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Today engineers, designers, buyers and all those who have to work with plastics face a dilemma. There has been a proliferation of test methods by which plastic properties are measured. The property data measured by these test methods are not identical and sometimes have large differences. How are engineers, designers, buyers going to decide the type and resin grade and their property data? Which are the valid test methods? The right plastic property data are the difference between success and failure of a design, thus making the property selection process critical. For the first time th
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monografia Rebiun19223156 https://catalogo.rebiun.org/rebiun/record/Rebiun19223156 m d cr -n--------- 130701s2008||||||| s|||||||||||eng|d 1-282-25307-7 1-282-02742-5 9786612253072 9786612253263 0-8155-1896-X UPVA 996894788703706 UPM 991005505389004212 UAM 991007751294704211 UCAR 991007753833404213 CBUC 991010342225006709 AU-PeEL eng AU-PeEL AU-PeEL eng 620.1/92 22 620.192 Campo, E. Alfredo SELECTION OF POLYMERIC MATERIALS Selection of Polymeric Materials electronic resource] How to Select Design Properties from Different Standards Plastics Design Library Burlington Elsevier Science 2008 Burlington Burlington Elsevier Science 1 online resource (275 p.) 1 online resource (275 p.) Text txt computer c online resource cr Plastics Design Library Description based upon print version of record Front Cover; Selection of Polymeric Materials; Copyright Page; Contents; Preface; Acknowledgement; Chapter 1. Polymeric Materials and Properties; 1.1 Tensile Stress-Strain Comparison Graphs; 1.2 Property Data Information for Polymeric Materials; 1.3 Material Selection Guidelines; 1.4 Polymeric Materials Specifications; 1.5 Testing Polymeric Materials; 1.6 The Need for Uniform Global Testing Standards; 1.7 Origin and Applications of Polymeric Materials; 1.8 Modern History of Polymeric Materials; 1.9 Polymeric Materials Families; 1.10 Classification of Polymeric Materials by Performance 1.11 Types of Thermoplastic Molecular Structures1.12 Manufacturing of Polymers; 1.13 Polymeric Materials Compounding Process; 1.14 Families of Thermoplastic Polymers; 1.15 Families of Thermoplastic Elastomers (TPEs); 1.16 Families of Thermoset Polymers; Chapter 2. Mechanical Properties of Polymeric Materials; 2.1 Introduction; 2.2 Comparison Tables of Mechanical Properties; 2.3 Comparison of ASTM and ISO Mechanical Test Standards; 2.4 Tensile Testing (ASTM D-638); 2.5 Tensile Strength Effects Caused by Cross-Head Speeds; 2.6 Molecular Orientation Effects 2.7 Compounding Processes and Properties of Glass Reinforced Polymeric Materials2.8 Effects of Fiber Glass on Polymeric Materials Properties; 2.9 Tensile Stress Effects Caused by Fiber Glass Orientation; 2.10 Weld Line Effects on Injection Molded Products; 2.11 Temperature Effects on the Behavior of Polymeric Materials; 2.12 Effects of Moisture on Nylon Properties; 2.13 Flexural Testing (ASTM D-790); 2.14 Compressive Strength Testing (ASTM D-695); 2.15 Shear Strength Testing (ASTM D-732); 2.16 Stress-Strain Curves and Load Type Comparison; 2.17 Creep, Rupture, Relaxation, and Fatigue 2.18 Tensile Creep Testing2.19 Flexural Creep Testing; 2.20 Isochronous Stress-Strain Curves; 2.21 Procedure for Applying Creep Modulus; 2.22 Creep Rupture; 2.23 Stress Relaxation; 2.24 Fatigue Characteristics; 2.25 Impact Strength Testing; 2.26 Impact Fracture Mechanism; 2.27 Pendulum Impact Tests; 2.28 Gardner Drop Weight Impact Testing (ASTM D-3029); 2.29 Falling Weight Tower Impact Testing; 2.30 Instrumented Impact Testing; 2.31 Instrumented High Speed Horizontal Plunger Impact Tester; 2.32 Instrumented Impact Testing (Dynatup®); 2.33 Product Design Analysis Using Dynatup® Test Data 2.34 Miscellaneous Impact TestingChapter 3. Thermal Properties of Polymeric Materials; 3.1 Introduction; 3.2 Thermal Properties for Elevated Temperatures; 3.3 Introduction to ISO Testing Standards; 3.4 Melting Temperature Test (ASTM D-3418); 3.5 Vicat Softening Temperature Test (ASTM D-1525); 3.6 Glass Transition Temperature (ASTM E-1356); 3.7 Brittleness Temperature (ASTM D-746); 3.8 Continuous Service Temperature Test (ASTM D-794); 3.9 UL Temperature Index (UL 746); 3.10 Heat Defiection Temperature Test (ASTM D-648); 3.11 Soldering Heat Resistance Performance 3.12 Coeffi cient of Linear Thermal Expansion Testing (ASTM D-696) Today engineers, designers, buyers and all those who have to work with plastics face a dilemma. There has been a proliferation of test methods by which plastic properties are measured. The property data measured by these test methods are not identical and sometimes have large differences. How are engineers, designers, buyers going to decide the type and resin grade and their property data? Which are the valid test methods? The right plastic property data are the difference between success and failure of a design, thus making the property selection process critical. For the first time th English Polymeric composites Polymers Polymers. Polymeric composites Polymers Polymeric composites Chemical & Materials Engineering. HILCC Engineering & Applied Sciences. HILCC Materials Science. HILCC Electronic books 0-8155-1551-0 Plastics Design Library