SIST-TP CEN/TR 17603-32-02:2022
(Main)Space engineering - Structural materials handbook - Part 2: Design calculation methods and general design aspects
Space engineering - Structural materials handbook - Part 2: Design calculation methods and general design aspects
The structural materials handbook, SMH, combines materials and design information on established polymer matrix composites with provisional information on the emerging groups of newer advanced materials and their composites. Design aspects are described, along with factors associated with joining and manufacturing. Where possible, these are illustrated by examples or case studies.
The Structural materials handbook contains 8 Parts.
A glossary of terms, definitions and abbreviated terms for these handbooks is contained in Part 8.
The parts are as follows:
Part 1 Overview and material properties and applications Clauses 1 ‐ 9
Part 2 Design calculation methods and general design aspects Clauses 10 ‐ 22
Part 3 Load transfer and design of joints and design of structures Clauses 23 ‐ 32
Part 4 Integrity control, verification guidelines and manufacturing Clauses 33 ‐ 45
Part 5 New advanced materials, advanced metallic materials, general design aspects and load transfer and design of joints Clauses 46 ‐ 63
Part 6 Fracture and material modelling, case studies and design and integrity control and inspection Clauses 64 ‐ 81
Part 7 Thermal and environmental integrity, manufacturing aspects, in‐orbit and health monitoring, soft materials, hybrid materials and nanotechnoligies Clauses 82 ‐ 107
Part 8 Glossary
NOTE: The 8 parts will be numbered TR17603-32-01 to TR 17603-32-08
Raumfahrttechnik - Handbuch Konstruktionswerkstoffe - Teil 2: Konstruktionsberechnungsverfahren und allgemeine Konstruktionsaspekte
Ingénierie spatiale - Manuel des matériaux structuraux - Partie 2 : Méthodes de calculs de conception et aspects généraux de conception
Vesoljska tehnika - Priročnik o strukturnih materialih - 2. del: Metode za izračun zasnove in splošni vidiki zasnove
Priročnik o strukturnih materialih, SMH, združuje informacije o materialih in oblikovanju uveljavljenih polimernih matričnih kompozitov z začasnimi informacijami o nastajajočih skupinah novejših naprednih materialov in njihovih kompozitov. Opisani so vidiki oblikovanja, skupaj z dejavniki združevanja in proizvodnje. Kjer je mogoče, so podani primeri ali študije primerov.
Priročnik o strukturnih materialih vsebuje 8 delov.
Slovar izrazov, opredelitve in okrajšave izrazov za te priročnike so v 8. delu.
Deli so:
1. del: Pregled in lastnosti materialov ter aplikacije Točke 1–9
2. del: Metode za izračun zasnove in splošni vidiki zasnove Točke 10–22
3. del: Prenos obremenitve ter projektiranje spojev in konstrukcij Točke 23–32
4. del: Nadzor integritete, smernice za preverjanje in proizvodnja Točke 33–45
5. del: Novi napredni materiali, napredni kovinski materiali, splošni konstrukcijski vidiki ter prenos obremenitve in oblikovanje sklepov Točke 46–63
6. del: Modeliranje zlomov in materialov, študije primerov, načrtovanje in nadzor integritete ter inšpekcijski pregled Točke 64–81
7. del: Toplotna in okoljska celovitost, proizvodni vidiki, spremljanje stanja materialov v orbiti, mehki materiali, hibridni materiali in nanotehnologije Točke 82–107
8. del: Slovar
OPOMBA: Teh 8 delov je označenih s številkami od TR17603-32-01 do TR 17603-32-08.
General Information
Standards Content (Sample)
SLOVENSKI STANDARD
SIST-TP CEN/TR 17603-32-02:2022
01-marec-2022
Vesoljska tehnika - Priročnik o strukturnih materialih - 2. del: Metode za izračun
zasnove in splošni vidiki zasnove
Space engineering - Structural materials handbook - Part 2: Design calculation methods
and general design aspects
Raumfahrttechnik - Handbuch Konstruktionswerkstoffe - Teil 2:
Konstruktionsberechnungsverfahren und allgemeine Konstruktionsaspekte
Ingénierie spatiale - Manuel des matériaux structuraux - Partie 2 : Méthodes de calculs
de conception et aspects généraux de conception
Ta slovenski standard je istoveten z: CEN/TR 17603-32-02:2022
ICS:
49.140 Vesoljski sistemi in operacije Space systems and
operations
SIST-TP CEN/TR 17603-32-02:2022 en,fr,de
2003-01.Slovenski inštitut za standardizacijo. Razmnoževanje celote ali delov tega standarda ni dovoljeno.
