rambomenaa
كبير مهندسين
عدد المساهمات : 2041
التقييم : 3379
تاريخ التسجيل : 21/01/2012
العمر : 46
الدولة : مصر
العمل : مدير الصيانة بشركة تصنيع ورق
الجامعة : حلوان
 |  موضوع: كتاب Casting Aluminum Alloys الثلاثاء 10 يوليو 2012, 11:20 am | |
| 
أخوانى فى الله
أحضرت لكم كتاب
Casting Aluminum Alloys
Vadim S. Zoijotorevsky
Nikolai a. Belov
Michael V Glazoff
و المحتوى كما يلي :
Alloying Elements and Dopants: Phase Diagrams
Structure and Microstructure of Aluminum Alloys in as-cast State
Influence of Heat Treatment Upon Microstructure of Casting Aluminum Alloys
Industrial Casting Aluminum Alloys
New Alloys
Activation Energy of Dissolution, 194
Aging, 240–245
Ai–si Alloys
Casting Properties of, 509
Characteristics of Crack Resistance,
Fracture Toughness, Fatigue
Properties, and Thermal Stability,
507–508
Corrosion Resistance of, 508
Al Alloys, 14, See Also Specific Alloys
Alloying Elements in, 2–6
Ancillary Additions in, 6–9
Casting Properties, See Casting Properties,
Of Al Alloys
Impurities in, 9–11
Al–be–fe–si Phase Diagram, 56–58
Al–be–fe System, 14–15, 16
Al–be–si System, 15–16
Al–ce Alloys, 14
Al–ce–cu System, 16
Non-variant Reactions in, 18
Phase Diagram, 17
Al–ce–fe System, 18
Non-variant Reactions in, 20
Phase Diagram, 19–20
Al–ce–ni System, 20–21
Al–ce–si System, 21–22
Al–cr–fe System, 22–23
Al–cr–mg System, 23–24
Al–cr–mn System, 24–26
Al–cr–si System, 26
Non-variant Phase Reactions in, 27
Al–cu Alloys, 425
Al–cu–fe–mg System, 58
Non-variant Phase Reactions in, 60
Phase Diagram, 59
Al–cu–fe–ni System, 60–62
Al–cu–fe–si System, 62–64
Non-variant Reactions in, Five-phase, 64
Phase Diagram, 63
Al–cu–fe System, 26
Non-variant Reactions in, 28
Phase Diagram, 28
Al–cu–mg–mn System, 64
Non-variant Reactions in, 66
Phase Diagram, 65
Al–cu–mg–si System, 64–66
Non-variant Reactions in, 68
Phase Diagram, 67
Al–cu–mg System, 29–32
Non-variant Reactions in, 31
Phase Diagram, 30
Al–cu–mg–zn System, 66–68
Non-variant Reactions in, 71
Phase Diagram, 70–71
Al–cu–mn System, 32–34
Non-variant Phase Reactions in, 33
Phase Diagram, 32
Al–cu–ni System, 34–35
Non-variant Phase Reactions in, 35
Phase Diagram, 34
Al–cu–si System, 36, 37
Al–cu (2xx) Alloys, 376–386
Alloying Elements
Copper, 377, 381, 386
Iron, 377, 379, 381, 382
Magnesium, 377, 379
Manganese, 377, 379, 381, 382
Nickel, 377, 385–386
Silicon, 379, 381, 382, 384, 385–386
Castability in, 377, 379, 386
Mechanical Properties, 379–386
Russian Alloy Am4.5kd, 381, 385–386
Al–cu–zn System, 36–38
Non-variant Reactions in, 38
Phase Diagram, 38
Al–fe–cu–mg–si System, 82–84
Alloys Rich in Magnesium, 91
Alloys With High Content of Copper, 87–91
Alloys With High Content of Silicon, 85–87
Bivariant Reactions in, 85
Monovariant Reactions in, 86
Non-variant Phase Reactions of
Solidification in, 89
Non-variant Reactions in, 86
Phase Diagram, 84, 88524 Index
Al–fe–mg–mn System, 68–69, 72
Al–fe–mg–si System, 70–74
Non-variant Five-phase Reactions in, 74
Phase Diagram, 73
Al–fe–mg System, 38–39
Al–fe–mn–si System, 74–77
Chemical Composition of Intermediate
Phases in, 77
Non-variant Five-phase Reactions in, 76
Non-variant Reactions in, 76
Phase Diagram, 75
Al–fe–mn System, 39–40
Al–fe–ni–si System, 77–79
Non-variant Phase Reactions in, 79
Phase Diagram, 78
Al–fe–ni System, 41–42
Non-variant Reactions in, 42
Phase Diagram, 41
Al–fe–si System, 42–45
Phase Diagram, 43
Solubility of Fe and Si in Al, 44
Allen–cahn Equations, 101
Alloying Elements
Functions, 2–6
Groups for Aluminum Alloy Design, 1
