Verfügbarkeit: Stress analysis of fiber-reinforced composite materials

Stress analysis of fiber-reinforced composite materials:

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Bibliographische Detailangaben
1. Verfasser:	Hyer, Michael W. (VerfasserIn)
Format:	Buch
Sprache:	English
Veröffentlicht:	Lancaster, PA DEStech Publ. 2009
Ausgabe:	Updated ed.
Schlagworte:	Spannungsanalyse Faserverstärkter Kunststoff Faserverbundwerkstoff
Online-Zugang:	Inhaltsverzeichnis Klappentext
Beschreibung:	Literaturangaben
Beschreibung:	XXII, 695 S. Ill., graph. Darst.
ISBN:	9781932078862

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MARC


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Datensatz im Suchindex

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adam_text	Contents Preface to the Updated Edition xiii Preface to Original Edition xvii 1 Fiber-Reinforced Composite Materials ........... 1 1.1 Background and Brief Overview .............. 1 1.2 Utilizing the Strength of Fibers ............... 4 1.3 Laminae and Laminates ................... 9 1.4 Fibers ............................. 10 1.4.1 Carbon-Based Fibers .................. 10 1.4.2 Glass-Based fibers ................... 20 1.4.3 Polymeric Fibers .................... 23 1.5 iMatrices ........................... 25 1.5.1 Thermosets ....................... 27 1.5.2 Thermoplastics ..................... 29 1.6 Fiber Surface Treatments .................. 31 1.6.1 Graphite Fiber Treatment ................ 33 1.6.2 Glass Fiber Treatment ................. 39 1.6.3 Polymeric Fiber Treatment ............... 41 1.7 Summary ........................... 42 1.8 Suggested Readings ..................... 42 2 Linear Elastic Stress-Strain Characteristics of Fiber-Reinforced Material ................. 43 2.1 Stress and Deformations in Fiber-Reinforced Materials .......................... 44 2.2 Maxwell-Betti Reciprocal Theorem ............ 55 2.3 Relationships among Material Properties ......... 57 2.4 Typical Material Properties ................ 64 2.5 Important Interpretation of Stress-Strain Relations ... 67 2.6 Free Thermal Strains .................... 76 v vi Contents 2.7 Stress-Strain Relations, Including the Effects of Free Thermal Strains .................... 80 2.8 Stress-Strain Relations, Including the Effects of Free Moisture Strains ................... 86 2.9 Summary .......................... 90 2.10 Suggested Readings ..................... 90 3 Prediction of Engineering Properties Using Micromechanics ..................... 93 3.1 Background .......................... 94 3.2 Finite-Element Results: Square- and Hexagonal-Packed Array Models .............. 95 3.2. J Material Properties of the Fiber and Matrix ...... 100 3.2.2 Thermal Effects and Determination of Thermal Expansion Coefficients αλ and a2 ........... 100 3.2.3 Tension in the Fiber Direction and Determination of Extensional Modulus E and Poisson s Ratios v 2 and V]3 ....................... 103 3.2.4 Transverse Tensile Loading and Determination of Extensional Modulus E2 and Poisson s Ratios V21 and i>23 ....................... m 3.2.5 Transverse Shear Loading and Determination of Shear Modulus G23 ................... 118 3.3 Theory of Elasticity Results: Concentric Cylinders Model ................ 122 3.3.1 Fiber-Direction Tension ................. 124 3.3.2 Axial Shear ....................... 134 3.4 Strength-of-Materials Results ................ 140 3.4.1 Model for Ex and vu .................. 140 3.4.2 Models for E2 ..................... 146 3.4.3 Models for Gl2 ..................... 154 3.4.4 Model for a and 012 .................. 156 3.5 Summary ........................... 162 3.6 Suggested Readings ..................... 162 4 The Plane-Stress Assumption ................. 165 4.1 Stress-Strain Relations for Piane Stress .......... 169 4.2 Important Interpretation of Stress-Strain Relations Revisited ...................... 