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Àâòîðèçàöèÿ |
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Ïîèñê ïî óêàçàòåëÿì |
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Hayes W.D., Probstein R.F. — Hypersonic Flow Theory |
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Ïðåäìåòíûé óêàçàòåëü |
Prandtl number influence, in stagnation point solutions 301—303
Prandtl number, longitudinal 391
Prandtl number, longitudinal 391
Prandtl number, turbulent 327
Prandtl number, turbulent 327
Prandtl — Glauert similitude 38 42 44
Prandtl — Glauert similitude 38, 42, 44
Prandtl — Meyer flow 39 52 258—265
Prandtl — Meyer flow 39, 52, 258—265
Prandtl — Meyer flow, turning angle in 39 258—261
Prandtl — Meyer flow, turning angle in 39, 258—261
Prandtl — Meyer relation in inverted form 264
Prandtl — Meyer relation in inverted form 264
Pressure coefficient in free molecule similitude 408
Pressure coefficient in hypersonic similitude 39 41 43
Pressure coefficient in steady Newtonian flow 78 81 82 84 117 119
Pressure coefficient in strip theory 46
Pressure coefficient in unsteady Newtonian flow 133 134 138
Pressure coefficient, in free molecule similitude 408
Pressure coefficient, in free molecule similitude 408
Pressure coefficient, in hypersonic similitude 39 41 43
Pressure coefficient, in hypersonic similitude 39, 41, 43
Pressure coefficient, in steady Newtonian flow 78 81 82 84 117 119
Pressure coefficient, in steady Newtonian flow 78, 81, 82, 84, 117, 119
Pressure coefficient, in strip theory 46
Pressure coefficient, in strip theory 46
Pressure coefficient, in unsteady Newtonian flow 133 134 138
Pressure coefficient, in unsteady Newtonian flow 133, 134, 138
Pressure coefficient, near general stagnation point 129
Pressure coefficient, near general stagnation point 129
Pressure coefficient, on circular cylinder in constant-density flow 153
Pressure coefficient, on circular cylinder in constant-density flow 153
Pressure coefficient, on circular cylinder in Newtonian flow 82 154
Pressure coefficient, on circular cylinder in Newtonian flow 82, 153
Pressure coefficient, on cone 145 146
Pressure coefficient, on cone 145, 146
Pressure coefficient, on conical Newtonian body 126
Pressure coefficient, on conical Newtonian body 126
Pressure coefficient, on oscillating Newtonian flat plate 137
Pressure coefficient, on oscillating Newtonian flat plate 137
Pressure coefficient, on sphere in constant-density flow 159 161
Pressure coefficient, on sphere in constant-density flow 159, 161
Pressure coefficient, on sphere in Newtonian flow 82 160
Pressure coefficient, on sphere in Newtonian flow 82, 160
Pressure coefficient, on wedge 142
Pressure coefficient, on wedge 142
Pressure coefficient, on yawed cone in Newtonian flow 126
Pressure coefficient, on yawed cone in Newtonian flow 126
Pressure coefficient, on yawed cylinder in Newtonian flow 122 125
Pressure coefficient, on yawed cylinder in Newtonian flow 122, 125
Pressure diffusion 289
Pressure diffusion 289
Pressure gradient behind corner 277
Pressure gradient behind corner 277
Pressure in free molecule flow 400 401
Pressure interaction 285 333—367
Pressure interaction 285, 333—367
Pressure interaction, integral and inverse methods for 365—367
Pressure interaction, integral and inverse methods for 365—367
Pressure problem (pressure given) 167 178 179
Pressure problem (pressure given) 167, 178, 179
Pressure ratio across shock 14
Pressure ratio across shock 14
Pressure, behind oblique shock 269
Pressure, behind oblique shock 269
Pressure, behind oblique shook 269
Pressure, generated by blunt nose 63 368 369
Pressure, generated by blunt nose 63, 368, 369
Pressure, in free molecule flow 400 401
Pressure, in free molecule flow 400, 401
Pressure, induced in interaction see "Induced pressure"
Pressure, induced in interaction see “Induced pressure”
Pretsch J. 359 364
Pretsch, J. 359 364
Pretsch, J. 359, 364
Prim R.C. 268
Prim, R.C. 268
Prim, R.C. 268
Principal characteristic 265—268 282
Principal characteristic 265—268, 282
Probstein R.F. 42 204 231 264 268—273 282 283 306 312 326—332 336 337 341 342 348 351—354 364 366 369 372 376 387 388 391 394
