Product Description
Adjustable Pitch V-Belt Pulleys
Product Description
2AK double groove pulleys are manufactured for 2 banded A-series v-belts or 2 single A-series v-belts, as well as multiple 3L v-belts can also be used with these pulleys. 2AK double groove sheave pulleys are commonly known as double AK pulleys and range in diameter from 2.00″ to 18.25,” but custom ones are also available CHINAMFG request. Double AK series pulleys are typically used in medium to heavy-duty agricultural and industrial applications. Our double v-belt pulleys are manufactured using state-of-the-art techniques combined with premium high-performance and high-strength features like grade 35 cast iron instead of grade 25.
Product Parameters
2AK Series Pulley Size Chart
|
Size |
Outside Diameter |
Pitch Diameter (4L/A) |
Pitch Diameter (3L) |
Type |
Dimension (F) |
Dimension (L) |
Dimension (P) |
Dimension (C) |
Pulley Weight |
|---|---|---|---|---|---|---|---|---|---|
| 2AK20 | 2.00″ | 1.80″ | 1.46″ | 1 | 1-3/8″ | 1-21/32″ | 15/32″ | 3/16″ | 0.8 LBS |
| 2AK21 | 2.15″ | 1.90″ | 1.56″ | 1 | 1-3/8″ | 1-21/32″ | 15/32″ | 3/16″ | 0.9 LBS |
| 2AK22 | 2.25″ | 2.00″ | 1.66″ | 1 | 1-3/8″ | 1-21/32″ | 15/32″ | 3/16″ | 0.9 LBS |
| 2AK23 | 2.35″ | 2.10″ | 1.76″ | 1 | 1-3/8″ | 1-21/32″ | 15/32″ | 3/16″ | 1.1 LBS |
| 2AK25 | 2.55″ | 2.30″ | 1.96″ | 1 | 1-3/8″ | 1-21/32″ | 15/32″ | 3/16″ | 1.3 LBS |
| 2AK26 | 2.65″ | 2.40″ | 2.06″ | 1 | 1-3/8″ | 1-21/32″ | 15/32″ | 3/16″ | 1.4 LBS |
| 2AK27 | 2.75″ | 2.50″ | 2.16″ | 1 | 1-3/8″ | 1-21/32″ | 15/32″ | 3/16″ | 1.5 LBS |
| 2AK28 | 2.85″ | 2.60″ | 2.26″ | 1 | 1-3/8″ | 1-21/32″ | 15/32″ | 3/16″ | 1.8 LBS |
| 2AK30 | 3.05″ | 2.80″ | 2.46″ | 1 | 1-3/8″ | 1-21/32″ | 15/32″ | 3/16″ | 1.8 LBS |
| 2AK32 | 3.25″ | 3.00″ | 2.66″ | 1 | 1-3/8″ | 1-21/32″ | 15/32″ | 3/16″ | 2.1 LBS |
| 2AK34 | 3.45″ | 3.20″ | 2.86″ | 1 | 1-3/8″ | 1-21/32″ | 15/32″ | 3/16″ | 2.3 LBS |
| 2AK39 | 3.75″ | 3.50″ | 3.16″ | 2 | 1-3/8″ | 1-11/32″ | 15/32″ | 1/2″ | 2.6 LBS |
| 2AK41 | 3.95″ | 3.70″ | 3.36″ | 2 | 1-3/8″ | 1-11/32″ | 15/32″ | 1/2″ | 2.9 LBS |
| 2AK44 | 4.25″ | 4.00″ | 3.66″ | 2 | 1-3/8″ | 1-11/32″ | 15/32″ | 1/2″ | 3.0 LBS |
| 2AK46 | 4.45″ | 4.20″ | 3.86″ | 2 | 1-3/8″ | 1-11/32″ | 15/32″ | 1/2″ | 3.1 LBS |
| 2AK49 | 4.75″ | 4.50″ | 4.16″ | 2 | 1-3/8″ | 1-11/32″ | 15/32″ | 1/2″ | 3.6 LBS |
| 2AK51 | 4.95″ | 4.70″ | 4.36″ | 2 | 1-3/8″ | 1-11/32″ | 15/32″ | 1/2″ | 3.8 LBS |
| 2AK54 | 5.25″ | 5.00″ | 4.66″ | 2 | 1-3/8″ | 1-11/32″ | 15/32″ | 1/2″ | 3.3 LBS |
| 2AK56 | 5.45″ | 5.20″ | 4.86″ | 2 | 1-3/8″ | 1-11/32″ | 15/32″ | 1/2″ | 3.4 LBS |
| 2AK59 | 5.75 “ | 5.50″ | 5.16″ | 2 | 1-3/8″ | 1-11/32″ | 15/32″ | 1/2″ | 3.5 LBS |
| 2AK61 | 5.95″ | 5.70″ | 5.36″ | 3 | 1-3/8″ | 1-11/32″ | 15/32″ | 1/2″ | 3.6 LBS |
| 2AK64 | 6.25″ | 6.00″ | 5.66″ | 3 | 1-3/8″ | 1-19/32″ | 11/32″ | 1/8″ | 4.8 LBS |
| 2AK74 | 7.25″ | 7.00″ | 6.66″ | 3 | 1-3/8″ | 1-19/32″ | 11/32″ | 1/8″ | 5.6 LBS |
| 2AK84 | 8.25″ | 8.00″ | 7.66″ | 3 | 1-3/8″ | 1-19/32″ | 11/32″ | 1/8″ | 6.4 LBS |
