Product Description
Conveyor Pulley is manufactured as per customer requirement,with main design under national standard,quality inspection focusing on shaft core,welded joint,rubber material and hardness,dynamic balance and so on for longer product life time.
| Drive/Head Pulley – A conveyor pulley used for the purpose of driving a conveyor belt. Typically mounted in external bearings and driven by an external drive source. |
| Return/Tail Pulley – A conveyor pulley used for the purpose of redirecting a conveyor belt back to the drive pulley. Tail pulleys can utilize internal bearings or can be mounted in external bearings and are typically located at the end of the conveyor bed. Tail pulleys commonly serve the purpose of a Take-Up pulley on conveyors of shorter lengths. |
| Snub Pulley – A conveyor pulley used to increase belt wrap around a drive pulley, typically for the purpose of improving traction. |
| Take-Up Pulley – A conveyor pulley used to remove slack and provide tension to a conveyor belt. Take-Up pulleys are more common to conveyors of longer lengths. |
| Bend Pulley – A conveyor pulley used to redirect the belt and provide belt tension where bends occur in the conveyor system. |
The specification of pulley:
Drive Drum: is the main component of power transmission. The drum can be divided into single drum (the angle of the belt to the drum is 210 ° ~ 230 °) , Double Drum (the angle of the belt to the drum is up to 350 °) and
multi-drum (used for high power) .Â
Bend Drum: is used for changing the running direction of the conveyor belt or increasing the surrounding angle of the conveyor belt on the driving roller, and the roller adopts a smooth rubber surface . The drum shaft shall be forgings and shall be nondestructive tested and the inspection report shall be provided.Â
The Various Surface of Pulley:
Conveyor pulley lagging is essential to improve conveyor belt performance, the combination of our pulley lagging can reduces belt slippage, improve tracking and extends life of belt, bearing & other components.
| PLAIN LAGGING:This style of finish is suitable for any pulley in the conveyor system where watershed is not necessary. It provides additional protection against belt wear, therefore, increasing the life of the pulley. |
| DIAMOND GROOVE LAGGING:This is the standard pattern on all Specdrum lagged conveyor pulleys. It is primarily used for reversing conveyor drive pulleys. It is also often used to allow bi-directional pulley rotation, and the pattern allows water to be dispersed away from the belt. |
| HERRINGBONE LAGGING:The herringbone pattern’s grooves are in the direction of rotation, and offers superior tractive properties. Each groove allows water and other liquids to escape between the face of the drum pulley and the belt. Herringbone grooved pulleys are directional and should be applied to the conveyor in a manner in which the grooves point toward the direction of the belt travel. |
| CHEVRON LAGGING:Some customers specify that the points of the groove should meet – as done in Chevron styled lagging. As before with the herringbone style, this would be used on drive drum pulleys and should be fitted in the correct manner, so as to allow proper use of the pattern and water dispersion also. |
| CERAMIC LAGGING:The Ceramic tiles are moulded into the lagging which is then cold bonded to the drum pulley. This style of finish allows excellent traction and reduces slippage, meaning that the belt tension is lower and, therefore as a result, increases the life of the pulley. |
| WELD-ON STRIP LAGGING: Weld-On Strip Lagging can be applied to bi-directional pulleys, and also has a finish to allow the easy dispersion of water or any fluids between the drum pulley and the belt. |
The Components of Pulley:
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| 1. Drum or Shell:The drum is the portion of the pulley in direct contact with the belt. The shell is fabricated from either a rolled sheet of steel or from hollow steel tubing. |
| 2.Diaphragm Plates:Â The diaphragm or end plates of a pulley are circular discs which are fabricated from thick steel plate and which are welded into the shell at each end, to strengthen the drum.The end plates are bored in their centre to accommodate the pulley Shaft and the hubs for the pulley locking elements. |
| 3.Shaft :The shaft is designed to accommodate all the applied forces from the belt and / or the drive unit, with minimum deflection. The shaft is located and locked to the hubs of the end discs by means of a locking elements. The shaft and hence pulley shafts are often stepped. |
| 4.Locking Elements:These are high-precision manufactured items which are fitted over the shaft and into the pulley hubs. The locking elements attach the pulley firmly to the shaft via the end plates. |
| 5.Hubs:The hubs are fabricated and machined housings which are welded into the end plates. |
| 6.Lagging:Â It is sometimes necessary or desirable to improve the friction between the conveyor belt and the pulley in order to improve the torque that can be transmitted through a drive pulley. Improved traction over a pulley also assists with the training of the belt. In such cases pulley drum surfaces are `lagged` or covered in a rubberized material. |
| 7.Bearing:Â Bearings used for conveyor pulleys are generally spherical roller bearings, chosen for their radial and axial load supporting characteristics. The bearings are self-aligning relative to their raceways, which means that the bearings can be ‘misaligned’ relative to the shaft and plummer blocks, to a certain degree. In practical terms this implies that the bending of the shaft under loaded conditions as well as minor misalignment of the pulley support structure, can be accommodated by the bearing. |
