Product Description
mall engineering plastic UHMW-PE pulley
UHMW-PE(Ultra high Molecular Weight Polyethylene )is a thermoplastic engineering plastic with the average molecular weight more than 9.0 million. (PE only has the molecular weight between 20 to 2 hundred thousand. ) This kind of material with 5 top performance of high-wear-resistance, good-chemical resistance, low-temperature resistance, self-lubrication and high-impact resistance, which is regarded as a “surprised” engineering plastic of excellent comprehensive capacity and competitive price.
Main characteristics:
1. Very high-wear resistance, 7 times wear resistance than steel, 4 times than PTFE
2. Very high anti-impact resistance, 2 times impact resistance than PC, 5 times than ABS.
3. Good self-lubrication, the same as PTFE, better than steel and brass appended lubricating oil.
4. Good anti-corrosion resistance, it has very stable chemicals property and can endure the corrosion of all kinds of corrosive medium and organic solvent in certain rang of temperature and humidity.
5. Very high-inadhesion resistance, the surface of product hardly affixes other material.
6. Very high-impact resistance, 10 times impact resistance than PA66, 8 times than PTFE.
7. Good low temperature resistance, in liquefied nitrogen (- 196º C), it still has the prolongation.
Few other materials can reach to this performance.
8. Non-toxic and clean property, UHMW-PE, which is the material that Food and Drug Administration (FDA) and United States Department of Agriculture (ASDA) permit to apply in food and medicine fields.
Property | Item No. | Unit | Value | |
Mechanical Properties | 1 | Density | g/cm3 | 0.94-0.96 |
2 | average molecular weight | g/mol | More than 9.0 million | |
3 | Tensile strength (23ºCin air) | MPa | 22 | |
4 | Breaking strength | MPa | 42 | |
5 | Tensile strain at break | % | 600 | |
6 | Charpy impact strength (notched) | mJ/mm 2 | No break | |
7 | Ball indentation hardness | N/mm 2 | 42 | |
8 | Shore D hardness | — | D65 | |
9 | Abrading(sand slurry experiment) | — | 100 |
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Material: | PE |
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Size: | According to Drawing or Sample |
Color: | White, Black, Green, Yellow, Blue, Red |
Tooling: | CNC Lathe |
Dentity: | 0.98 |
Shape: | Tube, Sheet, Rod, Gear, Pulley etc. |
Customization: |
Available
| Customized Request |
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Are there any limitations or temperature constraints with plastic pulleys?
Yes, there are certain limitations and temperature constraints associated with plastic pulleys. Here’s a detailed explanation:
1. Load Capacity:
Plastic pulleys have a limited load capacity compared to their metal counterparts. While they are suitable for many light to moderate load applications, they may not be suitable for heavy-duty or high-load scenarios. Exceeding the recommended load capacity of plastic pulleys can lead to deformation, premature wear, or failure of the pulley, compromising the overall performance and reliability of the system.
2. Temperature Sensitivity:
Plastic pulleys can be sensitive to temperature variations. Extreme heat or cold can affect the mechanical properties of the plastic material, leading to dimensional changes, reduced strength, or increased brittleness. High temperatures can cause the pulleys to deform or soften, while low temperatures can make them more prone to cracking or breakage. Therefore, it is important to consider the temperature range in which plastic pulleys will be operating and choose materials that can withstand the specific environmental conditions.
3. Thermal Expansion:
Plastic pulleys can exhibit thermal expansion, meaning they may expand or contract with changes in temperature. This can affect the precision and alignment of the pulley system. In applications where precise positioning or tight tolerances are required, thermal expansion of the plastic pulleys should be taken into account to ensure proper functioning of the system. Compensation techniques, such as using adjustable mounting brackets or incorporating thermal expansion calculations, may be necessary to maintain alignment under varying temperature conditions.
