Tag Archives: 40 roller chain

China high quality Carbon Steel/Stainless Steel Industrial Conveyor Roller Chain (08B 10B 12B 16B 40 50 60 80)

Product Description

Item Standard Transmission Roller Chains Model Series A, Series B, Heavy Duty
Row Simplex/Duplex/Triplex Application Machinery Parts
Surface Teatment Self-color/Sand-blasted/Shot-peening Brand OEM
Package Poly bag, then box, finally poly-wooden case Port Any sea port or airport in China
A Series 03C,04C-1,06C-1,085-1,08A-1,10A-1,12A-1,16A-1,20A-1,24A-1,28A-1,32A-1,36A-1,40A-1,48A-1. 15,25-1,35-1,41-1,40-1,50-1,60-1,80-1,100-1,120-1,140-1,160-1,180-1,200-1,240-1.
04C-2,06C-2,085-2,08A-2,10A-2,12A-2,16A-2,20A-2,24A-2,28A-2,32A-2,36A-2,40A-2,48A-2. 15,25-2,35-2,41-2,40-2,50-2,60-2,80-2,100-2,120-2,140-2,160-2,180-2,200-2,240-2.
04C-3,06C-3,085-3,08A-3,10A-3,12A-3,16A-3,20A-3,24A-3,28A-3,32A-3,36A-3,40A-3,48A-3. 15,25-3,35-3,41-3,40-3,50-3,60-3,80-3,100-3,120-3,140-3,160-3,180-3,200-3,240-3.
B Series 05B-1,06B-1,08B-1,10B-1,12B-1,16B-1,20B-1,24B-1,28B-1,32B-1,40B-1,48B-1,56B-1,64B-1,72B-1.
Heavy Duty Type 35H-1,40H-1,50H-1,60H-1,80H-1,100H-1,120H-1,140H-1,160H-1,180H-1,200H-1,240H-1.

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Standard or Nonstandard: Standard/Nonstandard
Application: Textile Machinery, Garment Machinery, Conveyer Equipment, Packaging Machinery, Motorcycle, Food Machinery, Marine, Mining Equipment, Agricultural Machinery, Car
Surface Treatment: Polishing
Structure: Roller Chain
Material: Carbon Steel/Stainless Steel
Type: Short Pitch Chain
US$ 5/Several links of standard chain
1 Several links of standard chain(Min.Order)

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How do you calculate the required horsepower for a conveyor chain drive?

The calculation of required horsepower for a conveyor chain drive involves considering various factors related to the conveyor system and the specific application. Here is a step-by-step process:

1. Determine the Total Resistance:

– Calculate the total resistance that the conveyor chain needs to overcome during operation. This includes the resistance due to the load being conveyed, frictional losses, elevation changes, and any other resistances in the system.

2. Convert the Resistance to Equivalent Inertia:

– Convert the total resistance to an equivalent inertia by multiplying it by the square of the chain speed.

3. Calculate the Total Inertia:

– Determine the total inertia of the system by considering the inertia of all the rotating components, such as the conveyor chain, sprockets, and any other driven elements.

4. Determine the Required Torque:

– Calculate the required torque by multiplying the total inertia by the desired acceleration or deceleration rate.

5. Convert Torque to Horsepower:

– Convert the required torque to horsepower by dividing it by the motor speed (in RPM) and multiplying by a conversion factor.

6. Consider Safety Factors and Efficiency:

– Apply safety factors to the calculated horsepower to account for variations, contingencies, and future growth.

– Consider the efficiency of the drive system, including the motor, gearbox, and other transmission components, to ensure accurate power transmission.

It’s important to note that the above calculation method provides an estimate of the required horsepower. Consulting with conveyor system manufacturers, engineers, or industry-specific guidelines is recommended for precise calculations and to ensure the selected conveyor chain drive meets the application requirements.


What are the different attachment options available for a conveyor chain?

Conveyor chains can be equipped with various types of attachments or accessories to accommodate specific material handling needs. Here are some common attachment options:

1. Cleats or Flights: Cleats or flights are raised sections attached to the conveyor chain to prevent materials from slipping or sliding off the chain. They are commonly used in incline or decline applications or when handling loose or bulk materials.