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SIST-TP CEN/TR 17603-32-02:2022
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SIST-TP CEN/TR 17603-32-02:2022
TECHNICAL REPORT CEN/TR 17603-32-02
RAPPORT TECHNIQUE
TECHNISCHER BERICHT
January 2022
ICS 49.140
English version
Space engineering - Structural materials handbook - Part
2: Design calculation methods and general design aspects
Ingénierie spatiale - Manuel des matériaux structuraux Raumfahrttechnik - Handbuch
- Partie 2 : Méthodes de calculs de conception et Konstruktionswerkstoffe - Teil 2:
aspects généraux de conception Konstruktionsberechnungsverfahren und allgemeine
Konstruktionsaspekte
This Technical Report was approved by CEN on 22 November 2021. It has been drawn up by the Technical Committee
CEN/CLC/JTC 5.
CEN and CENELEC members are the national standards bodies and national electrotechnical committees of Austria, Belgium,
Bulgaria, Croatia, Cyprus, Czech Republic, Denmark, Estonia, Finland, France, Germany, Greece, Hungary, Iceland, Ireland, Italy,
Latvia, Lithuania, Luxembourg, Malta, Netherlands, Norway, Poland, Portugal, Republic of North Macedonia, Romania, Serbia,
Slovakia, Slovenia, Spain, Sweden, Switzerland, Turkey and United Kingdom.
CEN-CENELEC Management Centre:
Rue de la Science 23, B-1040 Brussels
© 2022 CEN/CENELEC All rights of exploitation in any form and by any means Ref. No. CEN/TR 17603-32-02:2022 E
reserved worldwide for CEN national Members and for
CENELEC Members.
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CEN/TR 17603-32-02:2022 (E)
Table of contents
European Foreword . 25
Introduction . 26
10 Stress-strain relationships . 27
10.1 Introduction . 27
10.2 Elastic property prediction for UD ply from constituent properties. 27
10.3 Analytical notation for elastic constant methods . 29
10.4 Calculation methods for elastic constants of UD ply . 29
10.5 Longitudinal modulus . 31
10.6 Longitudinal Poisson's ratio . 33
10.7 Transverse modulus . 34
10.7.1 General . 34
10.7.2 Jones method . 34
10.7.3 Förster/Knappe method . 34
10.7.4 Schneider method . 35
10.7.5 Puck method . 35
10.7.6 Tsai method . 35
10.7.7 HSB method. 36
10.7.8 Graphs . 36
10.8 Transverse Poisson's ratio . 39
10.9 Transverse shear modulus . 39
10.9.1 General . 39
10.9.2 Jones method . 39
10.9.3 Förster/Knappe method . 39
10.9.4 Schneider method . 39
10.9.5 Puck method . 40
10.9.6 Tsai method . 40
10.9.7 HSB method. 40
10.9.8 Graphs . 41
10.10 In-plane stress calculation methods . 43
10.11 Analytical notation for in-plane methods . 43
2
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10.12 Stress-strain relations for unidirectional plies . 45
10.12.1 Fibre-oriented co-ordinate system . 45
10.13 On axis stress strain relations . 45
10.13.1 General . 45
10.13.2 Compliance matrix . 46
10.13.3 Modulus matrix . 46
10.13.4 Symmetry of compliance and modulus matrices . 46
10.14 Stress-strain relations for a ply of arbitrary orientation . 46
10.14.1 General . 46
10.14.2 Off axis stiffness of a unidirectional ply. 48
10.15 Stiffness matrix for a laminate . 49
10.15.1 General laminates . 49
10.15.2 Symmetric laminates . 51
10.15.3 Flow chart . 52
10.16 Calculation methods with interlaminar stresses and strains . 53
10.16.1 Calculation with free-edge stresses . 53
10.17 Qualitative evaluation of interlaminar strength for design purposes . 55
10.17.1 General . 55
10.17.2 Variation of fibre direction within a [±φ°, 0°, ±φ°] laminate . 57
