Principles of Tribology , 2nd Edition 摩擦學原理(

作者：溫詩鑄、黃平
定價：168元
印次：1-1
ISBN：9787302485261
出版日期：2017.10.01
印刷日期：2017.09.30

本書匯集摩擦學研究的最新進展及作者和其同事從事該領域的研究成果，系統地闡述摩擦學的基本原理與套用，全面反映現代摩擦學的研究狀況和發展趨勢。全書共 21章，由潤滑理論與潤滑設計、摩擦磨損機理與控制、套用摩擦學等 3部分組成。除摩擦學傳統內容外，還論述了摩擦學與相關學科交叉而形成的研究領域。本書針對工程實際中的各種摩擦學現象，著重闡述摩擦過程中的變化規律和特徵，進而介紹基本理論、分析計算方法以及實驗測試技術，並說明它們在工程中的實際套用。本書可作為機械設計與理論專業的研究生教材以及高等院校機械工程各類專業師生的教學參考書，也可以供從事機械設計和研究的工程技術人員參考。

AbouttheAuthorsxvii

SecondEditionPrefacexix

Prefacexxi

Introductionxxiii

PartILubricationTheory1

1PropertiesofLubricants3

1.1LubricationStates3

1.2DensityofLubricant5

1.3ViscosityofLubricant7

1.3.1DynamicViscosityandKinematicViscosity7

1.3.1.1DynamicViscosity7

1.3.1.2KinematicViscosity8

1.3.2RelationshipbetweenViscosityandTemperature9

1.3.2.1Viscosity–TemperatureEquations9

1.3.2.2ASTMViscosity–TemperatureDiagram9

1.3.2.3ViscosityIndex10

1.3.3RelationshipbetweenViscosityandPressure10

1.3.3.1RelationshipsbetweenViscosity,TemperatureandPressure11

1.4Non-NewtonianBehaviors12

1.4.1Ree–EyringConstitutiveEquation12

1.4.2Visco-PlasticConstitutiveEquation13

1.4.3CircularConstitutiveEquation13

1.4.4Temperature-DependentConstitutiveEquation13

1.4.5Visco-ElasticConstitutiveEquation14

1.4.6NonlinearVisco-ElasticConstitutiveEquation14

1.4.7ASimpleVisco-ElasticConstitutiveEquation15

1.4.7.1Pseudoplasticity16

1.4.7.2Thixotropy16

1.5WettabilityofLubricants16

1.5.1WettingandContactAngle17

1.5.2SurfaceTension17

1.6MeasurementandConversionofViscosity19

1.6.1RotaryViscometer19

1.6.2Off-BodyViscometer19

1.6.3CapillaryViscometer19

References21

2BasicTheoriesofHydrodynamicLubrication22

2.1ReynoldsEquation22

2.1.1BasicAssumptions22

2.1.2DerivationoftheReynoldsEquation23

2.1.2.1ForceBalance23

2.1.2.2GeneralReynoldsEquation25

2.2HydrodynamicLubrication26

2.2.1MechanismofHydrodynamicLubrication26

2.2.2BoundaryConditionsandInitialConditionsoftheReynoldsEquation27

2.2.2.1BoundaryConditions27

2.2.2.2InitialConditions28

2.2.3CalculationofHydrodynamicLubrication28

2.2.3.1Load-CarryingCapacityW28

2.2.3.2FrictionForceF28

2.2.3.3LubricantFlowQ29

2.3ElasticContactProblems29

2.3.1LineContact29

2.3.1.1GeometryandElasticitySimulations29

2.3.1.2ContactAreaandStress30

2.3.2PointContact31

2.3.2.1GeometricRelationship31

2.3.2.2ContactAreaandStress32

2.4EntranceAnalysisofEHL34

2.4.1ElasticDeformationofLineContacts35

2.4.2ReynoldsEquationConsideringtheEffectofPressure-Viscosity35

2.4.3Discussion36

2.4.4GrubinFilmThicknessFormula37

2.5GreaseLubrication38

References40

3NumericalMethodsofLubricationCalculation41

3.1NumericalMethodsofLubrication42

3.1.1FiniteDifferenceMethod42

3.1.1.1HydrostaticLubrication44

3.1.1.2HydrodynamicLubrication44

3.1.2FiniteElementMethodandBoundaryElementMethod48

3.1.2.1FiniteElementMethod(FEM)48

3.1.2.2BoundaryElementMethod49

3.1.3NumericalTechniques51

3.1.3.1ParameterTransformation51

3.1.3.2NumericalIntegration51

3.1.3.3EmpiricalFormula53

3.1.3.4SuddenThicknessChange53

3.2NumericalSolutionoftheEnergyEquation54

3.2.1ConductionandConvectionofHeat55

3.2.1.1ConductionHeatHd55

3.2.1.2ConvectionHeatHv55

3.2.2EnergyEquation56

3.2.3NumericalSolutionofEnergyEquation59

3.3NumericalSolutionofElastohydrodynamicLubrication60

3.3.1EHLNumericalSolutionofLineContacts60

3.3.1.1BasicEquations60

3.3.1.2SolutionoftheReynoldsEquation62

3.3.1.3CalculationofElasticDeformation62

3.3.1.4Dowson–HigginsonFilmThicknessFormulaofLineContactEHL64

3.3.2EHLNumericalSolutionofPointContacts64

3.3.2.1TheReynoldsEquation65

3.3.2.2ElasticDeformationEquation66

3.3.2.3Hamrock–DowsonFilmThicknessFormulaofPointContactEHL66

3.4Multi-GridMethodforSolvingEHLProblems68

3.4.1BasicPrinciplesofMulti-GridMethod68

