Product Description
Pulley Pulleys Customized Transmission Timing Belt Synchronous Pulley
1) Warranty: our timing pulley’s quality is very good and with ensurance within 1 year, when you receive the products and find quality problems, we promise you could return it back and free maintenance.
2) Drawings: please send you timing pulleys’ drawings to us to get the best quotation; If you have no drawings, then we could work out CAD drawings and the best quotation to you ASAP.
3) Sample: we accept 1 piece sample’s order, we could do samples until you’re satisfied.
4) Confidentiality agreetment: Strictly adherence to client confidentiality agreetment for timing pulleys.
Product Description |
Product Name |
Timing Belt Pulley | |
Teeth profile | Trapezoidal toothed | MXL, XXL, XL, L, H, XH, XXH |
T-toothed | T2.5, T5, T10, T20 | |
Arc toothed | HTD3M, HTD5M, HTD8M, HTD14M, HTD20M, Gt2, Gt3, Gt5 | |
S-toothed | S2M, S3M, S4.5M, S5M, S8M, S14M | |
Parabolic-toothed | P2M, P3M, P5M, P8M, P14M | |
Y-toothed | G2M, G3M, G5M, Y8M | |
Teeth Quantity | 10-150 teeth or customized | |
Inner Bore | 2-200mm H7 precision or customized | |
Belt width | 4mm, 6mm, 9mm, 10mm, 12mm, 15mm, 20mm, 25mm, 30mm, 40mm, 50mm, 1/4”, 5/16”, 3/8”, 1/2”, 3/4”, 1”, 1.5”, 2”or customized | |
Accessories | We can provide the service of assembling setscrews, bearings, shafts or taper bush | |
Surface treatment | Anodize,Black Oxide,Phosphate and Galvanization | |
Drawing Format | Timing belt pulley cad drawing,timing belt pulley UG drawing,Timing belt Pulley Soliwork drawing,Timing Pulley PDF drawing |
What is timing pulley?
Timing pulleys are specialized pulleys that have either teeth or pockets around the outside diameter of the pulley body. Timing teeth engage holes in the metal belt, while timing pockets engage drive lugs on a belt’s inner circumference. These teeth or pockets are used only for timing, not for power transmission.
How timing pulleys work?
The synchronous wheel transmission is composed of an endless belt with equal-spaced teeth on the inner peripheral surface and a pulley with corresponding teeth. During operation, the toothed teeth mesh with the tooth grooves of the pulley to transmit motion and power, which is integrated with the belt. A new type of belt drive with the advantages of transmission, chain drive and gear transmission.
What is gt2 timing pulley?
2mm pitch GT2 Pulley. The GT2 or 2GT Tooth Profile timing pulley prevails in the 3d printing hobby cause the Round tooth profile brings high precision of non-backlash, were known as today’s Reprap Pulley.
What is a timing pulley flange?
Timing pulley flanges are used to maintain belt contact with a timing pulley in power transmission applications.Timing pulley flanges are manufactured to fit timing pulleys of the same pitch and size. The dimensions of a pitch, including the mating flange, are specified by the number of grooves.
What are synchronous belts used for?
The trapezoidal tooth profile first used on synchronous belts is recognized as standard. Belts with this configuration are commonly used in machine tools, textile machinery, home appliances, business equipment, and as camshaft drives in engines.
Note:Please confirm you need teeth profile, teeth quantity, belt width, bore diameter, quantity and type (please refer below drawings) to get our the most complete CAD drawings and the best quotation.
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Certification: | ISO |
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Pulley Sizes: | Type F |
Manufacturing Process: | Forging |
Material: | Iron |
Surface Treatment: | Baking Paint |
Application: | Chemical Industry, Grain Transport, Mining Transport, Power Plant |
Samples: |
US$ 50/Piece
1 Piece(Min.Order) | |
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Customization: |
Available
| Customized Request |
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How do synchronous pulleys contribute to the overall performance and longevity of mechanical systems?
Synchronous pulleys play a vital role in enhancing the overall performance and longevity of mechanical systems. Here’s a detailed explanation:
1. Precise Power Transmission: Synchronous pulleys, also known as timing pulleys, are designed to work in conjunction with synchronous belts. The teeth on the pulley and belt mesh together, providing positive engagement. This precise power transmission eliminates slip and ensures accurate motion control. By maintaining consistent speed and positioning, synchronous pulleys improve the overall performance of mechanical systems.
