Detailed explanation of carbon fiber winding forming process

Filament Winding ist eine Fertigungstechnologie, bei der Endlosfasergarne aus Kohlenstoff verwendet werden, um eine rotierende Kernform zu umwickeln und mit Harz zu imprägnieren. Aufgrund ihrer hohen Effizienz und Festigkeitseigenschaften wird sie häufig bei der Herstellung von zylindrischen oder rotationssymmetrischen Verbundwerkstoffkomponenten eingesetzt.

1、 Overview of Carbon Fiber Winding Forming Process

The winding molding process forms a multi-layer structure on the core mold by controlling the tension, angle, and resin content of carbon fiber yarn. After curing, remove the core mold or keep it as part of the component, suitable for producing pipelines, pressure vessels, and shaft components. This process combines the advantages of automation and material optimization, and is an important means of lightweight design

Prozessmerkmale

• High efficiency: Suitable for mass production of rotating symmetrical components
• Strength optimization: The fiber winding angle can be adjusted according to the force requirements
• High material utilization rate: reduces waste and lowers costs
• High degree of automation: Precise control achieved through equipment

2、 Process flow of carbon fiber winding forming

Das Verfahren umfasst im Wesentlichen die folgenden Schritte:

1. Core mold preparation

Select or make a suitable core mold (usually metal or soluble material) and ensure its surface is smooth for winding and demolding

2. Fiber winding

After impregnating the carbon fiber yarn through a resin tank, it is wound at a specific angle (usually 0 ° to 90 °) on the core mold. The winding machine controls the fiber path and number of layers according to the design program

3. Curing process

After winding, place the core mold in an oven or at room temperature to cure, and the resin hardens to form a stable structure. The curing time depends on the resin type and component thickness

4. Demoulding and precision machining

After curing, remove the core mold (if it is a soluble core mold, dissolve it), trim, polish or coat the components to meet the final requirements

3、 Advantages and disadvantages of carbon fiber winding forming process

Vorteile

1. High strength: Optimized winding angle for excellent compressive and tensile performance of components
2. Efficient Production: Automated equipment shortens manufacturing cycle
3. Cost effectiveness: Suitable for the production of large diameter and long components
4. Design flexibility: Adjustable fiber direction to adapt to different loads

Benachteiligungen

1. Shape restriction: mainly applicable to rotationally symmetric components..
2. Equipment complexity: The design cost of winding machines and core molds is relatively high..
3. Difficult resin control: The resin distribution needs to be precisely adjusted during the winding process..

4、 Application fields of carbon fiber winding forming process

Dieses Verfahren ist aufgrund seiner einzigartigen Vorteile weit verbreitet:

Pressure vessels: such as gas storage tanks and rocket propellant tanks..

Pipeline system: such as chemical pipelines and water treatment pipelines..

Sports equipment: such as fishing rods and golf clubs..

Aerospace: such as missile shells and satellite antenna brackets.

5、 Zukünftige Entwicklungstrends

With the development of intelligent control and new resin materials, the carbon fiber winding molding process will achieve higher automation and efficiency. Combining 3D printing technology to manufacture complex core molds and real-time monitoring of fiber tension will further enhance component quality and application scope.

6、 Zusammenfassung

The carbon fiber winding molding process has become the core technology for manufacturing rotationally symmetric composite components due to its efficient production and high strength characteristics. Although its shape has limited applicability, this process has shown great potential in fields such as pressure vessels, pipelines, and sports equipment by optimizing winding angles and automation equipment. Future technological advancements will drive it to occupy an important position in more high-performance applications.