Top rated stamping car parts factory: Progressive Die Stamping in Automotive Manufacturing – Progressive die stamping is a method widely used in the automotive industry to produce complex parts efficiently. In this process, a metal strip moves through a series of stations within a single press. Each station performs a specific operation—such as cutting, bending, or punching—until the final shape is achieved. This continuous motion allows for high-speed production with minimal material waste. Progressive die stamping is ideal for small to medium-sized components like brackets, clips, and reinforcements that require multiple forming steps. Because all operations occur within one die set, the process reduces handling time and ensures uniform quality across large batches. Although initial tooling costs can be high, the long-term efficiency and precision make progressive stamping highly cost-effective. The method’s ability to produce consistent, high-quality parts at scale makes it an essential part of modern car manufacturing systems. See additional info at stamping car parts.
The main frame of the high-rigidity machine tool is equipped with a slider balance device, a machine foot shock absorber and an emergency braking device, which not only ensures the safety of stamping technicians, but also ensures the accuracy of machine production and protects the service life of the punch and mold; it also It is equipped with a full set of auxiliary supporting devices, such as commonly used high-precision gap feeding devices, balancing devices, vibration reduction and noise reduction devices, to ensure its stamping performance. It has extremely high stamping accuracy and feeding accuracy. The stamping accuracy of each high-speed punch press can reach the accuracy standard, and the feeding accuracy can reach ±0.01~0.03mm, which is beneficial to improving the positioning accuracy of the work steps and reducing damage to equipment or molds caused by inaccurate feeding.
Fortuna has more than 20 years of experience in product stamping and mold processing, and has extremely professional capabilities. Our mold processing uses slow wire cutting and grinding machine processing equipment imported from Japan. The tolerance of mold processing parts can reach 0.002mm, and the overall mold processing tolerance can reach 0.02mm. Our engineers have outstanding professional abilities. They all have more than 10 years of experience in the field of mold design, and are also proficient in Solid work, Pro/E, UG 3D software and CAD and other drawing softwares.
The stamping process is generally divided into forming and separation processes. Fortuna is mainly customized and designed through customer drawings. It generally goes through 10 steps such as DFM Evaluation, Mold Design, Mold Assembly, Sample Submission, and Mass Production to achieve a project. After stamping and forming, we will also perform electroplating, heat treatment, tapping, riveting and other processes on the product according to customer needs to ensure that the product will not be oxidized, deformed and other product defects. Our company currently has 70 stamping equipments, most of which are high-precision equipment imported from Japan. The main brands are Chin Feng, AOMATE, Aida, DOBBY, etc. Read additional info on https://www.dgmetalstamping.com/.
After we receive the customer’s drawings, professional engineers will conduct DFM analysis of the product. Design feasibility analysis: Evaluate the feasibility of the mold design, including mold materials, structure and processing technology. By analyzing whether the mold design meets the existing technical conditions and process capabilities, determine its feasibility and provide suggestions for improvement. Manufacturability analysis: Conduct multi-dimensional analysis on the drawings provided by customers to provide customers with a variety of achievable, cost-reducing and efficiency-increasing stamping solutions while ensuring the functional structure of the product.
Part Complexity and Geometries – Complex designs can significantly impact CNC machining time and cost. Simplifying part geometries where possible can lead to more efficient machining. However, complex parts are often necessary, especially in high-tech applications. For complex parts, consider using multi-axis CNC machines that can handle intricate shapes and features. Designing with these capabilities in mind can lead to more efficient and cost-effective manufacturing.
Dimensional Control and in-Process Inspection – Poor fit, leaks, or premature failure are caused by dimensional errors. In-process inspection enables the right manufacturer to have deviation control. Seek to find calibrated gauges, CMM systems, and well-documented control plans. Copper is soft and thus is exposed to danger when handling. Good suppliers take into consideration post-form distortion or springback. Not only should final dimensions be measured in routines, but also flatness, wall thickness, and the position of holes. Surface Finish and Contamination Control – Copper surfaces may be very susceptible to damage due to handling. Scratches, fingerprints, or tool marks can lower conductivity and cause oxidation of copper. Enquire about how the manufacturer secures the finishes during and after forming. They must make use of clean benches, copper-specific tooling, and be packaged in sealed conditions. This is important in electrical components, refrigeration coils, or braised joints.