Customization: | Available |
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Materials: | Q235 Carbon Steel Ss400 Rubber Nylon HDPE Ceramic |
Certification: | ISO9001 BV SGS TUV CE ISO14001 |
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Standard Diameter | Length scope ( mm) | Bearings Type (Min~Max) |
Idler's Shell Wall Thickness | |
mm | Inch | |||
63.5 | 2 1/2 | 150~3500 | 204 | 3.0mm~3.75mm |
76 | 3 | 150~3500 | 204 205 | 3.0mm~4.0mm |
89 | 3 1/3 | 150~3500 | 204 205 | 3.0mm~4.0mm |
102 | 4 | 150~3500 | 204 205 305 | 3.5mm~4.0mm |
108 | 4 1/4 | 150~3500 | 204 205 305 306 | 3.5mm~4.0mm |
114 | 4 1/2 | 150~3500 | 205 206 305 306 | 3.5mm~4.5mm |
127 | 5 | 150~3500 | 204 205 305 306 | 3.5mm~4.5mm |
133 | 5 1/4 | 150~3500 | 205 206 207 305 306 | 3.5mm~4.5mm |
140 | 5 1/2 | 150~3500 | 205 206 207 305 306 | 3.5mm~4.5mm |
152 | 6 | 150~3500 | 205 206 207 305 306 307 308 | 4.0mm~4.5mm |
159 | 6 1/4 | 150~3500 | 205 206 207 305 306 307 308 | 4.0mm~4.5mm |
165 | 6 1/2 | 150~3500 | 207 305 306 307 308 | 4.5mm~6.0mm |
177.8 | 7 | 150~3500 | 207 306 307 308 309 | 4.5mm~6.0mm |
190.7 | 7 1/2 | 150~3500 | 207 306 307 308 309 | 4.5mm~6.0mm |
194 | 7 5/8 | 150~3500 | 207 307 308 309 310 | 4.5mm~6.0mm |
219 | 8 5/8 | 150~3500 | 308 309 310 | 4.5mm~6.0mm |
When trying to understand and improve the conveying process, you have to understand all the types and designs of idlers that can be used in your conveyor system. In this article we will describe the basics.
In the evolution of idlers, many types of rollers were designed. Each of them having special features such as minimizing the pressure on the belt, cleaning the belt and many others.
The simplest way to differentiate the idler designs would be to divide them to carry and return idlers.
However, the differentiation of rollers is more granular, as explained below.
Troughing idlers are a type of the carry idlers. The main part of the troughing idler is a center roller which is accompanied by wing rollers on its sides which are connected in a troughing angle (for example 45 degrees).
Thanks to the troughing angle, the carried material is gathered in the center of the belt so that the material does not fall off the belt during transportation.
The troughing idlers can be seen in sets of 3 or 5. The more rollers are used, the better is the distribution of the loaded weight and enables higher transportation capacity.
Impact idlers are used at the place where material is loaded onto the belt. The newly loaded material presents a high-pressure impact on the belt and idlers with rubbered disks can better absorb the impact.
Impact idlers are positioned at a close range and are usually manufactured in 89mm diameter.
The transition idlers optimize the higher pulling tension which is observed close to the head and tail pulley. The transition idlers continuously adjust the troughing angle from 0 degrees to the 45 degrees right behind the head pulley in order to create the right belt shape for successfully transporting the material. Contrarily, the belt has to be flattened from 45 degrees to 0 degrees before getting onto the tail pulley in order to distribute the tension properly.
The belt has to be nicely aligned to the pulley in order to avoid long term damage. In the conveyor systems you would mostly see 2 or 3 transition idler sets.
When carrying the belt back to the feeder, it also needs support. However, since the belt does not carry any load, the support does not have to be as robust. Therefore, return idlers can be positioned in two or three times the distance of the carrying rollers. Even the number of rollers per idler can be reduced to one or two rollers.
If a single roller is used, it is usually called a flat return idler which spreads over the whole width of the belt and can be attached to the conveyor support structure.
When two rollers would be used, it is called a V return idler.
The return idlers can also be covered with rubbered disks which should be removing sticky materials from the belt.
The belt should be perfectly aligned when moving onto the pulley. In reality, the belt is often slightly shifted due to incorrect belt splicing or imbalanced material loading. In such cases, training idlers can align the belt nicely to the pulley in order to prevent damaging of the belt when put into tension in an incorrect position.
If your conveyor system needs to be more moveable or when the environment is not suitable for a static idler, you would be needing garland idlers. These idlers are attached to the conveyor frame and enable better mobility. While decreasing the maximum loading capacity.
The last component that plays a big part when using a conveyor system is a tension controller. In order to transport load as effectively as possible, the belt has to be in a high tension. The pulleys would move the belt faster and the belt would avoid up and down resonations which slows the movement.