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Shaft (mechanical engineering) (740 views - Mechanical Engineering)

A shaft is a rotating machine element, usually circular in cross section, which is used to transmit power from one part to another, or from a machine which produces power to a machine which absorbs power. The various members such as pulleys and gears are mounted on it.
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Shaft (mechanical engineering)

Shaft (mechanical engineering)

Shaft (mechanical engineering)

A shaft is a rotating machine element, usually circular in cross section, which is used to transmit power from one part to another, or from a machine which produces power to a machine which absorbs power.[1] The various members such as pulleys and gears are mounted on it.

Types

They are mainly classified into two types.

  • Transmission shafts are used to transmit power between the source and the machine absorbing power; e.g. counter shafts and line shafts.
  • Machine shafts are the integral part of the machine itself; e.g. crankshaft.

Materials

The material used for ordinary shafts is mild steel. When high strength is required, an alloy steel such as nickel, nickel-chromium or chromium-vanadium steel is used.

Shafts are generally formed by hot rolling and finished to size by cold drawing or turning and grinding.

Standard sizes

Source:[2]

Machine shafts

  • Up to 25 mm steps of 0.5 mm

Transmission shafts

  • 25 mm to 60 mm with 5 mm steps
  • 60 mm to 110 mm with 10 mm steps
  • 110 mm to 140 mm with 15 mm steps
  • 140 mm to 500 mm with 20 mm steps

The standard lengths of the shafts are 5 m, 6 m and 7 m.

Stresses

The following stresses are induced in the shafts.

  1. Shear stresses due to the transmission of torque (due to torsional load).
  2. Bending stresses (tensile or compressive) due to the forces acting upon the machine elements like gears and pulleys as well as the self weight of the shaft.
  3. Stresses due to combined torsional and bending loads.

Design stresses

The maximum permissible (design) stresses in bending (tension or compression) may be taken as:

  1. 112 N/mm2 for shafts with allowance for keyways.
  2. 84 N/mm2 for shafts without allowance for keyways.

The maximum permissible (design) shear stresses may be taken as:

  1. 56 N/mm2 for shafts with allowance for keyways.
  2. 42 N/mm2 for shafts without allowance for keyways.
  1. ^ Khurmi R S, (2014), 'A text book of machine design', Eurasia publishing house(P) ltd., New-Delhi, ISBN 9788121925372
  2. ^ Mahadevan K and Reddy K.Balaveera, (2015), 'Design data hand book', CBS publishers and Distributors (P) ltd., New-Delhi, ISBN 9788123923154


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Mechanical Engineering

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