10.17.3 Variation of the thickness of the 0° layer within the [± 30°, 0n°, ± 30°]
laminate . 57
10.17.4 Variation of the sequence of layers . 58
10.18 References . 58
10.18.1 General . 58
11 Strength prediction and failure criteria . 60
11.1 Introduction . 60
11.1.1 Micro-mechanical strength models . 60
11.1.2 Lamina failure models . 60
11.1.3 Failure criteria studies . 61
11.1.4 Summary of World Wide Failure Exercise (WWFE) . 62
11.2 Tensile strength of UD composites in fibre direction . 64
11.2.1 General . 64
11.2.2 Weakest-link failure model . 64
11.2.3 Cumulative weakening failure model . 64
11.2.4 Fibre break propagation model . 66
11.2.5 Cumulative group mode failure model . 66
11.2.6 Status of models . 66
3
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11.3 Compressive strength of UD composites in fibre direction. 66
11.3.1 General . 66
11.3.2 Extension mode buckling . 67
11.3.3 Shear mode buckling . 67
11.3.4 Analysis of compression failure . 68
11.4 Transverse tensile strength of UD composites . 70
11.4.1 General . 70
11.4.2 Prediction of transverse tensile strength . 71
11.4.3 Empirical analysis . 71
11.5 Static strength criteria for composites . 72
11.6 Analytical notation for static strength criteria for composites . 72
11.6.1 Co-ordinate system . 72
11.6.2 Formulae . 73
11.7 Different types of failure criteria . 74
11.7.1 General . 74
11.7.2 Evaluation studies . 75
11.8 Overview - Failure criteria . 75
11.8.1 Introduction . 75
11.8.2 Independent conditions . 76
11.8.3 Interactive conditions – Pure interpolative conditions . 77
11.8.4 Interactive conditions - Physical considerations . 78
11.9 Comparison between test data and various failure criteria . 87
11.9.1 Effects on failure mode . 87
11.10 Description of failure modes . 91
11.10.1 Laminates . 91
11.10.2 Failure . 91
11.11 Fatigue strength of composites . 96
11.11.1 Background . 96
11.11.2 Analytical notation . 97
11.11.3 Approximation of fatigue life . 97
11.12 References . 99
11.12.1 General . 99
12 Calculation of thermal stress and displacement . 103
12.1 Introduction . 103
12.1.1 General . 103
12.1.2 Longitudinal CTE . 103
12.1.3 Transverse CTE . 103
4
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12.2 Analytical notation for thermal stress calculations . 104
12.3 Calculation of CTE from constituents . 105
12.3.1 CTE in fibre direction . 105
12.3.2 CTE perpendicular to fibre direction . 105
12.4 CTE for a laminate . 106
12.5 Thermal stresses within laminate layers . 108
12.5.1 General . 108
12.5.2 Residual curing stresses . 108
12.6 Stress strain temperature relation . 109
12.6.1 General . 109
12.6.2 Mechanical strains . 109
12.6.3 Incremental strain theory . 109
12.7 Microstress analysis . 111
12.7.1 General . 111
12.7.2 Microstresses on fibre axis . 111
12.7.3 Microstresses normal to fibre axis . 111
12.8 References . 111
12.8.1 General . 111
13 Moisture effects on composite properties . 113
13.1 Introduction . 113
13.1.1 General . 113
13.1.2 Moisture penetration . 113
13.1.3 Moisture effects . 113
13.2 Analytical notation for moisture effects . 114
13.3 Typical effects of moisture. 115
13.3.1 General . 115
13.3.2 Sample data: Effects of moisture . 115
13.4 Approximate method for calculation of strength and modulus retention of
[0°/90°] laminates . 120
13.4.1 General . 120
13.4.2 Modulus retention . 120
13.4.3 Strength retention . 122
13.5 Moisture content . 123
13.5.1 Fick's law . 123
13.5.2 Determination of moisture content . 124
13.5.3 Maximum moisture content . 125