4. Chemical Compatibility:
Some plastic materials used in pulleys may not be compatible with certain chemicals or solvents. Exposure to chemicals that are incompatible with the plastic material can lead to degradation, discoloration, or weakening of the pulleys. It is important to consider the chemical environment in which the plastic pulleys will be used and select materials that are resistant to the specific chemicals present in that environment.
5. UV and Weather Resistance:
Not all plastic materials used in pulleys have excellent resistance to ultraviolet (UV) radiation or outdoor weather conditions. Prolonged exposure to sunlight or harsh weather elements can cause degradation, discoloration, or loss of mechanical properties in certain plastics. If plastic pulleys are intended for outdoor or UV-exposed applications, it is crucial to choose materials that are UV-resistant and weather-resistant to ensure long-term durability and performance.
6. Static Electricity:
Some plastic pulleys can generate static electricity during operation. This can be a concern in certain applications where static discharge can interfere with sensitive electronic components or create safety hazards in potentially explosive environments. In such cases, anti-static or conductive plastic materials may need to be used to mitigate the risks associated with static electricity generation.
In summary, plastic pulleys have limitations and temperature constraints that should be considered during their selection and application. These limitations include load capacity, temperature sensitivity, thermal expansion, chemical compatibility, UV and weather resistance, and static electricity generation. By understanding and addressing these constraints, it is possible to use plastic pulleys effectively and ensure their optimal performance and longevity in various mechanical systems.
What safety considerations should be kept in mind when using plastic pulleys?
When using plastic pulleys, several safety considerations should be kept in mind to ensure the well-being of operators and the proper functioning of machinery or equipment. Here’s a detailed explanation:
1. Load Capacity:
One important safety consideration is to ensure that the plastic pulleys are selected and designed to handle the anticipated loads and forces in the application. Exceeding the load capacity of the pulleys can lead to premature failure, belt or chain slippage, or even catastrophic accidents. It is essential to consult the manufacturer’s specifications and guidelines to determine the maximum load capacity of the plastic pulleys and ensure they are not overloaded.
2. Material Compatibility:
Consider the compatibility of the plastic pulley material with the surrounding environment and the materials it comes into contact with. Some chemicals, solvents, or extreme temperatures may adversely affect certain types of plastic. Ensure that the chosen plastic material is resistant to the specific chemicals or conditions present in the application to avoid material degradation, weakening, or failure of the pulleys.
3. Proper Installation:
Correct installation of plastic pulleys is crucial for safety. Follow the manufacturer’s instructions and guidelines for proper pulley installation, including mounting options, alignment, and fastening mechanisms. Improperly installed pulleys can lead to misalignment, belt or chain disengagement, excessive vibrations, or other operational issues that compromise safety. Ensure that pulleys are securely attached and aligned to prevent accidents or damage to the machinery or equipment.
4. Guarding and Enclosures:
Consider incorporating appropriate guarding and enclosures around the plastic pulleys to prevent accidental contact with moving parts. This is especially important in conveyor systems or machinery where operators or maintenance personnel may need to interact with the pulleys. Guards and enclosures help prevent injury caused by entanglement, pinching, or getting caught in the rotating components, enhancing overall safety in the work environment.
5. Regular Inspection and Maintenance:
Regular inspection and maintenance of plastic pulleys are essential for identifying any signs of wear, damage, or degradation. Inspect the pulleys periodically to check for cracks, excessive wear, or any other visible issues. Replace any damaged or worn-out pulleys promptly to avoid unexpected failures or accidents. Additionally, follow the manufacturer’s recommendations for lubrication, cleaning, or any other maintenance procedures to ensure the pulleys function optimally and safely.
6. Training and Awareness:
Proper training and awareness among operators and maintenance personnel are essential for safe operation and handling of machinery or equipment with plastic pulleys. Ensure that personnel are trained on the correct procedures for operating, maintaining, and troubleshooting the equipment. They should be aware of the potential hazards associated with plastic pulleys and understand the safety protocols to follow, including lockout/tagout procedures, emergency stop mechanisms, and personal protective equipment requirements.
