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Jiangsu Nanyang Chukyo Technology Co., Ltd.


High-Quality Forged Solutions

Established in 2017, Jiangsu Nanyang Chukyo Technology Co., Ltd. covers an area of 42,000 square meters with a production area of 20,000 square meters. It has a current workforce of 240 employees and a comprehensive production chain covering mold processing, sawing, forging, heat treatment, machining, inspection, and packaging. Forged Components Company and Custom Forging Parts Factory in China. Currently, the company possesses nine forging production lines with an annual production capacity of 25,000 tons; five heat treatment production lines and two stainless steel solution equipment with an annual production capacity of 15,000 tons; as well as 34 machining CNC lathes and eight machining centers, producing 3 million pieces annually. Our products are widely used in automotive, engineering machinery, industrial instrumentation, and fluid equipment industry used in die forging parts. Precision Forging Services online.

Certificate Of Honor
  • ISO14001 2015 Certificate
  • ISO45001 2018 Certificate
  • NYCT IATF16949
  • NYCT ISO9001
  • PED Certificate
  • PED Certificate
Industry knowledge
How do forged components, such as gears and shafts, contribute to the performance and durability of a vehicle's transmission?
Forged components, such as gears and shafts, play a crucial role in enhancing the performance and durability of a Vehicle Transmission System Forging's transmission system in several ways:
Superior Strength: Forged components are known for their superior strength compared to components made by other methods like casting or machining. This strength allows forged gears and shafts to withstand the high loads and stresses experienced during transmission operation without deformation or failure.
Increased Fatigue Resistance: The forging process aligns the grain structure of the material, making it more resistant to fatigue failure. This is particularly important for gears and shafts that undergo repetitive loading cycles during normal driving conditions. The enhanced fatigue resistance of forged components contributes to their long-term durability.
Improved Wear Resistance: Forged components often have a dense and uniform microstructure, which results in improved wear resistance. Gears and shafts made through forging are less prone to wear and surface damage, ensuring prolonged service life and consistent performance over time.
Precise Dimensional Accuracy: The forging process allows for precise control over the dimensions and tolerances of components. This precision is critical for gears and shafts to mesh correctly and transmit power efficiently within the transmission system. Proper meshing reduces friction, heat generation, and power losses, thereby improving overall performance.
Optimized Material Utilization: Forging minimizes material waste compared to other manufacturing methods, as it utilizes the material's properties efficiently. This leads to components with optimized strength-to-weight ratios, contributing to lighter yet stronger gears and shafts that enhance the vehicle's overall performance and fuel efficiency.
Resilience to Harsh Conditions: Vehicle Transmission System Forging operate in varying conditions, including high temperatures, heavy loads, and extreme forces. Forged components are designed to withstand such harsh environments, maintaining their structural integrity and performance even under demanding driving conditions.
Reduction in Maintenance Requirements: The durability and wear resistance of forged gears and shafts reduce the frequency of maintenance and replacement intervals for the transmission system. This not only saves costs for vehicle owners but also ensures consistent performance and reliability throughout the vehicle's lifespan.

How do forgings help improve the efficiency and fuel economy of a vehicle's transmission system?
Forgings contribute to improving the efficiency and fuel economy of a Vehicle Transmission System Forging's transmission system in several ways:
Reduced Weight: Forged components are often lighter than their counterparts made using other manufacturing methods like casting or machining. The optimized design and material utilization in forgings lead to reduced weight without compromising strength or durability. Lighter components in the transmission system contribute to overall vehicle weight reduction, which is directly linked to improved fuel economy.
Enhanced Strength-to-Weight Ratio: Forgings offer a superior strength-to-weight ratio compared to components made through casting or machining processes. This means that forged gears, shafts, and other transmission components can handle the required loads and stresses while being lighter. The improved strength-to-weight ratio translates to reduced energy expenditure during operation, contributing to fuel efficiency gains.
Improved Friction Reduction: The precise dimensional accuracy and surface finish of forged components help reduce friction within the transmission system. Properly meshed gears and accurately aligned shafts experience less friction during operation, leading to lower energy losses and improved mechanical efficiency. Reduced friction also means less heat generation, contributing to overall energy savings.
Optimized Gear Ratios: Forged gears can be manufactured with precise tooth profiles and geometries, allowing for optimized gear ratios within the transmission. Properly matched gear ratios improve power transfer efficiency, enabling the engine to operate more efficiently at various speeds and loads. This optimization minimizes unnecessary energy consumption and improves fuel economy.
Durable Wear Resistance: Forged components, such as gears and shafts, are known for their excellent wear resistance and longevity. The reduced wear and minimal surface deformation of forged parts ensure consistent performance over time. This durability leads to less frequent maintenance, reduced downtime, and sustained efficiency in the transmission system, ultimately benefiting fuel economy.
Resilience to High Loads: Vehicle Transmission System Forgings often encounter high loads and stresses, especially during acceleration, towing, or uphill driving. Forged components are designed to withstand such loads without deformation or failure, maintaining optimal performance under demanding conditions. The ability to handle high loads efficiently contributes to overall fuel economy by ensuring smooth power delivery and reduced energy losses.