13.5.4 Experimental determination of the diffusion coefficient . 126
5
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13.6 Calculation of swelling coefficient from constituents . 128
13.6.1 General . 128
13.6.2 Swelling coefficient β in fibre direction. 128
1
13.6.3 Swelling coefficient β transverse to fibres . 128
2
13.6.4 Swelling coefficient for a laminate . 129
13.7 Coefficient of moisture expansion (CME) . 131
13.7.1 Resin behaviour . 131
13.7.2 Composite behaviour . 132
13.8 References . 133
13.8.1 General . 133
14 Stress concentrations and fracture . 135
14.1 Introduction . 135
14.1.1 General . 135
14.1.2 Fracture mechanics models . 135
14.2 Analytical notation for stress concentrations . 136
14.3 Summary of fracture models . 136
14.4 Evaluation of fracture models . 137
14.5 WEK fracture model . 138
14.5.1 General . 138
14.5.2 Circular holes . 138
14.5.3 Straight crack . 141
14.6 WN fracture model . 144
14.6.1 General . 144
14.6.2 Failure criteria . 144
14.6.3 Characteristics of WN fracture model . 146
14.6.4 Circular holes . 147
14.6.5 Straight cracks . 151
14.6.6 Point stress criteria . 152
14.6.7 Average stress criterion . 153
14.7 Finite plate models . 157
14.8 Finite width correction (FWC) . 157
14.8.1 General . 157
14.8.2 Circular holes . 159
14.8.3 Centre crack. 160
14.9 Calculated stress concentration factor at circular holes . 160
14.9.1 NASA results . 160
14.9.2 Finite width correction (FWC) . 162
6
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14.9.3 MBB/ERNO study . 162
14.10 Stress distribution around circular holes . 167
14.10.1 General . 167
14.10.2 Stress concentration due to tensile load . 167
14.10.3 Stress concentration due to shear load . 168
14.11 Interlaminar fracture mechanics . 170
14.11.1 Nomenclature . 170
14.11.2 Delamination and fracture mechanics overview . 170
14.11.3 Standard test methods (static and fatigue) . 174
14.11.4 Calculation of strain energy release rate in structural analysis . 178
14.12 References . 184
14.12.1 General . 184
15 Prediction of dynamic characteristics . 188
15.1 Introduction . 188
15.2 Definition of damping terms . 188
15.2.1 General terms . 188
15.2.2 Complex modulus model . 190
15.3 Prediction methods for damping . 191
15.4 Determination of damping characteristics . 192
15.4.1 Unidirectional characteristics . 192
15.4.2 Off axis characteristics . 192
15.4.3 Laminate characteristics. 193
15.5 Approximate data on damping . 193
15.6 References . 194
15.6.1 General . 194
16 Computer analysis of composites . 195
16.1 Introduction . 195
16.2 Computer programs: Analysis of composites . 195
16.2.1 General . 195
16.2.2 Finite element programs. 197
16.2.3 Laminate analysis programs . 198
16.2.4 Special applications programs . 200
16.3 ESDU data for composite analysis . 202
16.3.1 General . 202
16.3.2 ESDU data items . 202
16.3.3 ESDUpac . 204
16.4 Buckling of orthotropic plates . 204
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16.4.1 Title . 204
16.4.2 Usage and scope . 204
16.4.3 Analysis . 204
16.4.4 ESDUpac A7303 . 204
16.4.5 Notes . 205
16.5 Flexural stiffness of flat strips . 205
16.5.1 Title . 205
16.5.2 Usage and scope . 205
16.5.3 Analysis . 205
16.6 Metallic skin stiffeners reinforced by composite - local buckling . 206
16.6.1 Title . 206
16.6.2 Usage and scope . 206
16.6.3 Analysis and data . 206
16.7 Laminate stress analysis . 207
16.7.1 Title . 207
16.7.2 Usage and scope . 207
16.7.3 Analysis . 207
16.8 Plate stiffnesses (In-plane) . 208
16.8.1 Title .
...
