Product Description
Product Description
We provide high precision manufacturing services for CNC machining/ forging /metal fabrication…
all parts can be produced according to customer’s drawings and designs.
Forgings including: mold forging , free forging, smith forging,open die forging, hot forging, cold forging.
Forging shape:Forged gear,Forged block,Forged flange,Forged ring,Forged shaft.
Product Parameters
| Production parameters | |
| Materials | alloy steel, carbon steel, stainless steel, quenched and tempered steel, aluminum, copper |
| Heat treatment | normalizing, annealing, quenching and tempering, surface quenching, induction quenching |
| Mechanical processing | CNC turning, CNC milling, CNC boring, CNC grinding, CNC drilling |
| Gear processing | hobbing, gear milling, CNC gear milling, gear cutting, spiral gear cutting, |
| nspection | Chemical composition testing, ultrasonic testing, penetration testing, radiographic testing,Magnetic testing, tensile strength testing, impact testing, hardness testing, size testing. |
| Test | Magnetic testing, tensile strength testing, impact testing, hardness testing, size testing.Chemical composition testing, ultrasonic testing, penetration testing, radiographic testing, |
| Main markets | United States, Australia, Malaysia, Israel, United Kingdom, Russia, Canada, etc. |
| Data parameters | |
| Gear module | 8-120 |
| Maximum value for gear grinding | Module 24 |
| Shaft diameter: maximum | 2 200mm |
| Axis length: maximum | 13000 millimeters |
| Gear diameter | MAX.13 000 mm |
| Spiral gear diameter | maximum. 2200mm |
| Gear shaft length: maximum | . 5000 millimeters |
Technical process
Detailed Photos
Packaging & Shipping
Certifications
Our Advantages
Excellent service attitude, fast response speed, on-time delivery, and excellent after-sales service have been our practices since the beginning. Combined with high credit, competitive prices, close interaction with customers, and innovative working methods, we have won more and more business and excellent customer satisfaction.
Choosing us as your business partner would be the most correct choice for you.
FAQ
Q: Is it possible to know how are my products going on without visiting your company?
A: Yes, it is. After the cooperation is reached, we will plan a perfect production solution for you. The Quality inspection team will track the production process and give regular feedback on the production progress to you. Our factory will also provide pictures and videos at any time. We can also let you see the real status of the order production through video calls.
Q: Will my drawings be safe after sending them to you?
A: Sure. We have a strict privacy policy and will protect each customer’s information. It will only be given to the person you designate with your permission.
Q: Are you a trading company or factory?
It is worth mentioning that our entire production process is controlled independently and there is no outsourced processing. This means that every step from raw material procurement, forging processing, heat treatment to finished product delivery is strictly controlled by us. Through refined management and cost control, we are able to provide customers with more competitive prices while ensuring product quality.
/* January 22, 2571 19:08:37 */!function(){function s(e,r){var a,o={};try{e&&e.split(“,”).forEach(function(e,t){e&&(a=e.match(/(.*?):(.*)$/))&&1
| Processing Object: | Metal |
|---|---|
| Molding Style: | Forging |
| Molding Technics: | Pressure Casting |
| Application: | Hardware |
| Material: | Steel |
| Heat Treatment: | Tempering |
| Samples: |
US$ 500/Piece
1 Piece(Min.Order) | |
|---|
| Customization: |
Available
| Customized Request |
|---|
How do you choose the right type of aluminum alloy for specific applications?
Choosing the right type of aluminum alloy for specific applications involves considering various factors. Here’s a detailed explanation:
1. Mechanical Properties: Assess the required mechanical properties for the application, such as strength, hardness, toughness, and wear resistance. Different aluminum alloys offer varying levels of these properties. For example, 2000 series alloys are known for their high strength, while 6000 series alloys offer a good balance of strength and formability.
2. Corrosion Resistance: Evaluate the environmental conditions the aluminum alloy will be exposed to. Some alloys have better corrosion resistance, making them suitable for applications in corrosive environments. For instance, 5000 series alloys are known for their excellent corrosion resistance.
3. Formability: Consider the required formability and ease of fabrication. Certain aluminum alloys, like 1000 and 3000 series, have excellent formability, making them suitable for applications that involve complex shapes or intricate designs.
4. Heat Treatability: Determine if heat treatment is necessary to achieve the desired mechanical properties. Some aluminum alloys, such as 7000 series, are heat-treatable and can be strengthened through heat treatment processes like solution heat treatment and aging.
5. Weight: Evaluate the weight requirements of the application. Aluminum alloys have lower density compared to many other metals, making them ideal for lightweight applications where weight reduction is critical, such as aerospace or automotive industries.
6. Cost: Consider the budget and cost constraints of the project. Different aluminum alloys have varying costs based on factors such as availability, production processes, and alloying elements. Balancing the desired properties with the project’s budget is important.
7. Compatibility: Ensure that the chosen aluminum alloy is compatible with other materials or components in the application. Compatibility includes factors such as galvanic corrosion potential, thermal expansion coefficients, and joining methods.
8. Industry Standards: Check if there are specific industry standards or regulations that dictate the use of particular aluminum alloys for certain applications. Industries such as aerospace, automotive, and marine often have specific alloy requirements based on performance and safety standards.
9. Consult Experts: When in doubt, consult with material engineers, metallurgists, or industry experts who have expertise in aluminum alloys. They can provide valuable insights and guidance based on their knowledge and experience.
Considering these factors in combination with the specific requirements and constraints of the application will help in choosing the right type of aluminum alloy. It’s important to note that selecting the most suitable alloy may involve trade-offs between different properties and considerations.