2. High Torque Transfer: Synchronous pulleys are capable of transmitting high levels of torque due to their toothed design. The teeth on the pulley and belt allow for a larger contact area compared to non-toothed pulley systems. This increased contact area enables synchronous pulleys to handle higher torque loads, making them suitable for heavy-duty applications. By efficiently transferring torque, synchronous pulleys enhance the power transmission capabilities of mechanical systems.
3. Reduced Slippage: Slip between the belt and pulley can lead to inefficiencies and inaccuracies in mechanical system operation. Synchronous pulleys, with their toothed profile, minimize slippage by providing positive engagement between the pulley and belt. This feature is particularly beneficial in applications that require precise motion control, such as CNC machines, robotics, or conveyor systems. By reducing slippage, synchronous pulleys improve the overall reliability and accuracy of mechanical systems.
4. Long Service Life: Synchronous pulleys and belts are designed for durability and long service life. The toothed profile of synchronous pulleys reduces wear and extends the lifespanof the pulley and belt compared to non-toothed alternatives. Additionally, the positive engagement between the pulley and belt eliminates the need for frequent tension adjustments, reducing wear and tear. The long service life of synchronous pulleys contributes to the longevity of mechanical systems and reduces maintenance requirements.
5. Minimal Maintenance: Synchronous pulleys require minimal maintenance compared to some other power transmission systems. The toothed design reduces the need for lubrication, eliminating the associated maintenance tasks such as oiling or greasing. Additionally, the positive engagement between the pulley and belt eliminates the need for frequent tension adjustments. The reduced maintenance requirements of synchronous pulleys enhance the overall longevity and reliability of mechanical systems.
6. Enhanced Efficiency: By providing precise power transmission, reducing slippage, and minimizing maintenance requirements, synchronous pulleys contribute to improved efficiency in mechanical systems. The accurate motion control and reduced energy losses result in higher operational efficiency and optimized performance.
Overall, synchronous pulleys contribute to the overall performance and longevity of mechanical systems through their precise power transmission, high torque transfer, reduced slippage, long service life, minimal maintenance requirements, and enhanced efficiency. These benefits make synchronous pulleys a preferred choice in various industries where reliable and efficient mechanical systems are essential.
What role do synchronous pulleys play in maintaining constant speed and synchronization?
Synchronous pulleys play a crucial role in maintaining constant speed and synchronization in various mechanical systems. By working in conjunction with synchronous belts, these pulleys ensure that rotational motion is accurately transferred from the driving component to the driven component while maintaining precise timing. Here’s an in-depth look at the role synchronous pulleys play in maintaining constant speed and synchronization:
1. Timing and Synchronization:
Synchronous pulleys are specifically designed with teeth or grooves that interlock with the teeth on the synchronous belt. This toothed engagement creates a positive drive system, ensuring precise timing and synchronization between the pulleys and the belt. The teeth on the pulleys fit into the corresponding gaps on the belt, establishing a reliable connection that prevents slippage and maintains accurate motion control. This synchronized operation is essential for applications where multiple components need to move in perfect coordination, such as in robotics, printing presses, or automated assembly lines.
2. Constant Speed Ratio:
Synchronous pulleys and belts work together to maintain a constant speed ratio between the driving and driven components. The teeth on the pulleys and the corresponding teeth on the belt ensure a fixed number of teeth engaged at any given time. This fixed engagement ratio determines the speed ratio between the pulleys, resulting in a consistent rotational speed for the driven component relative to the driving component. This constant speed ratio is essential in applications where precise speed control is required, such as in conveyors, machine tools, or packaging equipment.
3. Elimination of Slippage:
One of the key advantages of using synchronous pulleys is the elimination of slippage. The toothed engagement between the pulleys and the belt provides a positive drive system, preventing any relative motion or slipping between the components. This eliminates the potential for speed variations or loss of synchronization that can occur with other drive systems, such as friction-based belts or pulleys. The absence of slippage ensures that the driven component maintains a constant speed and remains synchronized with the driving component, contributing to reliable and accurate operation.
4. Backlash Reduction:
Synchronous pulleys help reduce backlash, which is the play or clearance between mating components. Backlash can introduce inaccuracies and delays in motion control systems, leading to diminished speed control and synchronization. The toothed design of synchronous pulleys minimizes backlash by providing a positive engagement between the pulleys and the belt. This positive engagement ensures that there is minimal or no play between the teeth, resulting in precise and immediate transfer of motion without any lag or delay. By reducing backlash, synchronous pulleys contribute to maintaining constant speed and synchronization in the system.
