板金曲げ

Here’s a  step-by-step process of transforming flat metal sheets into precise, custom-shaped components with expert bending techniques

Material Selection

The first step is choosing the right metal for your project. Common options include aluminum, stainless steel, mild steel, and copper. Material thickness, strength, and flexibility are considered to ensure the part will withstand bending without cracking or deforming.

Design and CAD Modeling

Engineers create a precise 3D model of the component using CAD software. This design specifies bend angles, radii, and locations. It ensures that each bend aligns perfectly with the overall geometry and functional requirements of the part.

Machine Setup

The sheet metal is positioned on a press brake or CNC bending machine. For complex bends, appropriate tooling, such as V-dies or forming dies, is installed. CNC programming ensures that the machine applies the exact amount of force at the correct location.

Bending Execution

The sheet is shaped by applying precise, regulated force along the designated bend line. Depending on the design, multiple bends may be performed sequentially. CNC control ensures precision, often maintaining tolerances within ±0.5 mm.

Inspection During Bending

Parts are periodically checked for accuracy. Measurements are taken to confirm angles and dimensions. Adjustments are made in real time if minor deviations occur, ensuring consistent quality across all pieces.

Final Quality Check

Before delivery, every part is inspected to verify that all bends meet the required specifications and tolerances. Only parts that pass this strict quality control process are approved for shipment or assembly.

What Are the Common Challenges in Sheet Metal Bending and How Can It Be Prevented?

Sheet metal bending is essential for producing functional components, it comes with its set of challenges. Understanding these issues and implementing effective solutions ensures high-quality results for both prototypes and large-scale production.

Material Springback

Challenge: After bending, some metals tend to partially return to their original shape, known as springback, which can affect accuracy.
Solution: Engineers compensate for springback by overbending the metal slightly or adjusting the CNC program. Using metals with predictable elasticity, like stainless steel, also helps maintain consistent results.

Cracking or Fracturing

Challenge: Bending metals too sharply or using the wrong tooling can cause cracks, especially in harder materials.
Solution: Choosing the right material thickness, proper bend radius, and suitable tooling is essential for successful bending. Preheating certain metals can also improve flexibility.

Inconsistent Bend Angles

Challenge: Manual or improperly calibrated machines can produce inconsistent angles across multiple parts, affecting assembly and fit.
Solution: CNC-controlled press brakes provide precise, repeatable bends. Regular machine calibration and in-process inspections ensure all parts meet tight tolerances.

Surface Damage

Challenge: Sheet metal surfaces can get scratched, marred, or dented during bending.
Solution: Protective materials like plastic pads or special tooling coatings prevent surface imperfections. After bending, finishing processes like deburring or polishing are used to enhance and restore the metal’s surface quality.

Handling Complex Geometries

Challenge: Components with multiple bends, channels, or tight angles are difficult to form accurately.
Solution: Advanced CNC bending techniques, combined with simulation software, allow engineers to plan complex sequences and select appropriate tooling, ensuring precise results for intricate designs.