173 4.3 Numerical Results for the Plane-Stress Condition ..... 173 4.4 Plane-Stress Stress-Strain Relations and the Effects of Free Thermal and Free Moisture Strains ........ 175 4.5 Suggested Readings ..................... 177 Contents vii Plane-Stress Stress-Strain Relations in a Global Coordinate System ....................... 179 5.1 Transformation Relations .................. 180 5.2 Transformed Reduced Compliances ............ 185 5.3 Transformed Reduced Stiffnesses .............. 201 5.4 Engineering Properties in a Global Coordinate System . . 212 5.5 Coefficients of Mutual Influence .............. 218 5.6 Free Thermal and Free Moisture Strains ......... 221 5.7 Effects of Free Thermal and Free Moisture Strains .... 225 5.8 Summary ........................... 234 Classical Lamination Theory: The Kirchhoff Hypothesis ...................235 6.1 Laminate Nomenclature ...................238 6.2 Laminate Strains and Displacements: The Kirchhoff Hypothesis .................. 241 6.3 Implications of the Kirchhoff Hypothesis ......... 245 6.4 Laminate Strains ....................... 248 6.5 Laminate Stresses ...................... 252 6.6 Stress Distributions through the Thickness ........ 253 6.6.1 CLT Example 1: [0/90] s Laminate subjected to Known ε°χ ........................254 6.6.2 CLT Example 2:[0/90]s Laminate Subjected to Known л -o ........................ 262 6.7 Force and Moment Resultants ............... 270 6.8 Further Examples ...................... 280 6.8. J CLT Example 3: [^ЗО/ОЈѕ Laminate subjected to Known ε°χ ........................280 6.8.2 CLT Example 4: [±30/0] s Laminate Subjected to Known κ° ........................286 6.8.3 CLT Example 5: [±30/0]T Laminate Subjected to Known ε°χ ........................296 6.8.4 A Note on the Kirchhoff Hypothesis ..........301 6.9 Suggested Readings .....................306 Classical Lamination Theory: Laminate Stiffness Matrix ..................307 7.1 Formal Definition of Force and Moment Resultants . . . 308 7.2 Laminate Stiffness: The ABD Matrix ...........310 7.3 Classification of Laminates and Their Effect on the ABD Matrix ......................... 330 7.3.1 Symmetric Laminates .................. 331 7.3.2 Balanced Laminates .................. 333 7.3.3 Symmetric Balanced Laminates ............ viii Contents 7.3.4 Cross Ply Laminates ..................335 7.3.5 Symmetric Cross-Ply Laminates ............335 7.3.6 Single Isotropie Layer .................336 7.4 Reference Surface Strains and Curvatures of Example Laminates .....................338 7.5 Comments ..........................340 7.6 Elastic Couplings .......................341 7.6.1 Influence of £>іб and D2e ................ 341 7.6.2 Influence of А ь and Агь ................ 347 7.6.3 Influence of the Bu ................... 355 7.7 Effective Engineering Properties of a Laminate ...... 361 7.8 Summary ........................... 365 7.9 Suggested Readings ..................... 366 8 Classical Lamination Theory: Additional Examples . . . 367 8.1 CLT Example 6: [0/90] s Laminate Subjected to Known Nx — Counterpart to CLT Example 1.......368 8.2 CLT Example 7: [іЗО /OJs Laminate Subjected to Known Nx — Counterpart to CLT Example 3.......372 8.3 CLT Example 8: [±30/0]5 Laminate Subjected to Known Μχ — Counterpart to CLT Example 4......380 8.4 Summary ...........................386 9 Failure Theories for Fiber-Reinforced Materials: Maximum Stress Criterion ..................387 9.1 Maximum Stress Failure Criterion .............395 9.2 Failure Example 1: Tube with Axial Load — Maximum Stress Criterion .............397 9.3 Failure Example 2: Tube in Torsion — Maximum Stress Criterion .......................405 9.4 Failure Example 3: Tube with Combined Load — Maximum Stress Criterion .............411 9.5 Failure Example 4: [0/90]$ Laminate Subjected to Nx — Maximum Stress Criterion ............422 9.6 Failure Example 5: [±30/0]s Laminate Subjected