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Jones R.M. — Mechanics of composite materials
Jones R.M. — Mechanics of composite materials



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Íàçâàíèå: Mechanics of composite materials

Àâòîð: Jones R.M.

Àííîòàöèÿ:

This book balances introduction to the basic concepts of the mechanical behavior of composite materials and laminated composite structures. It covers topics from micromechanics and macromechanics to lamination theory and plate bending, buckling, and vibration, clarifying the physical significance of composite materials. In addition to the materials covered in the first edition, this book includes more theory-experiment comparisons and updated information on the design of composite materials.


ßçûê: en

Ðóáðèêà: Ìåõàíèêà/

Ñòàòóñ ïðåäìåòíîãî óêàçàòåëÿ: Ãîòîâ óêàçàòåëü ñ íîìåðàìè ñòðàíèö

ed2k: ed2k stats

Èçäàíèå: second edition

Ãîä èçäàíèÿ: 1999

Êîëè÷åñòâî ñòðàíèö: 519

Äîáàâëåíà â êàòàëîã: 19.10.2005

Îïåðàöèè: Ïîëîæèòü íà ïîëêó | Ñêîïèðîâàòü ññûëêó äëÿ ôîðóìà | Ñêîïèðîâàòü ID
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Ïðåäìåòíûé óêàçàòåëü
Strength      2 26—31 390 398 423 “Generally “Orthotropic “Specially
Strength in fiber direction      88
Strength tensor      91 102 115
Strength transverse to fiber direction      88
Strength, analogy to plate buckling      238
Strength, angle-ply laminate      255—258
Strength, axial      88
Strength, cross-ply laminate      246—255
Strength, experimental determination of      91—102
Strength, fatigue      272 333—336 339
Strength, in fiber direction      88 91 93—95
Strength, longitudinal      88
Strength, of a laminate      237—260
Strength, of an orthotropic lamina      88—118
Strength, shear      88 91 96—101 115
Strength, transverse to fiber direction      88 91 95—96
Strength, unequal in tension and compression      89—91 115
Stress concentration      409
Stress concentration factor      336—339 342 383
Stress distribution      281
Stress-strain behavior, lamina      191
Stress-strain behavior, nonlinear      454 458
Stress-strain relations      118
Stress-strain relations, anisotropic      56
Stress-strain relations, compliances in      118
Stress-strain relations, engineering constants in      118
Stress-strain relations, for a generally orthotropic lamina      77
Stress-strain relations, for a lamina of arbitrary orientation      74—85
Stress-strain relations, for a specially orthotropic lamina      76
Stress-strain relations, isotropic      60
Stress-strain relations, monoclinic      59
Stress-strain relations, orthotropic      59
Stress-strain relations, plane stress (orthotropic)      71
Stress-strain relations, stiffnesses in      118
Stress-strain relations, thermal      242—244
Stress-strain relations, transformed      74
Stress-strain relations, transversely isotropic      59
Stresses, hygroscopic      245—246
Stresses, interiaminar      260—275
Stresses, moisture      245—246
Stresses, principal      88
Stresses, thermal      242—260
Stresses, transformation of      74
Strong design drivers      378
Structural configuration      426
Structural design process      368 370 372—389
Structural optimization      426
Structural optimization techniques      447
Structural polymers, thermoplastic-matrix materials      5 25—26
Structural polymers, thermoset-matrix materials      5 23
Structural reconfiguration      380 383—384 414—417
Structural response parameters      381—382
Structural synthesis      428
Supersonic transport      38 49
Sutton, W.H.      4
Swedlow, J.L.      345
Symmetric laminate      206—214
Symmetric laminate, angle-ply      212—213 233 291—295 306—307
Symmetric laminate, bending of      290—295
Symmetric laminate, buckling of      303—307
Symmetric laminate, cross-ply      210—211 225 354
Symmetric laminate, regular      210—212
Symmetric laminate, stiffnesses      206—214
Symmetric laminate, vibration      315—318
Symmetric laminate, with anisotropic layers      213—214
Symmetric laminate, with generally orthotropic layers      211—213
Symmetric laminate, with isotropic layers      207—209
Symmetric laminate, with specially orthotropic layers      209—211 290—291
Tailoring of composite materials      12 18 378
Talreja, R.      335
Tape laying      19—20
Taylor series      480—481
Taylor, R.L.      361
Technical constants      63 (see also “Engineering constants”)
Temperature effects      242—260 360
Tennyson, R.C.      118
Tensors      467 472—477
Tensors, cartesian      472
Tensors, contracted notation for      475—476
Tensors, direction cosines for      473
Tensors, dummy index      473
Tensors, index notation      472
Tensors, matrix form of      476—477
