameters 3.3 Flow curves and viscosity functions 3.3.1 Description of the test 3.3.2 Shear-thinning flow behavior 3.3.2.1 Structures of polymers showing shear-thinning behavior 3.3.2.2 Structures of dispersions showing shear-thinning behavior 3.3.3 Shear-thickening flow behavior 3.3.3.1 Structures of polymers showing shear-thickening behavior 3.3.3.2 Structures of dispersions showing shear-thickening behavior 3.3.4 Yield point 3.3.4.1 Yield point determination using the flow curve diagram 3.3.4.2 Yield point determination using the shear stress/deformation diagram 3.3.4.3 Further information on yield points 3.3.5 Overview: Flow curves and viscosity functions 3.3.6 Fitting functions for flow and viscosity curves 3.3.6.1 Model function for ideally viscous flow behavior 3.3.6.2 Model functions for shear-thinning and shear-thickening flow behavior 3.3.6.3 Model functions for flow behavior with zero-shear and infinite-shear viscosity 3.3.6.4 Model functions for flow curves with a yield point 3.3.7 The effects of rheological additives in aqueous dispersions 3.4 Time-dependent flow behavior and viscosity function 3.4.1 Description of the test 3.4.2 Time-dependent flow behavior of samples showing no hardening 3.4.2.1 Structural decomposition and regeneration (thixotropy and rheopexy) 3.4.2.2 Test methods for investigating thixotropic behavior 3.4.3 Time-dependent flow behavior of samples showing hardening 3.5 Temperature-dependent flow behavior and viscosity function 3.5.1 Description of the test 3.5.2 Temperature-dependent flow behavior of samples showing no hardening 3.5.3 Temperature-dependent flow behavior of samples showing hardening 3.5.4 Fitting functions for curves of the temperature-dependent viscosity. 3.6 Pressure-dependent flow behavior and viscosity function 4 Elastic behavior and shear modulus 4.1 Introduction 4.2 Definition of terms 4.2.1 Deformation and strain 4.2.2 Shear modulus 4.3 Shear load-dependent deformation behavior 4.3.1 Ideally elastic deformation behavior according to Hooke 5 Viscoelastic behavior 5.1 Introduction 5.2 Basic principles 5.2.1 Viscoelastic liquids according to Maxwell 5.2.1.1 Maxwell model 5.2.1.2 Examples of the behavior of VE liquids in practice 5.2.2 Viscoelastic solids according to Kelvin/Voigt 5.2.2.1 Kelvin/Voigt model 5.2.2.2 Examples of the behavior of VE solids in practice 5.3 Normal stresses 6 Creep tests 6.1 Introduction 6.2 Basic principles 6.2.1 Description of the test 6.2.2 Ideally elastic behavior 6.2.3 Ideally viscous behavior 6.2.4 Viscoelastic behavior 6.3 Analysis 6.3.1 Behavior of the molecules 6.3.2 Burgers model 6.3.3 Curve discussion 6.3.4 Definition of terms 6.3.4.1 Zero-shear viscosity 6.3.4.2 Creep compliance, and creep recovery compliance 6.3.4.3 Retardation time 6.3.4.4 Retardation time spectrum 6.3.5 Data conversion 6.3.6 Determination of the molar mass distribution 7 Relaxation tests 7.1 Introduction 7.2 Basic principles 7.2.1 Description of the test 7.2.2 Ideally elastic behavior 7.2.3 Ideally viscous behavior 7.2.4 Viscoelastic behavior 7.3 Analysis 7.3.1 Behavior of the molecules 7.3.2 Curve discussion 7.3.3 Definition of terms 7.3.3.1 Relaxation modulus 7.3.3.2 Relaxation time 7.3.3.3 Relaxation time spectrum 7.3.4 Data conversion 7.3.5 Determination of the molar mass distribution 8 Oscillatory tests 8.1 Introduction 8.2 Basic principles 8.2.1 Ideally elastic behavior 8.2.2 Ideally viscous behavior 8.2.3 Viscoelastic behavior 8.2.4 Definition of terms 8.2.5 The test modes controlled shear strain and controlled shear stress, raw data and rheological parameters 8.3 Amplitude sweeps 8.3.1 Description of the test 8.3.2 Structural character of a sample 8.3.3 Limiting value of the LVE range 8.3.3.1 Limiting value of the LVE range in terms of the shear strain 8.3.3.2 Limiting value of the LVE range in terms of the shear stress 8.3.4 Determination of the yield point and the flow point by amplitude sweeps 8.3.4.1 Yield point or yield stress 8.3.4.2 Flow point or flow stress 8.3.4.3 Yield zone between yield point and flow point 8.3.4.4 Evaluation of the two terms yield point and flow point 8.3.4.5 Measuring programs in combination with amplitude sweeps 8.3.5 Frequency-dependence of amplitude sweeps 8.3.6 SAOS and LAOS tests, and Lissajous