Alloying Elements and Constituent Particles, in
Industrial Casting Alloys, 331, 332,
See Also Specific Alloys
Alloys of the Solid Solution Type, 107
Alloy Systems, Basic, Role of Alloying Elements
In, 13–14
Al–mg Alloys, Equations Relating Mechanical
Properties of, to Grain Size, 285, 286
Al–mg Alloys (5xx Alloys), See Also Industrial
Al–mg and Al–mg–zn Alloys
Alloying Elements
Copper, 388
Iron, 388
Magnesium, 387
Manganese, 387
Silicon, 387
Zinc, 387
Castability in, 387, 389, 392
Casting Properties of, 389–390
Characteristics, 386–390
Equilibrium Solidus of, 396
Al–mg–mn–si System, 79
Non-variant Reactions in, 81
Phase Diagram, 80
Al–mg–mn System, 45, 46
Al–mg–ni–si System, 79–81
Phase Diagram, 82
Al–mg–si System, 45–47
Joint Solubility of Mg and Si in Solid Al, 49
Non-variant Phase Reactions in, 48
Phase Diagram, 47–48
Al–mg–zn Alloys, Characteristics of
Microsegregation in, 147
Al–mg–zn System, 47–49
Mutual Solubility of Mg and Zn in Solid
Aluminum, 52
Non-variant Phase Reactions in, 51
Phase Diagram, 50
Al–mn–ni System, 49–50, 52
Al–mn–si System
Maximum Solubility of Mn and Si in Al, 54
Non-variant Four-phase Reactions in, 54
Phase Diagram, 53
Al–ni Alloys, 14
Al–si Alloys, 260, 290
Binary, 5–6
Casting, 2, 11, 12
Al–si Alloys, With Low-si, 442–447
Alloying Elements Distribution
Copper and Magnesium, 443
Iron, 444
Manganese, 444
And Mechanical Properties, 446
Silicon, 443
Zinc, 444
Microstructure of, 445–446
Al–si Alloys (4xx and 3xx Alloys), 328, See Also
Al–si Alloys
Alloying Elements
Beryllium, 330
Copper, 328–329, 335, 336
Iron, 329, 330, 332, 336, 346
Magnesium, 328, 335
Manganese, 329
Nickel, 329–330, 335, 368
Silicon, 328, 332, 337
Zinc, 329, 354
Castability, 336, 342, 344, 352, 359
Compositions, 332
With Copper and Zinc, 351–367
Engine Piston Al–si Alloys, See Engine
Piston Al–si Alloysindex 525
Fractography of Cu-bearing Al–si Alloys
With Small Amounts of Silicon,
366–367
Phase Composition of 3xx Alloys, 361–366
Of Russian Nomenclature, 352, 353–359
Copper-less Al–si Alloys (3xx and 4xx Alloys),
336–351
Fractography of, 347–351, 352
Microstructure, 337–338
Phase Composition, 336–342, 346
Of Russian Nomenclature, 342–345
Corrosion Resistance, 335–336
Distribution of Alloying Elements, 331
Mechanical Properties, 332–336
Al–si–ni System, 54–55
Al– Zn–mg–cu System, 400, 424
Chemical Composition of High-strength,
Corrosion-resistant Alloys Based on,
404
Eutectic Alloys Based, 410
Aluminum Association Nomenclature Alloys,
336, 386
Ancillary Additions, 6–9
Ats7mg3n4 Alloy, 423–425
Az6n4 Alloy, 418–423
Beryllium, 9
Binary Al Alloys
Mechanical Properties Dependence and
Chemical Composition, 311–326
Binary Alloys
Composition, and Homogenization Time,
201–205
Eutectic Al–si Master Alloys, 332
Microsegregation Elimination Kinetics in,
201–206
Non-equilibrium Eutectic (Qme) in a,
129–130
Volume Fraction, 190–193
Binary Phase Diagrams Closer to Aluminum Side,
487–489
Bochvar Theory, 252
?-phase Inclusions, and Dissolution, 186
Burgers Vector, 113
Cadmium, 9
Cahn–hilliard Equation, 100
Castability, See Also Casting Properties, of Al Alloys
In Al–mg (5xx) Alloys, 387, 389, 392
Improvement in Eutectic Alloys, 408, 412
In Industrial Al–cu (2xx) Alloys, 377, 379,
385
In Industrial Al–si (4xx and 3xx) Alloys, 336,
342, 344, 352, 359
Casting Al Alloys, See Also New Casting Alloys;
Specific Alloys
Aging After Casting and Quenching, 240–245
Castability Dependence of, See Casting
Properties, of Al Alloys
Fracture Toughness and Fatigue Properties of,
302–311