to Nx — Maximum Stress Criterion ............424 9.7 Failure Example 6: [±30/0]* Laminate Subjected to Mx — Maximum Stress Criterion ............426 9.8 Summary ...........................428 9.9 Suggested Readings .....................429 10 Failure Theories for Fiber-Reinforced Materials: The Tsai-Wu Criterion ....................431 10.1 Determination of the Constants ..............433 Contents ix 10.2 Failure Example 7: Tube with Axial Load—Tsai-Wu Criterion .................444 10.3 Failure Example 8: lube in Torsion — Tsai-Wu Criterion .....................449 10.4 Failure Example 9: Tube with Combined Load —Tsai-Wu Criterion .................451 10.5 Failure Example 10: [0/90]^ Laminate Subjected to Nx — Tsai-Wu Criterion ..................459 10.6 Failure Example 11: [±30/0],$ Laminate Subjected to Nx— Tsai-Wu Criterion ................462 10.7 Failure Example 12: [±30/0]s Laminate subjected to Mx— Tsai-Wu Criterion ................463 10.8 Summary ..........................465 10.9 Suggested Readings .....................465 11 Environmentally Induced Stresses in Laminates .....467 11.1 Laminate Response ....................467 11.1.1 Displacements and Strains .............467 11.1.2 Stresses .......................469 11.2 Examples of Laminate Response .............471 11.2.1 CLT Example 9: [0/90]s Laminate Subjected to Known ε°χ and Known AT ............471 11.2.2 CLT Example 10: [±30/0] s Laminate Subjected to Known к® and Known AT ......477 11.3 Force and Moment Resultants in Examples .......482 11.3.1 Stress Resultant Calculation for CLT Example 9: [0/90ÌS Laminate Subjected to Known ε°χ and Known AT .............482 11.3.2 Stress Resultant Calculation for CLT Example 10: [^ЗО/ОЈѕ Laminate Subjected to Known к^ and Known AT .............484 11.4 Definition of Thermal Force and Moment Resultants ....................488 11.5 Definitions of Unit Thermal Force and Moment Resultants ....................494 11.6 The Effect of Laminate Classification on the Unit Thermal Force and Moment Resultants .........497 11.6.1 Symmetric Laminates ................ 498 11.6.2 Balanced Laminates ................ 498 11.6.3 Symmetric Balanced Laminates ........... 498 11.6.4 Cross-Ply Laminates ................ 499 11.6.5 Symmetric Cross-Ply Laminates .......... 499 11.6.6 Single Isotropie Layer ............... 499 11.7 Free Thermal Response of Laminates .......... 500 χ Contents 11.7.1 Equations Governing Free Thermal Response of Laminates ....................500 11.7.2 Laminate Coefficients of Thermal Expansion . . . . 500 11.8 Examples of Laminate Free Thermal Response .....504 11.8.1 CLT Example 11: [0/90] s Laminate Subjected to a Known AT ...................504 11.8.2 CLT Example 12: [±30/0] s Laminate Subjected to a Known AT .............509 11.8.3 CLT Example 13: [±30/0]T Laminate Subjected to a Known AT .............516 11.8.4 CLT Example 14: [±30/0] s Laminate Subjected to a Known AM .............519 11.9 Response Due to Stress Resultants and a Temperature Change ...................523 11.9.1 CLT Example 15: [0/90] s Laminate Subjected to Known Nx and Known AT ...........525 11.9.2 CLT Example 16: [±30/0] s Laminate Subjected to Known Nx and Known AT ......529 11.9.3 CLT Example 17: [±30/0] s Laminate Subjected to Known Mx and Known AT .....532 11.9.4 CLT Example 18: [±30/0] s Laminate Subjected to Known Nx, Known AT, and Known AM .....................538 11.10 Influence of Thermal Effects on Failure: The Maximum Stress Criterion .............542 11.10.1 Failure Example 13: [0/90] s Laminate Subjected to Nx and Known AT .........544 11.10.2 Failure Example 14: [±30/0]s Laminate Subjected to Nx and Known AT .........