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DESIGN OF MACHINE ELEMENTS U5MEA20

DESIGN OF MACHINE ELEMENTS U5MEA20. Prepared by Mr. Kishkorekumar & Mr. Sultan Batcha.Y Assistant Professor, Mechanical Department VelTech Dr.RR & Dr.SR Technical University. UNIT-I. Failure Theories. Stress in machine components should be accurately computed.

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DESIGN OF MACHINE ELEMENTS U5MEA20

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  1. DESIGN OF MACHINE ELEMENTSU5MEA20 Prepared by Mr. Kishkorekumar & Mr. Sultan Batcha.Y Assistant Professor, Mechanical Department VelTech Dr.RR & Dr.SR Technical University

  2. UNIT-I

  3. Failure Theories • Stress in machine components should be accurately computed. • Designer must understand material limits to ensure a safe design.

  4. Design Factor • Factor of Safety (N) • Suitable values depend on inherent danger, certainty of calculations, certainty of material properties, etc.

  5. Static Stresses - Brittle Materials • Percent elongation < 5% • for parts in tension • for parts in compression • for parts with general stress

  6. Ø4.00” R0.25” Ø5.00” R0.25” Example The Gray Cast Iron (Grade 40) cylinder carries an axial compressive load of 75,000 lbs and a torque of 20,000 in lbs. Compute the resulting design factor.

  7. Static Stresses - Ductile Materials • Percent elongation > 5% • Distortion Energy Theory • Define von Mises Stress • For nominal stress • For localized stress

  8. Static Stresses - Ductile Materials • Percent elongation > 5% • Maximum Shear Stress Theory • For nominal stress • For localized stress

  9. 450 5000 lbs Example Specify a diameter for the middle portion of the rod, if it is to be made from AISI 1040-hot rolled steel.

  10. 400 lb 200 lb 20” 14” Example For the seat support shown, specify a standard structural tube to resist static loads shown. The tube has properties similar to AISI 1020 hot-rolled steel. Use a design factor of 3.

  11. salt smean Repeated Loads

  12. 1.25” 0.1” R .75” 1” Example The notched bar is machined from AISI 1020 steel. This bar is subjected to a load that varies from 2000 lb to 3000 lb. Determine the mean and alternating nominal stresses.

  13. Motor Alternating Stress, sa Endurance Strength, sn 108 107 106 105 103 104 Cycles to Failure, N (log) Fatigue Strength • R.R. Moore Test

  14. Endurance Strength • sn = Endurance strength • Listed in tables • If no information is available, use • sn 0.5 su (Steel) • sn 0.4 su (Aluminum)

  15. Adjusted Endurance Strength • The data from the standard R.R. Moore test is adjusted for a particular application. • sn’ = Adjusted endurance strength = (Cs) (Cm) (Cst) (CR) (sn)

  16. Size and Stress Type Factors • Cs = Size Factor • D< 0.4 in Cs = 1.0 • 0.4 < D 2.0 in Cs = (D/0.3)-0.068 • 2.0 < D 10.0 in Cs = D-0.19 For rectangular sections, D=.808(h b)1/2 • Cst = Stress Type Factor • = 1.0 for bending • = 0.80 for axial tension • = 0.50 for torsion

  17. Material and Reliability Factor • Cm = Material Factor • = 1.0 for wrought steel • = 0.80 for cast steel • = 0.70 for cast iron • CR = Reliability Factor • 50% CR = 1.0 • 90% CR = 0.90 • 99% CR = 0.81 • 99.9% CR = 0.75

  18. 1.25” 0.1” R .75” 1” Example The notched bar is machined from AISI 1020 steel. This bar is subjected to a load that varies from 2000 lb to 3000 lb. Determine the endurance limit of the material.

  19. Repeated Stresses - Ductile Materials • Distortion Energy Theory • Define repeated von Mises Stress • Solderberg criterion

  20. Repeated Stresses - Ductile Materials • Maximum Shear Stress Theory • ssy = 0.5 sy • s’sn = 0.5 sn

  21. 1.25” 0.1” R .75” 1” Example The notched bar is machined from AISI 1020 steel. This bar is subjected to a load that varies from 2000 lb to 3000 lb. Comment on the robustness of the design.

