Product Description
Product spections :
1997 | Mercedes-Benz | SL500 | Base Convertible 2-Door | 5.0L 4973CC V8 GAS DOHC Naturally Aspirated |
1996 | Mercedes-Benz | SL500 | Base Convertible 2-Door | 5.0L 4973CC V8 GAS DOHC Naturally Aspirated |
1995 | Mercedes-Benz | SL500 | Base Convertible 2-Door | 5.0L 4973CC V8 GAS DOHC Naturally Aspirated |
1994 | Mercedes-Benz | SL500 | Base Convertible 2-Door | 5.0L 4973CC V8 GAS DOHC Naturally Aspirated |
1993 | Mercedes-Benz | 500SL | Base Convertible 2-Door | 5.0L 4973CC V8 GAS DOHC Naturally Aspirated |
1992 | Mercedes-Benz | 500SL | Base Convertible 2-Door | 5.0L 4973CC V8 GAS DOHC Naturally Aspirated |
1989 | Mercedes-Benz | 190D | 2.5 Sedan 4-Door | 2.5L 2497CC l5 DIESEL SOHC Naturally Aspirated |
1988 | Mercedes-Benz | 190D | 2.5 Sedan 4-Door | 2.5L 2497CC l5 DIESEL SOHC Naturally Aspirated |
1988 | Mercedes-Benz | 190E | 2.3 Sedan 4-Door | 2.3L 2299CC l4 GAS SOHC Naturally Aspirated |
1987 | Mercedes-Benz | 190D | 2.5 Sedan 4-Door | 2.5L 2497CC l5 DIESEL SOHC Naturally Aspirated |
1987 | Mercedes-Benz | 190D | 2.5 Turbo Sedan 4-Door | 2.5L 2497CC l5 DIESEL SOHC Turbocharged |
1987 | Mercedes-Benz | 190E | 2.3-16 Sedan 4-Door | 2.3L 2299CC l4 GAS DOHC Naturally Aspirated |
1987 | Mercedes-Benz | 190E | 2.3 Sedan 4-Door | 2.3L 2299CC l4 GAS SOHC Naturally Aspirated |
1986 | Mercedes-Benz | 190D | 2.5 Sedan 4-Door | 2.5L 2497CC l5 DIESEL SOHC Naturally Aspirated |
1986 | Mercedes-Benz | 190E | 2.3-16 Sedan 4-Door | 2.3L 2299CC l4 GAS DOHC Naturally Aspirated |
1985 | Mercedes-Benz | 190D | 2.2 Sedan 4-Door | 2.2L 2197CC l4 DIESEL SOHC Naturally Aspirated |
1984 | Mercedes-Benz | 190D | 2.2 Sedan 4-Door | 2.2L 2197CC l4 DIESEL SOHC Naturally Aspirated |
Description :
1. The tensioner is a belt tensioner used in the automobile transmission system. The tension pulley is mainly composed of a fixed shell, a tension arm, a wheel body, a torsion spring, a rolling bearing and a spring sleeve. It can automatically adjust the tension force according to the different tightness of the belt to make the transmission system stable, safe and reliable.
2. The main function of the tensioner bearing is to support the mechanical rotating body.
3.Reduce the friction coefficient during its movement and ensure its rotation accuracy.
4.Change sliding friction into rolling friction.
After-sales Service: | 1 Year Guarantee |
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Warranty: | 1 Year Guarantee |
Type: | Tensioner Bearing |
Material: | Aluminum |
Certification: | TS16949 |
Car Make: | Suzuki |
Customization: |
Available
| Customized Request |
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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.
Can idler pulleys withstand continuous use and high-speed rotation?
Idler pulleys are designed to withstand continuous use and high-speed rotation in various applications. Here’s a detailed explanation of the factors that contribute to the ability of idler pulleys to withstand continuous use and high-speed rotation:
1. Material Selection:
The choice of materials for idler pulleys is crucial in determining their ability to withstand continuous use and high-speed rotation. Idler pulleys are commonly made from durable materials such as steel, aluminum, or engineered plastics. These materials offer high strength, wear resistance, and dimensional stability. The selection of materials depends on factors such as the load capacity, operating conditions, and rotational speed requirements of the specific application.