-547 11.10.3 Falure Example 15: [±30/0]s Laminate Subjected to Mx and Known AT .........549 11.11 Influence of thermal Effects on Failure: The Tsai-Wu Criterion ..................551 11.11.1 Failure Example 16: [0/90] s Laminate Subjected to Nx and Known AT .........551 11.11.2 Failure Example 17: [±30/0]s Laminate Subjected to Nx and Known AT .........554 11.11.3 Failure Example 18: [±30/0]s Laminate Subjected to Mx and Known AT .........556 11.12 Summary ..........................558 11.13 Suggested Readings ....................558 12 Through-Thickness Laminate Strains ............561 12.1 Thickness Change of a Laminate, No Free Thermal or Moisture Strain Effects .................562 Contents xi 12.2 Through-Thickness Laminate Poisson s Ratios ...... 564 12.3 Thickness Change of a Laminate Due to Free Thermal Strain Effects ................... 569 12.4 Through-Thickness Laminate Coefficient of Thermal Expansion ..................... 571 12.5 Summary .......................... 574 12.6 Suggested Readings ..................... 574 13 Introduction to Fiber-Reinforced Laminated Plates . . . 575 13.1 Equations Governing Plate Behavior .......... 576 13.2 Governing Conditions in Terms of Displacements . . . 589 13.3 Simplifications to the Governing Equations ....... 596 13.3.1 Symmetric Laminates ................ 597 13.3.2 Symmetric Balanced Laminates ........... 600 13.3.3 Symmetric Cross-Ply Laminates .......... 602 13.3.4 Isotropie Plates ................... 605 13.4 Plate Example 1: A Long [0/90]5 Plate ......... 608 13.4.1 Solution of Governing Differential Equations . . . 608 13.4.2 Application of Boundary Conditions ........ 670 13.5 Plate Example 2: A Long [Оі^Огіг Plate ........ 616 13.5.1 Solution of Governing Differential Equations . . . 616 13.5.2 Application of Boundary Conditions ........ 618 13.6 Plate Example 3: A Long [±30/0].$ Plate ........ 623 13.7 Numerical Results for Plate Examples 1, 2, and 3 ... 625 13.7.1 Cross-Ply Plates .................. 625 13.7.2 [±30/0] s Plate ................... 630 13.8 Plate Example 4: A Rectangular, Uniformly Loaded, Cross-Ply Plate .................. 632 13.9 Summary .......................... 643 13.10 Suggested Readings .................... 645 14 Appendix: Manufacturing Composite Laminates ..... 647 14.1 Background and Overview ................. 647 14.2 Fabrication ......................... 648 14.2.1 Tooling and Specialty Materials ........... 648 14.2.2 Hand Lay-up ..................... 653 14.3 Processing .......................... 664 14.3.1 Overall Considerations ................ 664 14.3.2 Autoclave Curing ................... 667 14.4 Manufacturing by Other Methods ............ 669 14.4.1 Fiber-Only Preforms ................. 669 14.4.2 Other Combined Fiber-Matrix Preforms ....... 671 14.5 Forming Structural Shapes ................ 673 14.5.1 Wet Lay-up and Spray-up .............. 673 xii Contents 14.5.2 Filament Winding .................. 674 14.5.3 Pultrusion ...................... 678 14.5.4 Resin Transfer Molding ............... 681 14.6 Nonautoclave curing.................... 682 14.6.1 Oven Curing ..................... 682 14.6.2 Hot Pressing ..................... 683 14.7 Manufacturing Defects ................... 683 14.8 Suggested Readings ..................... 685 Index .................................. 687 his book focuses on the mechanical aspects of ir-reinforced composite materials. Classical lamination theory is developed and much of the book discusses the stresses due to applied deformations, applied loads, and temperature changes. No prior knowledge of composite materials is assumed. A set of examples is introduced early in the text and then built upon as additional concepts are developed. This set of examples provides continuity and allows the reader to evaluate the impact of more complex issues as the book progresses. Implications and interpretations of the various simplifying assumptions employed in studying the mechanical behavior of fiber-reinforced materials are emphasized throughout. Computer exercises that build on one another provide software tools for studying the response of composite materials.
