There are many elements to consider during the design of a conveyor pulley. The most important however is the design of the shafts. Other elements that need to be considered are the pulley diameter, the shell, the hubs and the locking elements.

1.0 Shaft design

  • There are three main factors that influence shaft design. Bending from the tensions on the conveyor belt. Torsion from the drive unit and deflection. The shaft therefore needs to be designed considering all three of these elements.
  • For the design of the shaft, based on bending and torsion, a max stress is used. This stress varies according to the material that is used for the shaft or according to the max stress allowed by the end user.

2.0 Pulley design

  • There are various factors influencing the pulley diameter. The pulley diameter is mainly determined by the conveyor belt class, but the required shaft diameter also influences the diameter. A golden rule for the pulley's diameter is that it should be at least three times the diameter of the shaft.

2.1 Pulley Types

  • There are two main types of pulleys i.e. the Turbine pulley and the T-Bottom Pulley. In both these types of pulleys the shaft is removable for easy maintenance.
  • The Turbine Pulley is well suited for low to medium duty applications with a hub designed to allow for flexing, thus preventing high stresses on the locking assemblies or welds.
  • The T-Bottom Pulley is normally used for heavy duty applications with shaft diameters of 200mm and bigger. The main feature of this construction is a face welded pulley and thus the shell to hub weld is moved out of the high stressed area at the end plate.

2.2 Pulley crowning

  • Full Crown: From the centre line of the pulley with a ratio of 1:100
  • Strip Crown: Crown from the first and last third of the pulley face with a ratio of 1:100 Crowning is normally only done on specific request.

2.3 Lagging

  • Various types of lagging can be applied to the pulley i.e. rubber lagging, flameproof (neoprene) lagging, Rubber backed ceramic lagging, Direct bond ceramic lagging and Polyurethane lagging.

International Standard

This is achieved with the help of

  • Solid works 3D Design software
  • Fully integrated FEA Analysis
  • 70+ years of design experience

Quality Assurance

  • Fully integrated ISO system
  • All materials are fully certified
  • Weld checks using either UT, MPI or X-ray
  • Comprehensive data book created

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