Machine Design Databook, Second Edition
by: K.Lingaiah
Abstract: This book provides the formulas and data you need to solve even the most complex machine design problems! Utilizing the latest standards and codes, "Machine Design Databook, Second Edition" is the power tool engineers need to tackle the full range of machine design problems. Packed with valuable formulas, tables, charts, and graphs this unique handbook provides information in both SI and US Customary units - more data than any other similar reference available today! Selecting the appropriate formula and locating the necessary information has never been easier ...or faster!With over 300 pages of additional material, "Machine Design Databook, Second Edition" has new chapters on: The Elements of Machine Tool Design; Applied Elasticity; Locking Machine Elements; and Retaining Rings. Turn to "Machine Design Databook, Second Edition" for: the latest Codes and standards from ASME, AGMA, BIS, ISO, DIN, and more; cutting-edge information on application of the latest analytic techniques in gear design; charts on material properties; calculations of friction, wear, and lubrication of sliding and contact bearings; determination of axial load, torsion, and bending moment for shafts; the design of couplings, clutches, and brakes; formulas (empirical, semi-empirical, and otherwise); the latest advances in tool design and composite materials; and much more! On the drafting table, at the workstation, and in the shop, here is the one-stop solution to all of your machine design problems.
Full details
Table of Contents
- A. PREFACE
- B. ACKNOWLEDGMENTS
- C. ABOUT THE AUTHOR
- 1. PROPERTIES OF ENGINEERING MATERIALS
- 2. STATIC STRESSES IN MACHINE ELEMENTS
- 3. DYNAMIC STRESSES IN MACHINE ELEMENTS 2
- 4. STRESS CONCENTRATION AND STRESS INTENSITY IN MACHINE MEMBERS
- 5. DESIGN OF MACHINE ELEMENTS FOR STRENGTH
- 6. CAMS
- 7. PIPES, TUBES, AND CYLINDERS
- 8. DESIGN OF PRESSURE VESSELS, PLATES, AND SHELLS
- 9. DESIGN OF POWER BOILERS
- 10. ROTATING DISKS AND CYLINDERS 1
- 11. METAL FITS, TOLERANCES, AND SURFACE TEXTURE
- 12. DESIGN OF WELDED JOINTS
- 13. RIVETED JOINTS
- 14. DESIGN OF SHAFTS
- 15. FLYWHEELS
- 16. PACKINGS AND SEALS
- 17. KEYS, PINS, COTTERS, AND JOINTS
- 18. THREADED FASTENERS AND SCREWS FOR POWER TRANSMISSION
- 19. COUPLINGS, CLUTCHES, AND BRAKES
- 20. SPRINGS
- 21. FLEXIBLE MACHINE ELEMENTS
- 22. MECHANICAL VIBRATIONS
- 23. DESIGN OF BEARINGS AND TRIBOLOGY
- 24. MISCELLANEOUS MACHINE ELEMENTS 2 , 3
- 25. ELEMENTS OF MACHINE TOOL DESIGN
- 26. RETAINING RINGS AND CIRCLIPS
- 27. APPLIED ELASTICITY
Tools & Media
Expanded Table of Contents
-
A.
PREFACE
-
B.
ACKNOWLEDGMENTS
-
C.
ABOUT THE AUTHOR
- 1. PROPERTIES OF ENGINEERING MATERIALS
-
2.
