Solution Description
Type | Belt width(mm) | Standard Diameter(mm) | Size(mm) |
Drive Pulley | five hundred | 500 |
Length of the pulley depends on the belt width of the conveyor |
650 | 500~630 | ||
800 | 630~one thousand | ||
one thousand | 800~1150 | ||
1200 | 800~1150 | ||
1400 | one thousand~1350 | ||
1600 | 1150~1600 | ||
1800 | 1150~1800 | ||
2000 | 1350~2000 | ||
2200 | 1600~2200 | ||
2400 | 1800~2400 | ||
Bend Pully | 500 | 250~500 | |
650 | 250~630 | ||
800 | 250~one thousand | ||
1000 | 250~1600 | ||
1200 | 250~1600 | ||
1400 | 315~1600 | ||
1600 | 400~1600 | ||
1800 | 400~1600 | ||
2000 | five hundred~1600 | ||
2200 | 630~1600 | ||
2400 | 800~1600 |
In a dual pulley program, this ratio is equal to the reference diameter of the output pulley currently being increased than the reference diameter of the enter pulley. It’s relatively uncomplicated as extended as you estimate the equipment ratios for a more complicated pulley program phase by step. For a number of pulleys, the ratios of the a variety of parts of the mechanism have to be calculated to decide the total ratio. In the image previously mentioned, the reference diameter of the decrease push wheel is 20mm, the radius of the higher wheel is 40mm, and the ratio is 2:1. 2 spins on the reduce wheel and 1 spin on the higher wheel. The equipment ratio also tells us something about the torque of the technique since the ratio of output torque to enter torque is equal to the gear ratio. As a result, the torque used to the higher wheel is two times as rapidly, but the velocity is halved.