China high quality Rotary Table Zp49.5 Spiral Bevel Gear (OD1950mm) worm gear motor

Product Description

Product Description

 

Material : 42CrMo, 20CrMnMo, 20Cr2Ni4, 35CrMo, 20CrMnTi and Other high intensity alloy steel
Tooth Flank : Tooth flank carburization and nitrification, with rigidity of HRC58-62
Gear precision : Grade V
Precise measurement : Precise measurement and surface finishes are available
Material : High dense alloy or other materials is also available
Customization : Customer drawing and samples are welcome

 

Detailed Photos

 

Gear Features

Rotary Table Zp49.5 Spiral Bevel Gear features:

1) Max. OD2000mm
2) Max. Mould 36
3) Material: 42CrMo, 20CrMnMo, 20Cr2Ni4, 35CrMo, 20CrMnTi and other high intensity alloy steel
4) Tooth flank carburization and nitrification, with rigidity of HRC58-62
5) Gear precision: Grade VI
6)Precise measurement and surface finishes are available
7)High dense alloy or other materials is also available
8)custormer’s drawing and samples are welcome

It is used in automobile, oil drilling rig, and so on 
 

Company Profile

For 12 years, Mr. Zhou has stood for innovative products, a passion for technology, responsibility.

As a globally technology manufacture company, we put all of energy to promise quality and excellence. We’ve organized resources into new and established markets and developed gears, sheaves and so on.
Our results announcement is over USD 10, 000, 000 per fiscal year. Last but not least, we’ve doing hard work to perfect ourselves, tapping business opportunities.

Note: For special order, please write and provide drawing sample!

Customer Visiting

 

Packaging & Shipping

 

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Application: Motor, Machinery, Marine
Hardness: Soft Tooth Surface
Gear Position: External Gear
Manufacturing Method: Cut Gear
Toothed Portion Shape: Bevel Wheel
Material: Stainless Steel
Customization:
Available

|

Customized Request

crown gear

What are the safety considerations when working with crown gear systems?

Working with crown gear systems requires attention to safety to prevent accidents and ensure the well-being of individuals involved. Here are some important safety considerations when working with crown gear systems:

  • Training and Knowledge:

Ensure that individuals working with crown gear systems have received proper training and possess the necessary knowledge and expertise. They should understand the gear system’s operation, potential hazards, safety protocols, and emergency procedures. Adequate training helps minimize the risk of accidents and promotes safe working practices.

  • Protective Equipment:

Provide appropriate personal protective equipment (PPE) to individuals working with crown gear systems. This may include safety glasses, gloves, ear protection, and any other necessary equipment based on the specific hazards associated with the system. PPE helps safeguard against potential injuries from flying debris, noise, or contact with moving parts.

  • Machine Guarding:

Ensure that crown gear systems are properly guarded to prevent accidental contact with the moving gears. Install protective barriers, covers, or interlocking mechanisms to restrict access to hazardous areas. Machine guarding helps prevent injuries and keeps personnel safe from potential pinch points, entanglement, or crushing hazards.

  • Lockout/Tagout Procedures:

Follow lockout/tagout procedures when performing maintenance or repair tasks on crown gear systems. Lockout/tagout involves isolating the equipment from its power source and affixing lockout/tagout devices to prevent unintended energization. This procedure protects workers from the unexpected startup of machinery and ensures their safety during maintenance activities.

  • Routine Inspections:

Regularly inspect the crown gear system for any signs of wear, damage, or abnormalities. Look for loose or missing bolts, excessive vibrations, unusual noise, or leaks. Detecting and addressing potential issues through routine inspections helps prevent accidents and maintain the safe functioning of the gear system.

  • Proper Lifting and Handling:

When moving or lifting crown gear components, adhere to proper lifting techniques and use appropriate lifting equipment. Crown gears can be heavy, and incorrect lifting or handling can lead to strains, sprains, or dropped objects. Follow ergonomic guidelines and use mechanical aids such as cranes, hoists, or lifting slings to ensure safe lifting practices.

  • Emergency Preparedness:

Establish emergency preparedness protocols specific to crown gear systems. This includes clear communication channels, knowledge of emergency shutdown procedures, and access to first aid supplies. Train personnel on how to respond to emergencies, such as gear system malfunctions, injuries, or unexpected incidents.

Promoting a safety-conscious culture, providing ongoing safety training, and ensuring the implementation of appropriate safety measures are critical when working with crown gear systems. It is important to adhere to local safety regulations, follow manufacturer guidelines, and prioritize the well-being of individuals involved in operating, maintaining, or repairing crown gear systems.

crown gear

What is the significance of crown gear alignment in mechanical systems?