Grain Microstructure of, 108
High-strength Weldable Casting Alloy, See
Az6n4 Alloy
Homogenizing Heat Treatment for, See
Homogenization, Processes in
Mechanical Properties, Dependence of,
See Mechanical Properties,
Dependence of
Oxides and Fatigue Life of, 309
Standard, Compositions of, 461–486
With Transition Metals, See Thermally Stable
Alloys
Casting Al Alloys, Substructure of
Decomposition of Aluminum Solid Solution,
177–182
Dislocation Microstructures
Influence of Solidification Conditions
Upon, 166–171
Mechanisms of Formation, 171–177
Dislocation Structures, Types of, 162–166
Casting Cooling Rate and Dissolution
Time, 200
Casting Hermeticity, 249, 254–255
Casting Properties, of Al Alloys
Basic, 247–258
Hermeticity, Casting, 249, 254–255
Hot Cracking, 250–251, 255–257
Linear Shrinkage, 249–250, 255
Liquid Fluidity, 247, 254
Macrosegregation, 251–252
Molten Metal Fluidity, 247, 248, 253
Volume Shrinkage, 254
Concentration Dependence of, 258–262
Casting Properties, of Al–mg Alloys, 389–390
Coagulation, in Homogenization, See
Fragmentation and Spheroidization
Processes526 Index
Compositions, Alloy
Of Binary Alloys and Homogenization Time,
201–206
And Subgrain Growth During
Homogenization, 228–229
Concentration
Of Alloying Elements and Aging, 241
Of Alloying Elements and Microsegregation
Binary Alloys, 201–206
Multicomponent Alloys, 206–213
Dependence on Casting Properties, 258–262
Gradient of Excessive Constituent Particles,
186
Of Silicon and Microstructure of Al–si Alloys,
258–262, 290
Of Transition Metals and Decomposition of
Al Solution, 230–240
Copper and Zinc Bearing Al–si Alloys (of
Russian Nomenclature), 352
Ak6m2 (Al–6si–2cu), 355
Ak5m2 (Al–5si–2cu), 354, 355, 358, 359
Ak5m4 (Al–5si–4cu), 355, 357
Ak5m (Al–5si–1cu), 353–354, 355
Ak5m7 (Al–5si–7cu), 357
Ak8m3 (Al–8si–3cu), 358–359
Ak8m (Al–8si–1cu), 357–358
Ak9m2 (Al-9si-2cu), 359
Chemical Composition of, 356
Copper-less Al–si Alloys (of Russian
Nomenclature), 342–345
Ak7 (Al–7si), 343, 344–345, 354
Ak8 (Al–8si), 343, 345
Ak9 (Al–9si), 342, 343, 344, 345, 354
Ak12 (Al–12si), 332, 338, 342, 343, 344
Ak13 (Al–13si), 342, 343
Ak10su, 343, 345
Corrosion Resistance,al–si Alloys (4xx and 3xx
Alloys), 335–336
Decomposition of Aluminum Solid Solutions,
Before Quenching, 230–240
Deformation Diagrams, for as-cast and
Quenched Aluminum Alloys, 266–280
Degree of Alloying, Tensile Mechanical
Properties and, 286
Dendritic Solidification
3d Phase-field Modeling of, 103
Of Pure Metals, 102–103
Density, 111
In Alloys With Subgrain Microstructure,
113–114
Of Dislocations, See Dislocation Density of
Alloys
Dislocation Density of Alloys, 112–113
And Fracture Toughness, 305
Tensile Mechanical Properties, and, 290–291
Dislocation Microstructures, 166
Alloys on the Basis of Al–cu System, 169–171
Alloys on the Basis of Al–mg System,
167–169
And Homogenization, 222–230
Influence of Solidification Conditions Upon,
166–171
Mechanisms of Formation in Cast Aluminum
Alloys, 171–177
Dispersoids, 229, 231, 233–234, 238–239, 243
Dissolution, During Homogenization, See Also
Dissolution Kinetics
Activation Energy of, 194
Of ?-phase Inclusions, 186
Kinetics and Experimental Studies, 190–194
Of Non-equilibrium Constituent Particles,
184–190
Time, 193
Casting Cooling Rate and, 200
And Effect of Refinement of as-cast
Microstructure on, 195–200
Equations Relating, of Excessive Phases
Dissolved Particles Thickness, 197,
198–199
Of Non-equilibrium Eutectic Dissolution,
188–189
Dissolution Kinetics
Experimental Studies, 190–194
