Machining: Sheet Metal Punching Technology

 

1. Precision requirements: In the automotive field, especially in the processing of automobile Chassis, the precision requirements of sheet metal punching are extremely high. The parts of the automobile chassis require precise hole positions and sizes to ensure accurate assembly and good performance between the various parts. For example, the suspension system mounting holes and brake system pipeline holes on the chassis, if the punching accuracy deviates, it may cause serious problems such as instability and brake failure during driving. However, in actual processing, due to the uneven material of the sheet, thickness tolerance and the precision limitation of the stamping equipment, it is easy to cause deviations in the punching position and inconsistent hole size. This is an important technical difficulty faced by sheet metal punching in the automotive field.

2. Die loss: Die wear during the punching process is also a problem that cannot be ignored. The die is the core tool for sheet metal punching. After long-term use, the punch and die of the die will gradually wear out due to frequent stamping friction. Die wear will not only affect the quality of punching, resulting in increased surface roughness of the hole wall and larger or smaller hole diameters, but also reduce the service life of the die and increase production costs. Especially in mass production, the problem of die wear will be more prominent.

3. Material deformation: During the punching process, sheet deformation is also a common technical difficulty. When the punch punches the sheet, the sheet is subjected to local pressure and is prone to deformation such as bending and warping. For some thinner or complex-shaped sheet metal parts, this deformation problem is more serious and may affect subsequent processing procedures and product performance.

 

1. In order to improve the punching accuracy, strict quality inspection of the sheet is required before processing to ensure that its material is uniform and its thickness meets the requirements. At the same time, high-precision stamping equipment and advanced mold manufacturing technology are used to improve the accuracy of the mold and the stability of the equipment. In addition, by optimizing the stamping process parameters, such as stamping speed, pressure, etc., the deviation of the punching position can also be reduced. In actual production, CNC punching technology can also be used to accurately control the position and size of the punching through computer programming to achieve high-precision punching processing.

2. For the problem of mold wear, we can choose high-quality mold materials to improve the hardness and wear resistance of the mold. At the same time, the mold is reasonably designed and optimized to reduce the friction and stress concentration of the mold during the stamping process. During the production process, the mold is regularly maintained and maintained, and the Mold Parts with severe wear are replaced in time. In addition, mold surface treatment technology, such as coating treatment, can also be used to reduce the friction coefficient between the mold and the plate and extend the service life of the mold.

3. In order to solve the problem of plate deformation, the plate can be properly pretreated before punching, such as annealing, to reduce the hardness of the plate, improve its plasticity and toughness, and reduce the possibility of deformation. During the punching process, the mold structure is reasonably designed, and the appropriate stamping sequence and process method are adopted to minimize the local force of the plate. For example, step-by-step punching and hedging can be used to balance the force of the sheet and reduce the degree of deformation. In addition, the sheet can be shaped after punching to correct the deformed part and ensure the quality of the product.

 

In today's rapidly developing intelligent industry, we can also use intelligent technology to solve the technical difficulties in sheet metal punching. For example, sensors are used to monitor parameter changes in the stamping process in real time, such as pressure, temperature, mold wear, etc., and process parameters are adjusted in time through intelligent control systems to achieve automated production control and quality optimization. At the same time, through big data analysis and simulation technology, the punching process can be optimized and predicted, potential problems can be discovered in advance, and corresponding measures can be taken to improve production efficiency and product quality.

 

Although the direct application of sheet metal punching is relatively small in the field of life sciences, sheet metal punching may also be involved in the manufacture of some Medical Equipment and instruments. For example, punching is required on the shell or structural parts of some medical equipment to meet functional requirements such as ventilation, heat dissipation, and installation. In these applications, it is also necessary to pay attention to issues such as punching accuracy and sheet metal deformation to ensure the quality and performance of medical equipment.

Although there are some technical difficulties in sheet metal punching, we can find effective solutions through continuous technological innovation and optimization. With the continuous advancement of science and technology, it is believed that sheet metal punching technology will be more widely used and developed in various fields, making greater contributions to the development of the manufacturing industry. Whether in chassis processing in the automotive field or in applications in other industries, we can expect the emergence of more efficient, precise and reliable sheet metal punching technology.