diagrams 8.4 Frequency sweeps 8.4.1 Description of the test 8.4.2 Behavior of unlinked polymers (solutions and melts) 8.4.2.1 Single Maxwell model for unlinked polymers showing a narrow MMD. 8.4.2.2 Generalized Maxwell model for unlinked polymers showing a wide MMD 8.4.3 Behavior of cross-linked polymers 8.4.4 Behavior of dispersions and gels 8.4.5 Comparison of superstructures using frequency sweeps 8.4.6 Multiwave test 8.4.7 Data conversion 8.5 Time-dependent behavior at constant dynamic-mechanical and isothermal conditions 8.5.1 Description of the test 8.5.2 Time-dependent behavior of samples showing no hardening 8.5.2.1 Structural decomposition and regeneration (thixotropy and rheopexy) 8.5.2.2 Test methods for investigating thixotropic behavior 8.5.3 Time-dependent behavior of samples showing hardening 8.6 Temperature-dependent behavior at constant dynamic mechanical conditions 8.6.1 Description of the test 8.6.2 Temperature-dependent behavior of samples showing no hardening 8.6.2.1 Temperature curves and structures of polymers 8.6.2.2 Temperature-curves of dispersions and gels 8.6.3 Temperature-dependent behavior of samples showing hardening 8.6.4 Thermoanalysis (TA) 8.7 Time/temperature shift 8.7.1 Temperature shift factor according to the WLF method 8.8 The Cox/Merz relation 8.9 Combined rotational and oscillatory tests 8.9.1 Presetting rotation and oscillation in series 8.9.2 Superposition of oscillation and rotation 9 Complex behavior, surfactant systems 9.1 Surfactant systems 9.1.1 Surfactant structures and micelles 9.1.2 Emulsions 9.1.3 Mixtures of surfactants and polymers, surfactant-like polymers 9.1.4 Applications of surfactant systems 9.2 Rheological behavior of surfactant systems 9.2.1 Typical shear behavior 9.2.2 Shear-induced effects, shear-banding and “rheo chaos” 10 Measuring systems 10.1 Introduction 10.2 Concentric cylinder measuring systems (CC MS) 10.2.1 Cylinder measuring systems in general 10.2.1.1 Geometry of cylinder measuring systems showing a large gap 10.2.1.2 Operating methods 10.2.1.3 Calculations 10.2.2 Narrow-gap concentric cylinder measuring systems according to ISO 3219 10.2.2.1 Geometry of ISO cylinder systems 10.2.2.2 Calculations 10.2.2.3 Conversion between raw data and rheological parameters 10.2.2.4 Flow instabilities and secondary flow effects in cylinder measuring systems 10.2.2.5 Advantages and disadvantages of cylinder measuring systems 10.2.3 Double-gap measuring systems (DG MS) 10.2.4 High-shear cylinder measuring systems (HS MS) 10.3 Cone-and-plate measuring systems (CP MS) 10.3.1 Geometry of cone-and-plate systems 10.3.2 Calculations 10.3.3 Conversion between raw data and rheological parameters 10.3.4 Flow instabilities and secondary flow effects in CP systems 10.3.5 Cone truncation and gap setting 10.3.6 Maximum particle size 10.3.7 Filling of the cone-and-plate measuring system 10.3.8 Advantages and disadvantages of cone-and-plate measuring systems 10.4 Parallel-plate measuring systems (PP MS) 10.4.1 Geometry of parallel-plate systems 10.4.2 Calculations 10.4.3 Conversion between raw data and rheological parameters 10.4.4 Flow instabilities and secondary flow effects in a PP system 10.4.5 Recommendations for gap setting 10.4.6 Automatic gap setting and automatic gap control using the normal force control option 10.4.7 Determination of the temperature gradient in the sample 10.4.8 Advantages and disadvantages of parallel-plate measuring systems 10.5 Mooney/Ewart measuring systems (ME MS) 10.6 Relative measuring systems 10.6.1 Measuring systems with sandblasted, profiled or serrated surfaces 10.6.2 Spindles in the form of disks, pins, and spheres 10.6.3 Krebs spindles or paddles 10.6.4 Paste spindles and rotors showing pins and vanes 10.6.5 Ball measuring systems, performing rotation on a circular line 10.6.6 Further relative measuring systems 10.7 Measuring systems for solid torsion bars 10.7.1 Bars showing a rectangular cross section 10.7.2 Bars showing a circular cross section 10.7.3 Composite materials 10.8 Special measuring devices 10.8.1 Special measuring conditions which influence rheology 10.8.1.1 Magnetic fields for magneto-rheological fluids 10.8.1.2 Electrical fields for electro-rheological fluids 10.8.1.3 Immobilization of suspensions by