2. Side Plates or Side Guards: Side plates or side guards are installed along the edges of the conveyor chain to provide containment and prevent materials from spilling or falling off the sides. They are particularly useful when conveying small or irregularly shaped items.

3. Pusher Bars: Pusher bars are extensions mounted on the conveyor chain that can be pneumatically or mechanically actuated to push materials onto a different conveyor line or divert them to a specific location. They are often used for sorting or diverting applications.

4. Hold-Downs or Brackets: Hold-downs or brackets are devices attached to the conveyor chain to secure and stabilize the transported materials. They ensure that the materials remain in a fixed position during the conveying process, especially when encountering vibrations or changes in speed.

5. Guide Rails: Guide rails are installed alongside the conveyor chain to provide guidance and alignment for the materials being conveyed. They help maintain the desired path and prevent lateral movement or misalignment.

6. Magnetic Attachments: Magnetic attachments are used when handling ferrous materials. They allow the conveyor chain to attract and hold magnetic objects, ensuring effective transport and separation.

7. Tooling Plates: Tooling plates are platforms or mounting surfaces attached to the conveyor chain to accommodate specific equipment, such as fixtures, sensors, or robotic arms. They provide a convenient and customizable interface for integrating additional functionalities into the conveyor system.

8. Diverters or Transfer Units: Diverters or transfer units are specialized attachments that enable the seamless transfer of materials from one conveyor line to another, or between different processing stations. They ensure smooth transitions and precise material flow control.

These attachment options offer flexibility and versatility in conveyor chain applications, allowing customization based on the specific requirements of the material being transported or the production process. By selecting the appropriate attachments, conveyor chains can effectively handle a wide range of materials and optimize material flow within a conveyor system.


How do you optimize the efficiency of a conveyor chain system?

To optimize the efficiency of a conveyor chain system, several factors should be considered and implemented:

1. System Design: Ensure that the conveyor system is properly designed to minimize energy losses, reduce friction, and optimize material flow. Consider factors such as conveyor length, incline/decline angles, and the number and placement of drive units to achieve efficient operation.

2. Chain Selection: Select the appropriate conveyor chain based on the specific application requirements, such as load capacity, speed, and environmental conditions. Consider factors like chain material, pitch, and strength to ensure optimal performance and longevity.

3. Lubrication: Proper lubrication of the conveyor chain is essential for reducing friction, wear, and power consumption. Choose the right lubricant for the application and regularly maintain the lubrication levels to ensure smooth chain operation.

4. Tensioning and Alignment: Regularly inspect and adjust the tension and alignment of the conveyor chain to prevent excessive slack or tightness. Proper tensioning and alignment help to minimize chain wear, reduce energy losses, and ensure consistent performance.

5. Preventive Maintenance: Implement a regular maintenance program to identify and address potential issues before they escalate. This includes cleaning the chain, inspecting sprockets and guides, replacing worn components, and checking for proper tension and alignment. A well-maintained system reduces downtime and extends the life of the chain.

6. System Monitoring: Utilize monitoring tools such as sensors, cameras, or automated systems to track the performance of the conveyor chain system. Monitoring can provide valuable data on chain tension, alignment, speed, and power consumption, allowing for timely adjustments and optimization.

7. Training and Operator Awareness: Train operators on best practices for operating and maintaining the conveyor chain system. Promote awareness of energy efficiency, proper handling, and safety protocols to ensure optimal system performance.

By considering these factors and implementing appropriate measures, the efficiency of a conveyor chain system can be optimized, leading to improved productivity, reduced energy consumption, and longer chain life.

China high quality Carbon Steel/Stainless Steel Industrial Conveyor Roller Chain (08B 10B 12B 16B 40 50 60 80)  China high quality Carbon Steel/Stainless Steel Industrial Conveyor Roller Chain (08B 10B 12B 16B 40 50 60 80)
editor by CX 2024-03-28