STATIC STRESSES IN MACHINE ELEMENTS
- SYMBOLS 3 , 4 , 5
- SIMPLE STRESS AND STRAIN
- STRESSES
- PURE SHEAR (FIG. 2–5)
- BIAXIAL STRESSES (FIG. 2–6)
- BIAXIAL STRESSES COMBINED WITH SHEAR (FIG. 2–7)
- MOHR’S CIRCLE
- TRIAXIAL STRESS (Figs. 2–10 and 2–11)
- MOHR’S CIRCLE
- STRESS-STRAIN RELATIONS
- STATISTICALLY INDETERMINATE MEMBERS (Fig. 2–13)
- THERMAL STRESS AND STRAIN
- COMPOUND BARS
- EQUIVALENT OR COMBINED MODULUS OF ELASTICITY OF COMPOUND BARS
- POWER
- TORSION (FIG. 2–18)
- BENDING (FIG. 2–19)
- ECCENTRIC LOADING
- COLUMN FORMULAS (Fig. 2–25)
- HERTZ CONTACT STRESS
- DESIGN OF MACHINE ELEMENTS AND STRUCTURES MADE OF COMPOSITE
- FILAMENT REINFORCED STRUCTURES (Fig. 2–34)
- FILAMENT BINDER COMPOSITE (Fig. 2–36)
- FILAMENT-OVERLAY COMPOSITE
- FORMULAS AND DATA FOR VARIOUS CROSS SECTIONS OF MACHINE ELEMENTS
-
3.
DYNAMIC STRESSES IN MACHINE ELEMENTS 2
- SYMBOLS 2 , 3
- INERTIA FORCE
- ENERGY METHOD
- IMPACT STRESSES
- BENDING STRESS IN BEAMS DUE TO IMPACT
- TORSION OF BEAM/BAR DUE TO IMPACT (Fig. 3–7)
- LONGITUDINAL STRESS-WAVE IN ELASTIC MEDIA (Fig. 3–8)
- LONGITUDINAL IMPACT ON A LONG BAR
- TORSIONAL IMPACT ON A BAR
- INERTIA IN COLLISION OF ELASTIC BODIES
- RESILIENCE
- 4. STRESS CONCENTRATION AND STRESS INTENSITY IN MACHINE MEMBERS
- 5. DESIGN OF MACHINE ELEMENTS FOR STRENGTH
-
6.
CAMS
- SYMBOLS 3 , 4
- RADIUS OF CURVATURE OF DISK CAM WITH ROLLER FOLLOWER
- RADIUS OF CURVATURE OF DISK CAM WITH FLAT-FACED FOLLOWER
- PRESSURE ANGLE (Figs. 6–3 and 6–4)
- RADIAL CAM-TRANSLATING ROLLER-FOLLOWER-FORCE ANALYSIS (Fig. 6–5)
- SIDE THRUST (Fig. 6–5)
- BASIC SPIRAL CONTOUR CAM
- BASIC SPIRAL CONTOUR CAM CONSTANTS
- HERTZ CONTACT STRESSES
-
7.
PIPES, TUBES, AND CYLINDERS
- SYMBOLS 5 , 6 , 9
- LONG THIN TUBES WITH INTERNAL PRESSURE
- ENGINES AND PRESSURE CYLINDERS
- OPENINGS IN CYLINDRICAL DRUMS
- THIN TUBES WITH EXTERNAL PRESSURE
- SHORT TUBES WITH EXTERNAL PRESSURES
- LAMÉ’S EQUATIONS FOR THICK CYLINDERS
- DEFORMATION OF A THICK CYLINDER
- COMPOUND CYLINDERS
- THERMAL STRESSES IN LONG HOLLOW CYLINDERS
- CLAVARINO’S EQUATION FOR CLOSED CYLINDERS
- BIRNIE’S EQUATIONS FOR OPEN CYLINDERS
- BARLOW’S EQUATION
-
8.
