China high quality Customized Sintered Metal Iron Alloy Inner Rack Double Spur Gear hypoid bevel gear

Product Description

Complicated Micro Metallurgy Sintered Metal Spur Engranaje Helicoidal Drawing Helical Double Gear

 

Item Name Helical Double Gear
Model No. /
Material Alloy powder
Process Power Metallurgy

1. Our products passed TS16949 ISO-9001: 2000 quality management system verification
2. We own exquisite and advanced equipment, professional technical designer and rich producing experience
3. We can produce different size and shapes base on your drawing and samples. 
4. Best quality, competitive price, shortest delivery time and good service. 
5. Products are widely used at automotive part, textile machine, sewing machine, gasoline generator, power tools, oil pump rotor, clutch, oilless bearing, cu base products, stainless steels and so on. 
6. If you are interested in our products and our company, please kindly let us know what you need, please donot hesitate to contact with us. 

Technological process
Powder metallurgy is a kind of processing method which uses metal powder as raw material to make various products by pressing and sintering. Powder metallurgy process consists of 3 main steps. First, the main material is decomposed into many fine particles; Then, the powder is put into the mold cavity, and a certain pressure is applied to form a compact with the required shape and size of the part; Finally, the compact was sintered.

The essential advantage of P / M parts production process is that it has the final forming ability and high material utilization rate.

Our team

Our Factory

Application: Machinery
Hardness: Hardened Tooth Surface
Gear Position: Internal Gear
Manufacturing Method: Sintered Gear
Toothed Portion Shape: Spur Gear
Material: Alloy Powder
Samples:
US$ 0.5/Piece
1 Piece(Min.Order)

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Customization:
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epicyclic gear

Can you explain how an epicyclic gear system handles torque distribution?

An epicyclic gear system, also known as a planetary gear system, is designed to handle torque distribution in an efficient and effective manner. Here’s a detailed explanation:

An epicyclic gear system consists of three main components: the sun gear, planet gears, and the ring gear. Each of these components plays a specific role in torque distribution:

1. Sun Gear:

The sun gear is the central gear in the system and receives torque input. It is typically connected to the power source, such as an engine or motor. The sun gear transfers torque to the other components of the system.

2. Planet Gears:

The planet gears are mounted on a carrier and rotate around the sun gear. They mesh with both the sun gear and the ring gear. The planet gears distribute torque between the sun gear and the ring gear, facilitating power transmission.

3. Ring Gear:

The ring gear is the outermost gear in the system and has internal teeth that engage with the planet gears. It is typically connected to the output shaft and transfers torque to the desired output, such as wheels in a vehicle or a generator in a wind turbine.

Here’s how the torque distribution works in an epicyclic gear system:

1. Torque Input:

The torque input is applied to the sun gear. As the sun gear rotates, it transfers torque to the planet gears.

2. Torque Distribution:

The planet gears receive torque from the sun gear and distribute it between the sun gear and the ring gear. Since the planet gears are meshed with both the sun gear and the ring gear, torque is transmitted from the sun gear to the ring gear through the planet gears.

3. Torque Multiplication or Reduction:

The torque distribution in an epicyclic gear system can be configured to provide either torque multiplication or torque reduction, depending on the arrangement of the gears. For example, if the sun gear is held stationary, the planet gears can rotate around the sun gear, causing the ring gear to rotate at a higher speed with increased torque. This configuration provides torque multiplication. Conversely, if the ring gear is held stationary, the sun gear can rotate, causing the planet gears to rotate in the opposite direction, resulting in torque reduction.

4. Even Torque Distribution:

An advantage of using an epicyclic gear system is that it facilitates even torque distribution among the planet gears. The multiple planet gears share the load, which helps distribute torque evenly across the gear system. This even torque distribution minimizes stress concentration on individual gear teeth, reducing wear and improving overall durability and reliability.

In summary, an epicyclic gear system handles torque distribution by transferring torque from the sun gear to the planet gears, which then distribute it between the sun gear and the ring gear. This configuration allows for torque multiplication or reduction and ensures even torque distribution among the planet gears, resulting in efficient power transmission and reliable operation.

epicyclic gear

How do epicyclic gears maintain smooth operation during gear shifts?