Tensors, order of      472 474
Tensors, range convention for      473
Tensors, scalar      474
Tensors, summation convention for      473
Tensors, transformation of      472—477
Tensors, vector      474
Tetelman, A.S.      345
thermal conductivity      2
Thermal expansion      242 390
Thermal stresses      242—260 356
Thermal stresses, coefficient of thermal expansion      242
Thermal stresses, equivalent mechanical loads      244
Thermal stresses, free thermal strain      242
Thermal stresses, thermal coupling      252—253 258
Thermal stresses, thermal forces      243 356
Thermal stresses, thermal moments      244 356
Thermoplastic-matrix materials      5 25—26
Thermoset-matrix materials      5 23
Thomas, R.L.      152
Timoshenko, S.P.      174—175 283 289 301 506
Torsion-tube test      99
Total potential energy      357
Trade studies      388
Trade-off      375 390 463 465
Transformation of stiffnesses      77 85
Transformation of strains      74
Transformation of stresses      74
Transformed reduced stiffnesses      77 85 97 191
Transverse load      289—290 296 353—354
Transverse shearing effects      345—355 460—461
Transverse shearing stresses      454 505
Transverse stiffness      91 95 101 129—131 148
Transverse strength      88 91 95 101
Transversely isotropic material      59
Transversely isotropic material, plane stress state      70
Transversely isotropic material, strain-stress relations      61
Transversely isotropic material, stress-strain relations      59
Triclinic material      58 (see also “Anisotropy”)
Trifurcation      358
Tsai — Hill failure criterion      105 109—112 115—116 241 246 249—250 256—258 422 435 439
Tsai — Wu tensor failure criterion      105 114—117
Tsai, S.W.      58 85 87 99 105—107 109 111—120 123 126 131 146 148—157 160—164 225 227—236 241 246 249 254—256 258—259 276 360 362—363 365 422 433 440—443 446—447 451 466 472 477
underdesign      383
Uniaxial tension test      93—98
Unidirectionally reinforced lamina      15 27—28 55 70 73 108
Unidirectionally reinforced lamina, fundamental strengths of      88—102
Unidirectionally reinforced lamina, invariant properties of      85—87
Unidirectionally reinforced lamina, macromechanical behavior      55—119
Unidirectionally reinforced lamina, micromechanical behavior      121—185
Unidirectionally reinforced lamina, representative volume element      124
Unidirectionally reinforced lamina, strength of      88—102 163—185
Unidirectionally reinforced lamina, strength of, compressive      171—185
Unidirectionally reinforced lamina, strength of, tensile      164—171
Unsymmetric laminate      206 214 218—219 323—327 356—359 362
Unsymmetric laminate, cross-ply      356—359
Unsymmetric laminate, postcuring shapes      356—359
Van Cleave, R.R.      47
Van Hamersveld, J.      47
Variations in displacements      506
Vasiliev, V.V.      277
Vibration      317 381—382 427
Vibration of laminated plates      277—279 288 315—322
Vibration of laminated plates, antisymmetric angle-ply laminates      320—322
Vibration of laminated plates, antisymmetric cross-ply laminates      318—320
Vibration of laminated plates, boundary conditions      288
Vibration of laminated plates, governing equations      288
Vibration of laminated plates, solution techniques      288—289
Vibration of laminated plates, specially orthotropic laminates      315—317
Vibration of laminated plates, symmetric angle-ply laminates      317—318
Vibration of laminated plates, unsymmetric cross-ply laminates      327
Vibration, frequencies      316—317 319—323 327 360—361
Vibration, mode shapes      316—317
Vinson, J.R.      245—246 277
Viscoelastic behavior      17 362
Volume fraction      123
von Mises, R.      104
Vought A-7 speedbrake      40—41
Vought S-3A spoiler      42—43
Waddoups, M.E.      99 306 345 435
Wang, A.S.D.      348
Wang, J.T.S.      289
Wave propagation      362
Weak design drivers      378
Weibull distribution      169
Weight      2 36—37 424
Weight-sensitive structures      386 390
Wendt, F.W.      364 466
Whiskers      15
Whiskers, definition of      4
Whiskers, properties of      4
Whitney, J.M.      99—100 147 246 277 292 295 298—299 301 307 312 314—316 318 321—322 328 350 354—355 360 461
Wide optimum design      378
Wilkins, D.J.      335
Woinowsky-Krieger, S.      283 289
Woven lamina      15 125
Wu, E.M.      105 114—117 339—340 343—344
Yang, P.C.      355
Young’s moduli      13 63 84 123 143
Young’s moduli, apparent      138—143
Young’s moduli, apparent for a lamina      127—131 143
Young’s moduli, for boron-epoxy      69
Young’s moduli, restrictions on      68
Yurenka, S.      363
Zhang, G.      183
1 2 3 4
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