3.4.1.1GridStructure68

3.4.1.2DiscreteEquation68

3.4.1.3Transformation69

3.4.2NonlinearFullApproximationSchemefortheMulti-GridMethod69

3.4.3VandWIterations71

3.4.4Multi-GridSolutionofEHLProblems71

3.4.4.1IterationMethods71

3.4.4.2IterativeDivision72

3.4.4.3RelaxationFactors73

3.4.4.4NumbersofIterationTimes73

3.4.5Multi-GridIntegrationMethod73

3.4.5.1TransferPressureDownwards74

3.4.5.2TransferIntegralCoefficientsDownwards74

3.4.5.3IntegrationontheCoarserMesh74

3.4.5.4TransferBackIntegrationResults75

3.4.5.5ModificationontheFinerMesh75

References76

4LubricationDesignofTypicalMechanicalElements78

4.1SliderandThrustBearings78

4.1.1BasicEquations78

4.1.1.1ReynoldsEquation78

4.1.1.2BoundaryConditions78

4.1.1.3ContinuousConditions79

4.1.2SolutionsofSliderLubrication79

4.2JournalBearings81

4.2.1AxisPositionandClearanceShape81

4.2.2InfinitelyNarrowBearings82

4.2.2.1Load-CarryingCapacity83

4.2.2.2DeviationAngleandAxisTrack83

4.2.2.3Flow84

4.2.2.4FrictionalForceandFrictionCoefficient84

4.2.3InfinitelyWideBearings85

4.3HydrostaticBearings88

4.3.1HydrostaticThrustPlate89

4.3.2HydrostaticJournalBearings90

4.3.3BearingStiffnessandThrottle90

4.3.3.1ConstantFlowPump91

4.3.3.2CapillaryThrottle91

4.3.3.3Thin-WalledOrificeThrottle92

4.4SqueezeBearings92

4.4.1RectangularPlateSqueeze93

4.4.2DiscSqueeze94

4.4.3JournalBearingSqueeze94

4.5DynamicBearings96

4.5.1ReynoldsEquationofDynamicJournalBearings96

4.5.2SimpleDynamicBearingCalculation98

4.5.2.1ASuddenLoad98

4.5.2.2RotatingLoad99

4.5.3GeneralDynamicBearings100

4.5.3.1InfinitelyNarrowBearings100

4.5.3.2SuperimpositionMethodofPressures101

4.5.3.3SuperimpositionMethodofCarryingLoads101

4.6GasLubricationBearings102

4.6.1BasicEquationsofGasLubrication102

4.6.2TypesofGasLubricationBearings103

4.7RollingContactBearings106

4.7.1EquivalentRadiusR107

4.7.2AverageVelocityU107

4.7.3CarryingLoadPerWidthW/b107

4.8GearLubrication108

4.8.1InvoluteGearTransmission109

4.8.1.1EquivalentCurvatureRadiusR110

4.8.1.2AverageVelocityU111

4.8.1.3LoadPerWidthW/b112

4.8.2ArcGearTransmissionEHL112

4.9CamLubrication114

References116

5SpecialFluidMediumLubrication118

5.1MagneticHydrodynamicLubrication118

5.1.1CompositionandClassificationofMagneticFluids118

5.1.2PropertiesofMagneticFluids119

5.1.2.1DensityofMagneticFluids119

5.1.2.2ViscosityofMagneticFluids119

5.1.2.3MagnetizationStrengthofMagneticFluids120

5.1.2.4StabilityofMagneticFluids120

5.1.3BasicEquationsofMagneticHydrodynamicLubrication121

5.1.4InfluenceFactorsonMagneticEHL123

5.2Micro-PolarHydrodynamicLubrication124

5.2.1BasicEquationsofMicro-PolarFluidLubrication124

5.2.1.1BasicEquationsofMicro-PolarFluidMechanics124

5.2.1.2ReynoldsEquationofMicro-PolarFluid125

5.2.2InfluenceFactorsonMicro-PolarFluidLubrication128

5.2.2.1InfluenceofLoad128

5.2.2.2MainInfluenceParametersofMicro-PolarFluid129

5.3LiquidCrystalLubrication130

5.3.1TypesofLiquidCrystal130

5.3.1.1TribologicalPropertiesofLyotropicLiquidCrystal131

5.3.1.2TribologicalPropertiesofThermotropicLiquidCrystal131

5.3.2DeformationAnalysisofLiquidCrystalLubrication132

5.3.3FrictionMechanismofLiquidCrystalasaLubricantAdditive136

5.3.3.1TribologicalMechanismof4-pentyl-4′-cyanobiphenyl136

5.3.3.2TribologicalMechanismofCholesterylOleylCarbonate136

5.4ElectricDoubleLayerEffectinWaterLubrication137

5.4.1ElectricDoubleLayerHydrodynamicLubricationTheory138

5.4.1.1ElectricDoubleLayerStructure138

5.4.1.2HydrodynamicLubricationTheoryofElectricDoubleLayer138

5.4.2InfluenceofElectricDoubleLayeronLubricationProperties142

5.4.2.1PressureDistribution142

5.4.2.2Load-CarryingCapacity143

5.4.2.3FrictionCoefficient144