And Homogenization Temperature
Dependence, 193–194
Microstructure Characteristics of, 193,
195–196
Solidification Rate and, 195
Effective Solidification Range, 252–253
Engine Piston Al–si Alloys, 367–376, See Also
Al–si Alloys (4xx and 3xx Alloys)
Chemical Composition, 370
Fractography of, 376
Phase Composition, 368–369, 373–376index 527
Of Russian Nomenclature
Ak12m2mgn (Al12si2cu1mg1ni),
375, 376
Ak12mmgn (Al12si1cu1mg1ni), 375,
376
Ak21m2.5n2.5 (Al121si2.5cu2.5ni),
375–376
Equilibrium Thermodynamics, 97
Of Concentrationally Non-uniform Systems,
98–101
Eulerian Tensor Field, 515
Eutectic Alloys, 2
Multicomponent, 405–420
Alloy Castability Improvement, 408, 412
Mechanical Properties, 411
Microstructure Analysis, 411–413,
417–418
Phase Composition in, 412–415
Silicon Phase in, 409
Phase-field Models of Solidification of,
104–106
Fatigue Properties, of Casting Al Alloys, 302–311
Five-component Phase Diagrams, 81–93
Al–fe–cu–mg–si System, 85–91
Five-component Systems With Manganese,
91–93
Fractography
Of Copper-bearing Al–si Alloys With Small
Amounts of Silicon, 366–367
Copper-less Al–si Alloys (3xx and 4xx Alloys),
347–351, 352
Of Engine Piston Al–si Alloys, 376
Fracture Toughness of Casting Al Alloys, 302–311
Fragmentation and Spheroidization Processes,
213–222
Friction Stress Parameter, 301
Ginzburg–landau Equation, 101
Grain Microstructure of Cast Aluminum Alloy,
108
Grain Refinement, During Homogenization, 229
Grain Size and Homogenization, 222–230
Grain Size Effect
And Fracture Toughness, 305
Tensile Mechanical Properties, and, 281–282,
284, 285
Hall–petch Relationship, 282
Heat Treatment(S), for Casting Al Alloys
Homogenizing, 184, See Also Homogenization,
Processes in
Types, 183
Hermeticity, Casting, 249, 254–255
High-strength Alloys of Solid Solution Type,
397–398
High-temperature Homogenization, 193,
See Also Homogenization
Alloying Element Concentrations and, 211
Porosity and, 240
Homogenization
Grain Refinement in, 230
Grain Size and Dislocation Microstructures,
Changes During, 222–230
High-temperature, See High-temperature
Homogenization
Particle Morphologies, Change During, See
Fragmentation and Spheroidization
Processes
Processes in
Decomposition of Aluminum Solid
Solution Containing Transition Metals,
230–240
Dissolution of Non-equilibrium
Constituent Particles, 184–200
Fragmentation and Spheroidization
Processes, 213–222
Grain Size and Dislocation Microstructures,
Changes in, 222–230
Microsegregation Elimination During,
200–213
Porosity Development, 240
Solidification Rate and, See Solidification Rate,
During Homogenization
Time
And Composition of Binary Alloys,
201–206
And Volume Fraction, 190–193, 238–239
Hot Cracking, 250, 251, 255–257
Index (Hci), 250, 251
Probes, 250–251
Hot Tearing Susceptibility (Hts), 415, 416
Hypo-eutectic Alloys, 2
Impurities, 9–11
Industrial Alloys, 2, 3, 4, See Also Specific Alloys528 Index
Industrial Al–mg and Al–mg–zn Alloys,
390–396, See Also Al–mg Alloys
(5xx Alloys)
Amg7 (Al7mg), 392, 393
Amg11 (Al11mg), 394
Amg10 (Al10mg) Alloy, 391–392
Amg5k1 (Al5mg1si), 395
Amg4k1.5m (Al4mg1.5si1cu), 395
Amg6l Alloy, 390
Amg6lch (Al6mg) Alloy, 391
Amg5mts (Al5mg1mn), 392
Ats4mg (Al4zn1mg), 395
Industrial Casting Al Alloys, See Specific Alloys
Kirkendall Effect, 240
Lagrangian Tensor Field, 515
Lead, 330, See Also Al–si Alloys
Linear Shrinkage, 249–250, 255
Liquid Fluidity, 247, 254
Lithium, 2
Local Macrosegregation, 252
Machine Equation, 514
Macrosegregation, 251–252
Macrostructure, 95
Magnesium, 282
