Classical V Ribbed Belt
are frequently used individually, particularly in A and B sizes. The larger C, D, and E sizes generally are not used in single-belt drives because of cost penalties and inefficiencies. Multiple A or B belts are economical alternatives to using single-belt C, D, or E sections.
Narrow V-belts, for a given width, offer higher power ratings than conventional V-belts. They have a greater depth-to-width ratio, placing more of the sheave under the reinforcing cord. These belts are suited for severe duty applications, including shock and high starting loads.
Banded V-belts solve problems conventional multiple V-belt drives have with pulsating loads. The intermittent forces can induce a whipping action in multiple-belt systems, sometimes causing belts to turn over. The joined configuration avoids the need to order multiple belts as matched sets.
Banded V-belts should not be mounted on deep-groove sheaves, which are used to avoid turnover in standard V-belts. Such sheaves have the potential for cutting the band of joined belts. Extremely worn sheaves produce the same result.
V-ribbed belts combine some of the best features of flat belts and V-belts. The thin belt operates efficiently and can run at high speeds. Tensioning requirements are about 20% higher than V-belts. The ribs ensure the belt tracks properly, making alignment less critical than it is for flat belts.
Synchronous belts have a toothed profile that mates with corresponding grooves in the pulleys, providing the same positive engagement as gears or chains. They are used in applications where indexing, positioning, or a constant speed ratio is required.
The first tooth profile used on synchronous belts was the trapezoidal shape. It is still recognized as standard. Recent modifications to tooth profiles have improved on the original shape. The full-rounded profile distributes tooth loads better to the belt tension members. PK Belt
also provides greater tooth shear strength for improved load capacity.