The alignment of crown gears in mechanical systems holds great significance for their proper functioning and overall system performance. Let’s explore the significance of crown gear alignment:

  • Efficient Power Transmission:

Proper alignment of crown gears ensures efficient power transmission within a mechanical system. When crown gears are correctly aligned, the teeth of the gears mesh smoothly and accurately, minimizing energy losses due to friction and misalignment. This efficient power transmission helps maximize the system’s overall efficiency and performance.

  • Reduced Wear and Noise:

Correct alignment of crown gears helps reduce wear and noise in a mechanical system. When gears are properly aligned, the load is distributed evenly across the gear teeth, minimizing localized wear and preventing premature tooth failure. Additionally, proper alignment reduces gear misalignment-induced noise, ensuring quieter operation in the system.

  • Prevention of Overloading and Failures:

Alignment plays a crucial role in preventing overloading and failures of crown gears. Misalignment can result in uneven distribution of loads, causing excessive stresses on certain teeth and leading to premature gear failure. Proper alignment helps distribute the load evenly, ensuring that each tooth shares the load proportionally, reducing the risk of overloading and gear failures.

  • Optimal Gear Meshing:

Correct alignment is essential for achieving optimal gear meshing between crown gears and other gears in the system. Proper meshing ensures that the teeth engage smoothly and accurately, providing efficient power transmission without slippage or excessive backlash. Optimal gear meshing contributes to the overall performance, reliability, and durability of the mechanical system.

  • Longer Gear Lifespan:

Proper alignment significantly extends the lifespan of crown gears. Misalignment increases wear, fatigue, and stress concentrations, leading to premature gear failure. By maintaining proper alignment, the gears experience reduced wear and lower stress levels, enhancing their longevity and minimizing the need for frequent replacements or repairs.

  • Improved System Stability:

Alignment of crown gears promotes system stability and smooth operation. Misaligned gears can introduce vibrations, imbalances, and uneven loading, affecting the overall stability and performance of the mechanical system. Proper alignment minimizes these issues, ensuring smooth and stable operation, reducing the risk of system malfunctions or disruptions.

In summary, the significance of crown gear alignment in mechanical systems lies in efficient power transmission, reduced wear and noise, prevention of overloading and failures, optimal gear meshing, longer gear lifespan, and improved system stability. Proper alignment of crown gears ensures optimal performance, reliability, and longevity of the gears and the overall mechanical system.

crown gear

How do crown gears contribute to transmitting motion and power?

Crown gears play a significant role in the transmission of motion and power in mechanical systems. Let’s explore how crown gears contribute to these essential functions:

  • Directional Change:

One of the primary contributions of crown gears is facilitating a change in motion direction. By meshing a crown gear with other gears, the rotational motion can be redirected by 90 degrees. This directional change capability enables the transmission of motion in different directions within a mechanical system, allowing for the desired movement and positioning of components.

  • Meshing and Torque Transfer:

Crown gears engage and mesh with other gears to transmit torque and rotational motion. The teeth of a crown gear interlock with the teeth of the meshing gear, creating a mechanical connection. As power is applied to the crown gear, the interlocking teeth transfer torque to the meshing gear, enabling the transmission of rotational motion and power from one gear to another.

  • Force Distribution:

Crown gears contribute to the distribution of forces in a gear system. When a crown gear meshes with other gears, the load and forces acting on the gear teeth are distributed across a larger contact area. This distribution helps reduce stress and wear on individual gear teeth, ensuring smoother operation, improved durability, and efficient power transmission within the system.

  • Compatibility with Different Gears:

Crown gears are designed to be compatible with various gear types, including gears with parallel axes or bevel gears with intersecting axes. This compatibility allows crown gears to mesh smoothly with different gear configurations, enabling the transmission of motion and power between different components of a machinery setup. Crown gears serve as a critical link in transferring power and rotational motion within complex gear systems.

  • Precision and Control:

Due to their unique design and meshing characteristics, crown gears offer precise control over motion and power transmission. The interlocking teeth of crown gears ensure a firm and accurate engagement, minimizing backlash and providing reliable and controlled movement. This precision is particularly crucial in applications that require accurate positioning, such as robotics, automation, and manufacturing processes.

In summary, crown gears contribute to the transmission of motion and power by enabling directional changes, meshing and torque transfer, distributing forces, ensuring compatibility with different gear types, and providing precision and control. These contributions make crown gears vital components in various mechanical systems, allowing for efficient power transmission, accurate motion control, and reliable operation.

China high quality Rotary Table Zp49.5 Spiral Bevel Gear (OD1950mm) worm gear motorChina high quality Rotary Table Zp49.5 Spiral Bevel Gear (OD1950mm) worm gear motor
editor by CX 2024-01-10

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