5. High Torque Transmission:
Synchronous pulleys are capable of transmitting high torque loads between the driving and driven components. The toothed engagement, along with the increased surface area of contact between the pulleys and the belt, enables efficient power transmission even under heavy loads. This high torque transmission capability ensures that the system can maintain constant speed and synchronization even when subjected to significant forces or torque fluctuations. It is particularly important in applications that require reliable and precise motion control, such as in industrial machinery or automotive systems.
6. Maintenance of Speed and Timing Accuracy:
By providing a positive drive system with precise timing and synchronization, synchronous pulleys help maintain speed and timing accuracy over extended periods of operation. The toothed engagement between the pulleys and the belt ensures that the system remains in sync and operates at the desired speed without significant deviations. This accuracy is maintained even under varying loads, environmental conditions, or changes in operating parameters. The consistent speed and timing accuracy provided by synchronous pulleys contribute to the overall efficiency, reliability, and performance of the mechanical system.
In summary, synchronous pulleys play a vital role in maintaining constant speed and synchronization in mechanical systems. They ensure precise timing and synchronization between the driving and driven components, eliminate slippage, reduce backlash, enable high torque transmission, and help maintain speed and timing accuracy. By providing a reliable and efficient power transmission solution, synchronous pulleys contribute to the smooth and accurate operation of various applications, ranging from robotics and automation to industrial machinery and automotive systems.
Can you explain the key components and design features of a synchronous pulley?
A synchronous pulley, also known as a timing pulley, consists of several key components and design features that enable its precise motion control and synchronization capabilities. Understanding these components and features is essential for comprehending the functionality and applications of synchronous pulleys. Here’s a detailed explanation of the key components and design features of a synchronous pulley:
1. Pulley Body:
The pulley body is the main component of a synchronous pulley. It is typically a cylindrical or disc-shaped structure with a central bore through which a shaft or axle passes. The pulley body provides the structural integrity and support for the pulley assembly.
2. Teeth or Grooves:
The teeth or grooves on the circumference of a synchronous pulley are the defining feature that sets it apart from other pulley types. These teeth are designed to precisely engage with the corresponding teeth on the synchronous belt. The teeth can have various profiles, such as trapezoidal, curvilinear, or modified curvilinear, depending on the specific belt design.
3. Tooth Profile:
The tooth profile refers to the shape and geometry of the teeth on the synchronous pulley. It is carefully designed to match the tooth profile of the synchronous belt, ensuring a positive engagement between the pulley and the belt. The tooth profile plays a crucial role in maintaining synchronization and preventing slippage between the pulley and the belt during operation.
4. Tooth Pitch:
The tooth pitch refers to the distance between adjacent teeth on the synchronous pulley. It is an important design parameter that determines the pitch diameter and the pitch length of the synchronous belt. The tooth pitch must match the corresponding pitch of the synchronous belt to ensure proper engagement and synchronization between the pulley and the belt.
5. Pitch Diameter:
The pitch diameter is the effective diameter of the synchronous pulley, calculated based on the tooth pitch and the number of teeth on the pulley. It represents the average diameter at which the synchronous belt engages the pulley. The pitch diameter affects the speed ratio and torque transmission characteristics of the pulley system.
6. Number of Teeth:
The number of teeth on a synchronous pulley determines its size and the speed ratio in relation to other pulleys or components in the system. The number of teeth is carefully selected to achieve the desired motion control and synchronization requirements. Pulleys with more teeth provide finer motion control but may require larger pulley diameters.
7. Material Selection:
Synchronous pulleys are commonly made from materials such as steel, aluminum, or plastic. The choice of material depends on factors such as load capacity, operating conditions, and cost considerations. Steel pulleys offer high strength and durability, making them suitable for heavy-duty applications. Aluminum pulleys are lightweight and corrosion-resistant, while plastic pulleys are often used in low-load or non-metallic environments.
8. Flanges and Hubs:
Synchronous pulleys may feature flanges or hubs on one or both sides of the pulley body. Flanges are raised edges that help keep the synchronous belt aligned and prevent it from sliding off the pulley during operation. Hubs are extended sections that allow for secure attachment to a shaft or axle, ensuring the pulley remains fixed in its position.
9. Surface Finish:
The surface finish of a synchronous pulley is typically smooth and free from burrs or rough edges. A smooth surface finish reduces friction and wear between the pulley and the synchronous belt, promoting efficient power transmission and prolonging the lifespan of the system.