The Production Process of Pulley: Our Products:
| 1.Different types of Laggings can meet all kinds of complex engineering requirements. |
| 2.Advanced welding technology ensures the connection strength between Shell and End-Disk. |
| 3.High-strength Locking Elements can satisfy torque and bending requirements. |
| 4.T-shape End-Discs provide highest performance and reliability. |
| 5.The standardized Bearing Assembly makes it more convenient for the end user to replace it. |
| 6.Excellent raw material and advanced processing technology enable the shaft can withstand enough torque. |
| 7.Low maintenance for continued operation and low total cost of ownership. |
| 8.Scientific design process incorporating Finite Element Analysis. |
Our Workshop:
| MACHINE:We have advanced laser cutting machines, a complete set of intelligent sheet metal forming equipment, robot welding and other processing and testing equipment. |
| PAINTING:  We use electrostatic spraying to ensure variety, model and quality of coatings, thinners and curing agents should meet the design requirements and the current relevant national standards. The steel surface should be free of welding slag, welding scars, dust, oil, water and burrs before painting. No mispainting or omission, and the coating should be free of peeling and rust. Inspection method: observation and inspection. Uniform brushing, consistent color,  no wrinkles,sagging and bubbles, good adhesion, and the color separation line should be clear and neat. |
| DELIVERY:The goods and product factory certificate, installation and use instructions and drawings, a full set of connectors. After the equipment arrives at the site, the company immediately arranges professional and technical personnel to guide the installation on site to provide customers with satisfactory services. |
| PACKAGE:Packed with steel frame or wooden box, according to the standardfor trade export or according to the special requirements of customers. |
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| Material: | Carbon Steel |
|---|---|
| Surface Treatment: | Baking Paint |
| Motor Type: | Frequency Control Motor |
| Installation: | Horizontal |
| Carrying Type: | Light, Medium, Heavy |
| Light Bearing Aperture: | 80-100mm |
| Samples: |
US$ 40/Piece
1 Piece(Min.Order) | |
|---|
| Customization: |
Available
| Customized Request |
|---|
How do you select the right idler pulley configuration for a specific task?
Selecting the appropriate idler pulley configuration for a specific task involves considering several factors. Here are the key steps to guide you in the selection process:
1. Identify System Requirements:
Understand the specific requirements of the task or application. Determine the type of belt or chain being used, the power transmission requirements, the operating conditions (such as temperature, speed, and load), and any specific constraints or limitations.
2. Determine Belt or Chain Type:
Identify the type and specifications of the belt or chain being used in the system. This includes factors such as the belt width, pitch, tooth profile (for timing belts), and chain size. Knowing the characteristics of the belt or chain will help in selecting an idler pulley that is compatible and optimized for that specific type.
3. Consider Pulley Material and Construction:
Select a pulley material that is suitable for the task at hand. Common options include steel, cast iron, aluminum, and various plastics. Consider factors such as the required strength, durability, corrosion resistance, and the environment in which the pulley will be operating.
4. Determine Pulley Size and Configuration:
Calculate or determine the appropriate pulley size, including the diameter and width. Consider factors such as the desired belt tension, the required wrap angle (the contact area between the pulley and the belt), and any specific clearance or spacing requirements within the system.
5. Assess Bearing and Shaft Requirements:
Consider the bearing and shaft requirements for the idler pulley. Determine the load capacity, rotational speed, and any specific mounting or attachment considerations. Select bearings and shafts that can handle the anticipated loads and provide smooth operation.
6. Consult Manufacturer Recommendations:
Refer to the manufacturer’s recommendations or specifications for the idler pulley. Manufacturers often provide guidelines and technical data for their products, including load capacity charts, speed limits, and other relevant information. Ensure that the selected idler pulley aligns with these recommendations.
7. Evaluate Cost and Availability:
Consider the cost and availability of the idler pulley. Evaluate different suppliers and compare prices, ensuring that the selected pulley offers a good balance of cost-effectiveness and quality. Additionally, ensure that the idler pulley is readily available when needed.
8. Installation and Maintenance:
Lastly, consider the installation and maintenance requirements of the idler pulley. Ensure that it can be easily installed within the system and that any necessary adjustments or maintenance can be performed without significant hassle.
By following these steps and considering the specific requirements of the task or application, you can select the right idler pulley configuration that ensures proper tensioning, reliable power transmission, and optimal performance in your specific task.
What role do idler pulleys play in maintaining proper belt alignment?
