China high quality M Series Conveyor Chains for Machine

Product Description

1) A series chains:
A) Simplex: 25-1 ~ 240-1
B) Duplex: 25-2 ~ 240-2
C) Triplex: 35-3 ~ 240-3
D) Quadruplex: 40-4 ~ 240-4
E) Quintuple: 40-5 ~ 240-5
F) Sextuple: 40-6 ~ 240-6
G) Octuple: 40-8 ~ 240-8
2) B series chains:
A) Simplex: 04B-1 ~ 48B-1
B) Duplex: 04B-2 ~ 48B-2
C) Triplex: 06B-3 ~ 48B-3
D) Quadruplex: 08B-4 ~ 48B-4
E) Quintuple: 08B-5 ~ 48B-5
F) Sextuple: 08B-6 ~ 48B-6
G) Octuple: 08B-8 ~ 48B-8
3) Colors available: Natural, yellow, blue, black
4) Materials: Alloy, Carbon steel, stainless steel
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Usage: Transmission Chain
Material: Alloy
Surface Treatment: Polishing
Feature: Heat Resistant
Chain Size: 1/2"*11/128"
Structure: Roller Chain


Customized Request


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 benefits of using a modular conveyor chain system?

A modular conveyor chain system offers several benefits in terms of flexibility, efficiency, and ease of maintenance. Here are some key advantages:

1. Versatility: Modular conveyor chains are designed with interlocking modules that can be easily connected and disconnected. This allows for flexibility in configuring the conveyor system according to specific layout requirements, production needs, or space limitations. Modules can be added, removed, or repositioned to accommodate changing production processes or product variations.

2. Customizability: The modular design of the conveyor chain system enables customization to meet specific application requirements. Different types of modules are available, including straight sections, curves, inclines, declines, merges, and diverters. Accessories such as side guides, cleats, or product hold-downs can be easily integrated into the system.

3. Quick Installation and Modification: Modular conveyor chains are designed for easy installation and modification. With their snap-in or snap-on connections, modules can be rapidly assembled or disassembled, reducing downtime during system setup or reconfiguration. This feature also facilitates maintenance, repairs, or future expansions.

4. Enhanced Efficiency: The modularity of the conveyor chain system allows for efficient material handling and optimized workflow. The smooth transfer between modules minimizes product jams or misalignments, ensuring a continuous and consistent flow of materials. The ability to incorporate curves or inclines in the system enables efficient use of floor space and facilitates the movement of products through different elevations.

5. Easy Maintenance: Modular conveyor chain systems are designed for ease of maintenance. Individual modules can be easily accessed and replaced without disassembling the entire system. This reduces maintenance time and costs. Additionally, the open structure of the modules allows for easy cleaning, debris removal, and inspection.

6. Durability and Reliability: Modular conveyor chains are typically made from high-quality materials such as plastic or stainless steel, ensuring durability and long-lasting performance. They are resistant to wear, corrosion, and chemical damage, making them suitable for various industrial environments. The interlocking design provides stability and prevents chain slippage during operation.

7. Safety Features: Modular conveyor chain systems can incorporate safety features such as emergency stop buttons, safety guarding, or sensors for detecting blockages or excessive loads. These features help maintain a safe working environment for operators and protect the integrity of the products being transported.

Overall, a modular conveyor chain system offers versatility, customizability, efficiency, and ease of maintenance. It is a reliable solution for material handling in industries such as manufacturing, packaging, distribution, and logistics.


What are the noise levels associated with conveyor chains?

The noise levels associated with conveyor chains can vary depending on several factors:

1. Chain Type: Different types of conveyor chains produce varying noise levels. For example, roller chains tend to generate more noise compared to silent chains or plastic modular chains.

2. Speed: The speed at which the conveyor chain operates can influence the noise level. Higher speeds generally result in increased noise due to the impact and friction between the chain and other components.

3. Chain Condition: The condition of the conveyor chain plays a role in noise generation. Worn-out or improperly maintained chains can produce more noise due to increased friction and vibration.

4. Surrounding Environment: The noise levels can also be affected by the environment in which the conveyor system operates. Factors such as the presence of other machinery, acoustics of the facility, and noise insulation measures can impact the overall noise level.

5. Design and Components: The design of the conveyor system and the choice of components can influence noise levels. Factors such as the use of noise-reducing materials, proper alignment of components, and vibration dampening measures can help reduce noise.

It is important to note that excessive noise levels in the workplace can have adverse effects on the well-being of employees and may require noise control measures to comply with occupational health and safety regulations. Implementing noise reduction strategies like using noise-dampening materials, incorporating proper lubrication, maintaining chain tension, and applying vibration isolation techniques can help minimize the noise associated with conveyor chains.

China high quality M Series Conveyor Chains for Machine  China high quality M Series Conveyor Chains for Machine
editor by CX 2024-04-23

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