It is estimated that a large number of people are already familiar with the technology of 3D printing; however, when it comes to the application of additive manufacturing technology, the majority of people may only stop at the following two stages:The process of printing through materials such as resin and plastic, as well as other non-metallic substances, is known as prototype manufacturing. Differentiate between prototypes and functional prototypes. In indirect manufacturing, the process of using 3D printing technology to first complete the manufacturing of tooling and molds, and then using those tooling and molds to manufacture parts, is called "indirect manufacturing. ".

As is common knowledge, with the advancement of 3D printing technology, in particular the progress of metal 3D printing technology in recent years, the application of additive manufacturing technology has expanded to include the direct manufacture of metal functional parts. Previously, the application of additive manufacturing technology was restricted to the appearance design of fast response products or the indirect manufacturing assisted by technology. At the moment, the technology of metal additive manufacturing is being utilized successfully in a growing number of industries, including the aerospace industry, the national defense industry, the medical equipment industry, automobile manufacturing, injection mold manufacturing, and a variety of other fields.

It is possible to say that the technology of metal additive manufacturing has reached a more advanced application stage within the manufacturing industry, and that it is the most valuable advanced manufacturing technology within the field of additive manufacturing for the manufacturing industry.

The technology of metal additive manufacturing can quickly produce parts that meet the requirements, and it has the injection molding china benefits of a short processing cycle, low manufacturing cost, and the elimination of the need for tooling and molds.

The high-energy beams, such as lasers and electrons, that are used in the metal additive manufacturing technology have a high density and a fast speed. This significantly increases the difficulty of the processing of metal materials, which in turn improves material utilization and lowers the cost of raw materials. The aerospace industry is a good example because it was the first and most widespread user of the technology known as metal additive manufacturing. In today's world, the application of medical devices is where the personalized manufacturing of metal additive manufacturing is currently seeing the greatest amount of success. On the one hand, it can be used to print implants and prostheses that meet specific individual requirements as well as complex structures that mimic bionic principles.

These implants are able to effectively realize the synchronous reconstruction of the external contour and internal structure as a result of the precise control provided by the technology of 3D printing. As a result, they are able to meet the high degree of matching required by the patient's local anatomy. Personalization and production in small batches have emerged as prominent trends in the manufacturing industry's most recent patterns of technological advancement. It has significant application potential not only in the medical device industry but also in a variety of other markets as well. In the past, damaged parts could only be repaired by surface coating. The repair process involved many steps, including some additional steps such as processing, polishing, testing, etc. , and was also limited by the repair time limit, which took a long time; And also can only do replacement processing for the slightly serious parts of damage. In modern times, surface coating is the only method that can be used to repair damaged parts.

The technology known as metal additive manufacturing can quickly form and repair any parts that are missing or damaged. For instance, the structures and prices of aerospace parts are very complex and expensive. Milling cutters are a common type of cutting tool that can be found in machining centers and milling machines. The term "universal tool" refers to an end milling CNC milling china tool that is the most common type of milling cutter. Knives that are capable of cutting workpieces efficiently along their flats, sides, grooves, and slits.

Cutting tools called drills are used for drilling, and they are frequently found in machining centers and drilling machines. There are many different drills, and they are subdivided into different categories based on the diameter of the hole and the depth of the hole. For example, there are oil hole drills, which can improve the chip removal efficiency, and long gun drills, which are suitable for deep holes. A tap is a type of cutting tool that is utilized in the process of thread cutting. When working with mechanical components that have a lot of threads, you can't do without this tool. When repairing holes in components that require a relatively high level of precision, such as those found in aircraft and automobile engines, a reamer is typically used. This helps to ensure that the repaired hole is accurate.

Gears and other toothed workpieces are typically processed with the assistance of specialized tools that CNC services are utilized on gear processing machinery such as hob hobbing machines and gear cutting machines. Diamond, tool steel, high-speed steel, and cemented carbide are some of the most common materials that are utilized in the production of cutting tools. Hardness and toughness are two important indicators of tools, which can vary from material to material and are typically chosen according to cutting scenarios and working conditions. Hardness and toughness are also important indicators of materials. The application of a coating is an essential component of surface treatment technology for tools. By coating a thin film on the surface of tools, it is possible to compensate for the inherent weakness of the tool materials.