DESIGN OF PRESSURE VESSELS, PLATES, AND SHELLS
- SYMBOLS 13 , 14 , 15
- PLATES 13 , 14 , 15
- SHELLS (UNFIRED PRESSURE VESSEL)
- FORMED HEADS UNDER PRESSURE ON CONCAVE SIDE
- FORMED HEADS UNDER PRESSURE ON CONVEX SIDE
- UNSTAYED FLAT HEADS AND COVERS (Fig. 8–9, Table 8–6 )
- STAYED FLAT AND BRACED PLATES OR SURFACES (Figs. 8–11 and 8–12)
- OPENINGS AND REINFORCEMENT
- LIGAMENTS
- BOLTED FLANGE CONNECTIONS
- INTEGRAL-TYPE FLANGES AND LOOSE-TYPE FLANGES WITH A HUB
- LOOSE-TYPE FLANGES WITHOUT HUB AND LOOSE-TYPE FLANGES WITH HUB WHICH THE DESIGNER CHOOSES TO CALCULATE
- 9. DESIGN OF POWER BOILERS
-
10.
ROTATING DISKS AND CYLINDERS 1
- SYMBOLS 1
- DISK OF UNIFORM STRENGTH ROTATING AT ω rad/s (Fig. 10–1)
- SOLID DISK ROTATING AT ω rad/s
- HOLLOW DISK ROTATING AT ω rad/s (Fig. 10–2)
- SOLAD CYLENDER ROTATING AT ω rad/s
- HOLLOW CYLINDER ROTATING AT ω rad/s
- SOLID THIN UNIFORM DISK ROTATING AT ω rad/s UNDER EXTERNAL PRESSURE p o (Fig. 10–3)
- HOLLOW CYLINDER OF UNIFORM THICKNESS ROTATING AT ω rad/s. SUBJECT TO INTERNAL (p i) AND EXTERNAL (p o) PRESSURES (Fig. 10–4)
- ROTATING THICK DISK AND CYLINDER WITH UNIFORM THICKNESS SUB SUBJECT TO THERMAL STRESSES
- ROTATING LONG HOLLOW CYLINDER WITH UNIFORM THICKNESS ROTATING AT ω rad/s SUBJECT TO THERMAL STRESS
- DEFLECTION OF A ROTATING DISK OF UNIFORM THICKNESS IN RADIAL DIRECTION WITH A CENTRAL CIRCULAR CUTOUT
- 11. METAL FITS, TOLERANCES, AND SURFACE TEXTURE
-
12.
DESIGN OF WELDED JOINTS
- SYMBOLS 2 , 3 , 4
- FILLET WELD
- BUTT WELD
- TRANSVERSE FILLET WELD
- PARALLEL FILLET WELD (Fig. 12–5)
- LENGTH OF WELD
- ECCENTRICITY IN A FILLET WELD
- ECCENTRIC LOADS
- STRESSES
- FATIGUE STRENGTH
- DESIGN STRESS OF WELDS
- THE STRENGTH ANALYSIS OF A TYPICAL WELD JOINT SUBJECTED TO ECCENTRIC LOADING (Fig. 12–8) 2 , 3 , 4
- COMBINED FORCE DUE TO P x, P y, AND P z AT POINT Q (Fig. 12–8)
- GENERAL
- 13. RIVETED JOINTS
- 14. DESIGN OF SHAFTS
- 15. FLYWHEELS
- 16. PACKINGS AND SEALS
- 17. KEYS, PINS, COTTERS, AND JOINTS
- 18. THREADED FASTENERS AND SCREWS FOR POWER TRANSMISSION
-
19.