Magnesium Silicide, 161
Manganese, 7, 151–154
Mechanical Properties
Of Al–cu Alloys, Role of Alloying Elements
And Constituent Particles in, 379–386
Of Al–si Alloys, 335–336
Heat Treatment Scheme and, 333–334
And Role of Alloying Elements and
Constituent Particles in, 328–332
Of Engine Piston Al–si Alloys, See Engine
Piston Al–si Alloys
Mechanical Properties, Dependence of,
262–266
Calculation Using Microstructural Parameters,
295–302
On Chemical Composition, Regularities in
Changes of, 311–326
On Microstructure
Fracture Toughness and Fatigue Properties,
302–311
Geometry of Deformation Diagrams for
As-cast and Quenched Aluminum Alloys,
266–280
Tensile Mechanical Properties and, See
Tensile Mechanical Properties
Micress (Microstructure Simulation Software),
107
Microsegregation
In Binary Aluminum Alloys, 119–125
Concentration Threshold for Appearance of
Non-equilibrium Constituent Particles
(Phases), 125–128
Elimination Kinetics, 200
Binary Alloys, 201–206
Multicomponent Alloys, 206–213
In Three-component and Industrial
Aluminum Alloys
Key Alloying Elements, 145–151
Manganese, 151–154
In Two-component Aluminum Alloys,
115–119
Microstructure, 95, 100, See Also Specific Entries
Characteristics
Calculation of Mechanical Properties of
Castings Using, 295–302
Tensile Mechanical Properties and, 284,
286–290
And Hot Cracking, 257
Mechanical Properties Dependence on
Fracture Toughness and Fatigue Properties,
302–311
Geometry of Deformation Diagrams for
As-cast and Quenched Aluminum Alloys,
266–280
Tensile Mechanical Properties and, See
Tensile Mechanical Properties
Microstructure and Homogenization
Characteristics of Dissolution Kinetics,
195–196
Fragmentation and Spheroidization Processes
Effect on, 213–222
Microsegregation Elimination and, 200
Binary Alloys, 201–206
Multicomponent Alloys, 206–213
Refinement of as-cast Microstructure, and
Dissolution Kinetics, 195–200
Molten Metal Fluidity, 247, 248, 253–254
Multicomponent Alloys, See Also Eutectic Alloys,
Multicomponentindex 529
Grain Size Change in, 229
Microsegregation Elimination Kinetics in,
206–213
New Casting Alloys
Alloys With Small Amounts of Eutectic,
397–405
01568 Alloy, 402
01976 Alloy, 403
01984 Alloy, 402–403
Al24p Alloy, 398
Al– Zn–mg–cu System for, 400, 404
Amg5k Alloy, 403
Drawbacks, 405
Val11 Alloy, 398, 399, 400
Val12 Alloy, 399, 400
Al–si Alloys, With Low–si, 441–447
Ats7mg3n4 Alloy, 418–424
Az6n4 Alloy, 418–424
Eutectic Alloys, 405–418
With Small Amounts of Silicon, 441–447
Thermally Stable Alloys, With Transition
Metals, 425–441
Nickalin, See Az6n4 Alloy
Non-equilibrium Eutectic (Qme) in a Binary
Alloy, 129–130
Non-equilibrium Solidification, 111
Non-equilibrium Solidification of Binary Alloys,
114
Microsegregation
In Binary Aluminum Alloys, 119–125
Concentration Threshold for Appearance of
Non-equilibrium Constituent Particles
(Phases), 125–128
In Two-component Aluminum Alloys,
115–119
Solidification
Constituent Particles of Secondary
(Excessive) Phases, 128–132
Suppression of Peritectic Reactions,
132–134
Non-equilibrium Solidification of
Multi-component Alloys
Microsegregation in Three-component and
Industrial Aluminum Alloys
Key Alloying Elements, 145–151
Manganese, 151–154
Phase Diagrams
Al–cu–fe–si System, 139–140
Al–fe–mg–si System, 140–143
Al–fe–ni–si System, 143–145
Al–fe–si System, 134–138
Order Parameters, 100
Oxides and Fatigue Life of Cast Al Alloys, 309
Peritectic Reactions, 132–134
Phase Composition
Of Copper-less Al–si Alloys and in Heat
Treatments, 336–342