10. Keyways and Set Screws:
In some synchronous pulley designs, keyways and set screws are incorporated to provide additional securement and alignment. Keyways are slots or grooves machined into the pulley bore that match with corresponding key or spline on the shaft, preventing rotational slippage. Set screws are threaded fasteners that can be tightened against the shaft to further secure the pulley in place.
In summary, the key components and design features of a synchronous pulley include the pulley body, teeth or grooves, tooth profile, tooth pitch, pitch diameter, number of teeth, material selection, flanges and hubs, surface finish, and optional keyways and set screws. These components and features work together to enable precise motion control, synchronization, and power transmission in mechanical systems that utilize synchronous pulleys.
Can you explain the key components and design features of a synchronous pulley?
A synchronous pulley, also known as a timing pulley, consists of several key components and design features that enable its precise motion control and synchronization capabilities. Understanding these components and features is essential for comprehending the functionality and applications of synchronous pulleys. Here’s a detailed explanation of the key components and design features of a synchronous pulley:
1. Pulley Body:
The pulley body is the main component of a synchronous pulley. It is typically a cylindrical or disc-shaped structure with a central bore through which a shaft or axle passes. The pulley body provides the structural integrity and support for the pulley assembly.
2. Teeth or Grooves:
The teeth or grooves on the circumference of a synchronous pulley are the defining feature that sets it apart from other pulley types. These teeth are designed to precisely engage with the corresponding teeth on the synchronous belt. The teeth can have various profiles, such as trapezoidal, curvilinear, or modified curvilinear, depending on the specific belt design.
3. Tooth Profile:
The tooth profile refers to the shape and geometry of the teeth on the synchronous pulley. It is carefully designed to match the tooth profile of the synchronous belt, ensuring a positive engagement between the pulley and the belt. The tooth profile plays a crucial role in maintaining synchronization and preventing slippage between the pulley and the belt during operation.
4. Tooth Pitch:
The tooth pitch refers to the distance between adjacent teeth on the synchronous pulley. It is an important design parameter that determines the pitch diameter and the pitch length of the synchronous belt. The tooth pitch must match the corresponding pitch of the synchronous belt to ensure proper engagement and synchronization between the pulley and the belt.
5. Pitch Diameter:
The pitch diameter is the effective diameter of the synchronous pulley, calculated based on the tooth pitch and the number of teeth on the pulley. It represents the average diameter at which the synchronous belt engages the pulley. The pitch diameter affects the speed ratio and torque transmission characteristics of the pulley system.
6. Number of Teeth:
The number of teeth on a synchronous pulley determines its size and the speed ratio in relation to other pulleys or components in the system. The number of teeth is carefully selected to achieve the desired motion control and synchronization requirements. Pulleys with more teeth provide finer motion control but may require larger pulley diameters.
7. Material Selection:
Synchronous pulleys are commonly made from materials such as steel, aluminum, or plastic. The choice of material depends on factors such as load capacity, operating conditions, and cost considerations. Steel pulleys offer high strength and durability, making them suitable for heavy-duty applications. Aluminum pulleys are lightweight and corrosion-resistant, while plastic pulleys are often used in low-load or non-metallic environments.
8. Flanges and Hubs:
Synchronous pulleys may feature flanges or hubs on one or both sides of the pulley body. Flanges are raised edges that help keep the synchronous belt aligned and prevent it from sliding off the pulley during operation. Hubs are extended sections that allow for secure attachment to a shaft or axle, ensuring the pulley remains fixed in its position.
9. Surface Finish:
The surface finish of a synchronous pulley is typically smooth and free from burrs or rough edges. A smooth surface finish reduces friction and wear between the pulley and the synchronous belt, promoting efficient power transmission and prolonging the lifespan of the system.
10. Keyways and Set Screws:
In some synchronous pulley designs, keyways and set screws are incorporated to provide additional securement and alignment. Keyways are slots or grooves machined into the pulley bore that match with corresponding key or spline on the shaft, preventing rotational slippage. Set screws are threaded fasteners that can be tightened against the shaft to further secure the pulley in place.
In summary, the key components and design features of a synchronous pulley include the pulley body, teeth or grooves, tooth profile, tooth pitch, pitch diameter, number of teeth, material selection, flanges and hubs, surface finish, and optional keyways and set screws. These components and features work together to enable precise motion control, synchronization, and power transmission in mechanical systems that utilize synchronous pulleys.
editor by CX
2024-03-30