  22. 48” Example Comment on the robustness of a 1-1/4” round bar made from AISI 1213 C-D steel. It carries a constant tensile load of 1500 lbs, a bending load that varies from 0 to 800 lbs at the senter of the 48” length and a constant torque of 1200 in lbs.

  23. UNIT-II

  24. Shafts • Connect power transmission components. • Inherently subjected to transverse loads and torsion.

  25. Wt Wr T Shaft Forces • Gears As before

  26. Ftight D T Fslack = 0 Shaft Forces • Chains

  27. Shaft Forces • V-belts Ftight D T Fslack

  28. Shaft Forces • Flat belts Ftight D T Fslack

  29. Material Properties • For steady load (torsion) sys=.5sy • For fatique load ( bending) sn’=cs cR sn cT = 1 (bending) cm = 1 (wrought steel)

  30. Stress Concentrations • Keyseats • Sled Runner Kt = 1.6 • Profile Kt = 2.0 • Woodruff Kt = 1.5

  31. Stress Concentrations • Shoulders • Sharp, Bearing (r/d .03) Kt = 2.5 • Round, Gear Bore (r/d .17) Kt = 1.5 • Grooves • Retaining Rings Kt = 1.5 Try not to let Kt’s overlap. Leave .10 - .15” between

  32. Strength Analysis • Bending stress • Torsion stress For round sections For round sections

  33. Strength Analysis • Mohr’s circle and Solderberg • Suggested Design Factors: • N=2 smooth operation • N=3 typical industrial operation • N=4 shock or impact loading

  34. Minimum Acceptable Diameter • The designer must size the shaft. • Solve for appropriate diameters

  35. Example Determine a suitable diameter for a shaft made from AISI 1144 OQT 1000. It is subjected to a reversing bending moment of 3000 ft lbs and a steady torque of 1800 ft lbs. The shaft has a profile keyway.

  36. Example The shaft shown is part of a grain drying system • At A, a 34 lb. propeller-type fan requires 12 hp when rotating at 475 rpm. • A flat belt pulley at D delivers 3.5 hp to a screw conveyor handling the grain. • All power comes to the shaft through the v-belt at C. Using AISI 1144 cold drawn steel, determine the minimum acceptable diameter at C.

  37. E B D A C 12” 4” 10” 10” 150 Sheave C Sheave D Example

  38. Shafts Accessories • Components used to securely mount power transmitting elements on a shaft. • Axial • Rotational

  39. Keys • Allow torque to be transferred from a shaft to a power transmitting element (gear, sprocket, sheave, etc.)

  40. H W L Key Design • Use a soft, low strength material (ie, low carbon steel) • Standard size H=W=1/4 D • Design length based on strength

  41. H W Shaft Dia. (in) W (in) T S Standard Key Sizes

  42. Key Design • Key Shear • Failure Theory • Length

  43. Example Specify a key for a gear (grade 40, gray cast iron) to be mounted on a shaft (AISI 1144, hot rolled) with a 2.00 in. diameter. The gear transmits 21000 lb-in of torque and has a hub length of 4 in.

  44. Retaining Rings • Also known as snap rings • Provides a removable shoulder to lock components on shafts or in bores. • Made of spring steel, with a high shear strength. • Stamped, bent-wire, and spiral-wound.

  45. Retaining Ring Selection • Based on shaft diameter & thrust force

  46. Set Screws • Setscrews are fasteners that hold collars, pulleys, or gears on shafts. • They are categorized by drive type and point style.

  47. Standard Set Screw Sizes

  48. Set Screw Holding

  49. D d Pins • A pin is placed in double shear • Holds torsion and axial loads • Hole is made slightly smaller than the pin (FN1 fit)

  50. Example Specify a pin for a gear (grade 40, gray cast iron) to be mounted on a shaft (AISI 1144, hot rolled) with a 2.00 in. diameter. The gear transmits 21000 lb-in of torque and has a hub length of 4 in.

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