Probstein, R.F. 42 204 231 264 268—273 282 283 306 312 326—332 336 337 341 342 348 351—354 364 366 369 372 376 387 388 391 394
Probstein, R.F. 42, 204, 231, 264, 268—273, 282, 283, 306, 312, 326—332, 336, 337, 341, 342, 348, 351—354, 364, 366, 369, 372, 376, 387, 388, 391, 394
Proper optimum shapes 93 97—105
Proper optimum shapes 93, 97—105
Proper optimum shapes, axisymmetric 103—105
Proper optimum shapes, axisymmetric 103—105
Proper optimum shapes, two-dimensional 101—103 105
Proper optimum shapes, two-dimensional 101—103, 105
Pseudo-elliptic region see "Transonic zone"
Pseudo-elliptic region see “Transonic zone”
Radiation 2 16
Radiation 2, 16
Rarefied gas effects 27 375—380
Rarefied gas effects 27, 375—380
Rarefied gas effects, cold wall paradoxes 379 383 384
Rarefied gas effects, cold wall paradoxes 379, 383, 384
Rarefied gas effects, slip phenomena 379 380
Rarefied gas effects, slip phenomena 379, 380
Rarefied gas effects, with interaction important 340
Rarefied gas effects, with interaction important 340
Rarefied gas flows 27 375—415
Rarefied gas flows 27, 375—415
Rarefied gas flows in axisymmetric stagnation region 377—381
Rarefied gas flows in two-dimensional stagnation region 381
Rarefied gas flows, continuum solutions for 386—395
Rarefied gas flows, continuum solutions for 386—395
Rarefied gas flows, in axisymmetric stagnation region 377—381
Rarefied gas flows, in axisymmetric stagnation region 377—381
Rarefied gas flows, in two-dimensional stagnation region 381
Rarefied gas flows, in two-dimensional stagnation region 381
Rarefied gas flows, on slender body 381—383
Rarefied gas flows, on slender body 381—383
Rarefied gas flows, regime classification in 384—386
Rarefied gas flows, regime classification in 384—386
Rarefied gas flows, with free molecule flow 383 384
Rarefied gas flows, with free molecule flow 383, 384
Ratio of specific heats 13 18—20
Ratio of specific heats 13, 18—20
Ratio of specific heats, frozen 264
Ratio of specific heats, frozen 264
Re-emission of molecules 383 395—398
Re-emission of molecules 383, 395—398
Real-fluid effects 26—29
Real-fluid effects 26—29
Recombination 264 284—288
Recombination 264, 284—288
Recombination, catalytic, on body 287 288 310 311 328
Recombination, catalytic, on body 287, 288, 310, 311, 328
Recovery temperature 296 307 344
Recovery temperature 296, 307, 344
Recovery temperature in free molecule flow 405 406
Recovery temperature in weak interaction 348
Recovery temperature, in free molecule flow 405 406
Recovery temperature, in free molecule flow 405, 406
Recovery temperature, in weak interaction 348
Recovery temperature, in weak interaction 348
Reduction in equation order in series expansion 325
Reduction in equation order in series expansion 325
Reference enthalpy method 296—298 301
Reference enthalpy method 296—298, 301
Reference enthalpy method, with turbulent boundary layers 328 329
Reference enthalpy method, with turbulent boundary layers 328, 329
Reflected characteristic 265—268 282
Reflected characteristic 265—268, 282
Reflection coefficient, for molecules 398
Reflection coefficient, for molecules 398
Reflection coefficient, shock 268—270 283
Reflection coefficient, shock 268—270, 283
Reflection of molecules 383 395—398
| Reflection of molecules 383, 395—398
Reflection of waves from shock waves 268—272
Reflection of waves from shock waves 268—272
Reflection of waves from vorticity 268 271 272
Reflection of waves from vorticity 268, 271, 272
Reflection of waves, from shock waves 268—272
Reflection of waves, from vorticity 268 271 272
Reimpingement of Newtonian free layers 88 89 120 138
Reimpingement of Newtonian free layers 88, 89, 120, 138
Reissner E. 67 68
Reissner, E. 67 68
Reissner, E. 67, 68
Relaxation 2 16 27 284
Relaxation 2, 16, 27, 284
Relaxation in thin shock layers 394
Relaxation techniques 226—230
Relaxation techniques 226—230
Relaxation times 16 254 263 264
Relaxation times 16, 254, 263, 264
Relaxation, in thin shock layers 394
Relaxation, in thin shock layers 394
Relaxation, method of characteristics with 254