Idler pulleys play a crucial role in maintaining proper belt alignment in mechanical systems. Here’s a detailed explanation of the role idler pulleys play in maintaining proper belt alignment:
Proper belt alignment refers to the correct positioning of the belt along the pulleys in a system. It ensures that the belt remains centered on the pulleys and follows its intended path without deviating or slipping off. Belt misalignment can lead to a range of issues, including increased friction, wear, noise, and reduced power transmission efficiency. Idler pulleys help address these alignment challenges and contribute to the smooth operation of the system.
1. Belt Tracking:
Idler pulleys guide the belt and help maintain its tracking along the pulleys. They are strategically positioned to ensure that the belt remains in the desired position and follows the correct path. By providing a reference point and support, idler pulleys prevent the belt from wandering or shifting laterally, which could otherwise cause misalignment.
2. Tension Adjustment:
Idler pulleys can be used to adjust and maintain the tension in the belt, which is crucial for proper alignment. By adding or removing idler pulleys or adjusting their position, the tension in the belt can be controlled. Proper tension ensures that the belt remains engaged with the pulleys and does not slack or become too tight, both of which can lead to misalignment.
3. Belt Support:
Idler pulleys provide support to the belt, helping to prevent sagging or excessive vibration. They act as additional contact points along the belt’s path and distribute the load, ensuring that the belt remains in its intended position. This support helps maintain the alignment of the belt, especially in applications where the belt spans long distances or encounters varying loads.
4. Load Distribution:
Idler pulleys contribute to load distribution across the belt. By introducing additional pulleys strategically, the load on the belt can be divided, reducing stress on individual components. This helps to minimize the risk of belt misalignment due to uneven loading or excessive strain. By distributing the load, idler pulleys promote uniform wear and ensure the longevity of the belt.
5. Vibration and Noise Reduction:
Idler pulleys play a role in reducing vibration and noise in mechanical systems. Misaligned belts can cause excessive vibration and noise due to uneven forces and increased friction. By maintaining proper alignment, idler pulleys help minimize these issues, resulting in quieter operation and increased system stability.
Overall, idler pulleys are essential components in maintaining proper belt alignment. Their role in guiding the belt, adjusting tension, providing support, distributing load, and reducing vibration ensures that the belt remains properly aligned, leading to improved efficiency, reduced wear, and extended belt life in mechanical systems.
How does the size and diameter of an idler pulley affect its performance?
The size and diameter of an idler pulley play a significant role in determining its performance characteristics. Here’s a detailed explanation of how the size and diameter of an idler pulley affect its performance:
1. Tension and Belt Engagement:
The size and diameter of an idler pulley impact the tension and engagement of the belt. A larger idler pulley will create more belt wrap around its circumference, resulting in increased belt contact and improved grip. This helps to maintain proper tension in the belt and prevent slippage, especially in high-torque applications. Conversely, a smaller idler pulley may have less belt wrap, leading to reduced grip and potentially lower tension.
2. Belt Speed:
The size and diameter of an idler pulley affect the speed at which the belt travels. A larger idler pulley will cover a greater distance per revolution, resulting in a higher belt speed. This can be advantageous in applications where increased speed is desired. Conversely, a smaller idler pulley will cover a shorter distance per revolution, leading to a slower belt speed.
3. Belt Flexibility:
The size and diameter of an idler pulley impact the flexibility of the belt. A larger idler pulley allows for a larger bend radius, reducing the stress on the belt and improving its durability. It also minimizes the risk of excessive bending or flexing that could lead to premature wear or failure. In contrast, a smaller idler pulley may require the belt to bend more sharply, potentially increasing the risk of damage or wear.
4. System Clearance:
The size and diameter of an idler pulley affect the overall clearance in the mechanical system. In tight spaces or constrained environments, a smaller idler pulley may be preferred, as it requires less clearance. Conversely, a larger idler pulley may require additional space to accommodate its size.
5. Load Distribution:
The size and diameter of an idler pulley impact its ability to distribute the load across the belt. A larger idler pulley can distribute the load over a larger surface area, reducing the stress on the belt and other components. It helps to minimize wear and prolong the life of the system. On the other hand, a smaller idler pulley concentrates the load on a smaller area, potentially increasing the risk of localized wear or failure.
6. Bearing Life and Friction:
The size and diameter of an idler pulley influence the bearing life and friction within the system. Larger idler pulleys typically have larger bearings, which can handle higher loads and exhibit improved durability. They also tend to generate lower friction, leading to reduced heat and wear. In contrast, smaller idler pulleys may have smaller bearings that may have limitations in terms of load capacity and friction.
It’s important to note that the specific requirements for size and diameter of an idler pulley will depend on the application and the intended function within the mechanical system. Factors such as belt type, load requirements, speed, and space constraints should be considered when selecting the appropriate size and diameter of an idler pulley for optimal performance.
editor by CX
2024-02-06