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Hayes W.D., Probstein R.F. — Hypersonic Flow Theory
Hayes W.D., Probstein R.F. — Hypersonic Flow Theory



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Название: Hypersonic Flow Theory

Авторы: Hayes W.D., Probstein R.F.

Язык: en

Рубрика: Физика/

Статус предметного указателя: Готов указатель с номерами страниц

ed2k: ed2k stats

Издание: 1st edition

Год издания: 1959

Количество страниц: 464

Добавлена в каталог: 18.10.2009

Операции: Положить на полку | Скопировать ссылку для форума | Скопировать ID
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Предметный указатель
Hammitt, A.G.      206 368 370
Hammitt, A.G. 206, 368, 370      
Hansen C.F.      17 19 258 295
Hansen, C.F.      17 19 258 295
Hansen, C.F. 17, 19, 258, 295      
Hantzsche W.      295
Hantzsche, W.      295
Hantzsche, W. 295      
Hasimoto Z.      207
Hasimoto, Z.      207
Hasimoto, Z. 207      
Hastings S.M.      17 259
Hastings, S.M.      17 259
Hastings, S.M. 17, 259      
Hat core      64
Hat core 64      
Hayes W.D.      10 12 20 22 24 30 36 42 67 130 147 156 161 173 174 177 181 187 195 196 253 306 320 322 371 372
Hayes, W.D.      10 12 20 22 24 30 36 42 67 130 147 156 161 173 174 177 181 187 195 196 253 306 320 322 371 372
Hayes, W.D. 10, 12, 20, 22, 24, 30, 36, 42, 67, 130, 147, 156, 161, 173, 174, 177, 181, 187, 195, 196, 253, 306, 320, 322, 371, 372      
Heat conduction      27 284
Heat conduction 27, 284      
Heat conduction coefficient      287
Heat conduction coefficient 287      
Heat transfer in dissociating gas      286—288
Heat transfer in dissociating gas 286—288      
Heat transfer parameter      300 307—309
Heat transfer parameter 300, 307—309      
Heat transfer to body      see also "Nusselt number" "Stanton
Heat transfer to body by integral methods      320—322
Heat transfer to body in constant-pressure solutions      295—297
Heat transfer to body in free molecule flow      402 403 405
Heat transfer to body in rarefied gas flows      378
Heat transfer to body in stagnation point solutions      299
Heat transfer to body in weak interaction      348
Heat transfer to body see also “Nusselt number, Stanton number”      
Heat transfer to body with diffusion      302
Heat transfer to body with local similarity      313
Heat transfer to body with transverse curvature      353 364
Heat transfer to body with vorticity interaction      372 373
Heat transfer to body, by integral methods      320—322
Heat transfer to body, by integral methods 320—322      
Heat transfer to body, in constant-pressure solutions      295—297
Heat transfer to body, in constant-pressure solutions 295—297      
Heat transfer to body, in free molecule flow      402 403 405
Heat transfer to body, in free molecule flow 402, 403, 405      
Heat transfer to body, in rarefied gas flows      378
Heat transfer to body, in rarefied gas flows 378      
Heat transfer to body, in stagnation point solutions      299
Heat transfer to body, in stagnation point solutions 299      
Heat transfer to body, in weak interaction      348 Nusselt Stanton
Heat transfer to body, in weak interaction 348      
Heat transfer to body, nature of      286—288
Heat transfer to body, nature of 286—288      
Heat transfer to body, on highly cooled body      314 315
Heat transfer to body, on highly cooled body 314, 315      
Heat transfer to body, with diffusion      302
Heat transfer to body, with diffusion 302      
Heat transfer to body, with local similarity      313
Heat transfer to body, with local similarity 313      
Heat transfer to body, with transverse curvature      353 364
Heat transfer to body, with transverse curvature 353, 364      
Heat transfer to body, with vorticity interaction      372 373
Heat transfer to body, with vorticity interaction 372, 373      
Heims S.P.      260 261
Heims, S.P.      260 261
Heims, S.P. 260, 261      
Herzfeld K.F.      396
Herzfeld, K.F.      396
Herzfeld, K.F. 396      
High temperature gasdynamics      2 284—286
High temperature gasdynamics 2, 284—286      
Highly cooled body, simplifications with      314—316 360
Highly cooled body, simplifications with 314—316, 360      
Hilbert D.      95 100
Hilbert, D.      95 100
Hilbert, D. 95, 100      
Hill's spherical vortex      158
Hill's spherical vortex 158      
Hirschfelder J.O.      287 288
Hirschfelder, J.O.      287 288
Hirschfelder, J.O. 287, 288      
Holder D.W.      335
Holder, D.W.      335
Holder, D.W. 335      
Holt M.      254
Holt, M.      254
Holt, M. 254      