Engine Piston Al–si Alloys, 368–369,
371–375
Of 2xx Series Alloys, Role of Alloying Elements
And Constituents Particle, 381–386
Of 3xx Series Alloys, 361–366
Of 5xx Series Alloys, Role of Alloying Elements
And Constituents Particle, 386–390
Phase Diagrams
Al–cu–fe–si System, 139–140
Al–fe–mg–si System, 140–143
Al–fe–ni–si System, 143–145
Al–fe–si System, 134–139
Phase-field Methodology, 101
Dendritic Solidification of Pure Metals,
102–103
Phase-field Models of Solidification, 102
Of Eutectic Alloys, 104–106
Solidification Microstructure Calculations,
106–107
Phase-field Theory, 96
Piola–kirchoff Stress, 520, 521
Porosity Development, and Homogenization,
240
Quantitative Characteristics of Alloy Structure
And Methods of Its Evaluation, 107–114
Refinement of as-cast Microstructure, 192,
195–200
Regression Equations, Drawbacks of, 296
Russian Aluminum Alloys, 336, See Also Engine
Piston Al–si Alloys
Am4.5kd, 381, 386
With Copper and Zinc, 351–366
Copper-less Al–si Alloys (3xx and 4xx Alloys),
342–345
Mechanical Properties, 491–498530 Index
Russian Casting Aluminum Alloys, 181
Heat Treatments of, 500–506
Precipitation and Microstructure of, 178
Secondary Precipitation of Excessive Phases,
292
Shrinkage Voids, 247, 248–249
Silver, 2
Solidification, 254
Constituent Particles of Secondary (Excessive)
Phases, 128–132
Dendritic, See Dendritic Solidification
Microstructure of Calculations, 106–107
Phase-field Models to, 102
Of Eutectic Alloys, 104–106
Suppression of Peritectic Reactions, 132–134
Volume Shrinkage During, 254
Solidification Rate, During Homogenization, 244
And Dissolution Kinetics, 195
And Grain Size Distribution, 225–226
Solid Solution Strengthening, 2–3
Copper Addition and, 5
Zinc Addition and, 5
Spheroidization Processes, See Fragmentation
And Spheroidization Processes
Substructure of Casting Aluminum Alloys
Decomposition of Aluminum Solid Solution,
177–182
Dislocation Microstructures
Influence of Solidification Conditions
Upon, 166–171
Mechanisms of Formation, 171–177
Dislocation Structures, Types of, 162–166
Tensile Mechanical Properties and, 290–295
Tensile Mechanical Properties, 280–281
Dislocation Density of Alloys and, 290–291
Grain Size, 281–282, 284, 285
Microstructure Characteristics, 284, 286–290
Of Pores, 286–287
Secondary Precipitation of Excessive Phases,
292
Subgrain Microstructure and, 292
Substructure, 290–295
Thermally Stable Alloys, With Transition Metals,
425–441
Al–tm1–tm2 Type Composition, 426–427
Microstructure Analysis, 427–429, 436, 437
Thermocalc, 29, 106
Tiller’s Theory, 173
Tin, 330
Transition Elements
And Aging of Castings After Casting and
Quenching, 240–245
And Decomposition of Al Solid Solutions,
230–240
Transition Metals
In Aluminum Alloys, 7–9
In Thermally Stable Alloys, 425–441
Uniaxial Tensile Testing in Finite Deformations,
Derivations of Equations, 511–513
Finite Deformations, 515–521
Infinitesimally Small Deformations, 513–514
Volume Fraction, 129, 130
Of Excessive Eutectic Phases and Fracture
Toughness, 306
And Homogenization Time, 190–194
Of Non-equilibrium Phases in Commercial
Alloys, 131
Of Pores
Tensile Mechanical Properties and,
286–287
Of Solidification, 252
Volume Shrinkage During Solidification, 254
Work Hardening, 272, 277
Zonal Macrosegregation
كلمة سر فك الضغط : books-world.net
The Unzip Password : books-world.net
أتمنى أن تستفيدوا من محتوى الموضوع وأن ينال إعجابكم
رابط من موقع عالم الكتب لتنزيل كتاب Casting Aluminum Alloys
رابط مباشر لتنزيل كتاب Casting Aluminum Alloys 
|
|