In summary, selecting the right type of aluminum alloy for specific applications involves assessing mechanical properties, corrosion resistance, formability, heat treatability, weight requirements, cost, compatibility, industry standards, and seeking expert advice. Taking a comprehensive approach ensures that the chosen aluminum alloy meets the performance, durability, and cost objectives of the application.
How do aluminum gears handle shock and impact loads?
Aluminum gears can effectively handle shock and impact loads. Here’s a detailed explanation:
1. Material Strength: Aluminum alloys used for gears exhibit good strength properties, allowing them to withstand sudden shock and impact loads. While aluminum is not as strong as materials like steel, proper gear design and material selection can ensure that aluminum gears meet the required load-bearing capacity for specific applications.
2. Flexibility and Ductility: Aluminum possesses inherent flexibility and ductility, which can help absorb and distribute impact forces. When subjected to shock or impact loads, aluminum gears can deform slightly to dissipate energy and reduce the risk of immediate failure. This characteristic allows aluminum gears to handle sudden and high-intensity loads without catastrophic damage.
3. Resilience: Aluminum gears have a certain degree of resilience, meaning they can recover their original shape after experiencing deformation from shock or impact loads. This resilience allows aluminum gears to continue functioning effectively even after encountering transient high loads.
4. Design Considerations: Proper gear design is crucial for handling shock and impact loads effectively. Engineers can incorporate features such as reinforced tooth profiles, optimized gear geometry, and appropriate surface treatments to enhance the strength and durability of aluminum gears. These design considerations help distribute stress evenly across the gear teeth, minimizing the risk of localized failures.
5. Load Distribution: Aluminum gears can distribute shock and impact loads over a larger contact area, reducing the concentration of stress on individual gear teeth. This load distribution capability prevents localized stress points and helps prevent premature tooth wear or breakage.
6. Surface Treatments: Surface treatments like shot peening or case hardening can be applied to aluminum gears to enhance their resistance to shock and impact loads. These treatments introduce compressive stresses on the gear surface, improving its fatigue strength and resistance to crack initiation and propagation caused by sudden loads.
7. Compatibility with Other Components: Aluminum gears can be designed to work in conjunction with other components in the system to handle shock and impact loads. By considering the overall system dynamics and ensuring compatibility between gears, bearings, shafts, and housing materials, the entire system can better absorb and distribute impact forces, improving its overall resilience.
8. Testing and Validation: Aluminum gears undergo rigorous testing and validation processes to ensure their performance under shock and impact loads. These tests simulate real-world operating conditions, including sudden impacts and high-intensity loads, to assess the gear’s durability and reliability. Manufacturers rely on these tests to verify that aluminum gears can handle the expected shock and impact loads in specific applications.
In summary, aluminum gears handle shock and impact loads through their material strength, flexibility, ductility, resilience, design considerations, load distribution capability, surface treatments, compatibility with other components, and validation through testing. By employing appropriate design practices and material selection, aluminum gears can reliably and effectively handle sudden and high-intensity loads in various applications.
Are there different types of aluminum alloys used for making gears?
Yes, there are different types of aluminum alloys used for making gears. Here’s a detailed explanation:
1. Aluminum-Copper Alloys: Aluminum-copper alloys, such as the 2000 series (e.g., 2014, 2024), are commonly used for gears. These alloys offer good strength and excellent fatigue resistance, making them suitable for gears subjected to moderate to high loads. They also exhibit good machinability, which facilitates gear manufacturing processes.
2. Aluminum-Silicon Alloys: Aluminum-silicon alloys, particularly the 4000 series (e.g., 4032), are used for gears requiring high wear resistance and low friction. These alloys have good mechanical properties and can withstand high contact pressures. They are often used in applications where gears operate in harsh conditions or require self-lubrication.
3. Aluminum-Zinc Alloys: Aluminum-zinc alloys, such as the 7000 series (e.g., 7075), are known for their high strength and excellent fatigue resistance. These alloys are commonly used in aerospace applications where lightweight gears with exceptional strength are required. However, they may have lower machinability compared to other aluminum alloys.
4. Aluminum-Magnesium Alloys: Aluminum-magnesium alloys, including the 5000 series (e.g., 5052, 5083), offer a good combination of strength, corrosion resistance, and weldability. These alloys are suitable for gears exposed to marine or corrosive environments. They are also commonly used in general machinery and equipment manufacturing.
5. Aluminum-Zinc-Magnesium Alloys: Aluminum-zinc-magnesium alloys, such as the 7000 series (e.g., 7049), provide an excellent balance of strength, corrosion resistance, and lightweight properties. These alloys are used in high-performance gears, particularly in industries like aerospace and motorsports.
6. Other Alloy Combinations: There are also specialized aluminum alloys tailored for specific gear applications. For example, aluminum-tin alloys are used for gears requiring excellent wear resistance and dimensional stability. These alloys are often employed in automotive applications.
It’s important to note that the selection of the aluminum alloy depends on the specific requirements of the gear application, including load conditions, wear resistance, corrosion resistance, temperature, and manufacturing considerations. Each alloy has its own unique properties and advantages, allowing gear manufacturers to choose the most suitable alloy for their specific needs.
In summary, different types of aluminum alloys, such as aluminum-copper, aluminum-silicon, aluminum-zinc, aluminum-magnesium, aluminum-zinc-magnesium, and specialized alloy combinations, are used for making gears. The choice of alloy depends on factors such as strength requirements, wear resistance, corrosion resistance, and specific application considerations.
editor by Dream 2024-04-30