SLOVENSKI STANDARD
kSIST-TP FprCEN/TR 17603-32-02:2021
01-oktober-2021
Vesoljska tehnika - Priročnik o strukturnih materialih - 2. del: Metode za izračun
zasnove in splošni vidiki zasnove
Space engineering - Structural materials handbook - Part 2: Design calculation methods
and general design aspects
Raumfahrttechnik - Handbuch Konstruktionswerkstoffe - Teil 2:
Konstruktionsberechnungsverfahren und allgemeine Konstruktionsaspekte
Ingénierie spatiale - Manuel des matériaux structuraux - Partie 2 : Méthodes de calculs
de conception et aspects généraux de conception
Ta slovenski standard je istoveten z: FprCEN/TR 17603-32-02
ICS:
49.140 Vesoljski sistemi in operacije Space systems and
operations
kSIST-TP FprCEN/TR 17603-32-02:2021 en,fr,de
2003-01.Slovenski inštitut za standardizacijo. Razmnoževanje celote ali delov tega standarda ni dovoljeno.
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kSIST-TP FprCEN/TR 17603-32-02:2021
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kSIST-TP FprCEN/TR 17603-32-02:2021
TECHNICAL REPORT
FINAL DRAFT
FprCEN/TR 17603-32-02
RAPPORT TECHNIQUE
TECHNISCHER BERICHT
July 2021
ICS 49.140
English version
Space engineering - Structural materials handbook - Part
2: Design calculation methods and general design aspects
Ingénierie spatiale - Manuel des matériaux structuraux Raumfahrttechnik - Handbuch
- Partie 2 : Méthodes de calculs de conception et Konstruktionswerkstoffe - Teil 2:
aspects généraux de conception Konstruktionsberechnungsverfahren und allgemeine
Konstruktionsaspekte
This draft Technical Report is submitted to CEN members for Vote. It has been drawn up by the Technical Committee
CEN/CLC/JTC 5.
CEN and CENELEC members are the national standards bodies and national electrotechnical committees of Austria, Belgium,
Bulgaria, Croatia, Cyprus, Czech Republic, Denmark, Estonia, Finland, France, Germany, Greece, Hungary, Iceland, Ireland, Italy,
Latvia, Lithuania, Luxembourg, Malta, Netherlands, Norway, Poland, Portugal, Republic of North Macedonia, Romania, Serbia,
Slovakia, Slovenia, Spain, Sweden, Switzerland, Turkey and United Kingdom.
Recipients of this draft are invited to submit, with their comments, notification of any relevant patent rights of which they are
aware and to provide supporting documentation.
Warning : This document is not a Technical Report. It is distributed for review and comments. It is subject to change without
notice and shall not be referred to as a Technical Report.
CEN-CENELEC Management Centre:
Rue de la Science 23, B-1040 Brussels
© 2021 CEN/CENELEC All rights of exploitation in any form and by any means Ref. No. FprCEN/TR 17603-32-02:2021 E
reserved worldwide for CEN national Members and for
CENELEC Members.
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kSIST-TP FprCEN/TR 17603-32-02:2021
FprCEN/TR 17603-32-02:2021 (E)
Table of contents
European Foreword . 25
Introduction . 26
10 Stress-strain relationships . 27
10.1 Introduction . 27
10.2 Elastic property prediction for UD ply from constituent properties. 27
10.3 Analytical notation for elastic constant methods . 29
10.4 Calculation methods for elastic constants of UD ply . 29
10.5 Longitudinal modulus . 31
10.6 Longitudinal Poisson's ratio . 33
10.7 Transverse modulus . 34
10.7.1 General . 34
10.7.2 Jones method . 34
10.7.3 Förster/Knappe method . 34
10.7.4 Schneider method . 35
10.7.5 Puck method . 35
10.7.6 Tsai method . 35
10.7.7 HSB method. 36
10.7.8 Graphs . 36
10.8 Transverse Poisson's ratio . 39
10.9 Transverse shear modulus . 39
10.9.1 General . 39
10.9.2 Jones method . 39
10.9.3 Förster/Knappe method . 39
10.9.4 Schneider method . 39
10.9.5 Puck method . 40
10.9.6 Tsai method . 40
10.9.7 HSB method. 40
10.9.8 Graphs . 41
10.10 In-plane stress calculation methods . 43
10.11 Analytical notation for in-plane methods . 43
2
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10.12 Stress-strain relations for unidirectional plies . 45
