China wholesaler API Oil Drilling Rotary Table Gear/Gear Ring (OD2000) for Gear Kit Commercial Vehicles Parts bevel spiral gear

Product Description

 

Product Description

Oil drilling rotary table 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

 

 

Detailed Photos

 

Production Profile

 

About Us

About Us
As a company of industries and trading integration with ISO 9001-2008 Certificate, HangZhou CHINAMFG Metallurgy Equipment Manufacturing Co., Ltd. Has been in manufacturing material handling equipment parts for many years, with professional experience.

Our Service:
If you are interested in any of our products, please contact me freely! Warmly Welcomed your visit to our factory in China, OEM service will be ok.

 

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Certifications

 

Packaging & Shipping

 

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Certification: ISO 9001:2008
Spiral Bevel Gear: Use for Oil Drilling Rig
Crown Wheel and Pinion: Use for Heavy Truck
Bevel Gear: Gearbox
Transport Package: Special Wooden Boxes
Specification: OD2000
Customization:
Available

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Customized Request

crown gear

How does a crown gear contribute to the overall efficiency of a system?

A crown gear plays a significant role in enhancing the overall efficiency of a system. Let’s explore how a crown gear contributes to system efficiency:

  • Power Transmission:

Crown gears efficiently transmit power between two intersecting shafts. By meshing with other gears in the system, the crown gear transfers rotational energy from the input shaft to the output shaft. The precise design and tooth profile of the crown gear ensure minimal energy losses during power transmission, resulting in high overall system efficiency.

  • Reduced Friction and Wear:

Crown gears are designed to minimize friction and wear. The tooth engagement between crown gears and other meshing gears is smooth due to their curved tooth profile. This reduces frictional losses and wear on the gear teeth, resulting in improved efficiency and longevity of the gear system. Additionally, crown gears distribute the load evenly across the gear teeth, minimizing localized stress concentrations and reducing the risk of premature failure.

  • Backlash Reduction:

Crown gears are effective in reducing or eliminating backlash, which is the slight clearance between the teeth of meshing gears. Backlash can cause inefficient power transmission and affect the accuracy of motion in a system. The tooth orientation and engagement properties of crown gears help minimize backlash, ensuring a tighter meshing with other gears. This reduces energy losses and improves the overall efficiency and precision of the system.

  • High Gear Ratios:

Crown gears can achieve high gear ratios due to their larger diameter and the increased number of teeth engaged with other gears. High gear ratios allow for precise speed reduction or torque multiplication, enabling the system to operate more efficiently. By optimizing the gear ratio, a crown gear contributes to the efficient conversion of input power into the desired output performance.

  • Versatility:

Crown gears offer versatility in different applications and system configurations. Their bidirectional capability allows them to handle variations in rotational direction without compromising efficiency. The ability to accommodate changes in rotational direction makes crown gears adaptable to a wide range of systems, contributing to overall system efficiency.

In summary, a crown gear enhances the overall efficiency of a system through efficient power transmission, reduced friction and wear, backlash reduction, high gear ratios, and versatility. By minimizing energy losses, optimizing gear engagement, and ensuring reliable power transfer, a crown gear plays a vital role in maximizing the efficiency and performance of the system it is employed in.

crown gear

How do crown gears contribute to power distribution in gear arrangements?

Crown gears play a significant role in power distribution within gear arrangements, ensuring efficient and balanced transmission of power. Let’s explore how crown gears contribute to power distribution:

  • Load Sharing:

Crown gears are often used in gear arrangements where multiple gears are present. In such arrangements, crown gears help distribute the power load among the gears. By sharing the load, each gear experiences a reduced load compared to if it were to carry the entire power load alone. This load sharing capability helps prevent overloading and excessive stress on individual gears, promoting more reliable and efficient power distribution.

