Dia 270mm Module3.5 Teeth 62 Internal Gear for Big Machine Reducer air compressor portable
Our Dia 270mm Module3.5 Teeth 62 Internal Gear is a high-quality gear shaft suitable for big machine reducers, air compressors, and portable machinery. Made from durable materials such as 20CrMnTi, 20CrMnMo, 42CrMo, 45#steel, 40Cr, and 20CrNi2MoA, this gear shaft is designed to withstand wear and tear. It’s also heat treated using various methods such as carburizing and quenching, tempering, nitriding, carbonitriding, and induction hardening to achieve a hardness range of 58-62HRC.
Our gear model is customizable according to customer’s sample or drawing, with CNC machines used for precision processing. The product adheres to GB, DIN, JIS, and AGMA quality standards, with an accuracy class of 5-8 class. Shipping is available via sea, air, or express.
Why Choose Our Gear Shaft?
- Durable material and heat treatment process ensure longevity and wear resistance.
- Precision processing using CNC machines guarantees accuracy.
- Customizable based on customer’s sample or drawing to meet specific needs.
- Adheres to international quality standards for reliable performance.
- Multiple shipping options available for convenience.
Other Industrial Products We Offer
At our company, we specialize in supplying various high-quality and durable industrial products, including:
- Agricultural gearboxes
- Power output shafts
- Sprockets
- Fluid couplings
- Worm gear reducers
- Gears and racks
- Roller chains
- Pulleys
- Planetary gearboxes
- Timing pulleys
- Bushings
Our products are available at preferential prices and come with considerate services. We welcome customers to submit their own drawings and samples for us to customize. Contact us today for a quote!
Frequently Asked Questions
What materials are used to make the Dia 270mm Module3.5 Teeth 62 Internal Gear?
The gear shaft is made from durable materials such as 20CrMnTi, 20CrMnMo, 42CrMo, 45#steel, 40Cr, and 20CrNi2MoA.
What is the heat treatment process used for this gear shaft?
The gear shaft undergoes various heat treatment processes such as carburizing and quenching, tempering, nitriding, carbonitriding, and induction hardening to achieve a hardness range of 58-62HRC.
Can I customize this gear shaft based on my own sample or drawing?
Yes, our gear model is customizable based on customer’s sample or drawing.
What quality standards does this gear shaft adhere to?
The gear shaft adheres to GB, DIN, JIS, and AGMA quality standards.
What shipping options are available for this gear shaft?
Shipping is available via sea, air, or express.
All the content of this page is from the Internet. The content is only for reference for product selection. Our products are replacement parts and not original spare parts. We are not the holder of the original trademarks mentioned in the content. Our replacement parts are only suitable for after-sales replacement and not as original spare parts. Our replacement parts can be perfectly adapted to the original spare parts. If you need to buy original spare parts, please contact the original factory.
Performance Characteristics of Internal Gear
Internal gear offers several performance characteristics that make it a valuable component in various applications. Firstly, its compact design allows for efficient power transmission in tight spaces. Secondly, the meshing of the gear teeth provides high torque capacity and smooth operation. Additionally, the internal gear’s ability to handle high loads and distribute stress evenly ensures its durability. Furthermore, its versatility allows for customization to suit specific application requirements. Lastly, the self-lubricating properties of internal gear reduce friction and extend its service life.
Types and Characteristics of Internal Gear
Internal gears can be classified into different types based on their tooth profile and application requirements. The most common types include spur, helical, herringbone, and double helical gears. Each type possesses unique characteristics that make it suitable for specific applications. For instance, spur gears are known for their simplicity and cost-effectiveness, while helical gears offer smoother and quieter operation. Herringbone gears provide improved load distribution and reduced axial thrust, making them ideal for high-load applications. Double helical gears, also known as herringbone gears, combine the advantages of helical and herringbone gears. They provide excellent load-carrying capacity and reduce gear noise.
Advantages of Internal Gear Materials
The choice of materials for internal gears greatly influences their performance and durability. Different materials offer varying advantages based on the requirements of the application. Steel internal gears are widely used due to their high strength and durability. They can withstand heavy loads and provide reliable performance. Cast iron internal gears offer excellent wear resistance and are suitable for applications where shock absorption is required. Additionally, nylon internal gears are lightweight, corrosion-resistant, and provide self-lubrication, making them ideal for applications with low noise requirements.
Application of Internal Gear
Internal gears find extensive applications in various fields, including Automotive Transmissions, Worm Gear Drives, Gear Pumps, Bicycles and Cycling Equipment, and Robotic Systems. In Automotive Transmissions, internal gears play a crucial role in transferring power from the engine to the wheels, ensuring smooth acceleration and efficient gear ratio changes. Worm Gear Drives utilize internal gears to achieve high torque transmission and self-locking capabilities. Gear Pumps employ internal gears to provide precise fluid displacement and efficient flow control. Bicycles and Cycling Equipment use internal gears for gear shifting and power transmission. Robotic Systems rely on internal gears for precise motion control and efficient power transfer.
Future Development Trends and Opportunities
The future of internal gear products looks promising, with several development trends and opportunities on the horizon. As technology advances, there is a growing demand for more compact and efficient gear systems, driving the need for innovative internal gear designs. The increasing focus on sustainability and energy efficiency also presents opportunities for the development of internal gears with reduced friction and improved performance. Furthermore, the expanding automation industry and advancements in robotics create a favorable environment for the application of internal gears in various robotic systems. Overall, the future holds immense potential for the continuous development and utilization of internal gear products.
Choosing a Suitable Internal Gear
Selecting the appropriate internal gear involves considering several key aspects. Firstly, the load requirements of the application must be carefully evaluated to ensure the chosen gear can handle the expected forces. Secondly, the gear ratio needs to be determined based on the desired speed and torque output. Material selection is crucial and should be based on factors such as strength, wear resistance, and corrosion resistance. Efficiency and backlash should also be taken into account to ensure smooth operation and minimal power loss. Additionally, mounting and space constraints should be considered when selecting an internal gear that fits within the available space.
In conclusion, internal gears offer exceptional performance characteristics, various types with unique advantages, and the ability to cater to different application requirements. Their extensive use across Automotive Transmissions, Worm Gear Drives, Gear Pumps, Bicycles and Cycling Equipment, Robotic Systems, and other fields highlights their value and importance. The future of internal gear products holds promising development trends and opportunities. When choosing a suitable internal gear, factors such as load requirements, gear ratio, material selection, efficiency and backlash, mounting, and space constraints should be carefully considered. By understanding these aspects, one can make informed decisions when selecting internal gears for their specific applications.
Author: Dream