COUPLINGS, CLUTCHES, AND BRAKES
- SYMBOLS 8 , 9 , 10
- SUFFIXES
- COUPLINGS
- MARINE TYPE OF FLANGE COUPLING
- PULLEY FLANGE COUPLING (Fig. 19–3)
- PIN OR BUSH TYPE FLEXIBLE COUPLING (Fig. 19–4, Table 19–3)
- OLDHAM COUPLING (Fig. 19–5)
- MUFF OR SLEEVE COUPLING (Fig. 19–6)
- FAIRBAIRN’S LAP-BOX COUPLING (Fig. 19–7)
- SPLIT MUFF COUPLING (Fig. 19–8)
- SLIP COUPLING (Fig. 19–9)
- SELLERS’ CONE COUPLING (Fig. 19–10)
- HYDRAULIC COUPLINGS (Fig. 19–11)
- CLUTCHES POSITIVE CLUTCHES (Fig. 19–12)
- FRICTION CLUTCHES
- DISK CLUTCHES (Fig. 19–14)
- DIMENSIONS OF DISKS (Fig. 19–15)
- DESIGN OF A TYPICAL CLUTCH OPERATING LEVER (Fig. 19–16)
- EXPANDING-RING CLUTCHES (Fig. 19–17)
- CENTRIFUGAL CLUTCH (Fig. 19–19)
- BRAKES ENERGY EQUATIONS
- BRAKE FORMULAS
- CONE BRAKES (Fig. 19–24)
- CONSIDERING THE LEVER (Fig. 19–24)
- DISK BRAKES
- INTERNAL EXPANDING-RIM BRAKE
- EXTERNAL CONTRACTING-RIM BRAKE
- HEATING OF BRAKES
-
20.
SPRINGS
- SYMBOLS
- SUFFIXES
- LEAF SPRINGS (Table 20–1) 1 , 2 , 3
- LAMINATED SPRING (Fig. 20–1) 5
- LAMINATED SPRINGS WITH INITIAL CURVATURE
- DISK SPRINGS (BELLEVILLE SPRINGS)
- HELICAL SPRINGS (Fig. 20–4) 5
- SPRING SCALE (Fig. 20–6)
- RESILIENCE
- RECTANGULAR SECTION SPRINGS (Fig. 20–7a) 5
- SQUARE SECTION SPRING
- SELECTION OF MATERIALS AND STRESSES FOR SPRINGS
- DESIGN OF HELICAL COMPRESSION SPRINGS
- STABILITY OF HELICAL SPRINGS
- REPEATED LOADING (Fig. 20–9)
- CONCENTRIC SPRINGS (Fig. 20–10)
- VIBRATION OF HELICAL SPRINGS
- STRESS WAVE PROPAGATION IN CYLINDRICAL SPRINGS UNDER IMPACT LOAD
- HELICAL EXTENSION SPRINGS (Fig. 20–11 to 20–13)
- CONICAL SPRINGS [Fig. 20–14(a)]
- NONMETALLIC SPRINGS
- TORSION SPRINGS (Fig. 20–16) 7
-
21.
FLEXIBLE MACHINE ELEMENTS
- SYMBOLS 11 , 12 , 13
- SUFFIXES
- BELTS
- BELT LENGTHS AND CONTACT ANGLES FOR OPEN AND CROSSED BELTS (Fig. 21–1A)
- PULLEYS (Fig. 21–2 and Fig. 21–3)
- INDIAN STANDARD SPECIFICATION
- V-BELT
- MINIMUM ALLOWANCES FOR ADJUSTMENT OF CENTERS FOR TWO TRANSMISSION PULLEYS
- INITIAL TENSION
- SYNCHRONOUS BELT DRIVE ANALYSIS
- CONVEYOR (Tables 21–12, 21–14, 21–20, and 21–31)
- SHORT CENTER DRIVE
- ROPES
- HOISTING TACKLE
- DRUMS
- HOLDING CAPACITY OF WIRE ROPE REELS
- WIRE ROPE CONSTRUCTION
- CHAINS
- CHECK FOR ACTUAL SAFETY FACTOR
- REFERENCES
-
22.
MECHANICAL VIBRATIONS
- SYMBOLS
- SIMPLE HARMONIC MOTION (Fig. 22–1)
- ENERGY
- LOGARITHMIC DECREMENT (Fig. 22–8)
- EQUIVALENT SPRING CONSTANTS (Fig. 22–9)
- UNBALANCE DUE TO ROTATING MASS (Fig. 22–13)
- WHIPPING OF ROTATING SHAFT (Fig. 22–16)
- EXCITATION OF A SYSTEM BY MOTION OF SUPPORT (Fig. 22–17)
- INSTRUMENT FOR VIBRATION MEASURING (Fig. 22–18)
- ISOLATION OF VIBRATION (Fig. 22–19)
- UNDAMPED TWO-DEGREE-OF-FREEDOM SYSTEM (Fig. 22–22) WITHOUT EXTERNAL FORCE
- DYNAMIC VIBRATION ABSORBER (Fig. 22–23)
- TORSIONAL VIBRATING SYSTEMS
-
23.
