Addressing Panelization Issues with Irregular Shapes and Structures
2 min
In production, JLCPCB has frequently had to process panel designs which have insufficient consideration for V-cutting. Simply tiling multiple boards together is suitable for uniformly sized and regularly shaped rectangular boards. However, for irregularly shaped boards with varying sizes, such a naive panel design is not feasible. Instead, it requires a consideration of the capabilities and requirements of the machines involved in production. Below, we will provide specific analyses using real-world examples to illustrate the shortcomings of these improper panel designs:
Case One:
In the example below, although fill-in have been added to surround the irregularly shaped board, there is no mechanical support at locations such as the upper left and lower left corners. Milling these areas leaves them suspended from one end, and when they pass through the V-cut machine, they deform. As a result, during the forming process, the uneven force distribution leads to a non-straight V-cut, causing scrap.
The correct panelization method, as shown below, eliminates this issue:
This image follows the same principle: the support points have a small load-bearing area, thus although the shape is different, as before, it is not suitable for V-cut.
Case Two:
In the image below, you might not immediately spot the issue, but this panelization is problematic. The details can be combined with the findings from Case One to identify the problem.
The correct panelization eventually involves adding tabs on the left and right sides to provide horizontal tension for the leftmost edge.
Let's take a look at another type of panelization, where the lack of horizontal balance leads to V-cut misalignment.
The image below represents the correct panelization, with the addition of extra process borders for support.
This image depicts the correct panelization approach, where V-cutting is avoided on the left and right sides, and instead, a routing (CNC) method is used for shaping.
Keep Learning
Design for Manufacturing and Assembly (DFMA): Optimizing Efficiency in Product Development
Design for Manufacturing and Assembly (DFMA) is an essential engineering tool that helps products be simpler to manufacture and assemble. DFMA enables businesses to reduce costs, prevent errors, and hasten product introduction, by combining the design and manufacturing processes. In areas such as electronics, automotive, aircraft, and consumer goods where exact and complex products are highly valued, this approach performs particularly effectively. highlighting fundamental ideas, advantages, and the b......
Design for Manufacturing (DFM): A Comprehensive Guide for Optimizing Production
Maintaining quality while improving the manufacturing process is critically important in the competitive fields of electronics and industry. Design for Manufacturing (DFM) here comes in handy. DFM is a design tool stressing the simplicity of manufacturing during the product development stage. Early on manufacturing limitations help DFM to guarantee that goods are not only useful but also reasonably priced, dependable, and easily produced at large-scale production. This article covers the importance of......
Understanding the Importance of DFM Analysis in PCB Design
Design for Manufacturing (DFM) analysis helps you on whether a printed circuit board (PCB) is fit for manufacturing, assembly, and sales. Early in the planning process, it looks for and fixes any possible problems arising throughout production. This will increase manufacturing efficiency and help to save expenses. DFM analysis is quite vital in the complex world of electronics, where even little design errors can create delays costing a lot of money. This article discusses the different types of DFM i......
Role of DFM Manufacturing in PCB Design
Design for Manufacturing (DFM) is crucial to make sure Printed Circuit Board (PCB) manufacture runs smoothly and fast. DFM manufacturing main focus is to makes PCBs as simple as feasible since it reduces errors, expenses, and production time. Engineers make a more stable product with fewer design-to-production problems when they think about manufacturing limitations during the design phase. This article will discuss about the basics of DFM manufacturing in PCB design, show why it is important, and giv......
SMT or Through Hole Technology?Which is Better for Your Project?
When designing and manufacturing electronics, one of the most important steps is selecting the appropriate assembly method. Nowadays we have through-hole technology and surface mount technology, which become the industry standards and are the two main approaches. The surface-mount technology (SMT) uses components that are perfectly aligned with the PCB surface. On the other hand through-hole technology (THT) uses leads that are placed into pre-drilled holes in the PCB and thereafter soldered. Consider......
FPC Panelization Design Standards and Requirements
FPC (Flexible Printed Circuit Board ) panelization is the process of arranging multiple FPC boards onto a single panel for efficient production. Proper panelization is crucial for optimizing material utilization, reducing production costs, and ensuring product quality. This article provides comprehensive FPC panelization design standards and requirements to guide engineers in creating optimal panel designs. General Panelization Guidelines Irregularly Shaped Frames: For irregularly shaped FPC frames, c......