7. Compliance with Regulations:
Ensure that the use of plastic pulleys complies with relevant safety regulations, standards, and guidelines specific to the industry or region. Different industries may have specific requirements for safety, such as those related to food processing, hazardous environments, or machinery certification. Adhering to these regulations helps ensure that the plastic pulleys and associated machinery or equipment meet the necessary safety standards.
By considering these safety considerations when using plastic pulleys, operators can minimize risks, prevent accidents, and ensure the safe and efficient operation of machinery or equipment in various industrial applications.
How do plastic pulleys contribute to effective belt or cable operation?
Plastic pulleys play a crucial role in ensuring effective belt or cable operation in numerous applications. Here’s a detailed explanation of how plastic pulleys contribute to effective belt or cable operation:
1. Reduced Friction:
Plastic pulleys are designed to have low friction surfaces. When a belt or cable passes over a plastic pulley, the reduced friction between the pulley and the belt or cable allows for smoother movement. This reduced friction minimizes energy losses, improves efficiency, and reduces wear and tear on the belt or cable. As a result, plastic pulleys contribute to effective and efficient operation by reducing the resistance encountered by the belt or cable during its movement.
2. Noise Reduction:
Plastic pulleys offer inherent damping properties, which help reduce noise and vibration during belt or cable operation. The damping effect of plastic materials absorbs vibrations and minimizes noise generation. This is particularly important in applications where quiet operation is desired, such as in office equipment or household appliances. By reducing noise and vibration, plastic pulleys contribute to effective belt or cable operation by providing a smoother and quieter system performance.
3. Wear Resistance:
Plastic pulleys are often engineered to be wear-resistant. They are designed to withstand the repetitive contact and rubbing of belts or cables without significant wear or damage. The wear-resistant properties of plastic pulleys ensure that the pulley maintains its shape and functionality over time, resulting in prolonged belt or cable life and consistent performance. By minimizing wear and extending the lifespan of the belt or cable, plastic pulleys contribute to effective and reliable operation in various applications.
4. Corrosion Resistance:
Plastic pulleys offer excellent resistance to corrosion. Unlike metal pulleys that may rust or corrode when exposed to moisture or certain chemicals, plastic pulleys remain unaffected by such corrosive elements. This corrosion resistance is particularly beneficial in environments where belts or cables may come into contact with moisture or chemicals, such as in outdoor machinery or marine equipment. By resisting corrosion, plastic pulleys ensure the longevity and reliable operation of belts or cables in harsh conditions.
5. Design Flexibility:
Plastic pulleys offer a high degree of design flexibility. They can be molded into various shapes, sizes, and configurations, allowing for precise customization to match the specific requirements of the belt or cable system. Plastic pulleys can incorporate features such as flanges, grooves, or mounting options directly into the design, ensuring optimal belt or cable engagement and alignment. This design flexibility contributes to effective belt or cable operation by providing a tailored solution that maximizes performance and minimizes the risk of belt slippage or misalignment.
6. Cost-Effectiveness:
Plastic pulleys are generally more cost-effective compared to pulleys made from other materials, such as metal or ceramic. The manufacturing process for plastic pulleys is typically less complex and less expensive, resulting in lower production costs. This cost advantage makes plastic pulleys a cost-effective choice for belt or cable systems, especially in applications where multiple pulleys are required. By offering a cost-effective solution, plastic pulleys contribute to effective belt or cable operation while keeping overall system costs under control.
In summary, plastic pulleys contribute to effective belt or cable operation through reduced friction, noise reduction, wear resistance, corrosion resistance, design flexibility, and cost-effectiveness. By providing smoother movement, minimizing wear, reducing noise and vibration, resisting corrosion, offering customized designs, and being cost-effective, plastic pulleys play a vital role in ensuring the optimal performance and longevity of belt or cable systems in various applications.
editor by CX
2024-05-09