| 2AK94 | 9.25″ | 9.00″ | 8.66″ | 3 | 1-3/8″ | 1-19/32″ | 11/32″ | 1/8″ | 7.3 LBS |
| 2AK104 | 10.25″ | 10.00″ | 9.66″ | 3 | 1-3/8″ | 1-19/32″ | 11/32″ | 1/8″ | 8.1 LBS |
| 2AK114 | 11.25″ | 11.00″ | 10.66″ | 3 | 1-3/8″ | 1-19/32″ | 11/32″ | 1/8″ | 9.0 LBS |
| 2AK124 | 12.25″ | 12.00″ | 11.66″ | 3 | 1-3/8″ | 1-19/32″ | 11/32″ | 1/8″ | 9.8 LBS |
| 2AK134 | 13.25″ | 13.00″ | 12.66″ | 3 | 1-3/8″ | 1-19/32″ | 11/32″ | 1/8″ | 12.3 LBS |
| 2AK144 | 14.25″ | 14.00″ | 13.66″ | 3 | 1-3/8″ | 1-19/32″ | 11/32″ | 1/8″ | 13.9 LBS |
| 2AK154 | 15.25″ | 15.00″ | 14.66″ | 3 | 1-3/8″ | 1-19/32″ | 11/32″ | 1/8″ | 14.3 LBS |
| 2AK184 | 18.25″ | 18.00″ | 17.66″ | 3 | 1-3/8″ | 1-19/32″ | 11/32″ | 1/8″ | 17.4 LBS |
Installation and Removal of Pulleys
Install
1. Check the pulley groove to make sure there are no scratches or sharp edges and all dimensions are up to standard;
2. Clean the surfaces of all parts, such as hub holes, taper sleeves, bolt holes, etc. Fit the cone sleeve into the pulley, aligning all the screw holes.
3. Apply oil to the screw (TB 1008-TB 3030) and thread (TB 3525-TB 5050) and screw them into the mounting holes, but do not tighten them yet.
4. Clean the surface of the drive shaft, push the pulley with the tapered sleeve installed to the predetermined position on the shaft, and check whether the V-belt pulley is aligned.
5. When using the keyway, it must be inserted into the hub first, and there must be a certain tolerance between the keyway and the hole hub.
6. Using a hexagonal wrench conforming to the DIN911 standard, alternately, gradually, and evenly tighten the bolts in each mounting hole until the torque shown in the table below is reached.
7. After a short period of operation (0.5 to 1 hour), check the tightening torque of the bolts and retighten them if necessary.
8. To prevent the intrusion of foreign matter, fill the hole’s connection hole with grease.
Disassemble
1. Loosen all the bolts, take out 1 or 2 of the bolts according to the number of disassembly holes, lubricate the bolt pattern and the tip of the bolt with oil, and insert the bolt into the disassembly hole.
2. Tighten the bolts alternately until the taper sleeve and pulley are loosened.
3. Remove the taper sleeve and pulley from the shaft.
Technological Processing
Company Profile
HZPT is a professional manufacturer of mechanical parts. Our main products are belt pulleys, sprockets, taper sleeves, coupling, and other transmission parts. Its products are mainly exported to Germany, Britain, France, and other European countries, with an annual export value of 18 million US dollars, accounting for more than 65% of the total output. The annual output value reached 200 million yuan.
Our products all adopt international, European, and American advanced industrial standards, use precise and good processing equipment, develop reasonable production technology, apply efficient and flexible management systems, and improve the quality management system to ensure that the product quality is good and the price is affordable.
