The Moulton formulae and methods : directly usable for calculations in mechanical engineering

Practising engineers - especially those concerned with innovation - continuously need quantitative information, especially orders of magnitude, directions and sense of values. In this loose-leaf book of convenient size (which acts as a companion to a scientific calculator), the editors have produced an open-ended collection of directly usable 'leaves'. Each leaf describes one topic, and includes definitions, units (both SI and Imperial), methods and formulae to determine values. Thus each leaf is an aide-memoire and as such contains the minimum text on explanation and derivation; instead it relies on graphical and diagrammatic presentation. These are fundamentally sound and not 'rule of thumb' calculations. The equations presented are suitable for incorporation into spreadsheet calculation/computing.Their access may well be quicker than trying any search on the Internet. The format of each leaf is essentially constant, with one topic as indicated by the Title at the top of the leaf, and all symbols used are tabulated in both SI and Imperial units. The key equations are boxed and coloured yellow. "The Moulton Formulae and Methods" presents essential information for calculation within topics of mechanical interest. It features conversion charts; statics; structures; mechanics; dynamics; vibrations; thermodynamics; fluid dynamics; and, mathematics. Dr Moulton is an outstanding British Engineer whose whole professional life has been devoted to research, development, design and manufacture of advanced innovative products for sale in world markets.

• Introduction and How to Use this Book 1
• About the Authors 1
• Conversion Charts
• Basic SI units, Standard SI Prefixes, Greek Alphabet, Units used by Engineers 2
• Length, Area, 3
• Mass, Volume, Density 4
• Force, Torque/Work/Energy, Power 5
• Pressure/Stress, Stiffness (Rate), Temperature 6
• Velocity, Acceleration, Volumetric Flow Rate 7
• Second Moment of Area, Modulus of Sections, Moment of Inertia, Volumetric Stiffness, Impedance, Impulse, Linear Momentum, Specific Fuel Consumption, Angular Velocity, Viscosity 8
• Statics
• Forces: Statics
• Resultant, Components, Equilibrium 9
• Concurrent Forces 10
• Forces in Space, Position of C of G 11
• Structures: Beams - Strength, Stress, Deflection, Shear Force, Bending Stress
• Uniform and Stepped Beam
• Point, Distributed and Offset loads 13
• Intermediate Couple 14
• Offset Load on a Bracket 15
• Overhanging Beam 16
• Deflection - Macaulay's Method 17
• Tapered Beam 18
• Continuous Beam 19
• Portal Frames 19
• Pin Jointed Frameworks - Forces in Members, Stress, Deflection
• Graphical Construction Method 20
• Analytical Method 21
• Deflections: Virtual Work Method, Graphical/Williot's Method 22
• Optimising the Triangular Frame 23
• Shafts - Torsion, Strength, Stress
• Torsion of Shafts 24
• Combined Bending and Torsion, Torsion and Tension 24
• Torsion of Thin Open Sections 25
• Struts / Columns
• Buckling/Euler Load 26
• Stresses: Design Load Factors and Fatigue 27
• Pressure Vessels 28
• Circular Plates 28
• Helical Springs 29
• Leaf Springs 30
• Spinning Discs 31
• Contact Stresses 31
• Flexible Cables 32
• Properties Of Sections And Figures
• Properties of Plane and Solid Figures 33
• Properties of Regular Sections: Solid and Hollow 34
• Properties of Any Shape Section: Solid and Hollow 35
• Properties Of Materials
• Solids: Mechanics of Materials 36
• Strength of Materials: Ultimate Tensile Strength, Yield Strength, Poisson's Ratio 37
• Density, Coefficient of Thermal Expansion, Thermal Conductivity, Specific Heat Capacity 38
• Dynamics
• Kinematics and Kinetics: Velocity and Acceleration, Rectilinear and Rotary Motion
• Constant Acceleration 39
• Varying Acceleration 39
• Influence of Forces on Motion 39
• Rotation of a Rigid Body about its C of G 39
• Centre of Percussion 39
• Motion up a Slope 40
• Rotation about a Fixed Axis 40
• Path of a Rolling Wheel 40
• Linkage mechanics
• Graphical Method for Velocities and Accelerations 41
• Scotch Yoke, Slider-Crank, Four-Bar Linkage 42
• Gyroscopic Effects 43
• Ballistics
• Path of a Projectile 44
• Friction
• Dry (Coulomb) or Sparse Lubrication 45
• Screw Threads 45
• Clutches 45
• Belt Drive 45
• Disk Brake 45
• Journal Bearing (Axle Friction) Moments of Inertia 46
• Gears
• Strength 47
• Simple Epicyclical Train (Tabular Method) 48
• Vibrations
• Relationship between Vibration Parameters 49
• Simple Harmonic Motion (SHM) 50
• Damping: Free Vibration 50
• Viscous Damping, Internal (Hysteretic) Damping 50
• Coulomb Damping, Velocity Square Damping 50
• Forced Vibrations
• Mass, Seismic and Unbalanced Excitation 51
• Whirling Shafts, Critical Speed, Dunkerley's Method for Natural Frequency 52
• Experimental Determination of the Moment of Inertia of a Body 52
• Natural Frequencies of Standard Systems (1 DOF): Torsional Systems 53
• Helical Springs 53
• Flat Plates 53
• Beams 53
• Shafts 53
• Free Vibrations of 2 Degrees of Freedom Systems: Rigid Body on Springs 54
• Vibration Control: Rigid Body on Isolators 55
• Mass Damper (Dynamic Absorber) 56
• 2 Degrees of Freedom Systems 57
• Non-Sinusoidal Forced Vibration 58
• Levered System and Test Rig 59
• Thermodynamics
• Gas Laws, Energy Balance, Expansion of Gases 60
• Heat Transfer, Conduction, Convection 60
• Fluid Mechanics
• Static Pressure, Buoyancy and Stability 61
• Fluid in Motion: 61
• Continuity, Discharge through an Orifice 61
• Bernoulli's Theorem 61
• Loss Coefficients in Pipe, Lift and Drag 62
• Reynolds Number 62
• Mathematics
• Algebra and Regression 63
• Trigonometry, Differential and Integral Calculus 64
• Vectors 65
• Determinants 66