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spelling	Hyer, Michael W. Verfasser aut Stress analysis of fiber-reinforced composite materials Michael W. Hyer Updated ed. Lancaster, PA DEStech Publ. 2009 XXII, 695 S. Ill., graph. Darst. txt rdacontent n rdamedia nc rdacarrier Literaturangaben Spannungsanalyse (DE-588)4055995-6 gnd rswk-swf Faserverstärkter Kunststoff (DE-588)4128805-1 gnd rswk-swf Faserverbundwerkstoff (DE-588)4134341-4 gnd rswk-swf Faserverbundwerkstoff (DE-588)4134341-4 s DE-604 Spannungsanalyse (DE-588)4055995-6 s Faserverstärkter Kunststoff (DE-588)4128805-1 s 1\p DE-604 Digitalisierung UB Bayreuth application/pdf http://bvbr.bib-bvb.de:8991/F?func=service&doc_library=BVB01&local_base=BVB01&doc_number=025345782&sequence=000003&line_number=0001&func_code=DB_RECORDS&service_type=MEDIA Inhaltsverzeichnis Digitalisierung UB Bayreuth application/pdf http://bvbr.bib-bvb.de:8991/F?func=service&doc_library=BVB01&local_base=BVB01&doc_number=025345782&sequence=000004&line_number=0002&func_code=DB_RECORDS&service_type=MEDIA Klappentext 1\p cgwrk 20201028 DE-101 https://d-nb.info/provenance/plan#cgwrk
spellingShingle	Hyer, Michael W. Stress analysis of fiber-reinforced composite materials Spannungsanalyse (DE-588)4055995-6 gnd Faserverstärkter Kunststoff (DE-588)4128805-1 gnd Faserverbundwerkstoff (DE-588)4134341-4 gnd
subject_GND	(DE-588)4055995-6 (DE-588)4128805-1 (DE-588)4134341-4
title	Stress analysis of fiber-reinforced composite materials
title_auth	Stress analysis of fiber-reinforced composite materials
title_exact_search	Stress analysis of fiber-reinforced composite materials
title_full	Stress analysis of fiber-reinforced composite materials Michael W. Hyer
title_fullStr	Stress analysis of fiber-reinforced composite materials Michael W. Hyer
title_full_unstemmed	Stress analysis of fiber-reinforced composite materials Michael W. Hyer
title_short	Stress analysis of fiber-reinforced composite materials
title_sort	stress analysis of fiber reinforced composite materials
topic	Spannungsanalyse (DE-588)4055995-6 gnd Faserverstärkter Kunststoff (DE-588)4128805-1 gnd Faserverbundwerkstoff (DE-588)4134341-4 gnd
topic_facet	Spannungsanalyse Faserverstärkter Kunststoff Faserverbundwerkstoff
url	http://bvbr.bib-bvb.de:8991/F?func=service&doc_library=BVB01&local_base=BVB01&doc_number=025345782&sequence=000003&line_number=0001&func_code=DB_RECORDS&service_type=MEDIA http://bvbr.bib-bvb.de:8991/F?func=service&doc_library=BVB01&local_base=BVB01&doc_number=025345782&sequence=000004&line_number=0002&func_code=DB_RECORDS&service_type=MEDIA
work_keys_str_mv	AT hyermichaelw stressanalysisoffiberreinforcedcompositematerials

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