DESIGN OF BEARINGS AND TRIBOLOGY
- SLIDING CONTACT BEARINGS 1 , 2 , 11
- SHEAR STRESS 1 , 2
- VISCOSITY
- HAGEN-POISEUILLE LAW
- VERTICAL SHAFT ROTATING IN A GUIDE BEARING (Fig. 23–5)
- BEARING PRESSURE (Fig. 23–9)
- INFLUENCE OF MISALIGNMENT OF SHAFT IN BEARING
- POWER LOSS
- PARTIAL JOURNAL BEARING (Fig. 23–25)
- INFLUENCE OF END LEAKAGE
- FRICTION IN A FULL JOURNAL BEARING WITH END LEAKAGE FROM BEARING
- OIL FLOW THROUGH JOURNAL BEARING
- THERMAL EQUILIBRIUM OF JOURNAL BEARING
- EXTERNAL PRESSURIZED BEARING OR HYDROSTATIC BEARING: JOURNAL BEARING (Fig. 23–47)
- IDEALIZED SLIDER BEARING (Fig. 23–48)
- DESIGN OF VERTICAL, PIVOT, AND COLLAR BEARING
- PLAIN THRUST BEARING (Fig. 23–50b)
- OIL FILM THICKNESS
- COEFFICIENT OF FRICTION
- HYDROSTATIC BEARING: STEP-BEARING
- SPHERICAL BEARINGS (Fig. 23–54)
- LIFT
- ROLLING CONTACT BEARINGS 1
- ROLLING ELEMENTS BEARINGS
- SPEED
- GEAR-TOOTH LOAD
- STATIC LOADING
- BASIC STATIC LOAD RATING AS PER INDIAN STANDARDS
- THRUST BEARINGS
- CATALOGUE INFORMATION FROM FAG FOR THE SELECTION OF BEARING
- DYNAMIC LOAD RATING OF BEARINGS
- LIFE
- BASIC DYNAMIC LOAD RATING AS PER FAG CATALOGUE
- LIFE ADJUSTMENT FACTORS
- BASIC DYNAMIC LOAD RATING OF BEARINGS AS PER INDIAN STANDARDS
- THRUST BEARINGS
- THE EQUIVALENT DYNAMIC LOAD FOR ANGULAR CONTACT BALL BEARINGS
- THE EQUIVALENT DYNAMIC LOAD FOR TAPERED ROLLER BEARINGS
- DIMENSIONS, BASIC LOAD RATING CAPACITY, FATIGUE LOAD LIMIT AND MAXIMUM PERMISSIBLE SPEED OF ROLLING CONTACT BEARINGS
- NEEDLE BEARING LOAD CAPACITY
- PRESSURE
- HERTZ-CONTACT PRESSURE
- SELECTION OF FIT FOR BEARINGS
- FRICTION AND WEAR 1
- FRICTION
- WEAR AND ABRASION
- GENERAL
- 24. MISCELLANEOUS MACHINE ELEMENTS 2 , 3
- 25. ELEMENTS OF MACHINE TOOL DESIGN
- 26. RETAINING RINGS AND CIRCLIPS
-
27.