Homogeneous layer model      77 80 112 113 129
Homogeneous layer model 77, 80, 112, 113, 129      
Hord R.A.      148
Hord, R.A.      148
Hord, R.A. 148      
Hot core      64
Howarth L.      290
Howarth — Dorodnitsyn transformation      290
Howarth — Dorodnitsyn transformation 290      
Howarth — Dorodnitsyn variable in constant-density flows      149
Howarth — Dorodnitsyn variable in Newtonian flow ($\rho_{\infty}m$)      110 111 120 121 134 135
Howarth — Dorodnitsyn variable, in constant-density flows      149
Howarth — Dorodnitsyn variable, in constant-density flows 149      
Howarth — Dorodnitsyn variable, in Newtonian flow ($\rho_\infty m$)      110 111 120 121 134 135
Howarth — Dorodnitsyn variable, in Newtonian flow ($\rho_\infty m$) 110, 111, 120, 121, 134, 135
Howarth, L.      290
Howarth, L. 290      
Hugoniot relation      12 184 385
Hugoniot relation 12, 184, 385      
Huribut, F.C.      397
Hurlbut F.C.      397
Hurlbut, F.C. 397      
Hydraulic analogy for blunt-body flows      172 173
Hydraulic analogy for blunt-body flows 172, 173      
Hyperbolic shock wave, solutions with      249—251
Hyperbolic shock wave, solutions with 249—251      
Hypersonic axisymmetric sonic line      208 237 249
Hypersonic axisymmetric sonic line 208, 237, 249      
Hypersonic boundary layer independence principle      305 306
Hypersonic boundary layer independence principle 305, 306      
Hypersonic boundary layer solutions      293 303—306 354—357
Hypersonic boundary layer solutions 293, 303—306, 354—357      
Hypersonic flow      1 3 9
Hypersonic flow 1, 3, 9      
Hypersonic similarity parameter      40
Hypersonic similarity parameter 40      
Hypersonic similarity parameter, local      338 340
Hypersonic similarity parameter, local 338, 340      
Hypersonic similarity parameter, unified      43
Hypersonic similarity parameter, unified 43      
Hypersonic similitude      10 30 36—42
Hypersonic similitude 10, 30, 36—42      
Hypersonic similitude with specular reflection      407 408 411 412
Hypersonic similitude, unsteady      67
Hypersonic similitude, unsteady 67      
Hypersonic similitude, viscous      42
Hypersonic similitude, viscous 42      
Hypersonic similitude, with specular reflection      407 408 411 412
Hypersonic similitude, with specular reflection 407, 408, 411, 412      
Ideal dissociating gas      37
Ideal dissociating gas 37      
Il'yushin A.A.      36
Il'yushin, A.A.      36
Il'yushin, A.A. 36      
Illingworth C.R.      290 304 319
Illingworth, C.R.      290 304 319
Illingworth, C.R. 290, 304, 319      
Image locus      193 194
Image locus 193, 194      
Implosions      52 65—67
Implosions 52, 65—67      
Incident molecules, flux of      400
Incident molecules, flux of 400      
Incipient merged layer regime, in flow classification      385
Incipient merged layer regime, in flow classification 385      
Incompressible flow      139
Incompressible flow 139      
Independence principle, hypersonic boundary layer      305 306
Independence principle, hypersonic boundary layer 305, 306      
Independence principle, Mach number      see "Mach number independence principle"
Induced pressure      285 333
Induced pressure 285, 333      
Induced pressure in strong interaction      339 355 359—365
Induced pressure in turbulent boundary layer      335
Induced pressure in weak interaction      338 339 345 349 350
Induced pressure with cold wall      345
Induced pressure, in strong interaction      339 355 359—365
Induced pressure, in strong interaction 339, 355, 359—365      
Induced pressure, in turbulent boundary layer      335
Induced pressure, in turbulent boundary layer 335      
Induced pressure, in weak interaction      338 339 345 349 350
Induced pressure, in weak interaction 338, 339, 345, 349, 350      
Induced pressure, on cone      352
Induced pressure, on cone 352      
Induced pressure, on three-quarter power body of revolution      364
Induced pressure, on three-quarter power body of revolution 364      
Induced pressure, on three-quarter power two-dimensional body      363
Induced pressure, on three-quarter power two-dimensional body 363      
Induced pressure, with cold wail      345
Induced pressure, with cold wall 345      
Infinite speed ratio flows      403—406
Infinite speed ratio flows 403—406      
Initial pressure gradient on ogives      48—52 280 281
Initial pressure gradient on ogives 48—52, 280, 281      
Insensitiveness of shock shape      167 230
Insensitiveness of shock shape 167, 230      