Our factory adheres to the enterprise concept of “quality: the basis of enterprise survival, integrity: the basis of enterprise development, service: the source of enterprise development, low price: the instrument of enterprise development.” We are always looking CHINAMFG to the presence of customers at home and abroad, seeking CHINAMFG benefits and joint cause development.
Warehouse Stock
The warehouse covers an area of 5000 square CHINAMFG and can provide all kinds of standard models A/B/C/Z, with complete quantity and large quantity in stock. Meanwhile, it accepts all sorts of non-standard customization for drawing production. The daily production capacity is 10 tons, and the delivery time is short.
Packaging & Shipping
Experienced Workers Packing Pulleys Carefully, safe wooden cases keep parts from being injured or damaged during sea or air shipment.
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| Certification: | CE, ISO |
|---|---|
| Pulley Sizes: | Type F |
| Manufacturing Process: | Forging |
| Material: | Carbon Steel |
| Surface Treatment: | Baking Paint |
| Application: | Chemical Industry, Grain Transport, Mining Transport, Power Plant |
| Samples: |
US$ 9999/Piece
1 Piece(Min.Order) | |
|---|
How does the configuration of a compound pulley affect its lifting capacity?
The configuration of a compound pulley has a direct impact on its lifting capacity. Here is a detailed explanation of how the configuration of a compound pulley affects its lifting capacity:
1. Number of Pulleys: The number of pulleys in a compound pulley system affects its lifting capacity. In a compound pulley system, the more pulleys that are used, the greater the mechanical advantage and lifting capacity. Each additional pulley increases the number of line segments supporting the load, distributing the weight and reducing the force required to lift the load. Therefore, a compound pulley system with more pulleys will have a higher lifting capacity compared to a system with fewer pulleys.
2. Arrangement of Pulleys: The arrangement of pulleys in a compound pulley system also impacts its lifting capacity. Compound pulleys can be configured in various arrangements, such as the “block and tackle” configuration or the “differential” configuration. These different arrangements determine how the pulleys are connected and how the load is distributed. The specific arrangement can affect the mechanical advantage and lifting capacity of the system. For example, a block and tackle configuration, where multiple movable pulleys are connected to a fixed pulley, can provide a higher mechanical advantage and lifting capacity compared to a simple system with a single movable pulley.
3. Ratio of Fixed to Movable Pulleys: The ratio of fixed to movable pulleys in a compound pulley system affects its lifting capacity. The presence of fixed pulleys in the system changes the direction of the force applied, contributing to the mechanical advantage. The ratio of fixed to movable pulleys determines the division of load and the amplification of force. As the number of movable pulleys increases relative to the fixed pulleys, the mechanical advantage and lifting capacity of the system also increase. Therefore, a compound pulley system with a higher ratio of movable to fixed pulleys will have a greater lifting capacity.
4. Efficiency and Friction: The efficiency of a compound pulley system and the amount of friction present can also impact its lifting capacity. Friction in the pulley system can reduce the effectiveness of the mechanical advantage and increase the force required to lift the load. Factors such as the quality of the pulleys, the condition of the ropes or cables, and proper lubrication can influence the efficiency and minimize friction. A well-maintained and properly lubricated compound pulley system will have a higher lifting capacity compared to a system with high friction and reduced efficiency.
5. Load Distribution: The way the load is distributed across the line segments in a compound pulley system affects its lifting capacity. The load should be evenly distributed among the line segments to ensure that each segment is sharing the weight. If the load is unevenly distributed or concentrated on one line segment, it can exceed the weight capacity of that particular segment, potentially leading to failure of the pulley system. Proper load distribution and balance are important for maximizing the lifting capacity and ensuring the safe operation of the compound pulley system.
In summary, the lifting capacity of a compound pulley is influenced by the number of pulleys, the arrangement of pulleys, the ratio of fixed to movable pulleys, the efficiency and friction of the system, and the proper distribution of the load. Understanding and optimizing these factors are crucial for determining the lifting capacity of a compound pulley system and ensuring its safe and efficient operation.
How are compound pulleys used in the operation of cranes and elevators?
Compound pulleys play a crucial role in the operation of cranes and elevators, enabling them to lift and move heavy loads with ease and efficiency. The design and arrangement of compound pulleys provide mechanical advantage, allowing for the multiplication of force and the reduction of effort required to lift objects. Here is a detailed explanation of how compound pulleys are used in the operation of cranes and elevators:
Crane Operation:
In cranes, compound pulleys are commonly used in the lifting mechanism to handle heavy loads. The pulleys are arranged in a system of ropes or cables, with multiple sheaves connected in series or parallel. The ropes or cables pass through the sheaves, creating multiple lines of support. The combination of fixed and movable pulleys in the system increases the mechanical advantage, making it easier to lift heavy objects. When force is applied to the rope or cable, the compound pulleys distribute the load and reduce the amount of force required from the operator.