10.12.1 Fibre-oriented co-ordinate system . 45
10.13 On axis stress strain relations . 45
10.13.1 General . 45
10.13.2 Compliance matrix . 46
10.13.3 Modulus matrix . 46
10.13.4 Symmetry of compliance and modulus matrices . 46
10.14 Stress-strain relations for a ply of arbitrary orientation . 46
10.14.1 General . 46
10.14.2 Off axis stiffness of a unidirectional ply. 48
10.15 Stiffness matrix for a laminate . 49
10.15.1 General laminates . 49
10.15.2 Symmetric laminates . 51
10.15.3 Flow chart . 52
10.16 Calculation methods with interlaminar stresses and strains . 53
10.16.1 Calculation with free-edge stresses . 53
10.17 Qualitative evaluation of interlaminar strength for design purposes . 55
10.17.1 General . 55
10.17.2 Variation of fibre direction within a [±°, 0°, ±°] laminate . 57
10.17.3 Variation of the thickness of the 0° layer within the [± 30°, 0n°, ± 30°]
laminate . 57
10.17.4 Variation of the sequence of layers . 58
10.18 References . 58
10.18.1 General . 58
11 Strength prediction and failure criteria . 60
11.1 Introduction . 60
11.1.1 Micro-mechanical strength models . 60
11.1.2 Lamina failure models . 60
11.1.3 Failure criteria studies . 61
11.1.4 Summary of World Wide Failure Exercise (WWFE) . 62
11.2 Tensile strength of UD composites in fibre direction . 64
11.2.1 General . 64
11.2.2 Weakest-link failure model . 64
11.2.3 Cumulative weakening failure model . 64
11.2.4 Fibre break propagation model . 66
11.2.5 Cumulative group mode failure model . 66
11.2.6 Status of models . 66
3
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11.3 Compressive strength of UD composites in fibre direction. 66
11.3.1 General . 66
11.3.2 Extension mode buckling . 67
11.3.3 Shear mode buckling . 67
11.3.4 Analysis of compression failure . 68
11.4 Transverse tensile strength of UD composites . 70
11.4.1 General . 70
11.4.2 Prediction of transverse tensile strength . 71
11.4.3 Empirical analysis . 71
11.5 Static strength criteria for composites . 72
11.6 Analytical notation for static strength criteria for composites . 72
11.6.1 Co-ordinate system . 72
11.6.2 Formulae . 73
11.7 Different types of failure criteria . 74
11.7.1 General . 74
11.7.2 Evaluation studies . 75
11.8 Overview - Failure criteria . 75
11.8.1 Introduction . 75
11.8.2 Independent conditions . 76
11.8.3 Interactive conditions – Pure interpolative conditions . 77
11.8.4 Interactive conditions - Physical considerations . 78
11.9 Comparison between test data and various failure criteria . 87
11.9.1 Effects on failure mode . 87
11.10 Description of failure modes . 91
11.10.1 Laminates . 91
11.10.2 Failure . 91
11.11 Fatigue strength of composites . 96
11.11.1 Background . 96
11.11.2 Analytical notation . 97
11.11.3 Approximation of fatigue life . 97
11.12 References . 99
11.12.1 General . 99
12 Calculation of thermal stress and displacement . 103
12.1 Introduction . 103
12.1.1 General . 103
12.1.2 Longitudinal CTE . 103
12.1.3 Transverse CTE . 103
4
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12.2 Analytical notation for thermal stress calculations . 104
12.3 Calculation of CTE from constituents . 105
12.3.1 CTE in fibre direction . 105
12.3.2 CTE perpendicular to fibre direction . 105
12.4 CTE for a laminate . 106
12.5 Thermal stresses within laminate layers . 108
12.5.1 General . 108
12.5.2 Residual curing stresses . 108
12.6 Stress strain temperature relation . 109
12.6.1 General . 109
12.6.2 Mechanical strains . 109
12.6.3 Incremental strain theory . 109
12.7 Microstress analysis . 111
12.7.1 General . 111
12.7.2 Microstresses on fibre axis . 111
12.7.3 Microstresses normal to fibre axis . 111
12.8 References . 111
12.8.1 General . 111
13 Moisture effects on composite properties . 113
13.1 Introduction . 113
13.1.1 General . 113
13.1.2 Moisture penetration . 113
13.1.3 Moisture effects . 113