Epicyclic gears, also known as planetary gears, are designed to maintain smooth operation during gear shifts. Here’s a detailed explanation:

1. Overlapping Engagement:

During gear shifts, epicyclic gears often utilize overlapping engagement, which means that multiple gears are engaged simultaneously for a brief period. This overlapping engagement allows for a gradual transition of torque from one gear to another, reducing sudden shocks or impacts that can cause jerky movements or noise.

2. Synchronizers or Clutches:

In certain applications, synchronizers or clutches are used in conjunction with epicyclic gears to facilitate smooth gear shifts. Synchronizers help match the speeds of the gears being engaged, while clutches enable gradual engagement and disengagement of gears. These mechanisms ensure that the gear shifts are seamless and minimize any jolts or vibrations.

3. Controlled Torque Transfer:

Epicyclic gears allow for controlled torque transfer during gear shifts. By manipulating the arrangement of the gears, such as holding a specific gear stationary, the torque can be gradually transferred from one gear to another. This controlled torque transfer helps maintain smooth operation during gear shifts.

4. Proper Gear Design:

The design of epicyclic gears plays a crucial role in maintaining smooth operation during gear shifts. Factors such as gear tooth profile, backlash, and clearance are carefully considered to minimize any sudden changes in contact and minimize gear meshing noise. Well-designed gears ensure smooth and efficient power transmission during gear shifts.

5. Lubrication and Damping:

Effective lubrication of the gear system helps reduce friction and wear during gear shifts. It also aids in damping vibrations and noise generated during the shifting process. Proper lubrication and damping techniques ensure smooth operation and minimize any disturbances during gear shifts.

6. Precise Manufacturing and Assembly:

Precision manufacturing and assembly of epicyclic gears are essential for maintaining smooth operation during gear shifts. Accurate gear tooth profiles, tight manufacturing tolerances, and precise gear alignment help ensure proper gear meshing and minimize any irregularities that can cause jolts or noise during gear shifts.

In summary, epicyclic gears maintain smooth operation during gear shifts through overlapping engagement, the use of synchronizers or clutches, controlled torque transfer, proper gear design, lubrication and damping techniques, as well as precise manufacturing and assembly. These factors work together to ensure seamless gear shifting, minimize shocks or impacts, and provide a smooth and comfortable driving experience in various applications.

epicyclic gear

How does an epicyclic gear differ from other types of gears?

An epicyclic gear, also known as a planetary gear, exhibits several distinguishing features that set it apart from other types of gears. Here’s a detailed explanation of the differences:

1. Gear Arrangement:

An epicyclic gear system consists of a central sun gear, multiple planet gears, and an outer ring gear, also known as the annular gear. This arrangement differs from other gear types like spur gears, helical gears, or bevel gears, which typically involve meshing between two parallel or intersecting shafts.

2. Gear Motion:

The motion of an epicyclic gear system is characterized by the planet gears rotating while simultaneously orbiting around the sun gear. This combination of rotational and orbital motion is unique to epicyclic gears and allows them to achieve different gear ratios and functions.

3. Gear Ratios:

Epicyclic gears offer a wide range of gear ratios by varying the engagement of the sun gear, planet gears, and annular gear. This versatility in gear ratios is not typically found in other gear types, which often have fixed ratios determined by the number of teeth on the gears.

4. Compactness:

Epicyclic gears are known for their compact design. The arrangement of the gears allows for a relatively large gear reduction or multiplication within a compact space. This compactness makes them suitable for applications where space is limited, such as in automotive transmissions.

5. Functions and Applications:

Epicyclic gears offer various functions beyond basic speed reduction or increase. They can achieve torque multiplication, directional changes, and braking capabilities, providing versatility in mechanical systems. These unique functions make epicyclic gears well-suited for applications ranging from automatic transmissions and power tools to robotics and aerospace systems.

6. Complexity:

Compared to simpler gear types like spur gears, epicyclic gears can be more complex and require precise design and manufacturing. The interaction between the sun gear, planet gears, and annular gear involves multiple points of contact, requiring careful consideration of gear profiles, clearances, and alignment.

In summary, an epicyclic gear stands out from other types of gears due to its specific gear arrangement, motion characteristics, versatile gear ratios, compactness, unique functions, and complexity. Its ability to provide multiple gear ratios and perform various functions makes it a valuable choice in many mechanical systems.

China high quality Customized Sintered Metal Iron Alloy Inner Rack Double Spur Gear hypoid bevel gearChina high quality Customized Sintered Metal Iron Alloy Inner Rack Double Spur Gear hypoid bevel gear
editor by CX 2023-09-13