Elevator Operation:
In elevators, compound pulleys are utilized in the hoisting system to move the elevator car vertically. The pulleys are typically located at the top of the elevator shaft. The elevator car is suspended by ropes or cables that pass over the sheaves of the compound pulleys. The mechanical advantage provided by the pulley system allows the elevator motor to exert less force to lift the car. The compound pulleys effectively distribute the weight of the car, making it easier to move up and down. Additionally, the design of the pulley system allows the elevator car to be lifted and lowered smoothly and safely.
Both in cranes and elevators, compound pulleys offer the following advantages:
- Increased Lifting Capacity: The mechanical advantage provided by compound pulleys allows cranes and elevators to lift much heavier loads than what could be achieved with a single pulley system. The compound pulleys distribute the load over multiple lines of support, reducing the strain on individual ropes or cables and enabling the lifting of heavier objects.
- Efficiency: Compound pulleys increase the efficiency of cranes and elevators by reducing the amount of force required to lift or lower loads. The mechanical advantage achieved through the arrangement of pulleys allows operators to lift heavy objects with less effort, making the operation more efficient and less fatiguing.
- Precise Control: Compound pulley systems offer precise control over the movement of cranes and elevators. By adjusting the tension and arrangement of the ropes or cables, operators can control the speed and direction of the lifting or lowering process. This precise control allows for safe and accurate positioning of loads in various applications.
- Smooth Operation: The combination of fixed and movable pulleys in compound pulley systems helps ensure smooth and stable operation of cranes and elevators. The pulleys reduce the friction between the ropes or cables and the sheaves, minimizing jerky movements and providing a smooth lifting or lowering experience.
In summary, compound pulleys are essential components in the operation of cranes and elevators. Their mechanical advantage, increased lifting capacity, efficiency, precise control, and smooth operation make them ideal for handling heavy loads and facilitating vertical transportation in various industries and settings.
Can you explain the key components and design of a compound pulley?
A compound pulley consists of several key components that work together to provide mechanical advantage in lifting or moving heavy loads. Here is a detailed explanation of the key components and design of a compound pulley:
1. Pulleys: The pulleys are the central components of a compound pulley system. They can be made of various materials such as metal or plastic and are typically circular in shape. Pulleys may have a grooved rim or a flat surface to guide the rope or cable. In a compound pulley, there are usually multiple pulleys, including fixed pulleys and movable pulleys.
2. Rope or Cable: A continuous loop of rope, cable, or belt is threaded through the pulleys of a compound pulley system. The choice of rope or cable depends on the application and load requirements. These flexible elements transmit the force applied to the pulley system and distribute the load across the pulleys.
3. Fixed Pulleys: Fixed pulleys are attached to a support structure and do not move. They serve as anchor points for the rope or cable and provide stability to the compound pulley system. Fixed pulleys change the direction of the force applied to the system but do not contribute to the mechanical advantage.
4. Movable Pulleys: Movable pulleys are connected to the load and can move vertically along with it. The movement of the movable pulleys allows for the lifting or moving of the load. Movable pulleys are responsible for providing the mechanical advantage in a compound pulley system.
5. Load: The load refers to the object or weight being lifted or moved by the compound pulley system. The load is typically attached to the movable pulleys through hooks, attachments, or other mechanisms. The load can vary in size and weight depending on the application.
6. Force Input: The force input is the force applied to the free end of the rope or cable to lift or move the load. This force can be applied manually or through mechanical means such as a motor or engine. The force input is transmitted through the rope or cable and distributed across the pulleys.
7. Mechanical Advantage: The mechanical advantage of a compound pulley system is determined by the number of line segments supporting the load. Each additional line segment increases the mechanical advantage. The mechanical advantage reduces the amount of force required to lift or move the load, making it easier to perform the task.
The design of a compound pulley system can vary depending on the specific application and load requirements. Factors such as the weight of the load, available space, and desired mechanical advantage influence the design choices. The number and arrangement of pulleys, the type of rope or cable used, and the attachment mechanisms for the load are tailored to meet the specific needs of the system.
In conclusion, a compound pulley consists of key components such as pulleys, rope or cable, fixed and movable pulleys, the load, force input, and the mechanical advantage. These components work together in a specific design to provide the mechanical advantage needed for lifting or moving heavy loads in various applications.
editor by CX
2024-04-12