13.2 Analytical notation for moisture effects . 114
13.3 Typical effects of moisture. 115
13.3.1 General . 115
13.3.2 Sample data: Effects of moisture . 115
13.4 Approximate method for calculation of strength and modulus retention of
[0°/90°] laminates . 120
13.4.1 General . 120
13.4.2 Modulus retention . 120
13.4.3 Strength retention . 122
13.5 Moisture content . 123
13.5.1 Fick's law . 123
13.5.2 Determination of moisture content . 124
13.5.3 Maximum moisture content . 125
13.5.4 Experimental determination of the diffusion coefficient . 126
5
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13.6 Calculation of swelling coefficient from constituents . 128
13.6.1 General . 128
13.6.2 Swelling coefficient in fibre direction. 128
1
13.6.3 Swelling coefficient transverse to fibres . 128
2
13.6.4 Swelling coefficient for a laminate . 129
13.7 Coefficient of moisture expansion (CME) . 131
13.7.1 Resin behaviour . 131
13.7.2 Composite behaviour . 132
13.8 References . 133
13.8.1 General . 133
14 Stress concentrations and fracture . 135
14.1 Introduction . 135
14.1.1 General . 135
14.1.2 Fracture mechanics models . 135
14.2 Analytical notation for stress concentrations . 136
14.3 Summary of fracture models . 136
14.4 Evaluation of fracture models . 137
14.5 WEK fracture model . 138
14.5.1 General . 138
14.5.2 Circular holes . 138
14.5.3 Straight crack . 141
14.6 WN fracture model . 144
14.6.1 General . 144
14.6.2 Failure criteria . 144
14.6.3 Characteristics of WN fracture model . 146
14.6.4 Circular holes . 147
14.6.5 Straight cracks . 151
14.6.6 Point stress criteria . 152
14.6.7 Average stress criterion . 153
14.7 Finite plate models . 157
14.8 Finite width correction (FWC) . 157
14.8.1 General . 157
14.8.2 Circular holes . 159
14.8.3 Centre crack. 160
14.9 Calculated stress concentration factor at circular holes . 160
14.9.1 NASA results . 160
14.9.2 Finite width correction (FWC) . 162
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14.9.3 MBB/ERNO study . 162
14.10 Stress distribution around circular holes . 167
14.10.1 General . 167
14.10.2 Stress concentration due to tensile load . 167
14.10.3 Stress concentration due to shear load . 168
14.11 Interlaminar fracture mechanics . 170
14.11.1 Nomenclature . 170
14.11.2 Delamination and fracture mechanics overview . 170
14.11.3 Standard test methods (static and fatigue) . 174
14.11.4 Calculation of strain energy release rate in structural analysis . 178
14.12 References . 184
14.12.1 General . 184
15 Prediction of dynamic characteristics . 188
15.1 Introduction . 188
15.2 Definition of damping terms . 188
15.2.1 General terms . 188
15.2.2 Complex modulus model . 190
15.3 Prediction methods for damping . 191
15.4 Determination of damping characteristics . 192
15.4.1 Unidirectional characteristics . 192
15.4.2 Off axis characteristics . 192
15.4.3 Laminate characteristics. 193
15.5 Approximate data on damping . 193
15.6 References . 194
15.6.1 General . 194
16 Computer analysis of composites . 195
16.1 Introduction . 195
16.2 Computer programs: Analysis of composites . 195
16.2.1 General . 195
16.2.2 Finite element programs. 197
16.2.3 Laminate analysis programs . 198
16.2.4 Special applications programs . 200
16.3 ESDU data for composite analysis . 202
16.3.1 General . 202
16.3.2 ESDU data items . 202
16.3.3 ESDUpac . 204
16.4 Buckling of orthotropic plates . 204
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16.4.1 Title . 204
16.4.2 Usage and scope . 204
16.4.3 Analysis . 204
16.4.4 ESDUpac A7303 . 204
16.4.5 Notes . 205
16.5 Flexural stiffness of flat strips . 205
16.5.1 Title . 205
16.5.2 Usage and scope . 205
16.5.3 Analysis . 205
16.6 Metallic skin stiffeners reinforced by composite - local buckling . 206
16.6.1 Title . 206
16.6.2 Usage and scope . 206
16.6.3 Analysis and data . 206
16.7 Laminate stress analysis . 207
16.7.1 Title .
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