APPLIED ELASTICITY
- SYMBOLS
- STRESS AT A POINT (Fig. 27–1)
- EQUATIONS OF EQUILIBRIUM
- TRANSFORMATION OF STRESS
- PRINCIPAL STRESSES
- STRAIN (Fig. 27–6)
- THREE-DIMENSIONAL STRESS-STRAIN SYSTEM
- BIAXIAL STRESS-STRAIN SYSTEM
- SHEAR STRAINS
- STRAIN AND DISPLACEMENT (Figs. 27–8 and 27–9)
- BOUNDARY CONDITIONS
- COMPATIBILITY
- GENERAL HOOKE’S LAW
- ARY’S STRESS FUNCTION
- CYLINDRICAL COORDINATES SYSTEM
- STRAIN COMPONENTS (Fig. 27–14)
- AIRY’S STRESS FUNCTION IN POLAR COODRINATES
- SOLUTION OF ELASTICITY PROBLEMS USING AIRY’S STRESS FUNCTION
- APPLICATION OF STRESS FUNCTION
- STRESS DISTRIBUTION IN A FLAT PLATE WITH HOLES OR CUTOUTS UNDER DIFFERENT TYPES OF LOADS
- ROTATING SOLID DISK WITH UNIFORM THICKNESS, (Fig. 27–22)
- ROTATING DISK WITH A CENTRAL CIRCULAR HOLE OF UNIFORM THICKNESS, Fig. 27–23
- ROTATING DISK OF VARIABLE THICKNESS (Fig. 27–24)
- NEUTRAL HOLES (MANSFIELD THEORY)
- COMPLEX VARIABLE METHOD APPLIED TO ELASTICITY
- STRAIN COMBINATIONS
- PLANE STRAIN (Figs. 27–29 and 24–30)
- BOUNDARY CONDITIONS
- FORCE AND COUPLE RESULTANTS AROUND THE BOUNDARY (Fig. 27–31)
- GENERALIZED PLANE STRESS
- CONDITIONS ALONG A STRESS-FREE BOUNDARY, Fig. 27–33
- SOLUTION INVOLVING CIRCULAR BOUNDARIES (Figs. 27–33 and 27–34)
- APPLICATION OF CONFORMAL TRANSFORMATION (Fig. 27–35)
- MUSKHELISHVILI’S DIRECT METHOD
- TORSION (Fig. 25–49)
- TORSION OF CIRCULAR SHAFT OF VARIABLE DIAMETER (Fig. 27–13)
- PLATES
Book Details
Title: Machine Design Databook, Second Edition
Publisher: McGraw-Hill: New York, Chicago, San Francisco, Lisbon, London, Madrid, Mexico City, Milan, New Delhi, San Juan, Seoul, Singapore, Sydney, Toronto
Copyright / Pub. Date: 2003, 1994 The McGraw-Hill Companies, Inc.
ISBN: 9780071367073
Authors:
K.Lingaiah is the author of this McGraw-Hill Professional publication.
Description: This book provides the formulas and data you need to solve even the most complex machine design problems! Utilizing the latest standards and codes, "Machine Design Databook, Second Edition" is the power tool engineers need to tackle the full range of machine design problems. Packed with valuable formulas, tables, charts, and graphs this unique handbook provides information in both SI and US Customary units - more data than any other similar reference available today! Selecting the appropriate formula and locating the necessary information has never been easier ...or faster!With over 300 pages of additional material, "Machine Design Databook, Second Edition" has new chapters on: The Elements of Machine Tool Design; Applied Elasticity; Locking Machine Elements; and Retaining Rings. Turn to "Machine Design Databook, Second Edition" for: the latest Codes and standards from ASME, AGMA, BIS, ISO, DIN, and more; cutting-edge information on application of the latest analytic techniques in gear design; charts on material properties; calculations of friction, wear, and lubrication of sliding and contact bearings; determination of axial load, torsion, and bending moment for shafts; the design of couplings, clutches, and brakes; formulas (empirical, semi-empirical, and otherwise); the latest advances in tool design and composite materials; and much more! On the drafting table, at the workstation, and in the shop, here is the one-stop solution to all of your machine design problems.
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