Relaxation, method of characteristics with 254
Relaxation, on shock thickness, effect of 378
Relaxation, on shock thickness, effect of 378
Reshotko E. 299 305—309 319—321
Reshotko, E. 299 305—309 319—321
Reshotko, E. 299, 305—309, 319—321
Residuals in relaxation technique 228
Residuals in relaxation technique 228
Resler E.L. 254
Resler, E.L. 254
Resler, E.L. 254
Resnikoff M.M. 72 93—95
Resnikoff, M.M. 72 93—95
Resnikoff, M.M. 72, 93—95
Reynold's analogy 297 328
Reynold's analogy 297, 328
Reynold's analogy in hypersonic free molecule flow 412
Reynold's analogy, in hypersonic free molecule flow 412
Reynold's analogy, in hypersonic free molecule flow 412
Reynolds number 297 299 325
Reynolds number 297, 299, 325
Reynolds number, based on leading edge thickness 7 63 335 367—369
Reynolds number, based on leading edge thickness 7, 63, 335, 367—369
Reynolds stress 327
Reynolds stress 327
Riddell F.R. 285—289 297 301—321
Riddell, F.R. 285—289 297 301—303 310 311 372
Riddell, F.R. 285—289, 297, 301—321
Rigid sphere model of kinetic theory 376
Rigid sphere model of kinetic theory 376
Rockett J.A. 253
Rockett, J.A. 253
Rockett, J.A. 253
Roller coaster problem 112—114
Roller coaster problem 112—114
Romig M.F. 148 295 296 300
Romig, M.F. 148 295 296 300
Romig, M.F. 148, 295, 296, 300
Rose P.H. 297 303 304 307 313—316 326—332
Rose, P.H. 297 303 304 307 313—316 326—332
Rose, P.H. 297, 303, 304, 307, 313—316, 326—332
Roshko A. 328 329 375 376
Roshko, A. 328 329 375 376
Roshko, A. 328, 329, 375, 376
Rossow V.J. 30
Rossow, V.J. 30
Rossow, V.J. 30
Rotational energy transfer 263 396 402
Rotational energy transfer 263, 396, 402
Rott N. 319
Rott, N. 319
Rott, N. 319
Rubesin M.W. 296
Rubesin, M.W. 296
Rubesin, M.W. 296
Rubinov S.I. 230
Rubinov, S.I. 230
Rubinov, S.I. 230
Sakurai A. 52 64
Sakurai, A. 52 64
Sakurai, A. 52, 64
Sanger E. 73
Sanger, E. 73
Sanger, E. 73
Sauer F.M. 415
Sauer, F.M. 415
Sauer, F.M. 415
Savin R.C. 268 273—276
Savin, R.C. 268 273—276
Savin, R.C. 268, 273—276
Scale transformation 37 45
Scale transformation 37, 45
Scattering coefficient 398
Scattering coefficient 398
Schaaf S.A. 351 376 379 387 396—398
Schaaf, S.A. 351 376 379 387 396—398
Schaaf, S.A. 351, 376, 379, 387, 396—398
Schlichting H. 323
Schlichting, H. 323
Schlichting, H. 323
Schmidt number 294 311
Schmidt number 294, 311
Sedov L.I. 53—61 64
Sedov, L.I. 53—61 64
Sedov, L.I. 53—61, 64
Self induced interactions see "Boundary layer induced interactions"
Self induced interactions see “Boundary layer induced interactions”
Self-similar fluid 37 40 52 293
Self-similar fluid 37, 40, 52, 293
Semenov number see "Lewis — Semenov number"
Semenov number see “Lewis — Semenov number”
Serbin H. 195
Serbin, H. 195
Serbin, H. 195
Series-expansion methods for boundary layers 322—325
Series-expansion methods for boundary layers 322—325
Sharp leading edge, with pressure interaction 335
Sharp leading edge, with pressure interaction 335
Shear layer, supersonic 271
Shear layer, supersonic 271
Shear stress in free molecule flow 400 402
Shear stress in free molecule flow 400, 402
Shear stress in rarefied gas flows 380
Shear stress in rarefied gas flows 380
Shear stress in viscous flows 296
Shear stress in viscous flows 296
Shen S.F. 49 231 353
Shen, S.F. 49 231 353
Shen, S.F. 49, 231, 353
Sherman F.S. 351 386 387
Sherman P.M. 351 352
Sherman, F.S. 351 386 387
Sherman, F.S. 351, 386, 387
Sherman, P.M. 351 352
Sherman, P.M. 351, 352
Shock as edge of boundary layer 336 354
Shock as edge of boundary layer 336, 354
Shock induced interactions 29 334 335
Shock induced interactions 29, 334, 335
Shock layer m scale 79 110—112 118—121 134 135
Shock layer m scale 79, 110—112, 118—121, 134, 135
Shock layer m scale in unsteady flow 134 135
Shock layer m scale, at genera stagnation point 128 164
Shock layer m scale, at general stagnation point 128 164
Shock layer m scale, at general stagnation point 128, 164
Shock layer m scale, in unsteady flow 134 135
Shock layer m scale, in unsteady flow 134, 135
Shock layer m scale, on circular cylinder 111 155
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