2. Bearing Design:
The bearing design used in idler pulleys plays a vital role in their ability to handle continuous use and high-speed rotation. High-quality bearings with appropriate load ratings and speed capabilities are selected to support the rotational motion of the pulley. The bearing design ensures smooth operation, minimizes friction, and provides reliable support for the pulley shaft under continuous and high-speed conditions.
3. Heat Dissipation:
During high-speed rotation, idler pulleys can generate heat due to friction. Adequate heat dissipation mechanisms are incorporated into the design to prevent excessive heat buildup. This can include features such as cooling fins, ventilation holes, or the use of heat-resistant materials. Effective heat dissipation helps maintain the integrity of the idler pulleys and prevents overheating that could lead to premature wear or failure.
4. Load Capacity:
Idler pulleys are designed to handle specific load capacities, which include both radial and axial loads. The load capacity of an idler pulley is determined by factors such as the size, material, and bearing selection. Manufacturers provide load capacity guidelines to ensure that the idler pulleys can withstand continuous use and high-speed rotation without excessive stress or deformation.
5. Precision Manufacturing:
Idler pulleys are manufactured with precision to ensure proper balance, concentricity, and dimensional accuracy. The precise manufacturing process helps minimize vibration, wobbling, and noise during high-speed rotation. It also enhances the overall stability and performance of the idler pulley under continuous use.
6. Quality Control:
Idler pulleys undergo rigorous quality control measures during the manufacturing process. These measures include inspections, testing, and adherence to industry standards to ensure that the pulleys meet the required specifications. Quality control measures help ensure the reliability, durability, and performance of idler pulleys during continuous use and high-speed rotation.
Overall, idler pulleys are designed and engineered to withstand continuous use and high-speed rotation in various applications. Through careful material selection, bearing design, heat dissipation, load capacity considerations, precision manufacturing, and quality control measures, idler pulleys can reliably perform their intended functions even under demanding operating conditions.
What is an idler pulley, and what is its role in mechanical systems?
An idler pulley is a specific type of pulley that is used in mechanical systems. Here’s a detailed explanation of what an idler pulley is and its role in mechanical systems:
Definition:
An idler pulley is a pulley that is not directly connected to a power source or used for power transmission. Instead, it is used to guide and redirect a belt or rope in a system. The idler pulley is typically positioned in such a way that it changes the direction of the belt or rope, adjusts tension, or provides support to ensure smooth operation.
Role in Mechanical Systems:
The primary role of an idler pulley in mechanical systems is to maintain proper tension and alignment of belts or ropes. It helps to redirect the path of the belt or rope, ensuring that it remains in the correct position and stays engaged with other pulleys or components.
Here are some specific roles and functions of idler pulleys:
1. Belt Tension:
An idler pulley can be used to adjust and maintain the tension in a belt or rope. By adding or removing an idler pulley or adjusting its position, the tension in the belt can be properly controlled. This is crucial for preventing slippage, ensuring efficient power transmission, and extending the lifespan of the belt.
2. Directional Change:
In some systems, an idler pulley is strategically placed to change the direction of the belt or rope. By guiding the belt along a different path, the idler pulley allows the belt to reach components that would otherwise be inaccessible or difficult to connect directly. This enables flexibility in designing mechanical systems and facilitates the proper functioning of various components.
3. Belt Alignment:
An idler pulley helps maintain proper alignment of belts or ropes. It ensures that the belt remains centered on the pulleys and does not deviate from its intended path. Proper alignment is vital for efficient power transmission, as misaligned belts can cause increased friction, wear, and loss of energy.
4. Load Distribution:
In systems with multiple belts or ropes, an idler pulley can be used to distribute the load evenly. By introducing an idler pulley between two driving pulleys, the load can be divided, reducing stress on individual components and improving overall system performance.
5. Noise and Vibration Reduction:
An idler pulley can help reduce noise and vibration in mechanical systems. By providing additional support and tension to belts or ropes, it minimizes excessive movement and vibration, resulting in quieter operation and increased stability.
Idler pulleys are commonly found in various applications, including automotive engines, HVAC systems, conveyor systems, and industrial machinery. Their role in maintaining tension, guiding belts, adjusting alignment, distributing load, and reducing noise makes them essential components in ensuring the smooth and efficient operation of mechanical systems.
editor by CX
2023-10-07