extraction of fluid 10.8.1.4 UV light for UV-curing materials 10.8.2 Rheo-optical measuring devices 10.8.2.1 Terms from optics 10.8.2.2 Microscopy 10.8.2.3 Devices for measuring anisotropy in terms of optical rotation and birefringence 10.8.2.4 SALS for diffracted light quanta 10.8.2.5 SAXS for diffracted X-rays 10.8.2.6 SANS for scattered neutrons 10.8.2.7 Velocity profile of flow fields 10.8.3 Other special measuring devices 10.8.3.1 Interfacial rheology on two-dimensional liquid films 10.8.3.2 Dielectric analysis, and DE conductivity of materials showing electric dipoles 10.8.3.3 NMR, and resonance of magnetically active atomic nuclei 10.8.4 Other kinds of testings besides shear tests 10.8.4.1 Tensile tests, extensional viscosity, and extensional rheology 10.8.4.2 Tack test, stickiness and tackiness 10.8.4.3 Tribology 11 Instruments 11.1 Introduction 11.2 Short overview: methods for testing viscosity and elasticity 11.2.1 Very simple determinations 11.2.2 Flow on a horizontal plane 11.2.3 Spreading or slump on a horizontal plane after lifting a container 11.2.4 Flow on an inclined plane 11.2.5 Flow on a vertical plane or over a special tool 11.2.6 Flow in a channel, trough or bowl 11.2.7 Flow cups and other pressureless capillary viscometers 11.2.8 Devices showing rising, sinking, falling and rolling elements 11.2.9 Penetrometers, consistometers and texture analyzers 11.2.10 Pressurized cylinder and capillary devices 11.2.11 Simple rotational viscometer tests 11.2.12 Devices with vibrating or oscillating elements 11.2.13 Rotational and oscillatory curemeters (for rubber testing) 11.2.14 Tension testers 11.2.15 Compression testers 11.2.16 Linear shear testers 11.2.17 Bending or flexure testers 11.2.18 Torsion testers 11.3 Flow cups 11.3.1 ISO cup 11.3.1.1 Capillary length 11.3.1.2 Calculations 11.3.1.3 Flow instabilities, secondary flow effects, turbulent flow conditions in flow cups 11.3.2 Other types of flow cups 11.4 Capillary viscometers 11.4.1 Glass capillary viscometers 11.4.1.1 Calculations 11.4.1.2 Determination of the molar mass of polymers using diluted polymer solutions 11.4.1.3 Determination of the viscosity index VI of petrochemicals 11.4.2 Pressurized capillary viscometers 11.4.2.1 MFR and MVR testers driven by a weight (“low-pressure capillary viscometers”) 11.4.2.2 High-pressure capillary viscometers driven by an electric drive, for testing highly viscous and paste-like materials 11.4.2.3 High-pressure capillary viscometers driven by gas pressure, for testing liquids 11.5 Falling-ball viscometers 11.6 Rotational and oscillatory rheometers 11.6.1 Rheometer set-ups 11.6.2 Control loops 11.6.3 Devices to measure torques 11.6.4 Devices to measure deflection angles and rotational speeds 11.6.5 Bearings 11.6.6 Temperature control systems 12 Guideline for rheological tests 12.1 Selection of the measuring system 12.2 Rotational tests 12.2.1 Flow and viscosity curves 12.2.2 Time-dependent flow behavior (rotation) 12.2.3 Step tests (rotation): structural decomposition and regeneration (“thixotropy”) 12.2.4 Temperature-dependent flow behavior (rotation) 12.3 Oscillatory tests 12.3.1 Amplitude sweeps 12.3.2 Frequency sweeps 12.3.3 Time-dependent viscoelastic behavior (oscillation) 12.3.4 Step tests (oscillation): structural decomposition and regeneration (“thixotropy”) 12.3.5 Temperature-dependent viscoelastic behavior (oscillation) 12.4 Selection of the test type 12.4.1 Behavior at rest 12.4.2 Flow behavior 12.4.3 Structural decomposition and regeneration (“thixotropic behavior”, e.g. of coatings) 13 Rheologists and the historical development of rheology 13.1. Development until the 19th century 13.2 Development between 1800 and 1900 13.3 Development between 1900 and 1949 13.4 Development between 1950 and 1979 13.5 Development since 1980 14 Appendix 14.1 Symbols, signs and abbreviations used 14.2 The Greek alphabet 14.3 Conversion table for units 15 References 15.1 Publications and books 15.2 ISO standards 15.3 ASTM standards 15.4 DIN, DIN EN, DIN EN ISO and EN standards 15.5 Important standards for users of rotational rheometers

Weitere, andere Bücher, die diesem Buch sehr ähnlich sein könnten:

Neuestes ähnliches Buch:
9783748600367 The Rheology Handbook (Thomas G. Mezger)


< zum Archiv...