Insensitiveness of solution to Mach number      see "Mach number independence principle"
Insensitiveness of solution to Mach number see “Mach number independence principle”      
Instability of procedures for inverse problem      230—234 246 247
Instability of procedures for inverse problem 230—234, 246, 247      
Integral methods for boundary layers      316—322
Integral methods for boundary layers 316—322      
Integral methods for pressure interaction      365 366
Integral methods for pressure interaction 365, 366      
Interaction parameter, hypersonic viscous      339 345
Interaction parameter, hypersonic viscous 339, 345      
Interaction, boundary layer      29 42 284 285 333—374
Interaction, boundary layer 29, 42, 284, 285, 333—374      
Intermediate regimes of rarefied gas flow      27 385 386
Intermediate regimes of rarefied gas flow 27, 385, 386      
Intermediate region in pressure interaction      338 362 365—367
Intermediate region in pressure interaction 338, 362, 365—367      
Internal degrees of freedom      403
Internal degrees of freedom 403      
Internal energy transfer, additional      402 403
Internal energy transfer, additional 402, 403      
Interpolation in relaxation techniques      228
Interpolation in relaxation techniques 228      
Interpolation polynomials      215 220
Interpolation polynomials 215, 220      
Intrinsic coordinates      204 212 255 256
Intrinsic coordinates 204, 212, 255, 256      
Inverse method for pressure interaction      366 367
Inverse method for pressure interaction 366, 367      
Inverse problem (shock given)      167 171 174 202 230—252
Inverse problem (shock given) 167, 171, 174, 202, 230—252      
Inviscid flow on equivalent body      341 371
Inviscid flow on equivalent body 341, 371      
Ionization      2 15 284 285
Ionization 2, 15, 284, 285      
Ipsen D.C.      353
Ipsen, D.C.      353
Ipsen, D.C. 353      
Isenberg J.S.      253
Isenberg, J.S.      253
Isenberg, J.S. 253      
Isentropic exponent      13 19 20
Isentropic exponent 13, 19, 20      
Isentropic exponent, frozen      264
Isentropic exponent, frozen 264      
Isotropic sail      92 120
Isotropic sail 92, 120      
Iteration methods for boundary layers      312
Iteration methods for boundary layers 312      
Ivey H.R.      47 79
Ivey, H.R.      47 79
Ivey, H.R. 47, 79      
Janssen E.      295
Janssen, E.      295
Janssen, E. 295      
Johainnsen N.H.      277
Johannsen, N.H.      277
Johannsen, N.H. 277      
JoHnson H.A.      296
Johnson, H.A.      296
Johnson, H.A. 296      
Jukoff D.      396
Jukoff, D.      396
Jukoff, D. 396      
Jump in shock angle      187 193 194
Jump in shock angle 187, 193, 194      
Jump in shock angle structure of 198, 199      
Jump in shock angle, structure of      198 199
Jump in shock structure of      198 199
Kantrowitz A.      286
Kantrowitz, A.      286
Kantrowitz, A. 286      
Karman momentum integral      316
Karman momentum integral 316      
Karman T. von      von Karman
Karman — Pohlausen method      318
Karman — Pohlausen method 318      
Karman — Pohlausen method in inviscid blunt-body flows      231 232
Karman — Pohlausen method in pressure interaction problems      365
Karman — Pohlausen method, in inviscid blunt-body flows      231 232
Karman — Pohlausen method, in inviscid blunt-body flows 231, 232      
Karman — Pohlausen method, in pressure interaction problems      365
Karman — Pohlausen method, in pressure interaction problems 365      
Karman, T. von      see "von Karman"
Karman, T. von see “von Karman”      
Kemp N.H.      153 157 159 297 301 307 313—316 388 394
Kemp, N.H.      153 157 159 297 301 307 313—316 388 394
Kemp, N.H. 153, 157, 159, 297, 301, 307, 313—316, 388, 394      
Kendall J.M., Jr.      349—351
Kendall, J.M., Jr.      349—351
Kendall, J.M., Jr. 349—351      
Kennard E.H.      399
Kennard, E.H.      399
Kennard, E.H. 399      
Kirkwood J.G.      254
Kirkwood, J.G.      254
Kirkwood, J.G. 254      
Kivel B.      386
Kivel, B.      386
Kivel, B. 386      
Klunker E.B.      79 295
Klunker, E.B.      79 295
Klunker, E.B. 79, 295      
Knudsen number      375 376 383 384
Knudsen number 375, 376, 383, 384      
Koga T.      351 352
Koga, T.      351 352
Koga, T. 351, 352      
Kogan A.      283
Kogan, A.      283
Kogan, A. 283      
Kopal Z.      48 148 352
Kopal, Z.      48 148 352
Kopal, Z. 48, 148, 352      
Korobkin I.      17 259
Korobkin, I.      17 259
Korobkin, I. 17, 259      
Krasheninnikova N.L.      53
1 2 3 4 5 6 7 8 9 10
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