  • Equal Torque Transfer:

Crown gears facilitate equal torque transfer among interconnected gears. When a crown gear meshes with another gear, the torque applied to the crown gear is transmitted to the meshing gear. Due to their tooth orientation and large contact area, crown gears enable a more uniform distribution of torque, ensuring that the torque is evenly transferred from one gear to another. This balanced torque distribution helps maintain smooth operation and prevent gear failures due to torque overload.

  • Elimination of Backlash:

Crown gears help reduce or eliminate backlash in gear arrangements. Backlash refers to the slight clearance or play between the teeth of meshing gears. It can cause inaccuracies, vibrations, and noise in the system. Crown gears, with their perpendicular tooth orientation and optimized meshing characteristics, minimize backlash and ensure a tight and precise engagement between gears. This tight meshing eliminates power losses associated with backlash and contributes to more efficient power distribution.

  • Better Load Distribution:

Due to their curved tooth profile and larger contact area, crown gears provide improved load distribution across the gear teeth. When power is transmitted through crown gears, the load is distributed over a greater number of teeth compared to other gear types. This even load distribution results in reduced stress concentrations on individual teeth, enhancing the gear’s load-carrying capacity and promoting uniform power distribution throughout the gear arrangement.

  • Enhanced System Efficiency:

By facilitating load sharing, equal torque transfer, backlash elimination, and improved load distribution, crown gears contribute to enhanced system efficiency. The balanced power distribution achieved through crown gears helps minimize power losses, reduce energy wastage, and optimize the overall efficiency of the gear arrangement. This improved efficiency translates into better performance, reduced energy consumption, and increased productivity in various mechanical systems.

In summary, crown gears contribute to power distribution in gear arrangements through load sharing, equal torque transfer, elimination of backlash, better load distribution, and enhanced system efficiency. These characteristics make crown gears an integral part of gear systems, ensuring reliable and efficient power transmission in a wide range of applications.

crown gear

Can you explain the unique design and shape of crown gears?

The design and shape of crown gears are indeed unique and distinguishable from other types of gears. Let’s delve into the characteristics that define the unique design and shape of crown gears:

  • Tooth Orientation:

One of the key features of crown gears is their tooth orientation. Unlike other gears such as spur gears or bevel gears, where the teeth are parallel or at an angle to the gear’s axis, crown gears have teeth perpendicular to the gear’s face. This perpendicular tooth orientation allows for specific functionalities in mechanical systems.

  • Teeth Shape:

The teeth of a crown gear are shaped like segments of a cylinder. They have a curved profile that matches the circumference of the gear. This unique tooth shape ensures smooth engagement and meshing with other gears, facilitating reliable torque transmission and rotational motion transfer.

  • Gear Face:

Crown gears have a flat gear face where the teeth are positioned. The gear face is perpendicular to the gear’s axis and provides a stable surface for the meshing of other gears. The flat gear face allows for effective contact and force distribution when the crown gear engages with other gears in a mechanical system.

  • Meshing with Other Gears:

The design of crown gears enables them to mesh with other gears in a unique manner. Crown gears can mesh with gears that have parallel axes or bevel gears with intersecting axes. The perpendicular tooth orientation and the curved tooth shape facilitate smooth and efficient meshing, allowing the transfer of torque and rotational motion between different gear types.

  • Application-Specific Modifications:

While the basic design and shape of crown gears are consistent, they can be modified or customized for specific applications. This may include alterations in the tooth profile, tooth size, or gear dimensions to suit the requirements of the machinery or system in which they are used.

In summary, crown gears possess a unique design and shape characterized by perpendicular tooth orientation, curved tooth profile, a flat gear face, and compatibility with different gear types. These features contribute to the effective engagement, smooth meshing, and reliable transmission of torque and motion in mechanical systems.

China wholesaler API Oil Drilling Rotary Table Gear/Gear Ring (OD2000) for Gear Kit Commercial Vehicles Parts bevel spiral gearChina wholesaler API Oil Drilling Rotary Table Gear/Gear Ring (OD2000) for Gear Kit Commercial Vehicles Parts bevel spiral gear
editor by CX 2024-01-11